Abstract: Systems and methods are disclosed for using a pressure relief shipping adapter to reduce the internal pressure of a container. A pressure relief shipping adapter includes a body comprising a first portion, a transitional portion, and a second portion. The first portion comprises a set of protrusions and a hole disposed through the set of protrusions. The second portion comprises an outlet disposed at a second end of the body. The outlet is concentric with an inlet disposed at the first end of the body. The transitional section is disposed between the first portion and the second portion. The pressure relief shipping adapter also includes an internal chamber within the body.

Abstract: In one embodiment, systems and methods include using a pressure measurement and leak test tool to measure the internal pressure of a container. A pressure measurement and leak test tool comprises a first side, a second side, a top end, a bottom end, and a front surface. The first and second side are disposed along the same plane opposite from each other, wherein the top and bottom end are coupled to the first and second side, wherein the top and bottom end are disposed opposite from each other, wherein the front surface is disposed on an edge defined by the first side, the top end, the second side, and the bottom end. The pressure measurement and leak test tool further comprises an electrical connector disposed on the top end, a power switch disposed on the front surface, and an information handling system comprising a display disposed in the front surface.

Abstract: In one embodiment, systems and methods include using a pressure relief shipping adapter to reduce the internal pressure of a container. A pressure relief shipping adapter comprises a body comprising a first portion and a second portion. The first portion comprises a first bore and a set of protrusions. The second portion comprises a second bore, wherein the second bore comprises a radial gap, wherein the radial gap comprises a uniform arc length along the length of the radial gap. A first end and a second end of the radial gap comprise a greater arc length than the radial gap. A pressure relief shipping adapter further comprises a pressure relief valve disposed at a first end of the first bore and an interlocking component comprising a first tab and a second tab, wherein the interlocking component is at least partially contained within the second bore.

Abstract: In one embodiment, systems and methods include using a pressure relief shipping adapter to reduce the internal pressure of a container. A pressure relief shipping adapter comprises a body comprising a first portion and a second portion. The first portion comprises a first bore and a set of protrusions. The second portion comprises a second bore, wherein the second bore comprises a radial gap, wherein the radial gap comprises a uniform arc length along the length of the radial gap. A first end and a second end of the radial gap comprise a greater arc length than the radial gap. A pressure relief shipping adapter further comprises a pressure relief valve disposed at a first end of the first bore and an interlocking component comprising a first tab and a second tab, wherein the interlocking component is at least partially contained within the second bore.

Abstract: In one embodiment, systems and methods include using a pressure measurement and leak test tool to measure the internal pressure of a container. A pressure measurement and leak test tool comprises a first side, a second side, a top end, a bottom end, and a front surface. The first and second side are disposed along the same plane opposite from each other, wherein the top and bottom end are coupled to the first and second side, wherein the top and bottom end are disposed opposite from each other, wherein the front surface is disposed on an edge defined by the first side, the top end, the second side, and the bottom end. The pressure measurement and leak test tool further comprises an electrical connector disposed on the top end, a power switch disposed on the front surface, and an information handling system comprising a display disposed in the front surface.

Abstract: A method for providing a calibration test gas sample includes identifying a first test canister containing a standard test gas including an ionic gas. A chemical formulation of the standard test gas includes a cation and an anion. The method further includes replacing the first test canister with a second test canister containing an improved test gas. A chemical formulation of the improved test gas includes a replacement atom comprising one of a heavier isotope of one of the cation and the anion.

Abstract: An improved gas cylinder configured to prevent degradation of a contained pressurized reactive gas includes a metallic gas cylinder configured to store a pressurized reactive gas within the cylinder. The improved gas cylinder further includes a cylinder lining including parylene. In one embodiment, the parylene lined cylinder can be heat treated. The improved gas cylinder prevents cracking of the cylinder lining, thereby preventing the contained reactive gas from coming into contact with the metallic gas cylinder.

Abstract: A gas detector is tested by releasing detectable gas from a storage medium and delivering it to the gas detector. A cartridge for delivering detectable gas includes a container with an outlet and a storage medium in the container. Detectable gas is stored in the storage medium for being desorbed from the storage medium. A test device can include a receptacle for receiving the cartridge, an interface for fluidly coupling the device to a gas detector, and passaging to provide fluid communication between the interface and both the cartridge received in the receptacle and external air. A pump can pump external air and the detectable gas released from the cartridge through the passaging and interface such that the pumped detectable gas and air form a proportioned mixture for testing the gas detector.

Abstract: An improved gas cylinder configured to prevent degradation of a contained pressurized reactive gas includes a metallic gas cylinder configured to store a pressurized reactive gas within the cylinder. The improved gas cylinder further includes a cylinder lining including parylene. In one embodiment, the parylene lined cylinder can be heat treated. The improved gas cylinder prevents cracking of the cylinder lining, thereby preventing the contained reactive gas from coming into contact with the metallic gas cylinder.

Abstract: A method for providing a calibration test gas sample includes identifying a first test canister containing a standard test gas including an ionic gas. A chemical formulation of the standard test gas includes a cation and an anion. The method further includes replacing the first test canister with a second test canister containing an improved test gas. A chemical formulation of the improved test gas includes a replacement atom comprising one of a heavier isotope of one of the cation and the anion.

Abstract: A gas detector is tested by releasing detectable gas from a storage medium and delivering it to the gas detector. A cartridge for delivering detectable gas includes a container with an outlet and a storage medium in the container. Detectable gas is stored in the storage medium for being desorbed from the storage medium. A test device can include a receptacle for receiving the cartridge, an interface for fluidly coupling the device to a gas detector, and passaging to provide fluid communication between the interface and both the cartridge received in the receptacle and external air. A pump can pump external air and the detectable gas released from the cartridge through the passaging and interface such that the pumped detectable gas and air form a proportioned mixture for testing the gas detector.