DE102010034848B4 - Dual fuel engine - Google Patents

Abstract

Dual-fuel engine based on cryogenic liquefied gases, in particular attitude control engine, with an ignition device, characterized in that the ignition device consists of a catalyst unit (5) in the form of an electrically heated cartridge or pill made of a ceramic or metal material having a surface coating is provided from polycrystalline platinum, and that the catalyst unit (5) in a separate from the main combustion chamber (1) of the drive and thermally decoupled secondary chamber (4) is arranged.

Description

The invention relates to a dual-fuel engine based on cryogenic liquid gases, in particular a position control engine, with an ignition device according to the preamble of patent claim 1.

In attitude control engines operating at short intervals, i. In so-called pulse-mode, operated, there is a special requirement to achieve a high spontaneity when igniting. Liquid acted on dual-fuel engines have the advantage of an automatic ignition, a property of the so-called hypergolen fuel-oxidizer mixtures. The still known monopropellant engines based on anhydrous hydrazine have the advantage of high spontaneity of ignition of the hydrazine decomposition reaction upon contact of the hydrazine with noble metal catalysts. The same applies to "green", i. so-called environmentally friendly monopropellant fuels, which have become known as "High Performance Green Propellants" (HPGP).

• - Förderung der kryogenen Flüssiggase mit Druckerhöhung,
• - Anhebung des thermodynamischen Zustandes auf einen „trockenen“ Dampfzustand,
• - Gemisch-Regelung eines konstanten, quasistöchiometrischen Massenstromes beider Gase trotz schwankender Gasdichten,
• - zuverlässige und spontane Zündung des unter Umständen tiefkalten Brenngas-Gemisches auch im Intervall-Betrieb (Pulse-Mode).

Dual-fuel engines based on cryogenic liquefied gases, eg liquid hydrogen (LH2) and liquid oxygen (LOX), do not ignite "hypergol", but require an ignition device that works even under deep cold conditions. In such engines, starting from the storage state of the cryogenic liquid gases (LH2 = liquid hydrogen and LOX = liquid oxygen), the following steps are required to achieve an ignitable gas mixture:

• Promotion of cryogenic liquefied gases with pressure increase,
• Raising the thermodynamic state to a "dry" vapor state,
• - Mixture control of a constant, quasi-stoichiometric mass flow of both gases despite fluctuating gas densities,
• - Reliable and spontaneous ignition of the possibly low-temperature fuel gas mixture in the interval mode (pulse mode).

By a high ignition speed to prevent gas mixture amounts unburned be released and that it comes in the case of a delayed ignition to an explosion of large, already released H ₂ / O ₂ gas mixture volumes. Basically, such mixtures of hydrogen and oxygen, ie explosive gas collections, which are located outside of the combustion chamber, must be avoided, otherwise damage to both the engine and components in its environment can not be avoided.

Prior art is known from the US 2008/0 264 327 A1 and from the DE 694 18 213 T2 known. The US 2008/0 264 372 A1 describes a method and apparatus for igniting a gas mixture. For this purpose, a small amount of the fuel mixture is ignited in a control stage to a control flame and passed to a main stage. In the main stage, the control flame ignites the fuel mixture, which is then used to drive. In the main stage, the use of a platinum-containing catalyst is preferred. In the control stage, a heterogeneous Group VIII metal, such as platinum, is used to ignite the fuel mixture. The DE 694 18 213 T2 discloses a process for the catalytic oxidation of hydrocarbons. In particular, in this case the use of a mixture of a hydrocarbon and an oxygen-containing gas is catalyzed and admixed with a sulfur-containing compound in order to reduce the amount of ammonia formed and hydrogen cyanide.

The object of the invention is to provide an engine of the type mentioned in such a way that even for cryogenic fuel gas mixtures an ignition process with high reliability and spontaneity is guaranteed.

The object is achieved by a two-component engine with the features of claim 1. The ignition device consists of a catalyst unit in the form of an electrically heated cartridge or pill of a ceramic or metal material, which is provided with a catalytically highly active surface coating of polycrystalline platinum. The catalyst unit is arranged in a separate chamber from the main combustion chamber.

The invention is based on the fact that with the use of vapors cryogenic liquefied gases, even after an increase in the internal energy and the vapor pressure of the gases by supplying heat admitted into such an engine gas mixture is still very cold, but dry, ie free of condensate. Since low temperatures have a direct effect on the catalytically activated ignition behavior of a fuel gas, in order to obtain a high spontaneity of the ignition process, a minimum temperature must be maintained at the catalyst surface, which necessitates permanent temperature control for the catalyst surface. The fact that in the engine according to the invention, the catalyst unit is not only provided with a catalytically highly active surface coating of polycrystalline platinum, but that they are also separated from the primary fuel gas stream in a laterally to the main Combustion chamber is arranged side chamber, these requirements are met.

The inventive design of the catalyst unit can be achieved for mixtures of hydrogen and oxygen, an extremely high ignition speed. The platinum is a very effective catalyst material, in particular in that it is used in the form of finely divided polycrystalline platinum with a very high specific surface, which, as of black color, also called platinum Mohr and that in this form is applied to the surface of the catalyst unit.

The reactivity or reaction rate of the catalytic process depends on the surface temperature of the catalyst. While spontaneously ignites the combustion reaction of hydrogen with air or pure oxygen in the range of room temperature, the ignition is increasingly delayed at lower temperatures until no ignition occurs at the end, since the heat generated during the catalytic reaction process flows into the environment and not sufficient to sufficiently increase the local temperature of the gas and the catalyst surface. The catalytic ignition of hydrogen with air or with pure oxygen is already known in principle from the so-called Döbereiner lighter, but not the temperature effect.

According to the invention, the catalyst unit is arranged separately from the primary fuel gas stream in a side chamber lying laterally to the main combustion chamber. This arrangement of the catalyst unit prevents the surface temperature of the catalyst unit is lowered so much due to their very low heat capacity by the very cold gas flow that they can no longer provide the required ignition energy and their ignitability would thus at least significantly reduced. However, since the catalyst unit according to the invention is arranged in a side chamber separate from the main combustion chamber, a less strong cold gas flow arrives at the catalyst surface for ignition and spontaneous ignition takes place in the first moment of the gas contact from this secondary chamber with a subsequent restrike in the fuel gas flow of the main combustion chamber. Additionally, in the engine of the invention, the catalyst unit is isolated from the surrounding, usually cryogenic, engine mass for the purpose of thermal decoupling, further reducing the need for electrical heating power. Once the engine according to the invention has sufficiently warmed up in operation, can be dispensed with an electrical heating of the catalyst unit.

In an advantageous further embodiment of the invention, the catalyst unit is equipped with redundant heating coils, also can be provided for redundancy reasons and to achieve a parallel Zündmöglichkeit a multiple arrangement of such catalyst units.

Another way of igniting the main gas flow is given in an advantageous embodiment of the invention in that a Zündfackel is generated from the ignition chamber out. This ignition torch is charged with a mixture of separately admitted gases, i. the fuel gas (GH2) and the oxidizer (GOX) operated. The ignition takes place on the hot surface of the catalyst unit, then the ignition torch is permanently maintained during the entire period of a position control action and provides a high ignition energy. In an advantageous embodiment of the invention, this Zündfackel arrangement can also be provided redundant and multiple for parallel operation.

The advantages of the invention consist in a spontaneous ignition of cryogenic H ₂ / O ₂ gas mixtures, in their redundancy, in the possibility of multiple ignition and in that there may be no ignition delay or misfires, since a cooling of the catalyst unit from the outset is excluded. In addition, the need for electrical energy is reduced to the controlled maintenance of the minimum surface temperature, with hot engine there is also no need for electrical energy.

Below, the engine according to the invention with reference to an embodiment shown in the drawing will be explained in more detail. The figure shows a schematic representation of the structure of an engine with catalytic igniter.

The dual-fuel position control engine based on cryogenic liquefied gases shown in the figure with a main combustion chamber 1 is with inlets for the fuel gases, ie one inlet each 2 for the liquid fuel, in this case gaseous hydrogen (GH2), and an inlet 3 for the oxidizer, in this case gaseous oxygen (GOX) equipped. In a side chamber 4 is a catalyst unit in the form of a cartridge 5 arranged, via an electrical heating connection 6 features. Further, in the case of the embodiment described herein, in the sub-chamber 4 an additional inlet 7 for a separate supply of the catalyst unit 5 provided with fuel gases.

The catalytically activated spontaneous ignition of a fuel gas, which consists of an ignitable gas mixture of, for example, and oxygen (GOX), requires a minimum temperature based on the contact region of the fuel gas mixture with the catalyst surface. In this zone, the cold gas mixture meets with its heat capacity and the surface of the catalyst unit 5 with their heat capacity on each other and it creates an average temperature in the boundary layer, which must not fall below a minimum value in order to maintain a minimum reaction rate. After ignition of the fuel gas mixture is released by the reaction enthalpy of the combustion reaction, a high energy, which keeps burning as ignition torch ignition of the main fuel gas flow.

Claims (3)

Dual-fuel engine based on cryogenic liquefied gases, in particular attitude control engine, with an ignition device, characterized in that the ignition device consists of a catalyst unit (5) in the form of an electrically heated cartridge or pill made of a ceramic or metal material having a surface coating is provided from polycrystalline platinum, and that the catalyst unit (5) in a separate from the main combustion chamber (1) of the drive and thermally decoupled secondary chamber (4) is arranged. Engine after Claim 1 , characterized in that the catalyst unit (5) is equipped with redundant heating coils. Engine after Claim 1 or 2 , characterized in that a multiple arrangement of catalyst units (5) is provided.

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