A containerized power flow control system is described, for attachment to a power transmission line or substation. The system includes at least one container that is transportable by road, rail, sea or air. A plurality of identical impedance injection modules is operable while mounted in the container, wherein each of the modules is configurable to inject a pre-determined power control waveform into the power line.

A containerized power flow control system is described, for attachment to a power transmission line or substation. The system includes at least one container that is transportable by road, rail, sea or air. A plurality of identical impedance injection modules is operable while mounted in the container, wherein each of the modules is configurable to inject a pre-determined power control waveform into the power line.

Systems, methods, and building block modules for modular power generation facilities are disclosed. A method of erecting a modular power generation facility includes producing a plurality of primary modules, each including a housing adapted from an intermodal shipping container having posts, rails, and sills connected together by shipping container corner castings; shipping the primary modules, which include gen-set modules and a switchgear module, to an installation location; positioning the primary modules in a vertical stack; attaching the primary modules to one another in the vertical stack; interconnecting the engine-generators of the one or more gen-set modules with the switchgear of the switchgear module; and operating the engine-generators and the switchgear to provide electricity to a transformer connected to the switchgear in response to a power load demand. The shipping, positioning, and attaching steps are carried out with engine-generators and switchgear operatively installed in the interior of the primary modules.

Systems, methods, and building block modules for modular power generation facilities are disclosed. A multi-stack modular power generation facility includes first and second pluralities of primary modules and first and second control systems. The first modules are positioned in a first stack to form a first vertical enclosure; the second modules are positioned in a second stack to form a second vertical enclosure; and the first and second modules each include gen-set modules, each with an engine-generator, and a switchgear module ganged to the gen-set modules. Each control system communicates with the respective gen-set modules to coordinate the engine-generators as a unit and to control the loading of each of the generators in response to a power load demand. The second plurality of primary modules are disposed immediately adjacent the first plurality of primary modules such that the second vertical enclosure abuts the first vertical enclosure.

The invention relates to a data center for IT and/or telecoms equipment, especially servers, comprising a building with an intermediate floor arranged for carrying IT and/or telecoms equipment, especially servers, as well as cooling means for cooling the IT and/or telecoms equipment, especially servers, in order to counteract overheating of the IT and/or telecoms equipment, especially servers.

A modular electric power plant housed within a container equipped with a transformer for direct connection to an local power distribution system that can supply energy in remote areas is disclosed. The container provides noise control, and includes a set of units that are interconnected and are capable of generating medium-voltage electric power for supplying a local power distribution system. The units include generator units; a cooling unit; a distribution unit and transformer built-in to a tank for collecting spilled oil. The built-in tanks have double walls for collecting contaminated oil/water installed inside the container base, while air inlets for aiding cooling and at least one pair of fans are provided in the cooling unit compartment. The generator units are powered by gas, diesel, or biodiesel automotive engines. Each generator is connected to an exhaust pipe for gases that is installed on the container upper wall.

A modular electric power plant housed within a container equipped with a transformer for direct connection to an local power distribution system that can supply energy in remote areas is disclosed. The container provides noise control, and includes a set of units that are interconnected and are capable of generating medium-voltage electric power for supplying a local power distribution system. The units include generator units; a cooling unit; a distribution unit and transformer built-in to a tank for collecting spilled oil. The built-in tanks have double walls for collecting contaminated oil/water installed inside the container base, while air inlets for aiding cooling and at least one pair of fans are provided in the cooling unit compartment. The generator units are powered by gas, diesel, or biodiesel automotive engines. Each generator is connected to an exhaust pipe for gases that is installed on the container upper wall.

A test cell (10) for containing equipment (12) subject to pressure testing comprises a plurality of metal plate wall panels (14) and a mesh roof panel (16) formed from mesh strands (26) of a high strength material. Each wall panel has a lapped connection (18) with an adjacent wall panel. The mesh panel (16) may be formed from a ballistic fabric, and the mesh strands (26) may be wire, rope and braid of steel, metal, plastic, natural or composite fiber, or a combination thereof. In the event of a pressure failure of the equipment (12) under test, the roof panel (16) captures fragments of the equipment while allowing the dissipation of pressure shock waves through the apertures (28) in the mesh. The lapped connections (18) between wall panels (14) result in increased friction between adjacent wall panels (14) and thus an increase in the strength of the connection when subject to pressure shock waves.

A test cell (10) for containing equipment (12) subject to pressure testing comprises a plurality of metal plate wall panels (14) and a mesh roof panel (16) formed from mesh strands (26) of a high strength material. Each wall panel has a lapped connection (18) with an adjacent wall panel. The mesh panel (16) may be formed from a ballistic fabric, and the mesh strands (26) may be wire, rope and braid of steel, metal, plastic, natural or composite fiber, or a combination thereof. In the event of a pressure failure of the equipment (12) under test, the roof panel (16) captures fragments of the equipment while allowing the dissipation of pressure shock waves through the apertures (28) in the mesh. The lapped connections (18) between wall panels (14) result in increased friction between adjacent wall panels (14) and thus an increase in the strength of the connection when subject to pressure shock waves.

The present invention relates to a container, and more particularly, to a container having an anti-vibration property so that the container does not shake in vibration.

The container comprises a bottom part, a ceiling part facing the bottom part, a sidewall part connecting the bottom part to the ceiling part, and a rack installed to be fixed in an inner space that is surrounded by the bottom part, the ceiling part, and the sidewall part.