Claims
- 1. In a process for liquefying hydrogen wherein a hydrogen stream is compressed, cooled, and catalytically converted in a multiplicity of steps from a largely ortho form of hydrogen to a largely para form of hydrogen, said converted, cooled, compressed hydrogen stream is expanded in an expander whereby said converted hydrogen stream is partially condensed, said partially condensed hydrogen stream is separated into a liquid phase and gaseous phase, said gaseous phase is warmed to recover refrigeration and recompressed and combined with said compressed hydrogen stream prior to cooling, and said liquid phase is withdrawn as a liquid hydrogen product, the improvement comprising utilizing a dense fluid expander preceding said final step of catalytic conversion to expand and further refrigerate said converted, cooled, compressed hydrogen stream and utilizing a closed-loop neon refrigeration cycle to provide at least intermediate refrigeration to said process prior to said final step of catalytic conversion.
- 2. The process of claim 1 which further comprises providing additional refrigeration for cooling of said compressed hydrogen stream.
- 3. The process of claim 1 which further comprises providing additional refrigeration for precooling neon in said closed-loop neon refrigeration cycle.
- 4. The process of claim 1 which further comprises providing additional refrigeration for cooling of said compressed hydrogen stream and for precooling neon in said closed-loop neon refrigeration cycle.
- 5. A process for the liquefaction of hydrogen which comprises:
- (a) compressing and cooling a gaseous hydrogen feed stream;
- (b) combining said compressed hydrogen feed stream with a compressed, recycled hydrogen stream from step (g) to form a combined hydrogen feed stream;
- (c) cooling said combined hydrogen feed stream by heat exchange with the warming recycled hydrogen stream and a closed loop neon refrigeration cycle;
- (d) converting said cooled, combined hydrogen feed stream in two stages in a first and second converter/heat exchanger from a largely ortho form of hydrogen to a largely para form of hydrogen while simultaneously further cooling said combined hydrogen feed stream by heat exchange with the closed-loop neon refrigeration cycle and the warming recycled hydrogen stream;
- (e) expanding the converted, combined hydrogen feed stream in a dense fluid expander whereby the converted, combined hydrogen feed stream is partially condensed;
- (f) separating said partially condensed hydrogen feed stream of step (e) into a gaseous phase and liquid phase wherein said gaseous phase is used to form a recycle hydrogen stream and said liquid phase is further converted to increase para-hydrogen concentration and removed as a liquid hydrogen product stream;
- (g) warming said recycle hydrogen stream to recover refrigeration and then compressing said recycle hydrogen stream prior to combining said recycle hydrogen stream with said compressed hydrogen feed stream in step (b);
- (h) compressing and precooling a closed-loop neon refrigeration stream;
- (i) splitting said closed-loop neon refrigeration stream into a first portion and a second portion;
- (j) further cooling said first portion and then expanding said cooled first portion in a turbine;
- (k) warming said first portion from step (j) in said second converter/heat exchanger thereby providing refrigeration;
- (l) expanding said second portion in an expander and combining said expanded second portion with said warmed first portion from step (k) into a recombined closed-loop neon refrigeration stream;
- (m) warming said recombined closed-loop refrigeration stream in said first converter/heat exchanger thereby providing refrigeration;
- (n) further warming said recombined closed-loop neon refrigeration stream to recover refrigeration value; and
- (o) recycling said recombined closed-loop neon refrigeration stream to step (h) as said closed-loop neon refrigeration stream.
- 6. The process of claim 5 which further comprises providing refrigeration for said cooling in step (c) and said precooling in step (h) with liquid and cold gaseous nitrogen.
Government Interests
The present invention was made under Air Force Contract No. FO-4611-85-C-4039 (AFRPL) and is subject to government rights arising therefrom.
US Referenced Citations (13)
Non-Patent Literature Citations (2)
Entry |
"A Plant for the Production of Liquid Hydrogen with Neon as an Intermediate Working Substance", K. Clusius, Kalte-Industrie 39, 1932. |
"Hydrogen Liquefaction Using Centrifugal Compressors", C. R. Baker, Hydrogen Energy Progress, vol. 3, 1982. |