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.

Provided is a sheet sensor comprising an anisotropically-conductive sheet exhibiting conductivity in a thickness direction and having a first surface as a contact surface for a sensing target object, and multiple conductive members electrically connected to a second surface of the anisotropically-conductive sheet and electrically insulated from each other.

A multiple layer composite material having fluid breach detection features provides indication of a failure in a fluid barrier. The indication of breach of fluid is provided before failure of a final layer of the composite material. The multiple layer composite material includes more than one fluid impermeable layer with an intermediate layer sealed between the fluid impermeable layers. Failure of one of the fluid impermeable layers is detected by fluid contact in the intermediate layer. The intermediate layer includes a reagent and/or detection device to indicate that the fluid has reached the intermediate layer.

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.

The present disclosure relates to a tangible, non-transitory, machine-readable medium, having machine-readable instructions to pair a water detection device of a plurality of water detection devices with a user account via a user device, receive a first signal indicative of a location of the water detection device from the user device, receive a second signal indicative of a personalized message to be sent to the user device upon a detection event of the water detection device, and display a list of the plurality of water detection devices and corresponding locations of each water detection device of the plurality of water detection devices on the user device.

A pipeline breach monitor includes an electric field sensor and a signal processing unit in communication with the electric field sensor. The electric field sensor includes an upper substrate, and a plurality of electrodes embedded in the upper substrate. The electrodes are substantially parallel to each other in the upper substrate and comprise at least one sense electrode and a plurality of elongate sensor electrodes disposed around the at least one sense electrode. The signal processing unit is configured to (i) apply a voltage signal to the sensor electrodes, (ii) receive at least one measurement set comprising a measurement of a phase and a magnitude of a current generated in the at least one sense electrode and the sensor electrodes, and (iii) generate an assessment of accumulation of a substance proximate the electric field sensor from the at least one measurement set and at least one predetermined substance accumulation profile.

The present disclosure relates to a water detection device that includes a water-activated battery configured to switch from a dormant condition to an active condition upon contact with water, such that the water-activated battery supplies an electrical voltage upon contact with the water, an electronic circuit configured to receive the electrical voltage from the water-activated battery, where the electronic circuit is configured to communicate with an external, electronic device via one or more wireless communication techniques when the electronic circuit is powered by the electrical voltage, and where communication between the electronic circuit and the external, electronic device is an uninterrupted communication when the electronic circuit is receiving the electrical voltage from the water-activated battery, and a housing configured to receive the water-activated battery and the electronic circuit, where the housing has passageways configured to facilitate movement of the water into the housing and toward the battery.

The present disclosure relates to a water detection device that includes a water-activated battery configured to supply an electrical voltage upon contact with water, an electronic circuit configured to receive the electrical voltage from the water-activated battery, where the electronic circuit is configured to communicate with an external, electronic device upon receipt of the electrical voltage, and a housing configured to receive the water-activated battery and the electronic circuit, where the housing has passageways configured to facilitate movement of water into the housing and toward the battery.

A switch device capable of safely opening or short-circuiting an electrical circuit in response to an abnormality such as wetting with water or liquid leaking from a battery is provided. The device includes first and second conductors connected to an external circuit, and a reaction part including an insulating material which changes state on contact with a liquid, the first and second conductors being electrically connected or disconnected by the insulating material changing state on contact with the liquid.

Disclosed is a battery device including a battery; a plurality of sensors attached to the battery; and a transceiving circuit configured to transmit a signal received from a monitoring device to the plurality of sensors and to transmit signals received from the plurality of sensors to the monitoring device. The plurality of sensors generate surface acoustic waves (SAWs) in response to the signal received from the monitoring device, when receiving the signal from the monitoring device through the transceiving circuit, and the plurality of sensors include at least one first sensor configured to output a first signal corresponding to a SAW varied depending on a temperature of the battery; at least one second sensor configured to output a second signal corresponding to a SAW varied depending on pressure of the battery; and at least one third sensor configured to output a third signal corresponding to a SAW varied depending on an electrolyte leakage state of the battery.