Ti–V–Mn based alloys for hydrogen compression system

“…For the Ti-V-Fe system within the pressure range of 0.02-20 atm, we have not observed two distinct plateau regions as reported in some earlier studies on Ti-V-Fe systems. Dehouche et al [5] studied the hydriding properties of Mn substituted Ti 0.9 Zr 0.1 V x Mn y alloys which are similar in composition to our Ti-V-Fe-Zr system and reported that the first plateau pressure is very close to 0 atm. With increasing temperature the length of the plateau region is found to decrease as expected, though the increase in the plateau pressure is beyond the detection limit of our setup.…”

“…Recently, Ti-V based systems with body centered cubic (BCC) structure have been identified as potential materials for hydrogen storage applications, due to their remarkable hydrogen-absorbing capacity [1][2][3][4][5]. However, these alloys suffer from certain disadvantages like difficulty in the activation for hydrogen absorption, slow kinetics, large hysteresis, low cyclic durability and high cost [6].…”

Hydrogen absorption characteristics of Zr substituted Ti0.85VFe0.15Ti0.85VFe0.15 alloy

“…For the Ti-V-Fe system within the pressure range of 0.02-20 atm, we have not observed two distinct plateau regions as reported in some earlier studies on Ti-V-Fe systems. Dehouche et al [5] studied the hydriding properties of Mn substituted Ti 0.9 Zr 0.1 V x Mn y alloys which are similar in composition to our Ti-V-Fe-Zr system and reported that the first plateau pressure is very close to 0 atm. With increasing temperature the length of the plateau region is found to decrease as expected, though the increase in the plateau pressure is beyond the detection limit of our setup.…”

“…Recently, Ti-V based systems with body centered cubic (BCC) structure have been identified as potential materials for hydrogen storage applications, due to their remarkable hydrogen-absorbing capacity [1][2][3][4][5]. However, these alloys suffer from certain disadvantages like difficulty in the activation for hydrogen absorption, slow kinetics, large hysteresis, low cyclic durability and high cost [6].…”

Hydrogen absorption characteristics of Zr substituted Ti0.85VFe0.15Ti0.85VFe0.15 alloy

“…Metal hydride materials for high-pressure hydrogen compressors have been investigated by researchers. AB 5 [1][2][3][4][5] and AB 2 [5][6][7][8] hydrogen storage alloys have been developed to be hydrogen compression materials. The maximum product hydrogen pressure that has been reported is about 45 MPa [5].…”

Laves phase hydrogen storage alloys for super-high-pressure metal hydride hydrogen compressors

“…High-pressure storage is restricted by the cylinders weight and safety issues. Metal hydrides present higher energy density (6.5 H atoms/cm 3 for MgH 2 ) than compressed hydrogen gas (0.99 H atoms/cm 3 ) and liquid hydrogen (4.2 H atoms/cm 3 ) [40,41]. In this context the storage of hydrogen in metal hydride form presents a low-pressure safe and promising solution for stationary applications, such as domestic use.…”

Solar hydrogen system for cooking applications: Experimental and numerical study