Cryogenic storage vessel

We claim: 1. A cryogenic storage vessel comprising: an inner vessel defining a cryogen space; an outer vessel spaced apart from and surrounding the inner vessel, defining a thermally insulating space between the inner vessel and the outer vessel; a receptacle defining passages for delivery of liquefied gas from the cryogen space to outside the cryogenic storage vessel; the receptacle comprising: an elongated outer sleeve intersecting opposite sides of the inner vessel and defining an interior space that is fluidly sealed from the cryoqen space and in fluid communication with the thermally insulating space; an elongated inner sleeve with an open end supported from the outer vessel, the elongated inner sleeve extending into the interior space defined by the elongated outer sleeve, the elongated inner sleeve having a closed end opposite the open end, thereby defining a receptacle space that is fluidly isolated from the thermally insulating space; and a fluid communication channel extending between the elongated outer sleeve and the elongated inner sleeve and fluidly connecting the cryogen space to the receptacle space. 2. The cryogenic storage vessel of claim 1 , further comprising a valve located in the fluid communication channel operable between an open position and a closed position to control fluid flow between the cryogen space and the receptacle space. 3. The cryogenic storage vessel of claim 2 , wherein the valve is automatically opened when a pump is installed inside the receptacle, and the valve is automatically closed when the pump is removed from the receptacle. 4. The cryogenic storage vessel of claim 2 , further comprising a valve actuator disposed outside the cryogenic storage vessel and a link operatively connected with the valve actuator and the valve. 5. The cryogenic storage vessel of claim 4 , further comprising a conduit disposed between the inner sleeve and the outer sleeve extending between the valve actuator and the valve and fluidly isolated from the thermally insulating space and the interior space, wherein the link extends through the conduit. 6. The cryogenic storage vessel of claim 4 , wherein the link comprises a rod and a cable, and the rod is operatively connected with the valve actuator and the cable is operatively connected with the valve. 7. The cryogenic storage vessel of claim 4 , further comprising a sensor to detect the position of the cryogenic storage vessel, and a severing mechanism operatively connected with the sensor to sever the connection between one of (a) the link and the valve and (b) the link and the valve actuator, when the sensor detects a position that is an emergency condition. 8. The cryogenic storage vessel of claim 2 , wherein the valve is a check valve that is biased to stop fluid from flowing out of the cryogen space unless it is actuated into an open position. 9. The cryogenic storage vessel of claim 2 , wherein the valve is a wafer-type check valve. 10. The cryogenic storage vessel of claim 1 , wherein the receptacle is vertically oriented with a lower end, the lower end and the fluid communication channel both located near the bottom of the cryogen space, and further comprising a pump disposed inside the receptacle space with an inlet near the lower end. 11. The cryogenic storage vessel of claim 1 , wherein the fluid communication channel has a flexible construction that allows movement of the elongated inner sleeve relative to the elongated outer sleeve. 12. The cryogenic storage vessel of claim 11 , wherein the flexible construction comprises a bellows arrangement. 13. The cryogenic storage vessel of claim 1 , wherein the closed end of the elongated inner sleeve is supported by a guide that constrains movement in directions transverse to a longitudinal axis of the elongated inner sleeve. 14. The cryogenic storage vessel of claim 13 , wherein the guide further constrains at least one of axial movement of the elongated inner sleeve and rotational movement of the elongated inner sleeve. 15. The cryogenic storage vessel of claim 1 , further comprising a pump assembly, wherein the elongated inner sleeve and the pump assembly have cooperating surfaces that seal against each other when the pump assembly is installed within the elongated inner sleeve, thereby limiting the height within the elongated inner sleeve into which the liquefied gas can rise. 16. The cryogenic storage vessel of claim 15 , wherein the cooperating surfaces are formed by a collar that forms a ledge inside the elongated inner sleeve and a flange associated with the pump assembly. 17. The cryogenic storage vessel of claim 1 , further comprising a well extending below a floor of the outer vessel into which the receptacle space and the fluid communication channel extend, and a valve for selectively fluidly connecting the cryogen space with the receptacle space through the fluid communication channel. 18. The cryogenic storage vessel of claim 1 , further comprising: a collar extending around an inner surface of the receptacle and fluidly dividing the receptacle into a warm end and a cold end when a pump assembly is installed in the receptacle; a purge valve in fluid communication with a supply of pressurized purging gas; a first purge conduit fluidly connecting the purge valve with the warm end; a second purge conduit fluidly connecting the purge valve with the cold end; a drain valve in fluid communication with one of a second storage vessel and the cryogen space; a first drain conduit fluidly connecting the drain valve with the warm end; and a second drain conduit fluidly connecting the drain valve with the cold end. 19. The cryogenic storage vessel of claim 18 , further comprising a sensor detecting the concentration of gaseous fuel downstream from the drain valve. 20. The cryogenic storage vessel of claim 18 , further comprising a pressure sensor detecting the pressure downstream from the drain valve.