DE1446917C1 - Rocket propulsion system using combustion chamber-bound solid propellants - Google Patents

Description

Solid rocket engines are so essential for certain areas of application compared to liquid propulsion systems Advantages that they cannot be easily replaced by liquid thrusters. Solid propulsion but have the disadvantage that, after firing, their burning behavior, d. H. for example in their thrust or their burning time, can no longer be changed, and a regulation is no longer feasible during the flight due to the burning properties.

Therefore, solid propellant charges must be designed for their precise purpose before they are used what by choosing a suitable solid propellant, a favorable pressure working range and a corresponding nozzle.

But the form of the propellant has a decisive influence on the flight characteristics, so that you have a essential moment in the design of the missile comes.

All solid propellants have in common that certain parts of the surface are affected by combustion must be excluded so that this progresses in a very special direction, the one before has been calculated, and that the other burn-up parameters are not influenced in an impermissible manner.

This insulation can be designed in such a way that it burns slowly with the propellant, in order not to generate any undesired gas flows or to change the clamping, sometimes the Insulations are designed so that they are retained and certain parts, e.g. B. the chamber wall, against protect from excessive heating.

A large number of propellant charge profiles have now been proposed by means of which get most of the tasks done. The internal burner constructions take a preferred place because this is accompanied by a simultaneous thermal insulation of the missile chamber.

The methods carried out so far consisted in that a propellant insulates on its outer surface and then inserted into a missile case and anchored there. The propellant mounts require a certain constructive effort. In addition, the propellant must be processed and to be isolated. Likewise, the solid propellant must have so great a mechanical strength that it remains dimensionally stable at higher temperatures.

A second method is that the propellant is no longer isolated as such, but into the chamber is introduced and connected to it there in such a way that the chamber wall acts as an insulation itself. The advantage This method consists in the fact that the chamber wall supports the propellant and that a special one Bracket is not required. The propellant body must, however, be seamlessly connected to the chamber wall, see above that the ignition and burning flame has no opportunity to strike between the chamber wall and the propellant.

The manufacture by the Casting process in which the propellant body is shaped and cured in the rocket chamber will.

An extraordinarily great disadvantage of this method, however, is that they generally differ large thermal expansion coefficients of the chamber wall and the propellant body large stresses Changes in temperature occur which are not readily affected by the propellant charge without tearing can be caught. To counter this tension, proposals have already been made, one introduce a thin insulating layer between the chamber wall and propellant charge, which is relatively elastic and which should be able to balance the tensions. But it has been shown that especially with double-base solid propellants, the nitroglycerin contained in the powder very easily into this intermediate layer can immigrate and thereby impair the strength and the adhesion in an inadmissible manner.

It has now been shown that especially for double-base powder propellants and propellant charges that are next to Oxygen-supplying salts contain double-base powder components as a binding material between powder and Combustion chamber wall containing polybutadienes containing carboxyl groups are eminently suitable. Regarding them Production is z. B. on the USA. Patent 31 08 994, British Patent 8 31 061 and Chemical and Eng. News, 1.8.1960, p. 35.

These polybutadienes, which preferably have terminal carboxyl groups and a molecular weight of about 5000 have an extremely high adhesive strength both to metal surfaces and to Powders or composite propellants and have an elongation that takes all the stresses that occur offset allowed. In addition, this binding material is elastic at very low temperatures, without that cold brittleness occurs, and last but not least, the immigration of nitroglycerin is extremely low, so that the properties of the binder course do not change.

In order to obtain the desired rubber-elastic products, the carboxylated polybutadienes still be networked, which z. B. can be carried out with polyepoxides or polyazaridines. Essential is the presence of several reactive azaridine groups, which are attached to any system can be bound.

The insulating compounds can be mixed with solids and / or with additional liquid components, as

olks come ζ. B. in question minerals, inorganic ; Chemical or organic salts, organic polymers, liquid extenders and plasticizers.

The solid fractions produced according to the invention are distinguished by particular storage stability ms and have advantages over the types previously used. Likewise, the above-described remain Advantages of the chamber-bound propellant charges, such as shielding the surface from burning, Support of the propellant charge by the chamber wall and elimination of the holding device.

The chamber-bound rocket propellants produced by the method according to the invention can can be manufactured using the following methods:

Prefabricated powder propellants are pre-insulated by applying a layer, e.g. B. by filling a filled binder layer or a hardened insulating compound and curing, into the missile chamber pushed and the remaining thin gap filled with liquid reaction mixture and subsequently hardened. The binder layer can also be produced directly in the combustion chamber, whereupon the propellant charge with a A thin layer of liquid material was painted over, pushed in and the liquid layer was subsequently hardened will. In addition, the propellant can be brought into the missile chamber; the liquid reaction resin is sucked in or injected and hardened by heat treatment

Combustion chamber-bound casting POL propellant charges can be produced in that in the with the Insulating compound pretreated combustion chamber, the powder casting compound is introduced into the combustion chamber is cured. The bond is made directly to the polybutadiene layer.

example

A missile chamber 1.50 m long and 11 cm inner diameter is exactly horizontal on a Trolley mounted and set in rotation about its axis.

Into the combustion chamber, which is provided with a 5 mm thick ring made of polyvinyl chloride on both sides becomes a mixture of

564 g polybutadiene with a molecular weight of 5000-5500,

which carries carboxyl end groups, and
36 g phosphoroxytriaethyleneimine

brought in. The combustion chamber is ^{heated to about 120 °} C. by air heating. After about 2 hours, the insulating compound is completely crosslinked and has reached its maximum strength and elongation. A casting powder mixture can now be poured into this pretreated combustion chamber using the usual method and cured in the combustion chamber.

Claims (4)

Patent claims: 1. Rocket propulsion system using case-bonded solid propellants from or with 2-base powder components, characterized in that the solid propellant in the combustion chamber through a binding intermediate layer of crosslinked, carboxyl-containing polybutadienes is cemented. 2. rocket propulsion system according to claim 1, characterized by the use of networked Polybutadienes with terminal carboxyl groups. 3. rocket propulsion system according to claims 1 and 2, characterized by the use of carboxyl group-containing polybutadienes which are crosslinked with polyepoxides or polyazaridines. 4. rocket propulsion system according to claims 1 to 3, characterized in that the binding Interlayer as a filler or as an admixture, minerals, inorganic or organic salts, contains organic polymers, liquid extenders and / or plasticizers.