A modular data center includes a controller; a data center control system configured to collect data center data associated with the modular data center via communication with one of the controller and a plurality of sensors; and a data module connected to a power supply source. The power supply source includes at least one of a power grid, a backup power source and a power module. The power module includes electronics equipment for conditioning and distributing power to the one or more data modules. The data module includes a first enclosure defining a first internal space; and a first sensor in the plurality of sensors. The first sensor is in communication with at least one of the controller and the data center control system. A second sensor in the plurality of sensors is in communication with the power supply source.

A bottle cap having an outer skin secured to an inner core by means of an inwardly folded or rolled edge of the outer skin, and space provided in the inner core. The outer skin may be painted. The space may be provided by a rabbet.

A closure assembly includes a cap having a top panel joined to a circumferential skirt by a plurality of bridges and an opening in the top panel. A plurality of complementary projections are provided on the inner surface of the skirt. An intermediate member has a top portion. An annular sealing surface joins and rises from the top portion. A neck is formed on the top portion located to protrude through the opening. A closure base with a complementary annular sealing surface is adapted to telescopically receive the annular sealing surface. A plurality of projections extend from the closure base. A sealing member is applicable between the annular sealing surface and complementary annular sealing surface to provide a seal between the intermediate member and the closure base.

Thermoformed polyester resin closures for closing containers, the polyester resins including polyethylene terephthalate (PET), polyethylene furandicarboxylate (PEF), or a copolymer including PET and PEF, are provided herein. Methods of making the thermoformed closures are further provided. Methods of sterilizing the thermoformed closures are further provided.

The container includes a flexible container body that has a closed bottom end and a top end with a lip that protrudes radially outward. The container has a cap that has first threads. The container also has a hollow bottom ring that has second threads that threadingly engage the first threads. The bottom ring has an open top defined by a top edge and an open bottom. The container body passes through the hollow bottom ring with the lip seating against the top edge of the bottom ring and in a sealed closed position, the cap is attached to the bottom ring to close off and seal the flexible container body.

A smart cap for use with a liquid container and a system therefor is disclosed herein. The components of the smart cap preferably comprise a micro motor, a microcontroller, a wireless transceiver (BTLE), a lithium ion battery, LED indicators, a waterproof rated charging port, a nozzle quick connect, a controllable valve, a touch sensor, a thermal sensor, a physical button, an impeller, and a cap housing.

The present application is directed to cap assemblies and particularly, cap assembly for closing an opening in a vessel, the cap assembly including a stopper including an polymer body adapted to fit an opening of a vessel, the stopper also including a tubular portion which defines an internal passageway extending through the polymer body; and a rigid cap attached to and integral with the stopper, wherein the cap is adapted to engage the vessel and provide a sealing force between the stopper and the vessel.

A cap-locking assembly includes an inner cap having a ribbed outer surface and a locking cap. The locking cap includes opposing first and second engagement mechanisms, opposing first and second stabilizing ridges, and a plurality of ramped tabs, all of which are disposed on the interior surface of the locking cap. When the ramped tabs engage a lower edge of the inner cap they retain the inner cap inside the locking cap. Further, the opposing first and second stabilizing ridges coaxially align the inner cap and the locking cap. Finally, the opposing first and second engagement mechanisms engage with the ribbed outer surface of the inner cap upon application of an inward force to the locking cap.

A combination cap and work support system includes a lower section configured to connect to a container and an upper section configured to provide a desired support to an object. The combination cap and work support system may be utilized alone or in multiples to support an object above a work surface during a project. Configurations of the upper section generally include support structures such as ridges and apices in a desired configuration. Configurations of the combination cap and work support system may be separable into individual segments each of which may be separately utilized as a support structure for an object. The combination cap and work support system may be included as part of a kit in conjunction with a compatible container, such as a can of surface coating.

A modular data center includes a controller; a data center control system configured to collect data center data associated with the modular data center via communication with one of the controller and a plurality of sensors; and a data module connected to a power supply source. The power supply source includes at least one of a power grid, a backup power source and a power module. The power module includes electronics equipment for conditioning and distributing power to the one or more data modules. The data module includes a first enclosure defining a first internal space; and a first sensor in the plurality of sensors. The first sensor is in communication with at least one of the controller and the data center control system. A second sensor in the plurality of sensors is in communication with the power supply source.