A modular system and method for monitoring and distributing power is disclosed. A container having at least one side surface with an exit port or entrance port, a conduit transmitting through the container and an internal cavity. A container system in the internal cavity has a power distribution system, a data distribution system, and monitoring sensor monitoring container system data. A processor receives the container system data from the monitoring sensor, processes the data and transmits the processed data to the container system.

The present invention discloses a plurality of modular containers. The modular containers can comprise a first container that includes a first top surface, a first bottom surface and at least one first side surface oriented between the first top and the first bottom surface. The first container can define a first internal cavity. The modular containers can also include a container system that is located in the first internal cavity. The modular containers can include a power distribution system and a data distribution system. In addition, the modular containers can include a second container. The second container can comprise a second top surface, a second bottom surface and at least one second side surface oriented between the second top and the second bottom surface. The second container can also define second internal cavity. Further, the modular containers can include a container subsystem located in the second internal cavity. The container system can also be in communication with the container subsystem.

Disclosed herein are an electrical wiring structure with connection points arranged on side walls and a building construction method, which can improve convenience of electrical wiring construction and reduce electrical wiring materials. The electrical wiring structure includes a first power wire drawn out of a distribution box and disposed through a first conduit embedded in a concrete-made bottom base of an indoor space, a first joint box embedded at a predetermined height in a first side wall formed in the indoor space and electrically connected to the first power wire, a first light wire electrically connected to the first joint box, and a second joint box embedded at a predetermined height in a second side wall formed in the indoor space and electrically connected to the first joint box by a second power wire disposed through a second conduit embedded in the bottom base of the indoor space.

An embodiment of the container can include a top surface, a bottom surface and at least one side surface oriented between the top and the bottom surface. At least one side surface can define at least one exit port and at least one entrance port to the container. The container can define an internal cavity. The container can also include a load bearing member oriented on at least one of: the top surface, bottom surface or the at least one side surface. The container's top surface is load bearing, non-slip surface. First and second containers can be coupled in multiple variations and at multiple angles and power, data, fluid, or gas can be transferred and communicated between the two containers. The containers described herein can function as a replacement for standard flooring, sidewalks, and roads, or can seamlessly blend into the pre-existing environment.

A recessed floor box system is provided herein. The recessed floor box system includes a housing having a set of walls defining an interior chamber; a riser; a non-use cover; and an in-use cover. The riser is connected to the housing and includes an interior opening connected to the interior chamber. The non-use cover is positioned on the riser and across the interior opening. The in-use cover is positioned on the riser and at least partially defines an egress opening that provides access to the interior opening. The in-use cover includes an upper portion having a substantially planar surface and a lower portion having a latch mechanism to secure the cover over the riser.

In various implementations, a raceway may be provided that is capable of providing power and/or data connectivity to items (e.g., devices, articles of furniture, etc.) coupled to the raceway. The raceway may be low profile. The raceway may be disposed on floor and/or under floor. The raceway may include an integrated power housing. The raceway may include segments that are selected, as desired for an application configuration, and that are coupleable to each other or other components of the raceway (e.g., nodes, joints, etc.). The housing of component(s) of the raceway may include a base and wall(s) with at least curved section and at least one straight section.

A connection system for electrically connecting a fixture in a vehicle has at least one cable, and a housing with a cable inlet and a cable outlet, and with a receiving space which is formed in the housing and extends helically along a housing axis with a receiving space cross section from the cable inlet towards the cable outlet. The cable has a cable cross section and runs completely through the receiving space from the cable inlet towards the cable outlet, with cable coils being formed. A radial extent of the cable cross section is smaller than a radial extent of the receiving space cross section. Therefore, different lengths of the at least one cable can be accommodated in the receiving space with different coil diameters being formed.

A system for distributing wireless networking components in a venue. The system includes panels that define a floor surface. The panels each have a planar configuration with an upper surface opposite a lower surface. The panels include a material that is transparent to radio waves, and the panels define a storage space below the panels and the storage space may be used to store and distribute wireless networking component.

An exemplary cabling system includes a plurality of containers. A first container of the plurality of containers defines a first plurality of openings. The system includes a plurality of bolts with a first bolt operable to insert into the first plurality of openings. The first bolt defines a first conduit operable to receive a first cable of a plurality of cables. An exemplary telecommunications central office includes a container with a plurality of walls defining an interior of the container and an exterior of the container, an opening, a vault entrance, and a plurality of cable runways. An exemplary method for arranging cables includes cutting a wall of a first and second container to create a first and second opening, inserting flanges of bolts into the openings, receiving with a pipe the flanges, and routing a cable through the first and second opening into an interior of the second container.

A wire protection member includes a pipe and a protector that define a routing pathway of a wire. The protector has a body part and a cover part that are connected to each other in a direction perpendicular to an axial direction of the pipe and cover an end part of the pipe. A protector-side locking part is provided at at least one of the body part or the cover part. At the pipe, a pipe-side locking part is provided that (i) when the body part and the cover part are connected, fits together with the protector-side locking part from the direction intersecting the axial direction and (ii) restricts positional deviation of the protector in a circumferential direction of the pipe and in the axial direction of the pipe.