Disclosed are systems and methods for remotely controlling and monitoring water supply systems in buildings. A system can include a sensor to continuously detect building conditions, an electromechanical device to control a water valve located along a water supply for the building, a user computing device to display information about the building conditions, and a computer system to: continuously receive building condition information from the sensor, determine, based on the information, that an emergency has been detected, generate and transmit first instructions that cause the electromechanical device to turn off the water valve, generate and transmit second instructions that cause the user computing device to present information about the emergency in a graphical user interface (GUI) display, receive user input to control the electromechanical device, and generate and return third instructions to control the electromechanical device based on the user input and/or the continuously received sensor information.

Disclosed are systems and methods for remotely controlling and monitoring water supply systems in buildings. A system can include a sensor to continuously detect building conditions, an electromechanical device to control a water valve located along a water supply for the building, a user computing device to display information about the building conditions, and a computer system to: continuously receive building condition information from the sensor, determine, based on the information, that an emergency has been detected, generate and transmit first instructions that cause the electromechanical device to turn off the water valve, generate and transmit second instructions that cause the user computing device to present information about the emergency in a graphical user interface (GUI) display, receive user input to control the electromechanical device, and generate and return third instructions to control the electromechanical device based on the user input and/or the continuously received sensor information.

An improved system detects an environmental anomaly in a shipping container and initiates a mediation response through a generated layered alert notification. The system includes sensor-based ID nodes associated with packages within the container, and a command node mounted to the container communicating with the ID nodes and an external transceiver on a vehicle transporting the container. The command node is programmed to detect sensor data from the ID nodes; compare the sensor data to package environmental thresholds in context data related to each ID node; detect the environmental anomaly when the comparison indicates an environmental condition for at least one package exceeds its environmental threshold; responsively generate a layered alert notification identifying a mediation recipient and mediation action, and establishing a mediation response priority based upon the comparison; and transmit the layered alert notification to the transceiver unit to initiate a mediation response related to the mediation action.

An improved system detects an environmental anomaly in a shipping container and initiates a mediation response through a generated layered alert notification. The system includes sensor-based ID nodes associated with packages within the container, and a command node mounted to the container communicating with the ID nodes and an external transceiver on a vehicle transporting the container. The command node is programmed to detect sensor data from the ID nodes; compare the sensor data to package environmental thresholds in context data related to each ID node; detect the environmental anomaly when the comparison indicates an environmental condition for at least one package exceeds its environmental threshold; responsively generate a layered alert notification identifying a mediation recipient and mediation action, and establishing a mediation response priority based upon the comparison; and transmit the layered alert notification to the transceiver unit to initiate a mediation response related to the mediation action.

An electronic fire sprinkler system includes a plurality of electronic fire sprinklers that each output a flow of fluid in response to receiving an activation signal, a plurality of temperature sensors that each detect a temperature and output an indication of the detected temperature, a plurality of network devices that detect a distance to at least one of the plurality of electronic fire sprinklers, and a processing circuit. The processing circuit receives a plurality of detected distances, calculates a location of each electronic fire sprinkler based on the of detected distances, determines that a fire condition is present based on the detected temperature, identifies one or more of the plurality of electronic fire sprinklers based on the calculated locations and an identifier of the temperature sensor from which the indication of the detected temperature was received, and transmits one or more activation signals to the identified electronic fire sprinklers.

An electronic fire sprinkler system includes a plurality of electronic fire sprinklers that each output a flow of fluid in response to receiving an activation signal, a plurality of temperature sensors that each detect a temperature and output an indication of the detected temperature, a plurality of network devices that detect a distance to at least one of the plurality of electronic fire sprinklers, and a processing circuit. The processing circuit receives a plurality of detected distances, calculates a location of each electronic fire sprinkler based on the of detected distances, determines that a fire condition is present based on the detected temperature, identifies one or more of the plurality of electronic fire sprinklers based on the calculated locations and an identifier of the temperature sensor from which the indication of the detected temperature was received, and transmits one or more activation signals to the identified electronic fire sprinklers.

A vehicle includes electrical equipment and a fire suppression system for the electrical equipment of the vehicle. The fire suppression system includes a sensor, an inert gas storage container, a nozzle, a delivery system, and a controller. The inert gas storage container is configured to store an amount of inert gas and discharge the inert gas based on the fire suppression system being activated. The delivery system includes a flexible conduit. The delivery system is fluidly coupled with the inert gas storage container and the nozzle. The controller is configured to receive sensor signals from the sensor and activate the fire suppression system based on the sensor signals so that the inert gas is provided to the electrical equipment.

A vehicle includes electrical equipment and a fire suppression system for the electrical equipment of the vehicle. The fire suppression system includes a sensor, an inert gas storage container, a nozzle, a delivery system, and a controller. The inert gas storage container is configured to store an amount of inert gas and discharge the inert gas based on the fire suppression system being activated. The delivery system includes a flexible conduit. The delivery system is fluidly coupled with the inert gas storage container and the nozzle. The controller is configured to receive sensor signals from the sensor and activate the fire suppression system based on the sensor signals so that the inert gas is provided to the electrical equipment.

In one implementation, a computer-implemented method includes receiving, at a computer system, information that indicates that a fire has been detected in a building and that a fire suppression system within the building has begun dousing the fire; monitoring sensor information from one or more sensors located within the building; determining, by the computer system and based on the sensor information, whether the fire has been extinguished; activating, in response to determining that the fire has been extinguished, a feature to turn off a water supply to the building, the feature being presented on a computing device for a user who is associated with the building; receiving, after activating the feature and from the computing device, a command to turn off the water supply; and transmitting, by the computer system, a control signal that causes an electromechanical device to close a water valve within the building.

In one implementation, a computer-implemented method includes receiving, at a computer system, information that indicates that a fire has been detected in a building and that a fire suppression system within the building has begun dousing the fire; monitoring sensor information from one or more sensors located within the building; determining, by the computer system and based on the sensor information, whether the fire has been extinguished; activating, in response to determining that the fire has been extinguished, a feature to turn off a water supply to the building, the feature being presented on a computing device for a user who is associated with the building; receiving, after activating the feature and from the computing device, a command to turn off the water supply; and transmitting, by the computer system, a control signal that causes an electromechanical device to close a water valve within the building.