An insert maintains the form of a glove while facilitating drying. The insert has palm, finger, and thumb portions. The palm portion is a planar or curved flange, having first and second sides. The finger portion includes an index finger flange, a middle finger flange, a ring finger flange, and a pinky finger flange, each extending from the palm portion. A first peripheral flange and a second peripheral flange are each configured to respectively extend away from, and be in continuous proximity to, a periphery formed by the first side and the second side of the palm portion and the finger flanges. First and second transverse flanges are formed for each of the finger flanges, each configured to extend away from first and second sides thereof, and be substantially centered on the finger flange, to provide eight radiused points of a contact/support being substantially equally spaced, for each glove finger.

The present invention relates to a desiccation apparatus, the apparatus comprising: a hollow drum mounted for revolution about a substantially longitudinal axis, the drum comprising a shell having an interior surface and an exterior surface; and a means to generate airflow through the hollow drum.

The present invention relates to a desiccation apparatus, the apparatus comprising: a hollow drum mounted for revolution about a substantially longitudinal axis, the drum comprising a shell having an interior surface and an exterior surface; and a means to generate airflow through the hollow drum.

A flexible panel in a sealable bag for disaster recovery has permeable inner layers and an impermeable outer layer affixed together so as to provide a plurality of cavities for receiving sorbent material. The cavities are arranged in a pattern across the flexible panel. A port is shown extending through all of the layers of the flexible panel. The port is used for introducing into and removing gas and/or liquid from the bag. The flexible panel may have one or more electronic components operable to monitor or control the chemical environment in the bag. The components may be affixed or printed on internal layers of the bag, such as: a conductor, a heater, a processor, a communications transmitter, a communications receiver and a GPS receiver. A remote module in electrical and/or wireless communication with the bag is operable to monitor and control the chemical environment in the bag.

A flexible panel in a sealable bag for disaster recovery has permeable inner layers and an impermeable outer layer affixed together so as to provide a plurality of cavities for receiving sorbent material. The cavities are arranged in a pattern across the flexible panel. A port is shown extending through all of the layers of the flexible panel. The port is used for introducing into and removing gas and/or liquid from the bag. The flexible panel may have one or more electronic components operable to monitor or control the chemical environment in the bag. The components may be affixed or printed on internal layers of the bag, such as: a conductor, a heater, a processor, a communications transmitter, a communications receiver and a GPS receiver. A remote module in electrical and/or wireless communication with the bag is operable to monitor and control the chemical environment in the bag.

The present disclosure provides methods, compositions and systems for drying coal fines.

The present disclosure provides methods, compositions and systems for drying coal fines.

Systems and methods are provided to detect a developed bad word-line of a flash memory. Embodiments provide an improved Background media scan (BGMS) process that can predict at the end of a block read if a word-line will potentially become bad with the use of the flash memory. Accordingly, data from the potentially bad block can be recovered and the block can be retired. The embodiments can minimize the need for the expensive chip-kill method.

The invention relates to a method for producing a plastic granulate (16), in which a process fluid (12) is contained in a process chamber (10) where an underwater granulation takes place and the process fluid in the process chamber has a temperature greater than 120° C. A process pressure of at least 2.0 bar is obtained in the process chamber, at which a granulation of the plastic strands (14) into plastic granulate occurs. From the process chamber, a mixture (18) of process fluid and plastic granulate is diverted into a first cooling zone (25) during cooling of the plastic granulate, while maintaining the process pressure. In a first separating device (22), the plastic granulate is separated from the process fluid under process pressure. In the process chamber, the process fluid has a temperature in the range from 120° C. to 160° C., and the process pressure obtained there is greater than the pressure of the vapour pressure curve of the process fluid. After separation from the process fluid in the first separating device, the plastic granulate is fed continuously in a line to a dealdehydization container (46).

The invention relates to a method for producing a plastic granulate (16), in which a process fluid (12) is contained in a process chamber (10) where an underwater granulation takes place and the process fluid in the process chamber has a temperature greater than 120° C. A process pressure of at least 2.0 bar is obtained in the process chamber, at which a granulation of the plastic strands (14) into plastic granulate occurs. From the process chamber, a mixture (18) of process fluid and plastic granulate is diverted into a first cooling zone (25) during cooling of the plastic granulate, while maintaining the process pressure. In a first separating device (22), the plastic granulate is separated from the process fluid under process pressure. In the process chamber, the process fluid has a temperature in the range from 120° C. to 160° C., and the process pressure obtained there is greater than the pressure of the vapour pressure curve of the process fluid. After separation from the process fluid in the first separating device, the plastic granulate is fed continuously in a line to a dealdehydization container (46).