A method for determining the level of efficiency of a ventilation system of an electrical enclosure intended to house one or more electrical devices, the method including a learning step including a step for determining a profile of the power dissipated via the Joule effect by each electrical device, an evaluation step for evaluating the level of efficiency of the ventilation system, including a step for determining the average air flow rate of a fan from a profile of the temperature of the air outside the enclosure obtained over an evaluation period, a profile of the temperature of the air at the outlet of the enclosure, and the dissipated power profile determined during the learning step, a step for comparing the average air flow rate with one or more threshold values in order to determine the level of efficiency of the ventilation system.

A measuring and/or control system (1), to control for example a machine tool, comprises at least a first and a second unit, each comprising a casing with a front wall, electronic circuits and at least one socket. The system further comprises a bridge connector (11) having a first multipolar connector (11A) and a second multipolar connector (11B), each of which can be coupled to one of the sockets in order to electrically connect the first and the second unit. In each of the first unit and second unit, the socket is positioned on the respective front wall and comprises planar electrical contacts. The first and the second multipolar connectors of the bridge connector are directed in the same direction so as to face the front wall of the first unit and the second unit and each comprise retractable contacts. The bridge connector comprises fastening elements for fastening the bridge connector to the front wall of the first unit and of the second unit.

A carrier rail housing comprises: a carrier rail receiving opening into which the holding legs of a carrier rail are insertable; a locking mechanism to secure the holding legs in a desired mounting position and comprising locking slides to interlock with the carrier rail housing in a locking position; a plug-in contact element arranged inside the carrier rail housing to face the carrier rail receiving opening; and a bus connector into which plug-in contacts of the plug-in contact element are insertable, the bus connector being connectable to a plug-in contact element of at least one additional carrier rail housing, wherein each of the locking slides comprises a first end that comprises a holding section that extends in sections into the carrier rail receiving opening in the locking position, so that the bus connector is secured between the holding sections of the locking slides and the plug-in contact element.

An electronics module for coupling to a module arrangement, in particular valve island, in a line-up direction, comprises a casing which comprises a front side, a back side, an upper side, a bottom side and two opposite lateral surfaces extending along the line-up direction in relation to a state mounted on the module arrangement. In the casing an electronics is accommodated and at least a first bus connection and two second bus connections are provided, which are connected to the electronics within the casing. The at least one first bus connection is arranged either on the upper side or on the bottom side, while a second bus connection is arranged on each of the lateral surfaces, respectively. A module assembly comprises a module arrangement, in particular a valve island, and an electronics module, wherein the electronics module directly abuts on the module arrangement in the line-up direction, and is detachably connected thereto in a non-destructive manner.

A measuring and/or control system (1), to control for example a machine tool, comprises at least a first and a second unit, each comprising a casing with a front wall, electronic circuits and at least one socket. The system further comprises a bridge connector (11) having a first multipolar connector (11A) and a second multipolar connector (11B), each of which can be coupled to one of the sockets in order to electrically connect the first and the second unit. In each of the first unit and second unit, the socket is positioned on the respective front wall and comprises planar electrical contacts. The first and the second multipolar connectors of the bridge connector are directed in the same direction so as to face the front wall of the first unit and the second unit and each comprise retractable contacts. The bridge connector comprises fastening elements for fastening the bridge connector to the front wall of the first unit and of the second unit.

The invention concerns a function component upper part (500) for placing on a function component lower part (401) of a function component (400), having a first interface for electrically connecting the function component lower part (401) of the function component (400), and a second interface for electrically 409 connecting a housing upper part (403) of the function component (400).

A coupling unit for an industrial control system has two module connections for making electrical contact with control modules, a field connection for making electrical contact with an industrial field device, a data transmission medium for the transmission of communication data, and a signal transmission medium for the transmission of field signals. Each of the two module connections comprise electrical contact elements which form a communication signal region and a field signal region. Contact elements of the communication signal regions of each of the two module connections are connected in an electrically conductive manner to the data transmission medium, and contact elements of the field signal regions of each of the two module connections are connected to the field connection via the signal transmission medium.

An electronics module for coupling to a module arrangement, in particular valve island, in a line-up direction, comprises a casing which comprises a front side, a back side, an upper side, a bottom side and two opposite lateral surfaces extending along the line-up direction in relation to a state mounted on the module arrangement. In the casing an electronics is accommodated and at least a first bus connection and two second bus connections are provided, which are connected to the electronics within the casing. The at least one first bus connection is arranged either on the upper side or on the bottom side, while a second bus connection is arranged on each of the lateral surfaces, respectively. A module assembly comprises a module arrangement, in particular a valve island, and an electronics module, wherein the electronics module directly abuts on the module arrangement in the line-up direction, and is detachably connected thereto in a non-destructive manner.

A building controller receiving base for receiving a building controller. The building controller may include a building controller housing that houses a building controller electrical connector that includes a spring contact extending outside of the building controller housing. The building controller receiving base includes a base housing including one or more attachment features for releasably securing the building controller to the base housing, and a base electrical connector housed by the base housing. The base electrical connector includes a spring contact extending outside of the base housing at a location that is aligned with the spring contact of the building controller electrical connector when the building controller is secured to the base housing via the one or more attachment features. The base electrical connector further comprises a first terminal pin that extends outside of the base housing and is accessible from outside of the base housing.

A power distributor having a plurality of power distribution modules arranged in a row, for directly mounting on a carrier rail, having a supply module arranged on one end face and a signal module arranged on the opposite end face, and having at least one connection module arranged therebetween. The supply module has a supply connection for a main power line for tapping off a supply power. The connection module is fitted or can be fitted with a protective switch that can be actuated and a plurality of load connections for connecting to an interruptible load circuit by means of the protective switch. The signal module has a first signal connection for a switch signal actuating the protective switch, and the power distribution modules are or can be coupled to each other in an electrically conductive manner.