A method for dehydration and critical point drying of a sample in a single chamber is introduced, comprising the steps of (a) dehydrating the sample by replacing water by an intermediate fluid, (b) replacing the intermediate fluid by a transitional fluid, (c) pressurising the transitional fluid to or beyond its critical pressure and/or heating the transitional fluid (4 to or beyond its critical temperature, and (d) in response to gradually releasing the pressure, letting the transitional fluid gasify and escape from the sample. In step (a) and/or step (b), a ratio of the fluid to-be-replaced to the replacing fluid is measured and used to control a supply of the replacing fluid.

The method reduces consumption of intermediate fluid and/or transitional fluid, making the process more efficient in terms of duration and user interaction while ensuring a high degree of dryness and the integrity of the sample.

A method for dehydration and critical point drying of a sample in a single chamber is introduced, comprising the steps of (a) dehydrating the sample by replacing water by an intermediate fluid, (b) replacing the intermediate fluid by a transitional fluid, (c) pressurising the transitional fluid to or beyond its critical pressure and/or heating the transitional fluid (4 to or beyond its critical temperature, and (d) in response to gradually releasing the pressure, letting the transitional fluid gasify and escape from the sample. In step (a) and/or step (b), a ratio of the fluid to-be-replaced to the replacing fluid is measured and used to control a supply of the replacing fluid.

The method reduces consumption of intermediate fluid and/or transitional fluid, making the process more efficient in terms of duration and user interaction while ensuring a high degree of dryness and the integrity of the sample.

Provided is a dryer for clothes. The dryer for the clothes includes a cabinet, a drying drum accommodated in the cabinet, a suction passage supplying hot air into the drying drum, a heating unit disposed on one position of the suction passage to heat the air introduced into the suction passage at a high temperature, an exhaust passage through the hot air discharged from the drying drum flows, a blower mounted on one position of the exhaust passage to forcibly blow the air within the drying drum, a lint filter mounted on the other position of the exhaust passage, a guide duct defining a portion of the exhaust passage to accommodate the lint filter therein, and a blocking member disposed at a position where the air discharged from the drying drum flows.

Technologies (e.g., devices, systems and methods) for sanitizing reservoirs of humidifiers are described. In some embodiments, the technologies include a sanitization gas system and a connector unit. The connector unit is configured to install into a portion (e.g., wall, bottom, top, or lid) of a reservoir, such as a reservoir of a humidifier. The connector unit includes an inlet passageway for supplying sanitizing gas (e.g., ozone) into the reservoir, and an outlet passageway for removing sanitizing gas from the reservoir. In some embodiments at least a portion of the outlet passageway is disposed radially around the inlet passageway. The sanitization gas system may provide a sanitizing gas to the inlet passageway and receive the sanitizing gas from the outlet passageway.

A dryer for flat materials, in particular panels, films or sheets, wherein a porous gas-permeable metal plate is provided for arranging at a distance from the flat material which is to be dried, wherein an arrangement is provided for delivering a gaseous fluid through the metal plate, and wherein the metal plate is of a metal foam.

A drilling mud remediation and drilling cutting treatment device and method. There are three main components: a vacuum liquid solid separator; a pelletizer; and an induction furnace. The liquid solid separator has a seamless filter belt configured to carry a mixture of liquids and solids over a vacuum. A slurry comprised of drilling mud and cuttings is deposited on the filter belt. An applicator ensures that the slurry is deposited evenly across the entire filter belt at a uniform thickness. The vacuum removes most of the liquids for further treatment and reuse. The solids are transferred to a pelletizer which compacts them into relatively uniform pellets while removing much residual liquid. The pelletized cuttings are then passed through an induction furnace, which removes any residual liquids, renderings the cuttings safe for disposal.

A drilling mud remediation and drilling cutting treatment device and method. There are three main components: a vacuum liquid solid separator; a pelletizer; and an induction furnace. The liquid solid separator has a seamless filter belt configured to carry a mixture of liquids and solids over a vacuum. A slurry comprised of drilling mud and cuttings is deposited on the filter belt. An applicator ensures that the slurry is deposited evenly across the entire filter belt at a uniform thickness. The vacuum removes most of the liquids for further treatment and reuse. The solids are transferred to a pelletizer which compacts them into relatively uniform pellets while removing much residual liquid. The pelletized cuttings are then passed through an induction furnace, which removes any residual liquids, renderings the cuttings safe for disposal.

A substrate carrier adapted to use in a processing system includes an electrode assembly and a support base. The electrode assembly is configured to generate an electrostatic chucking force for securing a substrate to the substrate carrier. The support base has a heating/cooling reservoir formed therein. The electrode assembly and the support base form an unitary body configured for transport within a processing system. A quick disconnect is coupled to the body and configured to trap a heat regulating medium in the reservoir heating/cooling reservoir when the body is decoupled from a source of heat regulating medium.

A substrate carrier adapted to use in a processing system includes an electrode assembly and a support base. The electrode assembly is configured to generate an electrostatic chucking force for securing a substrate to the substrate carrier. The support base has a heating/cooling reservoir formed therein. The electrode assembly and the support base form an unitary body configured for transport within a processing system. A quick disconnect is coupled to the body and configured to trap a heat regulating medium in the reservoir heating/cooling reservoir when the body is decoupled from a source of heat regulating medium.

A substrate carrier adapted to use in a processing system includes an electrode assembly and a support base. The electrode assembly is configured to generate an electrostatic chucking force for securing a substrate to the substrate carrier. The support base has a heating/cooling reservoir formed therein. The electrode assembly and the support base form an unitary body configured for transport within a processing system. A quick disconnect is coupled to the body and configured to trap a heat regulating medium in the reservoir heating/cooling reservoir when the body is decoupled from a source of heat regulating medium.