초록 ▼

The subject of the invention is method and envelope structure for handling gas diffusion of airships and other balloons to significantly decrease, respectively fully eliminate envelope diffusion of gases through envelopes of airships and other balloons. During the method according to the invention t

The subject of the invention is method and envelope structure for handling gas diffusion of airships and other balloons to significantly decrease, respectively fully eliminate envelope diffusion of gases through envelopes of airships and other balloons. During the method according to the invention the gases diffused through the envelope (8, 9) of airships and other balloons are collected into a separator space (2). These gases are separated from the mixture of this separator space by physical and/or chemical action and forwarded back to their sources. The invention is further an envelope structure for handling gas diffusion of airships and other balloons for applying methods according to the invention.

대표청구항 ▼

The invention claimed is: 1. A method for handling gas diffusion through an envelope of an airship or balloon or hose-container, wherein the envelope is a multilayer envelope comprising at least one separator space, the method comprising, separating gases to their components which gases have penetr

The invention claimed is: 1. A method for handling gas diffusion through an envelope of an airship or balloon or hose-container, wherein the envelope is a multilayer envelope comprising at least one separator space, the method comprising, separating gases to their components which gases have penetrated from a gas container space and from surrounding air into the at least one separator space, and I) returning the separated gases back to their initial sources, and/or II) applying electrical gas diffusion inhibition to at least one layer of a material membrane forming the at least one separator space. 2. A method according to claim 1, wherein gases penetrated into the at least one separator space are separated by disjunctive separation. 3. A method according to claim 1, wherein the separated gases are piped into a fuel cell. 4. A method according to claim 1, wherein the envelope is an active isolation envelope and contains three separator spaces, and wherein the gas container space is filled with helium, or wherein the envelope is a null-diffusion envelope and contains two separator spaces, and wherein the gas container space is filled with hydrogen and/or helium. 5. A method according to claim 1, wherein at least one of the layers of the envelope is a static and/or alternating current potential space, optionally a gas diffusion inhibitor and optionally applying gas absorption and/or gas penetration. 6. A method according to claim 1, wherein vacuum gas-compound extraction is performed in at least one of the separator spaces. 7. A method according to claim 1, wherein a basic compound gas of positive or negative pressure is applied as intermediate gas-trap in at least one of the separator spaces. 8. A method according to claim 1, wherein gases penetrated into the at least one separator space are separated by adsorption, chemo-sorption, perm-selective membranes, liquefaction, or fractional distillation. 9. A multi-layer gas isolation envelope of an airship or balloon or hose-container for handling gas diffusion, comprising at least one separator space, and I) a gas separating apparatus, an inlet of which is connected to at least one separator space, and an outlet of which is connected to a gas container space allowing the return of a separated gas to the gas container space, and another outlet of which is connected to the surrounding air, and/or II) an electrical gas diffusion inhibitor in or on at least one layer of a material membrane forming the at least one separator space. 10. An envelope according to claim 9, wherein in the envelope there are three isolation material layers and these layers constitute two, an inner and an outer separator spaces, thereby the layers forming a multi-layer closed envelope around a gas container space, and an inlet of the gas separating apparatus is connected to a gas compound outlets of the inner and outer separator spaces, and a gas feedback of the gas separating apparatus is connected to an outer separator space. 11. An envelope according to claim 9, wherein in the envelope there are four isolation material layers and these layers constitute three, an inner, an outer and an interval separator spaces, thereby the interval separator space is located between the inner and the outer separator spaces, and an inlet of the gas separating apparatus is connected to a gas compound outlets of the inner and outer separator spaces, and a gas feedback of the gas-separating apparatus is connected to the interval separator space. 12. A method according to claim 1, wherein the envelope comprises two or more separator spaces to which a gas separator is attached, and wherein the gas in the gas container space is hydrogen and/or helium. 13. A method according to claim 1, wherein the gas container space is filled with hydrogen, and wherein hydrogen is separated from the gases from the at least one separator space by a perm-selective membrane, optionally by conduction of the hydrogen through a glowing palladium membrane or by adsorption or chemo-sorption. 14. A method according to claim 1, wherein the gas container space is filled with helium, and wherein the helium is separated from the gases from the at least one separator space in a way that other gas components are separated to achieve the helium as residuum gas. 15. A method according to claim 1, wherein I), the separated gases are returned back to their initial sources. 16. A method according to claim 1, wherein II) electrical gas inhibition diffusion is applied to at least one layer of a material membrane forming the at least one separator space. 17. A multi-layer gas isolation envelope according to claim 9, which comprises I) a gas separating apparatus, an inlet of which is connected to at least one separator space, and an outlet of which is connected to a gas container space allowing the return of a separated gas to the gas container space, and another outlet of which is connected to the surrounding air. 18. A multi-layer gas isolation envelope according to claim 9, which comprises II) an electrical gas diffusion inhibitor in or on at least one layer of a material membrane forming the at least one separator space. 19. A method for handling gas diffusion during storage of a gas through an envelope of a gas storage container, wherein the envelope is a multilayer envelope comprising at least one separator space, the method comprising, separating gases to their components which gases have penetrated from a gas container space and from surrounding air into the at least one separator space, and I) returning the separated gases back to their initial sources, and/or II) applying electrical gas diffusion inhibition to at least one layer of a material membrane forming the at least one separator space. 20. A method according to claim 19, wherein the gas is hydrogen fuel.