Abstract: This described invention related generally to thermal desorption systems. In one example embodiment, to methods, apparatus, and systems to a soil box design of thermal desorption system, wherein the soil box realizes a design for efficient heating and removing of containments such as hydrocarbons from contaminated soil by minimizing a distance between a point of treatment gas insertion and another point of treatment gas exit.

Abstract: Contaminated soil can be in-situ cleaned without an excavation process. Heated gas can be injected to the contaminated soil to heat the soil for vaporizing the contaminants. Vacuum extraction can be used for extracting the volatile contaminants. Cool air can be injected to the cleaned soil to prevent total organic carbon degradation.

Abstract: Active or closed feedback/feed forward loop controls may be used to improve operation of a thermal desorption process. Characteristics of the thermal desorption process may be monitored, e.g., carbon monoxide concentration, and then may be used to predict the end point of the thermal desorption process. Inputs and effluent treatment elements may also be modulated to further optimize the treatment time and quality (completeness) and to avoid any unwanted effects associated with excess processing. Post-treatment gas comprising non-condensed condensable hydrocarbon contaminants may be recycled as pre-treatment gas or used to heat fresh air. Mean free paths of the exhaust gas exiting a thermal desorption chamber are restricted to limit the flame propagation and explosion fronts. Temperature and concentration of flammable elements may be monitored and controlled to prevent explosion hazards. An isolation valve and a pressure relief chimney may also be coupled to the exhaust of the thermal desorption chamber.

Abstract: Contaminate soil can be treated using inductive energy. An inductive generator can generate inductive power to heat inductively heatable elements disposed in the contaminate soil or in a soil box. Input treatment gas can pass through the heated soil to remove contaminants in the soil to the exhaust. The inductively heatable elements can be placed in a mesh conduit, which can heat the input treatment gas.

Abstract: Contaminated soil can be in-situ cleaned without an excavation process. Heated gas can be injected to the contaminated soil to heat the soil for vaporizing the contaminants. Vacuum extraction can be used for extracting the volatile contaminants. Cool air can be injected to the cleaned soil to prevent total organic carbon degradation.

Abstract: A high velocity munition comprises a projectile, mounted on a cartridge case, that can be fired from an automatic cannon or weapon. During storage or transport an IM venting device included in the cartridge case prevents the propellant charge from firing the projectile, leaving the cartridge damaged, but intact upon premature ignition. The IM vent exhaust channel is filled with a solid fusible material that melts at a lower temperature than the ignition temperatures of the igniter (or primer) and the propellant charge of the projectile. At least one non-fusible, ruptureable member is included in the IM vent channel and positioned to provide structural integrity to the fusible material in the channel. Alternatively or in addition to the fusible material, a shape memory alloy ring surrounds the igniter (or primer) and separates from the cartridge when the cartridge reaches a temperature that causes auto-ignition.

Abstract: Active or closed loop controls can be used to improve the operation of a thermal desorption process. Characteristics of the thermal desorption process can be monitored, and then can be used to predict the end point of the thermal desorption process. Inputs and effluent treatment elements can also be modulated to further optimize the treatment time and quality (completeness) and to avoid any unwanted effects associated with excess processing.

Abstract: A high velocity cartridge munition comprises a cartridge shell and a projectile inserted into it. A propulsion chamber within the cartridge shell receives a propulsive charge that may be ignited by a pyrotechnic igniter and that develops propulsive gases that act on the base of the projectile, driving it out of the cartridge shell. To prevent the pyrotechnic igniter from igniting spontaneously, and from igniting the propulsive charge due to the ambient temperature or because of a fire, which would cause the cartridge shell and projectile to be separated and fly apart, at least one exhaust channel between the propulsion chamber and the exterior of the cartridge shell is filled with a fusible material. The fusible material has a lower melting point than the ignition point of the igniter and of the propulsive charge.

Abstract: A high velocity cartridge munition comprises a cartridge shell and a projectile inserted into it. A propulsion chamber within the cartridge shell receives a propulsive charge that may be ignited by a pyrotechnic igniter and that develops propulsive gases that act on the base of the projectile, driving it out of the cartridge shell. To prevent the pyrotechnic igniter from igniting spontaneously, and from igniting the propulsive charge due to the ambient temperature or because of a fire, which would cause the cartridge shell and projectile to be separated and fly apart, at least one exhaust channel between the propulsion chamber and the exterior of the cartridge shell is filled with a fusible material. The fusible material has a lower melting point than the ignition point of the igniter and of the propulsive charge.