A deployable explosive charge structure includes a carpenter's tape capable of transitioning from an undeployed state to a deployed state in which the tape extends linearly over its length, an explosive charge connected to the carpenter's tape, a connecting structure for connecting the carpenter's tape and the explosive charge, and a two-sided adhesive tape for engaging a structure (for example, a door or wall) when the carpenter's tape is in the deployed state.

A field filled, flexible linear charge system for cutting through material by explosive detonation; the system including a flexible carcass for application to a surface; the carcass adapted for filling with an explosive compound at a site of use.

An explosive separation joint system having an expandable tube containing a mild detonating fuse (MDF) in separable portions of the joint. The MDF extends into a detonation manifold at a first port, an end of the MDF having booster bonded thereto. An external initiating ordnance transfer line enters the manifold at an initiating ordnance (IO) port, has an IO end tip and provides a detonation impulse train where each detonating component is axially aligned within a passageway with the next detonating component. In embodiments, particular detonating components of the detonation train are fixed in place where other detonating components are movable. Each detonating component that is not in direct contact with a preceding detonating component in the detonation train is in direct linear access.

An explosive separation joint system having an expandable tube containing a mild detonating fuse (MDF) in separable portions of the joint. The MDF extends into a detonation manifold at a first port, an end of the MDF having booster bonded thereto. An external initiating ordnance transfer line enters the manifold at an initiating ordnance (IO) port, has an IO end tip and provides a detonation impulse train where each detonating component is axially aligned within a passageway with the next detonating component. In embodiments, particular detonating components of the detonation train are fixed in place where other detonating components are movable. Each detonating component that is not in direct contact with a preceding detonating component in the detonation train is in direct linear access.

A field filled, flexible linear charge system for cutting through material by explosive detonation; the system including a flexible carcass for application to a surface; the carcass adapted for filling with an explosive compound at a site of use.

A deployable explosive charge structure includes a carpenter's tape capable of transitioning from an undeployed state to a deployed state in which the tape extends linearly over its length, an explosive charge connected to the carpenter's tape, a connecting structure for connecting the carpenter's tape and the explosive charge, and a two-sided adhesive tape for engaging a structure (for example, a door or wall) when the carpenter's tape is in the deployed state.

An explosive separation joint system having an expandable tube containing a mild detonating fuse (MDF) in separable portions of the joint. The MDF extends into a detonation manifold at a first port, an end of the MDF having booster bonded thereto. An external initiating ordnance transfer line enters the manifold at an initiating ordnance (IO) port, has an IO end tip and provides a detonation impulse train where each detonating component is axially aligned within a passageway with the next detonating component. In embodiments, particular detonating components of the detonation train are fixed in place where other detonating components are movable. Each detonating component that is not in direct contact with a preceding detonating component in the detonation train is in direct linear access.

An explosive separation joint system having an expandable tube containing a mild detonating fuse (MDF) in separable portions of the joint. The MDF extends into a detonation manifold at a first port, an end of the MDF having booster bonded thereto. An external initiating ordnance transfer line enters the manifold at an initiating ordnance (IO) port, has an IO end tip and provides a detonation impulse train where each detonating component is axially aligned within a passageway with the next detonating component. In embodiments, particular detonating components of the detonation train are fixed in place where other detonating components are movable. Each detonating component that is not in direct contact with a preceding detonating component in the detonation train is in direct linear access.

A deployable, linear explosive structure includes a split tube, an explosive coupled to the split tube, and a fragmentable or non-fragmentable projectile disposed with respect to the explosive. The split tube can be rolled into a non-deployed state in which the split tube has a flat, rolled profile. The split tube also can be deployed from the non-deployed state to a deployed state in which the split tube is extended along its length and has a curved cross-section along its length. The split tube provides support of the explosive structure in the deployed state. The split tube also provides smaller storage and transportation volume for the explosive structure when rolled in the non-deployed state.

An unmanned aerial vehicle line charge deployment system includes an unmanned aerial vehicle, a payload bay mounted beneath the unmanned aerial vehicle, and a line charge release subsystem coupled to the payload bay. A first line charge release mechanism releasably secures a first portion of a line charge to the unmanned aerial vehicle payload bay and a second line charge release mechanism, independent from the first line charge release mechanism, releasably secures a second portion of the line charge to the unmanned aerial vehicle payload bay.