An electronic control device (2) for controlling a sensor (3) comprising a box-shaped body provided on one side with an electronic connector (21), suitable for coupling with an analogous electrical connector (31) associated with such a sensor (3). Such a device, inside such a box-shaped body, comprises electrical power supply means (22) for supplying said sensor, at least one electronic control board (23) for controlling said sensor, with which radio transmission means of the data detected by the sensors are associated.

An electronic control module, particularly for a transmission, includes a first circuit board element and a sensor unit carrier fastened to the first circuit board element. The sensor unit carrier has a sensor unit receptacle configured to receive a sensor unit. The sensor unit has a sensor element fastened and electrically connected to a second circuit board element so as to detect at least one measured value. The sensor unit is fastened in the sensor unit receptacle. The second circuit board element has a flexible region that separates a first sub-region of the second circuit board element from a second sub-region of the second circuit board element. The first sub-region has a predetermined angle to the second sub-region. The sensor element is electrically connected to the first circuit board element by the second sub-region of the second circuit board element.

A composite manhole cover includes a body made of a polymer that has a mass of magnetic material embedded there within. The mass of magnetic material is detectable by a metal detector and, therefore, the composite manhole is locatable by the metal detector when the composite manhole cover is obscured by a material such as pavement, dirt, sand, grass/sod, etc.

A redundant memory for use with an instrument arranged to acquire and store data while underwater. Such an instrument comprises a main housing which contains instrument electronics that acquires and may process data received from one or more sensors, with a primary memory located within the main housing and arranged to store at least some of the acquired and/or processed data, and a secondary memory which stores a copy of the data stored in the primary memory. The instrumentation may be arranged to write data to the primary and secondary memories contemporaneously in either a burst or continuous mode, or with primary memory backed up to secondary memory periodically and/or in response to the occurrence of a triggering event. The instrument may comprise a second housing within which the secondary memory is located. The main and second housings may be contained within a common enclosure.

A multi-sensor component for the installation of at least two sensors at an individual port of a container for culturing biological material is provided. The multi-sensor component has a housing that can be introduced by a front housing segment into an uptake opening extending through the port of the container so that the front housing segment is facing the inside of the container. The multi-sensor component has a first sensor unit or a mount for a first sensor unit arranged on the front housing segment and has a second sensor unit or a mount for a second sensor unit arranged on the front housing segment.

A circuit assembly for mounting on a vehicle assembly is provided. The circuit assembly may be a mountable sensor assembly. The assembly may include a housing with a cavity that houses a circuit, for example a sensor circuit. The circuit may be sealed in the cavity of the housing by epoxy. The housing may include a connector recess with terminals extending into the connector recess. The terminals may provide an electrical connection to the circuit. The housing may have openings between the cavity and the connector recess through which the terminals extend. One or more of the openings may have a cross sectional profile larger than the cross sectional profile of the terminal such that a passage is formed between the cavity and the recess after the terminal is inserted through the opening.

The present disclosure relates to a measuring tube for conveying a liquid, comprising a tubular section and at least one tubular branch for accommodating at least one component of a measuring device. A first end region of the tubular branch is arranged at or in an opening in a wall along a longitudinal axis of the tubular section. According to the disclosure all points of at least a first portion of the wall, such as an inner surface of the wall, of the tubular section, which first portion defines the opening, are located in a plane. Furthermore, the present disclosure relates to an arrangement for determining or monitoring at least one process variable of a liquid in a pipeline, comprising a measuring device and a measuring tube of the disclosure.

A fluid monitoring assembly includes a conduit having a wall defining a lumen for carrying fluid. A sensor mount is integrally formed with the wall of the conduit and extends generally transverse with respect to a longitudinal axis of the conduit, the sensor mount including an aperture defining an inner surface extending to the lumen. The assembly includes a sensor configured to be removably secured within the sensor mount, the sensor having an elongate body terminating at one end thereof in a sensing portion, the elongate body having a male projection on a portion thereof and configured to rest within the inner surface of the sensor mount. The assembly further includes a housing having first and second portions connected to one another, the housing defining an interior portion configured to encapsulate the conduit, at least a portion of the elongate body of the sensor, and the sensor mount.

Disclosed is a sensor device for a towing vehicle coupling or as a component of a towing vehicle coupling, in particular a fifth-wheel coupling, with which a trailer vehicle can be coupled to a towing vehicle wherein the towing vehicle coupling has a coupling element for detachably coupling to a coupling counter element, in particular a fifth-wheel king pin, wherein the coupling element is/can be secured to the towing vehicle and the coupling counter element is/can be secured to the trailer vehicle, and in the coupled state forming a joint, they can rotate relative to one another about at least one joint rotational axis, wherein the sensor device has a follower, mounted on a bearing body such that it can rotate about a follower rotational axis, for detecting a rotation of the coupling counter element relative to the coupling element about the at least one joint rotational axis wherein the follower can rotate about the follower rotational axis by rotationally following the coupling counter element in a rotation about the at least one joint rotational axis, and the sensor device has at least one sensor for detecting a respective rotational position of the follower relative to the bearing body in relation to the follower rotational axis. The follower is arranged outside a bearing region of the joint, in which the coupling element and the coupling counter element are engaged with one another in a bearing manner, and the at least one sensor is arranged inside the follower and/or the follower forms a protective housing for the at least one sensor.

A wireless sensor assembly includes a housing defining a first aperture for receiving an external sensor, and a second aperture defining a communication port, a wireless power source mounted within the housing, and electronics mounted to the housing and configured to receive power from the wireless power source and to be in electrical communication with the external sensor. The electronics include a wireless communications component, and firmware configured to manage a rate of data transmittal from the wireless communications component to an external device. The communication port is configured to receive a wire harness connected to the external sensor.