A wireless connector includes: a first unit attached detachably from the outside of a first object; and a second unit attached detachably from the outside of a second object. The first unit includes a first housing to which a first transmission/reception part and a first connector part are secured, the first connector part being attached to the first object and transmitting a to-be-transmitted target between the first connector part and the first object. The second unit includes a second housing to which a second transmission/reception part and a second connector part are secured, the second connector part being attached to the second object and transmitting a to-be-transmitted target between the second connector part and the second object. The first transmission/reception part and the second transmission/reception part are arranged so as to be separated from each other and opposed to each other to wirelessly transmit the to-be-transmitted target.

A wireless connector includes: a first unit attached detachably from the outside of a first object; and a second unit attached detachably from the outside of a second object. The first unit includes a first housing to which a first transmission/reception part and a first connector part are secured, the first connector part being attached to the first object and transmitting a to-be-transmitted target between the first connector part and the first object. The second unit includes a second housing to which a second transmission/reception part and a second connector part are secured, the second connector part being attached to the second object and transmitting a to-be-transmitted target between the second connector part and the second object. The first transmission/reception part and the second transmission/reception part are arranged so as to be separated from each other and opposed to each other to wirelessly transmit the to-be-transmitted target.

A control attachment for an in-wall power adapter configured to control the application of power to a load is described. The control attachment comprises a first contact element of a plurality of contact elements configured to receive a power signal; a second contact element of the plurality of contact elements configured to provide the power signal to the load; a conductor electrically coupling the first contact element to the second contact element; wherein the control attachment enables the in-wall power adapter to control the application of power received at the first contact element to be applied to the load.

A rotary plug electrical connector includes a plug and a socket, both of which include power contacts and signal contacts. The plug is rotatable within the socket between operable and inoperable positions. The power contacts of the socket include opposed surfaces which are engaged by resilient blade power contacts of the plug. The signal contact of the socket preferably includes a pair of contacts, and the signal contact of the plug preferably is a bridge contact that engages the socket signal contacts in the operable position and disengages the socket signal contacts in the inoperable position. When the signal contacts are disengaged, no power is transferred by the connector.

A rotary plug electrical connector includes a plug and a socket, both of which include power contacts and signal contacts. The plug is rotatable within the socket between operable and inoperable positions. The power contacts of the socket include opposed surfaces which are engaged by resilient blade power contacts of the plug. The signal contact of the socket preferably includes a pair of contacts, and the signal contact of the plug preferably is a bridge contact that engages the socket signal contacts in the operable position and disengages the socket signal contacts in the inoperable position. When the signal contacts are disengaged, no power is transferred by the connector.

The present disclosure generally relates to a recreational vehicle (RV) pedestal, system, network, and mobile software application. Pedestals may integrate power sources of different power levels for different vehicle load requirements. Pedestals may combine power, electronics, communications connections, and water sources in the same device. The pedestals may be networked so that users may access a mobile application to reserve, pay for, and review pedestals and the RV park.

A terminal block including: a connector that has a tubular shape; and a seating that is formed on an outer periphery of the connector, and is to be fixed to the housing so as to close an opening of the housing, wherein: the seating includes: a first wall that extends in a direction that intersects an axial direction of the connector; a second wall that faces the first wall in the axial direction of the connector; a rib that is provided between the first wall and the second wall so as to connect the first wall and the second wall with each other; and a space that is partitioned by the rib between the first wall and the second wall, and the space is open in a direction that intersects the axial direction of the connector.

A charging inlet for an electric vehicle includes a housing, a terminal arranged within the housing for engaging with a corresponding mating terminal of a charging plug, and a sensor connectable to a monitoring system of the electric vehicle for detecting the presence of a charging plug installed within the charging inlet.

A multi-position conversion device and a conversion socket with the multi-position conversion device; the first pin, the second pin, the first connecting sheet and the second connecting sheet are installed together onto the main frame to modularize and integrate the conversion device; therefore, only one main frame is needed to complete the installation of the first pin, the second pin, the first connecting sheet and the second connecting sheet, and this can effectively decrease the volume of the multi-position conversion device and thus decrease the volume and weight of the whole conversion socket, prevent the conversion socket from sagging due to gravity and thus increase the corresponding user experience and safety; meanwhile, after being modularized, the multi-position conversion device is installed directly into the housing and thus can decrease the assembling steps, reduce the assembling difficulty and finally improve the assembling efficiency.

A wall-mounted electrical-connector-engaging assembly for axial engagement with an electrical connector, the assembly including (a) a wall-surface adapter having front and back faces and attached to a wall over an opening in the wall and (b) a backcap. The adapter back face has a plurality of wire-connection points for installation of a corresponding plurality of wires, and the adapter front face has a plurality of slidably-engaging electrical connection points for engagement in at least an axial direction with the electrical connector. The backcap surrounds the plurality of wire-connection points and adjacent portions of the corresponding plurality of wires connected thereto, and includes a twist lock for installation on the wall-surface adapter.