An integrated pressure regulator is provided with three stages configured to reduce an extreme tank pressure down to a typical working pressure. The regulator is configured to supply a steady working pressure until the tank pressure is reduced to little more than the working pressure itself. Stages of the pressure regulator are integrated into a body and arranged to minimize regulator mass and volume. A thermally-triggered pressure relief device may be included with a triggering time adapted to enhance the safety of smaller cylinders that may be used, e.g., in aerial applications.

A fluid discharge event detection apparatus measures a change in capacitance to detect the presence of a fluid in a sensing conduit where the presence of fluid indicates a discharge event. The apparatus includes a first conduit, the sensing conduit and a control valve, coupled between the first conduit and the sensing conduit. The control valve is configured to activate and fluidly couple the first conduit and the sensing conduit to one another when the control valve detects at least one predetermined condition of a fluid within the first conduit. A sensor, configured to measure a capacitance value, is disposed about the sensing conduit. A controller, coupled to the sensor, is configured to detect a change in the sensing conduit capacitance value and assert an alarm condition upon detection of the change in the sensing conduit capacitance value.

The present invention relates to a portable thermal container (1) for consumer products (2′) comprising at least a storing chamber (2) of the consumer products (2′) and at least a reaction chamber (4) of a reagent component (5′) and a of a reactive component (5″), wherein the reaction chamber (4) extends substantially entirely along the dimension of the largest dimension of the portable thermal container (1) and the storing chamber (2) is arranged side-by-side to the reaction chamber (4) to maximize the thermal exchange between the reaction chamber (4) and the storing chamber (2) in an homogeneous way, and the reaction chamber (4) comprises at least a storing portion and at least an expansion portion, wherein the total volume of said expansion portions is greater than the total volume of said storing portions to allow the safe expansion of the chemical reaction gases in said reaction chamber (4).

A thermal relief device (1) is described comprising a housing (2) having an inlet (3) and an outlet (4) connected by a relief channel (5). Such a thermal relief device should have a simple construction. To this end a microporous structure (10) is arranged between inlet (3) and outlet (4).

A composite valve apparatus is attachable to an attachment hole. A relief-valve mechanism includes a first valve movable in the depthwise direction of an attachment hole. A thermo-valve mechanism includes a second valve fastened to a thermo actuator, and a cylindrical body that retains therein the second valve. The first valve of the relief-valve mechanism and the second valve of the thermo-valve mechanism have respective axial lines overlapping with each other. The thermo actuator is supported by the first valve, and the cylindrical body is fastened to or integrated with the first valve.

A pressure relief valve may comprise a housing, a disk, and a seal. The disk may be configured to deflect relative to the housing. The seal may form a sealing interface with at least one of the housing or disk. The pressure relief valve may be coupled to an inflatable slide or an aspirator.

The invention relates to an intelligent safety valve comprising a valve body having a first valve inlet, a valve outlet and a first sensor compartment, the first sensor compartment including a first sensor assembly, the first sensor compartment being arranged in the valve body, a first closing unit suitable for closing the intelligent safety valve, an actuator mechanically connected to the first closing unit in order to close the first closing unit, and a control unit which is connected to the actuator and is suitable for controlling the actuator, wherein the control unit is connected to the first sensor assembly in order to evaluate sets of measured values from the first sensor assembly, and wherein the first sensor assembly comprises at least one analysis sensor, for example a pH sensor, a conductivity sensor or an oxygen sensor.

The invention relates to an intelligent safety valve comprising a valve body having a first valve inlet, a valve outlet and a first sensor compartment, the first sensor compartment including a first sensor assembly, the first sensor compartment being arranged in the valve body, a first closing unit suitable for closing the intelligent safety valve, an actuator mechanically connected to the first closing unit in order to close the first closing unit, and a control unit which is connected to the actuator and is suitable for controlling the actuator, wherein the control unit is connected to the first sensor assembly in order to evaluate sets of measured values from the first sensor assembly, and wherein the first sensor assembly comprises at least one analysis sensor, for example a pH sensor, a conductivity sensor or an oxygen sensor.

A battery box comprises: a box frame, a heat management component, and an outer plate. The heat management component is disposed on one side of the box frame and is configured to adjust temperature of a battery housed in the battery box; the outer plate is arranged adjacent to the heat management component and is configured to make the heat management component cover on the box frame, and the outer plate is provided with a balance valve, the balance valve is configured to connect a cavity between the outer plate and the heat management component communicate with outside air.