Washstand furniture includes: a wash device including a wash bowl, a water supply assembly for supplying water to the wash bowl, and a drainage assembly for draining the water supplied to the wash bowl; an inner cabinet provided under the wash bowl, the inner cabinet having a space defined therein; an outer cabinet for covering the outside of the inner cabinet; and a residual-water-suction-device-drying module provided inside the inner cabinet, the residual-water-suction-device-drying module including a plurality of receiving units for receiving and drying separate components of a residual water suction device for suctioning liquid, wherein an external connection channel communicating with the outside is defined between the inner cabinet and the outer cabinet, and the residual-water-suction-device-drying module further includes a plurality of fans for moving air that flows in the external connection channel to the receiving units of the residual-water-suction-device-drying module.

My desiccator comprises a plurality of chambers in series communication with each other so a desiccating gas flows from one chamber into an adjacent chamber. A desiccating purge gas is introduced through an inlet into the desiccator's chambers at a predetermined flow rate, and a one-way bleed valve allows gas within the chambers to constantly flow from the desiccator while maintaining a positive pressure within the desiccator. A fan that constantly mixes and circulates the gas between the chambers as the desiccating purge gas is introduced into the desiccator, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. My method employs my desiccator to store items, wherein a dry, pressurized desiccating gas is introduced into the desiccator's chambers in a manner that constantly circulates the gas between the chambers as gas is slowly bled from the chambers, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. In my method the dew point of the desiccating gas is from 20 to 90 F. , the pressure of the desiccating gas is from 30 to 120 psi, and the average flow rate of the desiccating gas into the desiccator is from 0.25 to 4.0 cubic feet per minute.

A washstand may include a wash device including a wash bowl, a water supply assembly that supplies water to the wash bowl, and a drainage assembly that drains the water supplied to the wash bowl. The washstand may also include a cabinet provided under the wash bowl, the cabinet having a space, a dryer that discharges air through a discharge port from an interior of the cabinet, and a utensil-drying module provided in the space of the cabinet and coupled to the dryer to receive air discharged from the dryer to dry utensils placed in the utensil-drying module. The cabinet may include a drainage hole arranged to drain residual water from the utensil-drying module out of the cabinet.

A method and apparatus for eliminating or minimizing the non-uniformity of edge vials compared to center vials during freezing or primary drying of product therein in a freeze dryer. A temperature controlled surface is positioned in close proximity to or in contact with the edge vials to control the temperature thereof. The method and apparatus may be used to simulate in a development freeze dryer the conditions of the center and edge vials in a larger batch target freeze dryer.

A sterile solution product bag for lyophilizing includes a bladder, a first stem having a first stem inlet end and a first stem outlet end. The first stem outlet end is fluidly connected to the bladder and the first stem inlet end is adapted to receive a liquid. A first filter is disposed in-line with the first stem and includes a first filter membrane, a first filter open end, and a first filter closed end. The first filter closed end is disposed between the first stem inlet end and the first stem outlet end and the first filter open end is disposed in proximity to the first stem inlet end. A second stem having a second stem inlet end fluidly connected to the bladder and a second stem outlet end adapted to receive a vapor. A second filter is disposed within the second stem and includes a filter membrane.

Washstand furniture includes: a wash device including a wash bowl, a water supply assembly for supplying water to the wash bowl, and a drainage assembly for draining the water supplied to the wash bowl; a cabinet provided under the wash bowl, the cabinet having a space defined therein; and a residual-water-suction-device-drying module provided inside the cabinet for receiving and drying separate components of a residual water suction device for suctioning liquid.

Washstand furniture is disclosed. The washstand furniture includes: a wash device including a wash bowl, a water supply assembly for supplying water to the wash bowl, and a drainage assembly for draining the water supplied to the wash bowl; an inner cabinet provided under the wash bowl, the inner cabinet having a space defined therein; an electrically operated module provided in the inner cabinet; an outer cabinet provided outside the inner cabinet for maintaining the rigidity of the washstand furniture; and a storage module provided in a space defined by the wash bowl, the inner cabinet, and the outer cabinet, the storage module having therein a storage space for storing a printed circuit board for controlling the operation of the inner module.

My desiccator comprises a plurality of chambers in series communication with each other so a desiccating gas flows from one chamber into an adjacent chamber. A desiccating purge gas is introduced through an inlet into the desiccator's chambers at a predetermined flow rate, and a one-way bleed valve allows gas within the chambers to constantly flow from the desiccator while maintaining a positive pressure within the desiccator. A fan that constantly mixes and circulates the gas between the chambers as the desiccating purge gas is introduced into the desiccator, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. My method employs my desiccator to store items, wherein a dry, pressurized desiccating gas is introduced into the desiccator's chambers in a manner that constantly circulates the gas between the chambers as gas is slowly bled from the chambers, constantly diluting the gas within the chambers with a fresh supply of the desiccating gas. In my method the dew point of the desiccating gas is from 20 to 90 F, the pressure of the desiccating gas is from 30 to 120 psi, and the average flow rate of the desiccating gas into the desiccator is from 0.25 to 4.0 cubic feet per minute.

An improved ventilated locker includes a pair of sidewalls and a a back wall connecting the sidewalls. A plurality of compartments is defined between the sidewalls, including at least an upper compartment and a lower compartment. A plenum is disposed adjacent the back wall, the plenum configured for connection to an existing HVAC system. At least one ventilation grille is carried by the back wall in fluid communication with at least one of the plurality of compartments and with the plenum. At least one circulation fan is disposed in one of the plurality of compartments to circulate air from the ventilation grilles through the plurality of compartments.

An object of the present invention is to provide a method for drying non-fried noodles for obtaining non-fried noodles that are easily loosened without sticking of noodle strings and excellent in restorability. The present invention includes, as a step of drying non-fried noodles, a step of putting gelatinized noodle strings into a retainer, the retainer having one or more small holes in a bottom surface thereof so as to give a ratio of the total area of the small holes to the area of the bottom surface of the retainer of 30% or less, or having no small hole in the bottom surface, that is, the retainer having an aperture ratio of 0 to 30%, and blowing a high-speed air flow, preferably having a wind speed of 50 m/s or higher, from above the retainer toward the noodle strings in the retainer.