A vacuum volume reduction system and method for reducing a volume to be evacuated at a vacuum tube vehicle station are provided. The system has a station vacuum tube in an interior of a station wall of the vacuum tube vehicle station. The station vacuum tube has a tube volume. The system has a volume reduction assembly coupled to the station vacuum tube, and a control system for radially moving the assembly to and from a vehicle outer surface of a vacuum transport tube vehicle, to engage around the vehicle outer surface, for loading and unloading of passengers and/or cargo. The system further has door seal(s), an air supply assembly, and a vent-to-vacuum assembly. The system displaces the tube volume between the station wall and the vehicle outer surface, and in turn, reduces a volume to be evacuated at the vacuum tube vehicle station.

Provided is a high-purity tin product that does not contain undesirable carbonaceous impurities as a result of the following: a vacuum-packed high-purity metal article (vacuum-packed high-purity tin article) is obtained by vacuum packaging a high-purity metal (high-purity tin), at least a portion of a surface of a high-purity metal being covered with a fluorocarbon resin sheet; and the vacuum-packed high-purity metal article(vacuum-packed high-purity tin article) is obtained by vacuum packaging, with a vacuum packaging film, the high-purity metal in which at least a portion of a surface is covered with the fluorocarbon resin sheet.

Examples of a pre-cooked instant food products and a process for preparing such pre-cooked instant food products are described. The process comprises the steps of i) steaming the food product for pre-determined time; ii) immersing the steamed food product in a high concentration cooled brine solution for about 5 to 15 minutes; iii) removing excess water from the surface of the food product for up to about 10 minutes; iv) packing a pre-determined amount of the food product into a container and sealing such container, and v) storing the containers of pre-cooked instant food products at temperatures of 2 C. or lower. The container is made of a material safe for keeping food products and is able to withstand temperatures higher than 90 C. The surface of the food product is coated with the salt from the brine solution to preserve it. In one example, the pre-cooked instant food product is a freshly made pasta.

A theft-proof packaging system includes a product package having a clear compartment configured to encapsulate a product that is pneumatically vacuumized below a surrounding environment. A pressure sensor assembly is located within the compartment, the pressure sensor assembly including a pressure sensor, a power source electrically connected to the pressure sensor, and a transmitter electrically connected to the power source. The transmitter is configured to send a signal and a receiving unit located outside the compartment of the product package and disposed remote from the product package receives said signal and sounds an alarm. The pressure sensor assembly is configured to detect a change in pressure inside the compartment and then send the signal to the receiving unit activating the alarm. A passive RFID tag is located within the compartment and configured to be detected when it passes through a walk-through scanner activating a second alarm.

A vacuum volume reduction system and method for reducing a volume to be evacuated at a vacuum tube vehicle station are provided. The system has a station vacuum tube in an interior of a station wall of the vacuum tube vehicle station. The station vacuum tube has a tube volume. The system has a volume reduction assembly coupled to the station vacuum tube, and a control system for radially moving the assembly to and from a vehicle outer surface of a vacuum transport tube vehicle, to engage around the vehicle outer surface, for loading and unloading of passengers and/or cargo. The system further has door seal(s), an air supply assembly, and a vent-to-vacuum assembly. The system displaces the tube volume between the station wall and the vehicle outer surface, and in turn, reduces a volume to be evacuated at the vacuum tube vehicle station.

A multilayer cover has a sandwich design for placement on a drawer of a vacuum drawer device, and the cover allows an evacuation of the drawer interior after sealing against the drawer. The cover has an outer air-tight cover layer and a core layer, recesses molded into the core layer and partly into one of the at least one outer cover layer, and an evacuation channel, a pump, and at least one sensor are arranged therein. The cover is to have a more compact design with a very low height, resulting in a minimal susceptibility to malfunction. This is achieved in that a printed circuit board is arranged on one of the at least one outer air-tight cover layers so as to face the core layer or the at least one outer air-tight cover layer is designed as a printed circuit board on which the core layer lies and on which the electric components integrated into the cover are mechanically held and are electrically connected.

A method of storing extreme ultraviolet (EUV) pellicles or pellicle film is disclosed. The method includes selecting a material, such as stainless steel or glass material, for the construction of the storage or transportation containers. Vacuum-sealed or inert-gas-filled containers are further preferred. The material maintains one or more properties of extreme ultraviolet (EUV) lithography pellicle, the one or more properties being selected from EUV transmission rate, EUV transmission variation, EUV scattering, EUV pellicle film deflection, EUV pellicle film tensile strength, or a combination thereof.

A system and method for providing a screen protector to a portable handheld electronic device or cell phone with a user facing surface comprises a mold having an outer surface matching a user facing surface. A stack of layers including the screen protector is disposed over the outer surface of the mold. A vacuum bag receives and surrounds the stack of layers disposed over the mold. The vacuum bag is sealed and evacuated of air. The screen protector is heated and/or cured while in the vacuum bag to shape the screen protector over the mold to have curved lateral edges matching curved lateral edges of the outer surface of the mold and the user facing surface of the display screen of the cell phone. The vacuum bag maintains the curved lateral edges of the screen protector against the curved lateral edges of the outer surface of the mold.

A nursing pillow is provided, having a continuous body structure, a receiving area configured to receive a torso of a user, and a nursing surface configured to accommodate an infant in an inclined position on the nursing pillow. A method for displaying a plurality of nursing pillows on a salesfloor, is also provided.

One feature pertains to a device that includes a main body having a bottle-receiving end that receives an end of a bottle having a mouth and forms an airtight seal between an exterior surface of the bottle and an interior air cavity of the main body. The device also includes an actuator assembly that drives a stopper securement device into a stopper positioned within the mouth of the bottle and retracts the stopper securement device to remove the stopper from the mouth of the bottle. The device also includes a vacuum pump that evacuates air out of the interior air cavity and the bottle's headspace after the stopper has been removed to create a vacuum within the headspace. The actuator assembly may also drive the stopper securement device and the stopper back into the mouth of the bottle to reseal the bottle while the headspace is under vacuum.