RT Journal Article ID 55bbbe2e7080001b A1 Lukin, Alexander T1 THE ADVANCED TECHNOLOGY OF PREVENTION OF THE ANOMALOUS COMBUSTION REGIMES DEVELOPMENT IN THE SUBMARINE'S BALLISTIC ROCKET WITH LARGE-SIZED SPRM JF International Journal of Energetic Materials and Chemical Propulsion JO IJEMCP YR 2002 FD 2002-01-01 VO 5 IS 1-6 SP 116 OP 131 K1 submarine ballistic rockets K1 large-sized SPRM K1 ignition system K1 intrachamber processes K1 anomalous ignition regimes K1 impact and vibrational loads K1 new ignition technology K1 ignition system design schemes AB An important direction of the modern submarine ballistic rockets (SBR) top stages solid propellant rocket motor (SPRM) improvement is investigation of methods of optimal organization of the intrachamber processes development at the SPRM ignition-transient period of operation with the purpose of reduction of impact and vibrational loads on the rocket and its systems. The main peculiarity of the structural diagrams of SBR top stages propulsion systems is that the case-bonded charge with internal channel has a partially non-fastening and unarmored end-face surface in the vicinity of the head end. The thickness of the non-flowing clearance (stagnation zone) between the SPRM casing head end internal surface and the charge end-face surface can increase in 20−100 times at the operating pressures in the combustion chamber (5−10) MPa. In a number of cases, operation of the above mentioned engine can occur in abnormal mode. An anomalous mode of ignition and combustion in the beginning of the SPRM combustion chamber can serve the non-estimated action from the pyrotechnic ignition system (IS). Such a non-calculated effect results in non-uniformity of the course of working processes during the propellant charge ignition. In the course of filling the intrachamber volume with combustion products (CP) coming from the IS and from the already ignited part of the charge, the boot from the engine casing and from the charge may break off. The numerical study of the physicochemical processes subsequent to the boot break off is conducted. Executed calculations demonstrate that the ignition in an abnormal mode appearance in the SPRM described above can be prevented. The appropriate technology for the prevention of the solid propellant charge anomalous ignition regimes was developed. This technology provides uniformity of the SPRM operation during the ignition-transient period by means of the CP selection, coming from the IS, both in space orientation and in time. For practical realization of new ignition technology, two special SPRM IS design schemes were developed. PB Begell House LK https://www.dl.begellhouse.com/journals/17bbb47e377ce023,76f8e14974df93a8,55bbbe2e7080001b.html