A heat dissipation assembly includes a case and a partition structure. The case has a chamber. The partition structure includes a partition wall vertically disposed in the chamber to separate a first flow path and a second flow path in the chamber, and the partition wall has a breach and a valve structure disposed at the breach, wherein the valve structure covers the breach when the valve structure is not pushed open. When a fluid pressure existed in a section of one of the first flow path and the second flow path which is adjacent to the valve structure is greater than a fluid pressure existed in a section of the other one of the first flow path and the second flow path which is adjacent to the valve structure, the valve structure is pushed away to expose at least a part of the breach.

An overflow and overheat shutoff safety gas inlet connector, comprising a gas inlet connector, to be connected to the gas source, with a gas inlet hole configured axially, a chamber configured on one end to be connected to the gas inlet hole, and a plurality of holding compartments configured on one side of the chamber, a connecting tube, in threaded connection with the gas inlet connector, with a convex portion on its one end, a transfer canal configured axially and going through the convex portion, said transfer canal matching the gas inlet hole, a first magnetic piece, made of a magnetic material, movably configured inside the chamber and matching the gas inlet hole and the transfer canal, able to seal the transfer canal when being pressed against the convex portion, a plurality of second magnetic pieces, made of a magnetic material, and a plurality of temperature control pieces.

A safety relief valve for a high-pressure hydrogen cylinder is provided therein with a compression spring and an adjusting nut. The adjusting nut can move up and down to adjust the pressure of the compression spring to compress a sealing plug, so as to adjust the pressure in the hydrogen cylinder to reach an upper limit of pressure relief, which is convenient. Meanwhile, the safety relief valve is provided therein with a fusible seal. When the temperature is lower than a melting point, the fusible seal solidifies, and the sealing plug keeps a gas outlet sealed to prevent hydrogen leakage. When the temperature is higher than the melting point, the fusible seal melts. When the pressure in the hydrogen cylinder is higher than the set upper limit, the sealing plug is forced to open, and the hydrogen flows from an exhaust hole to a hydrogen collection tube.

A valve assembly failsafe configured to be coupled to an actuator of a coolant control regulator assembly is provided. The valve assembly failsafe includes a wind arm, a spring that engages the wind arm under spring tension, a latch that engages the wind arm, a drive gear that engages the wind arm and the actuator, and a driver that engages the latch. The valve assembly failsafe is configured to be positioned in a set state where the latch engages and retains the wind arm under spring tension and the drive gear freely rotates during rotation of the actuator, and a tripped state where the driver rotates the latch to disengage the latch from the wind arm, causing the wind arm to rotate under the spring tension to engage the drive gear and cause the drive gear to drive the actuator to a default position.

Fluid detection systems and methods using the same are disclosed. In embodiments the fluid detection systems include a sensor module and an electronics module. The sensor module includes a sensor housing that includes a liquid flow path and a sensor element disposed around at least part of the liquid flow path. The sensor element can detect a capacitance of the liquid flow path and provide a sensor signal to a controller in the electronics module. The electronics module can determine a detected capacitance in the liquid flow path based at least in part on the sensor signal, and can determine whether a wet event has occurred based on a comparison of the detected capacitance to a threshold capacitance. Methods using the fluid detection systems and fluid supply systems including the fluid detection systems are also disclosed.

In an embodiment, a system comprises a valve disc configured in an overpressure protection device. The system can also include a valve gasket configured to rest on the valve disc. The system also includes a valve seat configured above the valve gasket, wherein the valve gasket is sealed in between the valve seat and the valve disc. The system further includes a supporting structure configured above the valve seat. The supporting structure is configured to enable the valve gasket to remain in position between the valve disc and the valve seat in response to an increase in pressure.

In an embodiment, a system comprises a valve disc configured in an overpressure protection device. The system can also include a valve gasket configured to rest on the valve disc. The system also includes a valve seat configured above the valve gasket, wherein the valve gasket is sealed in between the valve seat and the valve disc. The system further includes a supporting structure configured above the valve seat. The supporting structure is configured to enable the valve gasket to remain in position between the valve disc and the valve seat in response to an increase in pressure.

A safety relief valve for a high-pressure hydrogen cylinder is provided therein with a compression spring and an adjusting nut. The adjusting nut can move up and down to adjust the pressure of the compression spring to compress a sealing plug, so as to adjust the pressure in the hydrogen cylinder to reach an upper limit of pressure relief, which is convenient. Meanwhile, the safety relief valve is provided therein with a fusible seal. When the temperature is lower than a melting point, the fusible seal solidifies, and the sealing plug keeps a gas outlet sealed to prevent hydrogen leakage. When the temperature is higher than the melting point, the fusible seal melts. When the pressure in the hydrogen cylinder is higher than the set upper limit, the sealing plug is forced to open, and the hydrogen flows from an exhaust hole to a hydrogen collection tube.

A pressure and temperature valve comprising a pressure relief valve (100) and a temperature probe (200). The pressure relief valve comprises a valve seat (14) and a valve member (20) arranged to rest in contact with the valve seat to close the valve and to be lifted off the valve seat to open the valve. The temperature probe (200) comprises a housing (52), a volume of expansion material (62) within the housing, a piston (64) slidable within the housing and arranged to be moved in a first direction by expansion of the expansion material, and in a second direction opposite to the first direction on contraction of the expansion material. A lift rod (90) is arranged to be moved by movement of the piston (64) in the first direction thereby to move the valve member (20) to open the valve.

A temperature pressure relief device includes a body including an inlet passage into which high-pressure gas is introduced, an interior passage extending from the inlet passage in a predetermined first direction, and a high-pressure gas exhaust passage that is formed between the inlet passage and a reference end that is a distal end of the interior passage in the first direction and that connects the interior passage to an outside, a blocking part disposed in the interior passage of the body and selectively placed in one of a blocking state or a connecting state, and a support part arranged between the blocking part and the reference end, in which the support part is maintained in a solid state at a reference temperature or less and is in a molten state at more than the reference temperature and discharged from the interior passage.