Provided is a can body containing contents such as carbonated beverages, the can body being capable of suppressing the occurrence of an unexpected opening while increasing the internal pressure resistance. In the can body, formula (A+B).Math.E/Z<1.88 is satisfied when 0<L<Y2, with the following definitions: L=D.Math.cos (1 2), A=X.Math.(L+Y1Y2)/Y1, and B=L+Y1Y2, under a condition of E<Z.

A drawn aluminum can shell has a peripheral crown which is double-seamed with an end portion of an aluminum can body to provide a can end having a generally flat center panel connected by an inclined curved or straight panel wall to an inner wall of an annular U-shaped countersink. The countersink has an outer wall which connects with a lower wall portion of a chuck wall, and the chuck wall has an upper wall portion which connects with an inner wall of the crown. The chuck wall also has an intermediate wall portion forming a break, and the inner bottom width of the countersink is less than the radial width of the panel wall.

Embodiments described herein include specialized barrel containers and methods for using the containers to safely transport and dispose of airbag inflators having ammonium-nitrate-based propellant. For example, a container is provided that can hold multiple airbag inflators and withstand up to 4 moles of matter being deployed from an inflator having ammonium-nitrate-based propellant. The container can contain the inflator and any shrapnel associated with the explosion while also venting gases expelled as a result of the explosion. Various container designs are provided, along with methods for using these containers.

Embodiments described herein include layered mesh containers and methods for using the containers to safely transport and dispose of airbag inflators having ammonium-nitrate-based propellant. For example, a container is provided that can hold multiple airbag inflators and withstand up to 4 moles of matter being deployed from an inflator having ammonium-nitrate-based propellant. The container can contain the inflator and any shrapnel associated with the explosion while also venting gases expelled as a result of the explosion. Various container designs are provided, along with methods for using these containers.

Embodiments described herein include systems and methods for safely transporting and disposing of airbag inflators. For example, a container is provided that can hold multiple airbag inflators and withstand inflator explosion resulting in failure of the metal inflator housing. The container can contain the inflator and any shrapnel associated with the explosion while also venting gases expelled as a result of the explosion. Various container designs are provided, along with methods for using these containers.

A joint assembly includes a first container portion, a second container portion, a band strip, and a fastener. The first container portion has a first flange including a first sealing surface and a first outer surface. The second container portion has a second flange including a second sealing surface and a second outer surface. The second sealing surface is configured to cooperate with the first sealing surface to form together a sealed connection. The fastener is configured to attach the band strip to one of the first and second container portions. An inner surface of the band strip is configured to engage at least one of the first and second outer surfaces such that the sealing surfaces of the first and second flanges are fixed with respect to one another when the band strip is attached to at least one of the first and second container portions.

A can end that is attached to a metal can body with a bottom end forming a cavity that may be filled with food, liquid, etc. The can end is made of metal with a bead configuration located in the outer circumference of the can end that increases its resistance to deformation when subjected to high pressure cooking environments and assists in preventing the can end from separating along the frangible score.