An electrical supply system including: an extension module including a composite board having an anode layer and a cathode layer of an electrically conducting material, which anode layer and cathode layer are separated by an insulator of an electrically insulating material, the anode layer and the cathode layer each having a trench extending from a connection surface of the composite board and including a connection element, connector pins for the trenches of the extension module, each connector pin having a first complementary connection element for engaging the connection element of the trench of the composite board of a further extension module and a second complementary connection element for engaging the connection element of the trench of the composite board of the extension module, and a power supply capable of providing a constant voltage or a constant current between the anode layer and the cathode layer.

A furniture structure including: one or more generally vertical side panels; one or more shelf boards configured to extend from the one or more side panels; two electrical conductors coupled to a side panel of the furniture structure, to receive electrical power of differing polarity from a power supply; an electrical component coupled to a shelf board, wherein said electrical component includes two power terminals located at one end of the electrical component, the power terminals being accessible from a side surface of the shelf board; and wherein the electrical power is supplied to the electrical component via a direct physical contact between the power terminals of the electrical component and the two electrical conductors.

One of more panels of the cabinet include at least one conductive region that is optionally covered by an insulative covering. These conductive regions are coupled to an external power source. Shelves, drawers, other cabinet components, electrical devices in a cabinet (including, but not limited to, a motor, lights, outlet, appliance, sensor, processor, etc.), and the like can further conduct or receive electrical energy by electrically coupling to the conductive regions within the panels of the cabinet, for example, through shelf pins that are inserted into holes in the panels.

One of more panels of the cabinet include at least one conductive region that is optionally covered by an insulative covering. These conductive regions are coupled to an external power source. Shelves, drawers, other cabinet components, electrical devices in a cabinet (including, but not limited to, a motor, lights, outlet, appliance, sensor, processor, etc.), and the like can further conduct or receive electrical energy by electrically coupling to the conductive regions within the panels of the cabinet, for example, through shelf pins that are inserted into holes in the panels.

There is provided herein controllable power and lighting arrangement suitable for use in commercial and/or domestic applications. There is particularly provided a method for the arrangement and automatic control of light emitting diode (LED) lights, and optionally non-LED based devices, powered by low voltage AC power distributed on bus bars. In addition there is provided a power and lighting arrangement which is especially suitable for use in a uniform and safe manner in close proximity to living organisms, particularly organisms capable of growth, such as plants, in a domestic or commercial growth system.

A power distribution system includes a panel assembly that has an outer surface and two conductive structures spaced from each other and spanning beneath the outer surface. An application module is configured to engage one of a plurality of locations disposed over the outer surface of the panel assembly. The application module includes a first contact configured to engage the first conductive structure and a second contact configured to engage the second conductive structure. The second contact is electrically insulated from the first contact and the first conductive structure for the panel assembly to deliver low voltage power to the engaged application module.

The present disclosure discloses a flexible sliding power supply assembly, and a massage cushion and a control method therefor. A flexible conductive rail is provided with two or more fixing slots; conductive bars are mounted in the fixing slots in an embedded manner; a sliding conductive assembly is mounted on the flexible conductive rail; the sliding conductive assembly is in slidably electric connection with the conductive bars; and the conductive bars are correspondingly electrically connected to a power supply and a controller. The flexible conductive rail of the present disclosure can bend in a large arc in one direction to adapt to massage chairs with different shapes, so that the adaptability is good, and it can be used for both a common cushion and a curved cushion. In the flexible conductive rail, the tunnel type sliding conductive assembly can be made to be a standard component, so that it adapts to various kinds of cushions, the development cost is reduced, and assembling is facilitated. The flexible conductive rail is connected by a tunnel type probe control sleeve structure, so that reliable fixing is achieved during sliding guidance. In the present disclosure, one controller can be connected to a plurality of massage movements with the tunnel type sliding conductive assemblies, so that the number of wires is reduced, and the problems of breakage of wires of the massage cushion and twining of the wires on a massage head are completely solved.

An electrical supply system including: an extension module including a composite board having an anode layer and a cathode layer of an electrically conducting material, which anode layer and cathode layer are separated by an insulator of an electrically insulating material, the anode layer and the cathode layer each having a trench extending from a connection surface of the composite board and including a connection element, connector pins for the trenches of the extension module, each connector pin having a first complementary connection element for engaging the connection element of the trench of the composite board of a further extension module and a second complementary connection element for engaging the connection element of the trench of the composite board of the extension module, and a power supply capable of providing a constant voltage or a constant current between the anode layer and the cathode layer.

A low voltage power system with a rail member that fits on the front portion of a shelf of a merchandise display, where is the rail member has a pair of conductive members positioned within an upper channel of the rail member is disclosed. The rail member may have supply power to a variety of low voltage power devices.

The modular power electrical system provides a plurality of base modules, connectors, and functional device modules, and mating modules which can be connected together to provide a fully reconfigurable power transfer system. A magnetic connection is used to connect the devices together and to transmit power some embodiments. Methods for controlling the modules are also described.