Shock Initiation Of Pbx 9502 At Elevated Temperatures




Temperature-dependent Shock Initiation of TATB-based High Explosives

Author :

Publisher :

Page : 9 pages

File Size : 21,92 MB

Release : 1993

Category :

ISBN :

Get eBook

Book Description

The effects of temperature on the shock sensitivity of two TATB formulations PBX 9502 and LX-17 are studied over the temperature range -54°C to 252°C. The shock Hugoniot curves over this same temperature range are developed. Thermal expansion properties and porosities are used to help determine the mechanisms of thermal sensitization. Impact sensitivities over the range from ambient to 300°C are reported. Analyses of these results imply that thermal sensitization is the result of purely chemical kinetics enhancement and intracrystalline hot-spot growth. Additional results on the ambient shock sensitivity of PBX 9502 and LX-17 following thermal cycling to 252°C and back to ambient is presented.



Shock Initiation Experiments on Ratchet Grown PBX 9502

Author :

Publisher :

Page : pages

File Size : 23,4 MB

Release : 2010

Category :

ISBN :

Get eBook

Book Description

This study compares the shock initiation behavior of PBX 9502 pressed to less than nominal density (nominal density is 1.890 ± 0.005 g/cm3) with PBX 9502 pressed to nominal density and then ''ratchet grown'' to low density. PBX 9502 is an insensitive plastic bonded explosive consisting of 95 weight % dry-aminated tri-amino-tri-nitro-benzene (TATB) and 5 weight % Kel-F 800 plastic binder. ''Ratchet growth'' - an irreversible increase in specific volume - occurs when an explosive based on TATB is temperature cycled. The design of our study is as follows: PBX 9502, all from the same lot, received the following four treatments. Samples in the first group were pressed to less than nominal density. These were not ratchet grown and used as a baseline. Samples in the second group were pressed to nominal density and then ratchet grown by temperature cycling 30 times between -54 C and +80 C. Samples in the final group were pressed to nominal density and cut into 100 mm by 25.4 mm diameter cylinders. During thermal cycling the cylinders were axially constrained by a 100 psi load. Samples for shock initiation experiments were cut perpendicular (disks) and parallel (slabs) to the axial load. The four sample groups can be summarized with the terms pressed low, ratchet grown/no load, axial load/disks, and axial load/slabs. All samples were shock initiated with nearly identical inputs in plate impact experiments carried out on a gas gun. Wave profiles were measured after propagation through 3, 4, 5, and 6 mm of explosive. Side by side comparison of wave profiles from different samples is used as a measure of relative sensitivity. All reduced density samples were more shock sensitive than nominal density PBX 9502. Differences in shock sensitivity between ratchet grown and pressed to low density PBX 9502 were small, but the low density pressings are slightly more sensitive than the ratchet grown samples.







Detonation Shock Dynamics Calibration for PBX 9502 with Temperature, Density, and Material Lot Variations

Author :

Publisher :

Page : pages

File Size : 43,34 MB

Release : 2010

Category :

ISBN :

Get eBook

Book Description

We present a methodology for scaling the detonation shock dynamics D{sub n}[[kappa]] calibration function to accommodate variations in the HE starting material. We apply our model to the insensitive TATB-based explosive PBX 9502, for which we have enough front curvature rate stick data to characterize three material attributes: initial temperature T0, nominal density [rho]0, and manufacturing lot (representing different microstructures). A useful feature of the model is that it returns an absolute estimate for the reaction zone thickness, [delta]. Lacking demonstrated material metrics(s), we express microstructural variation indirectly, in terms of its effect on [delta]. This results in a D{sub n}[[kappa]] function that depends on T0, [rho]0, and [delta]. After examining the separate effects of each parameter on D{sub n}[[kappa]], we compute an arc geometry as a validation problem. We compare the calculation to a PBX 9502 arc experiment that was pressed from one of the calibrated HE lots. The agreement between the model and experiment is excellent. We compute worst, nominal, and best-performing material parameter combinations to show how much difference accrues throughout the arc.





The Thermal Response of TATB-Based PBXs

Author :

Publisher :

Page : pages

File Size : 21,33 MB

Release : 2015

Category :

ISBN :

Get eBook

Book Description

In the design mode of operation, TATB-based PBXs, such as PBX 9502 or LX-17, are promptly initiated by a detonator and booster system. In abnormal situations, such as accidents, a wide variety of non-design-mode insults can arise and it is desirable that these do not produce detonation but rather that, at most, they lead to a low chemical energy release. The most significant abnormal hazard is the direct shock initiation threat arising from high-velocity fragment impact. This is quite well defined and may result in a detonative response if the fragment is large enough and fast enough. However, it is of considerably greater significance to the safety envelope of these explosives whether they are at all capable of DDT (deflagration-to-detonation transition), either at ambient or elevated temperatures since accidental insults to the explosive, either mechanical or thermal, that may produce local burning are both more numerous and more likely than shock loading. The purpose of this document is to demonstrate, based on the accumulated body of conservative experimental testing, that in explosive geometries and masses relevant to the Weapons Program, TATB-based PBXs do not present a deflagration-to-detonation transition (DDT) hazard at any temperature. This is a significant statement since it removes detonative outcome concerns from the majority of insult scenarios on TATB-based charges. It does not address the response of included detonator and booster assemblies, the response of which must be considered separately.



Numerical Modeling of Explosives and Propellants

Author : Charles L. Mader

Publisher : CRC Press

Page : 539 pages

File Size : 15,48 MB

Release : 2007-10-18

Category : Technology & Engineering

ISBN : 142005239X

Get eBook

Book Description

Major advances, both in modeling methods and in the computing power required to make those methods viable, have led to major breakthroughs in our ability to model the performance and vulnerability of explosives and propellants. In addition, the development of proton radiography during the last decade has provided researchers with a major new experimental tool for studying explosive and shock wave physics. Problems that were once considered intractable – such as the generation of water cavities, jets, and stems by explosives and projectiles – have now been solved. Numerical Modeling of Explosives and Propellants, Third Edition provides a complete overview of this rapidly emerging field, covering basic reactive fluid dynamics as well as the latest and most complex methods and findings. It also describes and evaluates Russian contributions to the experimental explosive physics database, which only recently have become available. This book comes with downloadable resources that contain— · FORTRAN and executable computer codes that operate under Microsoft® Windows Vista operating system and the OS X operating system for Apple computers · Windows Vista and MAC compatible movies and PowerPoint presentations for each chapter · Explosive and shock wave databases generated at the Los Alamos National Laboratory and the Russian Federal Nuclear Centers Charles Mader’s three-pronged approach – through text, computer programs, and animations – imparts a thorough understanding of new computational methods and experimental measuring techniques, while also providing the tools to put these methods to effective use.