An onboard system for winterizing vessels includes an antifreeze storage system. The onboard system includes a control system capable of determining one or more of the one or more system components to be winterized, an antifreeze storage system, and one or more pumps capable of pumping antifreeze from the antifreeze storage system. The antifreeze flows through the determined one or more system components to be winterized.

An onboard system for winterizing vessels includes an antifreeze storage system. The onboard system includes a control system capable of determining one or more of the one or more system components to be winterized, an antifreeze storage system, and one or more pumps capable of pumping antifreeze from the antifreeze storage system. The antifreeze flows through the determined one or more system components to be winterized.

An onboard system for winterizing vessels includes an antifreeze storage system. The onboard system includes a control system capable of determining one or more of the one or more system components to be winterized, an antifreeze storage system, and one or more pumps capable of pumping antifreeze from the antifreeze storage system. The antifreeze flows through the determined one or more system components to be winterized.

Disclosed herein are flow control devices including at least one remote temperature sensor configured to determine first temperature data associated with air outside of a dwelling; a valve configured to control a first flow rate of the liquid flowing from an inlet of the supply pipe along a controlled liquid flow path by moving a valve position from a closed position to an open position; a flow control component in fluid communication with the valve, and configured to control a second flow rate of the liquid flowing from the valve; at least one internal temperature sensor configured to determine second temperature data associated with air inside the dwelling; a controller communicatively connected to the temperature sensors and configured to control operation of the valve based at least on at least one of the first temperature data and the second temperature data; and a housing configured to contain the flow control device components and further configured to releasably attach to a spigot or spout of a supply pipe. Also disclosed herein are methods for using the disclosed devices.

An agricultural irrigation control system including a pump, a dual port and on/off diverter in fluid communication with the pump, a multi-port diverter in fluid communication with the dual port and on/off diverter, a controller board in electronic communication with the dual port and on/off diverter and the multi-port diverter, the controller board controlling the operation of the dual port and on/off diverter and the multi-port diverter, and a plurality of environmental sensors in electronic communication with the controller board, where the agricultural irrigation control system is configured for individualized administration of one or more substances to one or more agricultural products based on real-time analysis of the one or more agricultural products and/or a surrounding environment of the one or more agricultural products provided by one or more environmental sensors of the plurality of environmental sensors.

An earthquake gas valve that uses a battery powered actuation mechanism to automatically close a gas valve when the movement caused by an earthquake is perceived. A gear motor is activated by a plurality of shake switches which in turn cause a motor driven radial rack to rotate. The rack terminates in a closure plug which obstructs the gas outlet opening and prevents gas from entering the house or office when an earthquake occurs. A timing circuit delays the activation of the closure plug to make sure that the motion has been caused by an earthquake and not by an accidental brief jarring action.

An onboard system for winterizing vessels includes an antifreeze storage system. The onboard system includes a control system capable of determining one or more of the one or more system components to be winterized, an antifreeze storage system, and one or more pumps capable of pumping antifreeze from the antifreeze storage system. The antifreeze flows through the determined one or more system components to be winterized.

An agricultural irrigation control system including a pump, a dual port and on/off diverter in fluid communication with the pump, a multi-port diverter in fluid communication with the dual port and on/off diverter, a controller board in electronic communication with the dual port and on/off diverter and the multi-port diverter, the controller board controlling the operation of the dual port and on/off diverter and the multi-port diverter, and a plurality of environmental sensors in electronic communication with the controller board, where the agricultural irrigation control system is configured for individualized administration of one or more substances to one or more agricultural products based on real-time analysis of the one or more agricultural products and/or a surrounding environment of the one or more agricultural products provided by one or more environmental sensors of the plurality of environmental sensors.

A system for storing a pressurized gas in a motor vehicle is provided, having a storage container and at least one thermally activatable safety valve for emptying the storage container. The safety valve activates automatically at a corresponding high temperature. The storage container has an additional activatable emptying device, which has an interface for an external energy source. The interface can be connected to the external energy source in order to empty the storage container in a targeted manner. Also provided is a method for emptying a storage container for a pressurized gas in a motor vehicle.

Disclosed herein are flow control devices including at least one remote temperature sensor configured to determine first temperature data associated with air outside of a dwelling; a valve configured to control a first flow rate of the liquid flowing from an inlet of the supply pipe along a controlled liquid flow path by moving a valve position from a closed position to an open position; a flow control component in fluid communication with the valve, and configured to control a second flow rate of the liquid flowing from the valve; at least one internal temperature sensor configured to determine second temperature data associated with air inside the dwelling; a controller communicatively connected to the temperature sensors and configured to control operation of the valve based at least on at least one of the first temperature data and the second temperature data; and a housing configured to contain the flow control device components and further configured to releasably attach to a spigot or spout of a supply pipe. Also disclosed herein are methods for using the disclosed devices.