A differential pressure monitoring system includes a differential pressure monitoring device and at least one client device. The differential pressure monitoring device includes a water pressure sensor that detects a water pressure at an inlet of the dry pipe valve, a valve air pressure sensor that detects an air pressure at an outlet of the dry pipe valve, and a control circuit that computes a ratio of the water pressure and the air pressure, predicts whether a valve tripping event is expected to occur based on the computed ratio, and in response to predicting that the valve tripping event is expected to occur, provides a prediction that the valve tripping event is expected to occur for remedial action. The system includes at least one client device that receives the prediction from the control circuit and presents display data regarding the prediction.

A steering device for a motor vehicle is specified, having a housing and having a liquid sensor, comprising at least two electrical conductors, and at least one bridging element that is movably mounted and that is in a first position in the absence of liquid and is in a second position in the presence of liquid, a flow of current between the at least two electrical conductors being prevented in one of the two positions, and a flow of current between the at least two electrical conductors being enabled in the other of the two positions, and a tripping element made of a liquid-absorbing material that expands upon contact with a liquid and thereby moves the bridging element into the second position, the liquid sensor being arranged at least partially inside the housing.

Provided are techniques for operating a hydrocarbon well system that include installing a wellhead seal assembly at a wellhead of a hydrocarbon well system, conducting pressure testing of a wellhead seal cavity defined by the seal assembly to verify its integrity, disposing a control fluid into the wellhead seal cavity, conducting baseline ultrasonic imaging of the wellhead seal cavity to generate a baseline ultrasonic image that depicts a signature of the control fluid disposed in the wellhead seal cavity at a first point in time, conducting updated ultrasonic imaging of the wellhead seal cavity to generate an updated ultrasonic image that depicts a signature of substances disposed in the wellhead seal cavity at a second point in time, comparing the updated ultrasonic image to the baseline ultrasonic image to determine whether the integrity of the wellhead seal cavity has been compromised.

A wireless sensing device for environmental monitoring of a location is provided. The sensing device includes an electronic system and a housing for securing and protecting the electronic system in a cavity therein. The housing includes a vented top portion defining the cavity, and a wicking base portion including wicking material attached to and covering an exposed underside of the top portion. The electronic system includes: a temperature and humidity sensor for sensing a current temperature and humidity of the location and converting the sensed temperature and humidity to temperature and humidity signals; a wireless transmitter for periodically wirelessly transmitting the temperature and humidity signals from the location to an external computing device; an alerting device for providing an audible, visual, or tactile signal from the location in order to alert a user of a condition of interest; and a microcontroller for controlling the electronic system devices.

A water-impermeable membrane assembly, having leak alarm capabilities and useful for sealing a roof surface, comprises upper and lower water-impermeable membranes sealed to each other at respective perimeters to form a plenum enclosed from above and below with area defined by the perimeter sealing, a leak-alarm circuit within the plenum, activatable by the presence of water, a leak-alarm target in the circuit being operative to trigger activation of the leak-alarm circuit when in contact with water, and a capillary pathway disposed within the plenum in contact with the leak-alarm target, to provide a pathway for transport of water by capillary action to the leak-alarm target. The leak-alarm circuit comprises a transmitter for transmitting a signal when activated, and a battery for powering the transmission of the signal. A ratio of leak-alarm target footprint to plenum area is less than 0.05.

Dialysis systems and methods for operating dialysis machines (e.g., peritoneal dialysis machines) for conducting dialysis treatments are disclosed. The dialysis system may include a dialysis machine for transferring dialysate to a patient from a dialysate source. The dialysate may flow from the dialysate source through a cartridge or cassette (e.g., a disposable cartridge or cassette) positionable within the dialysis machine. The dialysis machine includes a piston for pumping fluid (e.g., dialysate) from the cassette to the patient. In various embodiments, during use, the piston is arranged and configured to contact, compress, etc. a membrane defining one or more fluid chambers in the cassette. In one embodiment, the piston includes a sensor for detecting a leak at the interface between the piston and the membrane. The sensor may be a capacitive sensor.

An incontinence detection system monitors an area for moisture events and wirelessly transmits moisture-related information to one or more notification devices. The system has a pad that includes a substrate and one or more sensors supported by the substrate. The sensor(s) emit wireless signals indicative of the moisture-related information. A sensor event communication system forwards the sensor signals to another device, such as a notification device. Portions of the system are included in a patient support apparatus, such as a bed.

A liquid intrusion detection system includes a controller board, an absorbent material, first electrical contacts, and at least one processor. The controller board is disposed within a housing of an electric power steering unit. The absorbent material is at least partially disposed about a component. The first electrical contacts have first ends disposed on at least one of the controller board and the absorbent material. The at least one processor in communication with the first electrical contacts.

A leak detection system includes a testing interface, which includes a rotation holder configured to retain and rotate a package. The testing interface includes a plunger apparatus configured to actuate a plunger to apply a pressure to the package before and/or during the package being inspected using a high voltage leak detection (HVLD) apparatus. The testing interface also includes a controller configured to operate and coordinate the operation of the testing interface with operation of the HVLD apparatus.

A leak detection system includes a testing interface, which includes a rotation holder configured to retain and rotate a package. The testing interface includes a plunger apparatus configured to actuate a plunger to apply a pressure to the package before and/or during the package being inspected using a high voltage leak detection (HVLD) apparatus. The testing interface also includes a controller configured to operate and coordinate the operation of the testing interface with operation of the HVLD apparatus.