Oxy-acetylene driven laboratory scale shock tubes for studying blast wave effects

TL;DR

This paper presents a modular oxy-acetylene driven shock tube capable of generating realistic blast waves for laboratory studies, enabling diverse applications in material testing, biological response, and numerical model validation.

Contribution

The development of a cost-effective, easy-to-operate shock tube that produces true blast wave profiles without large jet effects, improving laboratory blast simulation capabilities.

Findings

Produced peak pressures from 204 kPa to 1187 kPa

Maintained true blast wave profiles up to one diameter from the opening

Reduced operational costs and complexity compared to traditional shock tubes

Abstract

This paper describes the development and characterization of modular, oxy-acetylene driven laboratory scale shock tubes. Such tools are needed to produce realistic blast waves in a laboratory setting. The pressure-time profiles measured at 1 MHz using high speed piezoelectric pressure sensors have relevant durations and show a true shock front and exponential decay characteristic of free-field blast waves. Descriptions are included for shock tube diameters of 27 - 79 mm. A range of peak pressures from 204 kPa to 1187 kPa (with 0.5 - 5.6% standard error of the mean) were produced by selection of the driver section diameter and distance from the shock tube opening. The peak pressures varied predictably with distance from the shock tube opening while maintaining both a true blast wave profile and relevant pulse duration for distances up to about one diameter from the shock tube opening. This shock tube design provides a more realistic blast profile than current compression-driven shock tubes, and it does not have a large jet effect. In addition, operation does not require specialized personnel or facilities like most blast-driven shock tubes, which reduces operating costs and effort and permits greater throughput and accessibility. It is expected to be useful in assessing the response of various sensors to shock wave loading; assessing the reflection, transmission, and absorption properties of candidate armor materials; assessing material properties at high rates of loading; assessing the response of biological materials to shock wave exposure; and providing a means to validate numerical models of the interaction of shock waves with structures. All of these activities have been difficult to pursue in a laboratory setting due in part to lack of appropriate means to produce a realistic blast loading profile.