Provided herein are methods, systems, and devices incorporating use of materials to store, ship, and deliver process gases to micro-electronics fabrication processes and other critical process applications.

Provided herein are methods, systems, and devices incorporating use of materials to store, ship, and deliver process gases to micro-electronics fabrication processes and other critical process applications.

Provided herein are methods, systems, and devices incorporating use of materials to store, ship, and deliver process gases to micro-electronics fabrication processes and other critical process applications.

The present disclosure provides for a porous gas sorbent monolith with superior gravimetric working capacity and volumetric capacity, a gas storage system including a porous gas sorbent monolith of the present disclosure, methods of making the same, and method for storing a gas. The porous gas sorbent monolith includes a gas adsorbing material and a non-aqueous binder.

Methods of contacting a fluid comprising a light hydrocarbon with a metal-organic framework adsorbent having bis(pyrazolyl) ethanediimine ligands and internal pores; adsorbing the fluid in at least a portion of the internal pores of the metal-organic framework thereby creating an adsorbed fluid; storing the adsorbed fluid in the internal pores of the metal-organic framework; and releasing the adsorbed fluid from the internal pores of the metal-organic framework, wherein the metal-organic framework adsorbent undertakes a reversible phase transition upon adsorbing the fluid. Systems of a metal-organic framework having bis(pyrazolyl) ethanediimine ligands and internal pores, wherein the metal-organic framework undertakes a reversible phase transition upon adsorption and desorption of a light hydrocarbon fluid; wherein the fluid is stored in the internal pores of the metal-organic framework.

A system for supplying hydrogen gas to an engine is disclosed. The system includes a main line configured to send hydrogen gas produced in a hydrogen gas producer by electrolysis to a supply line; a sub-line configured to send hydrogen gas from a hydrogen absorbing alloy cylinder to the main line, a governor configured to maintain an engine rotation speed within certain range; and a control device. The governor sends a signal corresponding to the engine rotation speed to the control device. A pressure regulating valve is disposed in the sub-line to be downstream with respect to the hydrogen absorbing alloy cylinder to regulate a supply amount of added hydrogen. An opening degree of the valve is adjusted based on a signal from the control device corresponding to the opening degree of the valve for supplying the added hydrogen with an amount according to a load state of the engine.

A heat generating system includes a heat-generating element cell and a circulation device. The heat-generating element cell includes a container having a recovery port and a discharge port, and a reactant that is provided in the container, is made from a hydrogen storage metal or a hydrogen storage alloy, has metal nanoparticles on a surface of the reactant. The heat-generating element cell generates excess heat when hydrogen-based gas contributing to heat generation is supplied into the container and hydrogen atoms are occluded in the metal nanoparticles. The circulation device circulates the hydrogen-based gas in the heat-generating element cell. The circulation device includes a circulating passage that is provided outside the container and connects the recovery port to the discharge port, a pump circulates the hydrogen-based gas in the container via the circulating passage, and a filter on the circulating passage adsorbs and removes the impurities in the hydrogen-based gas.

A heat generating system includes a heat-generating element cell and a circulation device. The heat-generating element cell includes a container having a recovery port and a discharge port, and a reactant that is provided in the container, is made from a hydrogen storage metal or a hydrogen storage alloy, has metal nanoparticles on a surface of the reactant. The heat-generating element cell generates excess heat when hydrogen-based gas contributing to heat generation is supplied into the container and hydrogen atoms are occluded in the metal nanoparticles. The circulation device circulates the hydrogen-based gas in the heat-generating element cell. The circulation device includes a circulating passage that is provided outside the container and connects the recovery port to the discharge port, a pump circulates the hydrogen-based gas in the container via the circulating passage, and a filter on the circulating passage adsorbs and removes the impurities in the hydrogen-based gas.

A hydrogen tank, preferably a tank for storing liquid hydrogen at low pressure in cryogenic condition, includes at least one gaseous hydrogen capture system. The system is provided with absorbent fillers configured to capture the gaseous hydrogen, the absorbent fillers being linked to at least a part of a wall of the tank, and/or to a skin arranged on an outer face of the tank, and/or to an outer jacket intended to implement an auxiliary function. The system has a reduced weight and is able to retain and store gaseous hydrogen which could escape from the tank so as to prevent it from being given off into the environment of the tank. The captured gaseous hydrogen is able to be restored later by the system.

Provided are methods for storing a gas. An example method comprises providing a vessel containing a manifold system and an adsorbent, the manifold system comprising: a gas tubing, a filter disposed over openings in the gas tubing, a pressure relief valve, and an inlet coupled to the gas tubing and the vessel. The method further comprises introducing the gas into the manifold system via the inlet; circulating the gas in the gas tubing; flowing the gas through the openings in the gas tubing; and adsorbing the gas onto the adsorbent.