A method of sterilizing and storing laboratory consumables comprises slidably receiving a carrier holding a plurality of laboratory consumables into each of one or more of a plurality of storage compartments within an interior chamber defined in a housing, exposing the plurality of laboratory consumables to ultraviolet (UV) light from a UV lamp positioned above each respective storage compartment and from a UV lamp positioned below each respective storage compartment, determining from which of the plurality of storage compartments a carrier should be removed based on for which carrier a longest period of time has elapsed since going through a predefined sterilization procedure, and indicating to a user into which of the plurality of storage compartments a carrier should be placed or indicating to a user from which of the plurality of storage compartments a carrier should be removed.

The noodle driving apparatus includes an enclosure having a lateral partition separating the enclosure into an upper chamber and a lower chamber. At least one first cool-air provision device and at least one warm-air recovery device are disposed to a side inside the upper chamber. A number of first cool-air inlets and warm-air inlets are configured on the partition toward another side of the upper chamber. Noodles to be dried are placed in the lower chamber. Cool air produced by the first cool-air provision device is introduced into the lower chamber through the first cool-air inlets to absorb moisture from the noodles. Warm air produced from the first cool-air provision device is collected by the warm-air recovery device and introduced into the lower chamber through the warm-air inlets to dry the noodles. The noodle driving apparatus thereby achieves improved drying performance, enhanced energy consumption, and better drying quality.

A method for obtaining pure drinking water from dewatered biological products is described. The process is carried out in a hermetic dewatering chamber isolated from the ambient atmosphere and in parallel with a process during which dried products are placed on drying trays. All the process parameters, such as temperature, humidity, and appropriate pressure inside the chamber, are controlled. The vapor generated during the product dewatering process, released from the products, is continuously removed from the dewatering chamber through the upper opening, exits through the outflow channel, and enters through the condenser. The process of obtaining clean drinking water is carried out outside the chamber and is conducted in several stages: vapor passes through disinfectant grids, vapor flows to a condenser cooled with ice water, and the vapor condenses on densely arranged lamellas. The condensate is then pumped to a discharge tub.

Embodiments herein include devices adaptable to dehydrate articles, including foods. Embodiments are shown which can be compacted for reduced storage, and/or shipping requirements and/or for other purposes. Embodiments include simple, inexpensive means for controlling dehydrating conditions, including airflow. Various article holding devices, including devices to hold foods being dehydrated, are also shown. Such devices include vertical, diagonal, and horizontal panels to secure articles. Embodiments shown have variations which include the use of non-motorized convection airflow, as well as devices which incorporate motor driven air movement means. Embodiments are shown which may be used for preparing articles, including foods, for dehydration, including slicing such articles.

Disclosed are systems and methods for aseptically filling pharmaceutical containers with a pharmaceutical substance and then lyophilizing it. In one general aspect, the system and method can employ a lyophilizer loader subsystem having an interior chamber in communication with an interior chamber of a lyophilizer subsystem via a portal with a sealable door, with the collective interior being aseptically sealable. An articulated robotic arm can be employed to batch transfer to the lyophilizer subsystem container nests bearing the pharmaceutical containers. In one embodiment, the nests may be transferred serially to the loader subsystem, with the articulated robotic arm being configured to transfer the nests of containers in batches to the lyophilizer subsystem. The articulated robotic arm can also be configured to be used to move batches of nests within the lyophilizer subsystem. One implementation includes two articulated arms and a joint rotary wrist driven by two rotary shoulders.

An improved locker seat includes a pair of spaced-apart upstanding sidewalls having a pair of lateral edges. A generally horizontal seat is disposed between the lateral edges of the sidewalls. In a first mode, an air source is connected to an airway formed within the seat to create an airflow. The airflow from the air source creates a first temperature differential to cool the seat. In a second mode, an external or internal heat source provides heat to a top surface of the seat, creating a second temperature differential to heat the seat. The first and second temperature differential are distributed across the top surface of the seat. The seat is hinged to be movable about the hinge between an open and a closed position.

Disclosed herein are devices systems and methods for removing moisture from a material via radio frequency electromagnetic wave exposure. A moisture-removal system can include having spaced apart a first and a second electrical conductor extending along a same first direction, each of the first and second electrical conductor comprising opposing broad top and bottom sides, the broad bottom side of the first electrical conductor facing the broad top side of the second electrical conductor. The system includes a material containing moisture at least partially filling the space between the first and the second electrical conductor. The system further includes at least one first wire attached to a first radio frequency generator and to the first end of the first electrical conductor. The system also includes at least one second wire attached to the electrical ground of the first radio frequency generator to the first end of the second electrical conductor.

The disclosure concerns methods for executing PBV protocols to preserve biopharmaceuticals using a conventional lyophilizer. Also described are steps for maintaining isolation of a biopharmaceuticals for achieving aseptic drying using the conventional lyophilizer. As a collateral benefit, the invention provides good manufacturing practice (GMP) compliant methods for achieving aseptic drying of biopharmaceutical compositions using a conventional lyophilizer disposed outside of a clean-room area. Finally, methods and formulations str disclosed for preserving biopharmaceuticals suitable for mucosal or transdermal delivery to a patient.

A shoe dryer including a main body, a shoe receiver provided inside the main body and configured to receive a shoe, a blower configured to blow air toward the shoe received in the shoe receiving portion, a camera configured to obtain an image of the shoe by photographing the shoe received in the shoe receiver, and a control device configured to recognize information about the shoe from the image of the shoe obtained by the camera, and control a direction of air blown by the blower based on the information about the shoe.

Machines, systems and methods for curing materials, including organic and nonorganic materials, are described. In particular, machines, systems and methods for machines, systems and methods for materials, such as organic plant materials or inorganic materials, including cannabis materials. In particular, the present invention relates to machines, systems and methods for an automated drying and curing chamber machine for both personal and commercial applications, wherein the machine uses customized variable settings and laminar air flow dynamics via negative pressure to ensure the optimal curing and drying environment for plant materials are described.