DE1152851B - Combustion process for use in combustion chambers of jet engines or rockets and jet engine or rocket to carry out the process - Google Patents

Description

GERMAN

PATENT OFFICE

S 62784 Ia / 46g

REGISTRATION DATE: 27. A P R I L 1959

NOTICE
THE REGISTRATION
AND ISSUE OF THE
EDITORIAL: AUGUST 14, 1963

The planning of missiles with high flight speeds leads to the choice of high ejection speeds (i.e. specific impulses) and large mass ratios.

It should be remembered that under the term "specific impulse" that refers to the weight of the Fuel in kilograms related product of the thrust in kilograms and the operating time the rocket can be understood in seconds. Furthermore, under the expression "mass ratio" comes the ratio between the sum of the masses of the fuel and the oxygen carrier on the one hand and the Understood the sum of the masses of the empty rocket, the fuel and the oxygen carrier on the other hand.

The high ejection speeds require the use of very hot ejected gases, low molecular weight and high relaxation ratio.

The achievement of considerable mass ratios ao is achieved through the use of very dense fuels and oxygen carriers.

The rocket fuels must therefore meet the following theoretical requirements:

1. a high upper calorific value (to achieve a considerable temperature before expansion);

2. A high density of substances before the reaction in the rocket's combustion chamber;

3. a low density of the emitted gases.

A combustion process has now been found for use in combustion chambers of jet engines or rockets, in which liquid oxidants, in particular atomized HNO ₃ and liquid fuels based on lithium and hydrocarbons, are brought to an exothermic reaction, known disadvantages can be avoided if in the built-in combustion chamber, two specific and spatially separate reactions are caused at the same time: the first with a strong development of combustion heat in the axial zone of the combustion chamber, caused by the injection of metallic, liquid lithium, the injection jets of which intersect in a manner known per se with the atomized jets of the oxidizing agent , the other with relatively low heat of combustion and the first enveloping in the circumferential zone along the inner wall of the combustion chamber, brought about by combustion processes known per se for use

in combustion chambers of jet engines

or missiles and jet engines or

Rocket to carry out the procedure

Applicant:

Societe Nationale d'Etude

et de Construction de Moteurs d'Aviation,

Paris

Representative: Dr.-Ing. H. Negendank, patent attorney,
Hamburg 36, Neuer Wall 41

Claimed priority:
France of December 15, 1958 (No. 781 835)

Roger Adrien Feraud, Epinay-sur-Orge,

and Robert Oscar Aider, Saint Mande (France),

have been named as inventors

Injection of kerosene, the injection jets of which are mixed with the jets of oxidizing agent cross.

A special embodiment is that the liquid lithium to form a per se known, mainly eutectic alloy sodium and potassium is added, which is injected will.

In the case of the jet engine or the rocket in which the method according to carries out the invention is useful for receiving the liquid lithium or the alloy a thermally insulated container is provided, which is used to inject these liquid fuels into the Combustion chamber is connected to a pump for liquid metal.

A certain number of simple bodies, which develop a large amount of heat when burned, can be performed in the following manner in the order of decreasing heat generation per unit weight of the fuel:

309 667/92

3 kCaVkg
of the
encountered
Fabric body Combustion reaction
with oä 5410 beryllium Be + 1/2 O ₂
= BeO + 135.9 kCal 4760 lithium 2Li + 1 / 2O ₉
= Li ₂ O "+ 142.8 4000 boron 2B + 3 / 2O ₂
= B ₂ O ₃ + 280 3720 aluminum 2Al + 3 / 2O ₂
= Al ₂ O ₃ + 380 3600 magnesium Mg + 1/2 O,
= MgO + 144

The walls of the rocket can be cooled in a simple known manner, e.g. B. in that the oxygen carrier is placed in the throat of the nozzle before it is injected into the interior of the chamber and the jacket surrounding the wall of the combustion chamber can flow.

The disadvantage of the spontaneous oxidation of lithium in the air can easily be avoided in this way be that you cover it with a thin layer of ίο oil or a silicone-containing substance.

The invention is explained below by way of example with reference to the drawing single figure shows a longitudinal section of a missile according to the invention.

The wall 1 (made of metal or a temperature-resistant material) of the combustion chamber and the Nozzle neck, which on the one hand to the

In addition to its high heating base of the chamber forming flange 2 and anwert, the lithium has the following advantages: on the other hand, on the diverging part 3 of the nozzle, its melting point is relatively low 20 closes, is surrounded by a jacket la, which Roo γλ “η K ^ o "f λ ™ i * no r """"" ν * ™ Λ _η between it and the wall 1 an annular space Ib

manufactures. The line coming from the pump for supplying the nitric acid is connected to the connecting piece 4 connected to the annular space Ib. The nitric acid therefore flows in countercurrent between the walls 1 and la, cools the wall 1, whereby it heats up, emerges from the space Ib through the nozzle 5 and reaches the nozzle 6, which through the bottom of the rocket into the combustion chamber no difficulty makes 30 chamber worked out channels with in this floor. distributed multiple nozzles 7 are connected. For

Regarding the auxiliary combustion with lower simplification of the drawing, these channels are not Heat of reaction, the inventor has found that shown, and the nozzles 7 for injection of the

kerosene is expediently used for this, and that ~ * ~ ~

by changing the relative amounts of kerosene and Lithium obtained a great adaptability

(180 ° C) and can be lowered to around 150 ° C when used with potassium and sodium in small amounts is alloyed. Furthermore, because of its high heat of fusion, it can be kept in a liquid state more easily will.

The technique of pumps for molten metals is currently being applied at Atomic piles known so that the manufacture of a pump for the injection of the molten lithium

Nitric acid are indicated by squares.

The wall 1 of the chamber can be porous, so that some nitric acid seeps into the chamber, the evaporation of which takes place on the inner surface of this wall then causes additional cooling.

The molten lithium alloy is fed to the flange 8 by a pump, which through channels in the bottom of the chamber with injection nozzles 9 distributed over the central part of the bottom connected is. These nozzles are shown in the drawing by small circles.

The kerosene or other fuel used to produce a temperature below combustion of the lithium lying combustion temperature is conveyed by a pump to the nozzle 10,

b) kerosene or another in another ⁵ ° ^which through channels with liquid grains embedded on the periphery of the container (hy-bottom of the chamber located injection nozzles 11

' · - - connected is. These nozzles for injecting the

Kerosene are represented by small triangles.

The nozzles 7 for injecting the oxygen carrier can have injection directions which from those of the fuel nozzles 9 and 11 are different, as shown by the arrows to the To facilitate mixing of the substances to be injected and to improve the homogeneity of the combustion Mixture has a specific impulse of 60 favorable.

of 300 seconds, i.e. a very large ejection.

speed. maintained combustion temperatures of kerosene,

The temperature of the combustion gases is high. which are of the order of 3000 ° K, The mean temperature is about 4000 ° K, are lower than those in the central part while maintaining the real temperatures between 65 nen temperatures of lithium (in the size-3200 and 4400 ° K Hegen. Order of 4700 ° K).

The handling and nature of the die resulting from the temperature gradient

Oxygen carriers are commonplace these days. The difference in viscosity, the difference

can which the appropriate choice of the temperature of the exiting gases and the specific weight this allows mixed gases.

According to the invention, for. B. The following substances are injected into the combustion chamber of the rocket:

1. Oxygen carrier: NO ₃ H, which can be acidic.

2. Fuels:

a) previously melted and in a container provided with a thermal protection embedded mixture of Li + Na + K;

drazin, xilidine, aromatic amines, etc.).
The following composition is recommended:

NO ₃ H 71 »/ 0

Li + Na + K 23%

Kerosene 6%

the chemical nature of the gases and the longitudinal component of the flow velocity prevent the Temperature compensation.

The wall of the chamber is thus covered by the protective screen formed by the low temperature zone Protected against excessive thermal loads.

In addition to this protective effect, there may also be the cooling effect of the flow of the oxygen carrier and its evaporation in the case of porous walls. One can get such an effective protection, without having to accept a great loss of energy, which affects the thermal efficiency would have an adverse impact. The mixed injection specific impulse is only little less than that of lithium alone. There are rocket combustion chambers with openings to the Injection of the reactant for the second, hot exothermic reaction are already provided known.

With the known methods and devices, however, it is not possible to carry out the two reactions develop a different heat of combustion, without a special, separating partition nor is it possible to deduce from this that liquid lithium is being injected can. It is only known to use metal powder as a suspended admixture to liquid hydrocarbons injected, the known engines have a partition and beyond only one combustion reaction takes place, which takes place inside the partition.

Alkali or alkali borohydrides, such as. B. LiBH ₄ , recommended for recoil propulsion in water. The use of a separate oxidizing agent, of the nitric acid type, is new, however, and it was by no means to be deduced from the previously known that the propulsion can be stimulated in a simple manner by using two different fuels or combustion methods.

Claims (3)

PATENT CLAIMS: 1. Combustion method for use in combustion chambers of jet engines or rockets, in which liquid oxidants, in particular atomized HNO ₃ and liquid fuels based on lithium and hydrocarbons, are brought to an exothermic reaction, characterized in that two specific and spatial at the same time in the built-in combustion chamber Separate reactions are caused: the first with a strong development of heat of combustion in the axial zone of the combustion chamber, caused by the injection of metallic, liquid lithium, the injection jets of which intersect in a manner known per se with the atomized jets of the oxidizing agent, the other with relatively low heat of combustion and the first enveloping in the peripheral zone along the inner wall of the combustion chamber caused by injection of kerosene, known per se, the injection jets of which intersect with jets of the oxidizing agent. 2. Combustion method according to claim 1, characterized in that the liquid Lithium sodium and potassium are added to form a known, predominantly eutectic alloy that is injected. 3. Jet engine or rocket, in which or in which the method according to claim 1 or 2 is carried out, characterized in that for taking up the liquid lithium or the alloy, a thermally insulated container is provided for injecting it liquid fuel in the combustion chamber is connected to a liquid metal pump. Considered publications: British Patent Nos. 738 219, 727 720,
807;
U.S. Patent Nos. 2,763,987, 2,754,656; Wehrtechnische Monatshefte, 55th year, issue 8 (August 1958), pp. 344 to 354; Industriekurier, supplement "Technology and Research" 11th year, issue 79 (19) from May 28, 58, p. 304;
Zeitschrift des VDI, Volume 99, No. 31 (1.11. 57), p. 1587; Volume 97, No. 3 (1. 1. 55), p. 68; Flight, Volume 70, No. 2501 (12/28/56), p. 998; Business Week, Issue 1394 (May 19, 56), p. 105; E. Schmidt, "Introduction to Technical Thermodynamics", 4th edition, Springer-Verlag,
Berlin 1950, pp. 306 to 314; H. Meyer, "Textbook of the mechanical technology of machine building materials" 8th edition, Jänecke-Verlag, Leipzig 1938, pp. 81 to 83 and 320, 321. 1 sheet of drawings