RU2245511C1 - Method for destruction of charges of solid propellant - Google Patents

Abstract

FIELD: rocketry.

SUBSTANCE: the method for destruction of charges of solid propellant or its fragment located in the body of the rocket engine consists in filling of the charge cavities with refrigerant - waterhelium composition based on polyacrylamide and burning up of the charge. The waterhelium composition based on polyacrylamide is prepared by separate introduction of aqueous solutions of the components of the redox system of solidification-potassium bichromte and sodium thiosulfate in equal volume of aqueous solution of polyacrylamide, and the cavities of the charge are filled by synchronous feeding of the obtained volumes through a mixing head, after that solidification is performed.

EFFECT: provided controlled burning up of charges.

2 dwg, 2 tbl, 1 ex

Description

The invention relates to methods for eliminating charges of solid rocket fuel (TRT) by combustion, mainly to methods of burning channel charges TRT directly in the housing of rocket engines.

A known method of eliminating charges TRT / Occupational safety in industry No. 9, 1988, p.46-52 / by the method of burning, which consists in burning the charge from the housing in open areas. In this case, the combustion products TRT freely flow out of the body and dissipate in the atmosphere. The disadvantage of this method is the infliction of great environmental damage.

In the method of burning bulky charges on a stand, the combustion products are cooled by water, collected in a large volume tank and neutralized. The disadvantage of this method is the large second consumption of combustion products and large heat dissipation / Express information. Engineering News, No. 23, 1974, p.9 /.

The known method / patent of the Russian Federation 2021560, class. F 02 K 9/08, 10/15/94 / regulated combustion of charges TRT, which allows the use of stands of small capacity, equipped with gas treatment plants, when burning large charges, including defective ones. The effect is achieved due to the use of water or aqueous solutions of salts as a coolant supplied to the free volume of the charge casing. The disadvantage of this method is the need for the vertical arrangement of the charge of the TRT and continuous supply of refrigerant during the combustion process to compensate for its rapid evaporation, as well as the need to use sophisticated equipment to treat the surface of the charges with ultrasound in order to enhance the phlegmatizing ability of the refrigerant.

For the prototype, the authors chose a method for eliminating solid rocket fuel charges / RF patent No. 2123991, MKI 6 C 06 V 21/00, F 42 B 33/00, F 42 D 5/04 04 /, the essence of which is the burning of TPT charges placed in the body of a rocket engine, or a fragment of a charge using a refrigerant, while a water-gel composition is used as the refrigerant. Gelling agents are carboxymethyl cellulose (CMC), polyacrylamide (PAA), gelatin, agar-agar, guargam, etc., as well as mixtures thereof. The composition of the refrigerant can be added additives that neutralize the harmful components of the combustion products. The refrigerant is applied to the TPT surface by spraying, spreading or dipping. The method allows for delayed controlled burning of TPT charges, including defective ones. The disadvantages of the method include the following: the effect of high temperatures on the gelling agents during the charge burning process can lead to destruction of the gel structure, disruption of the contact surface with solid fuel, leakage of the composition from the housing and thereby upsetting the regulation of the charge combustion process.

An object of the invention is to develop a method that allows for slow, controlled burning of TPT charges with phlegmatization of the charge surface with a refrigerant - a gelling composition that preserves structural characteristics during combustion.

The technical result is achieved in a method of eliminating a charge of solid rocket fuel or a fragment thereof placed in a rocket engine housing, including filling charge cavities with a refrigerant — a water-gel composition based on polyacrylamide — and burning a charge, so that a water-gel composition based on polyacrylamide is prepared by separate introduction of aqueous solutions of the components of the redox curing system - potassium dichromate and sodium thiosulfate in equal volumes of an aqueous solution with polyacryls and, filling the cavities carry charge received synchronous feed volumes through the mixing head, after which the curing is carried out at a temperature of 5-25 ° C and pH 5,3-7,5 environment. The polyacrylamide used as a gelling agent has a molecular weight of not less than 1 · 10 ⁶ and a degree of hydrolysis of 10-40 mol.%. Cr ³⁺ chromium is used as a hardener of polyacrylamide, which is formed as a result of a redox reaction between the components of the curing system: potassium dichromate and sodium thiosulfate, expressed by the equation

4K ₂ Cr ₂ O ₇ + 3Na ₂ S ₂ O ₃ + 13H ₂ O = 3Na ₂ SO ₄ + 3K ₂ SO ₄ + 2KOH + 8Cr (OH) ₃

The operational properties of the water-gel composition are determined by the survivability and time of approval. Survivability - the time during which the composition remains mobile on the surface of the solid fuel, ensuring its full wettability and a given adhesive strength. Curing time - the period after which the water-gel composition, poured into a vessel simulating the shape of the filled volume, does not give a meniscus when it is rotated through 180 °. Vitality and curing time of the water-gel composition is a function of acidity (pH) and temperature.

Example 1. The survivability of the polyacrylamide composition, consisting of a 3.15% aqueous solution of PAA and components of the curing system with a ratio of sodium thiosulfate (reducing agent) to potassium dichromate (oxidizing agent) by weight 2.37: 1 depending on the pH of the medium at a temperature of + 25 ° C and + 5 ° C are presented graphically in figure 1. Dependencies are asymptotically ascending and descending branches with plateau areas in the pH range of 5.8-7.5 (25 ° C) and 5.3-6.8 (5 ° C).

The dependence of the curing time and survivability on environmental parameters is shown in the examples presented in table 1, the component composition of the water-gel composition of which corresponds to example 1.

Indicators Example 2 3 4 5 6 7 8 PH environment 7.8 7.0 6.0 5.8 7.0 6.5 5.3 Temperature ° C 25 25 25 25 5 5 5 Vitality, min 120 40 thirty fifteen 90 40 fifteen Curing time, hour 24 16 thirteen 8 thirty twenty 12

The mechanical characteristics of the cured aqueous gel compositions under compression are shown in Table 2.

table 2 Example Mechanical indicators Voltage, σ, kg / cm ² Relative strain, ε,% The compression modulus, E, kg / cm ² 2 0.009 0.22 0,040 3 0.009 0.23 0,039 4 0.009 0.22 0,040 5 0.009 0.22 0,040 6 0.009 0.23 0,039 7 0.009 0.22 0,040 8 0.009 0.23 0,039

The above examples show that lowering the pH environment reduces the curing time of the water-gel composition, while the level of mechanical properties does not change. However, at the same time, the survivability of the composition decreases, which imposes a time limit on the charge filling of the refrigerant. Filling of selected cavities (gaps, separate areas of the channel, the ends of the charge with a refrigerant - water-gel composition, is carried out portionwise by fragments with the composition curing before pouring the next portion. The choice of the optimal ratio between the survivability and curing time of the composition is determined by the geometric characteristics of the charge and is selected taking into account the data are given in table 1. To ensure the possibility of working with water-gel compositions having low survivability, the components of the curing system are introduced separately in equal volumes polyacrylamide solution. Entry components is carried out in the form of aqueous solutions, the concentration of which is defined at a selected temperature limiting solubility of potassium bichromate process is most soluble component.

Schematic diagram of the preparation of a water-gel composition and filling of free charge cavities is presented in figure 2. Hydrolysis, neutralization of the PAA solution to the desired pH of the medium is carried out in tank 2, from which the compressed air (compressor 9, receiver 1) is dosed with equal volumes in tank 3, 4, where it is mixed with the components of the curing system, then two synchronized flows by pumps 7, 8 through shut-off valves 11, 12 it is supplied to the mixing head 13 and, using a telemetry manipulator 14 with a micro-camera 15, enters the selected charge cavities 16. A trap 1 is used to catch ammonia vapors released during the hydrolysis of the PAA solution 0. Cleaning the premises and the area from the straits after preparing the water-gel composition and filling them with charge cavities is carried out in a vacuum collector 5 using a vacuum pump 6.

Verification of the proposed method with positive results was carried out when burning a horizontally installed bulky charge from TRT. The gap gap of the charge was filled with a cured PAA gel at an acidity of 6.5-7.0 and a temperature of 8-10 ° C. The survivability of the composition was ≈30 minutes, the curing time of 20 hours. When the charge is burned, stable combustion is achieved with a decrease in the burning time corresponding to the calculated value.

Claims (1)

A method for eliminating a charge of solid rocket fuel or a fragment thereof located in a rocket engine housing, comprising filling charge cavities with a refrigerant - a polyacrylamide-based water-gel composition - and charging a charge, characterized in that the polyacrylamide-based water-gel composition is prepared by separately introducing aqueous solutions of the oxidation and oxidation components recovery curing system - potassium dichromate and sodium thiosulfate - in equal volumes of an aqueous solution of polyacrylamide, filling cavities with the charge is carried out by synchronously supplying the volumes obtained through the mixing head, after which curing is carried out at a temperature of 5-25 ° C and pH values of 5.3-7.5.

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