Vessel including insulating corner blocks provided with stress relief slots

The invention claimed is: 1. A sealed and thermally-insulating fluid storage tank comprising at least one thermally insulating barrier ( 5 ) retained on a supporting structure ( 3 ) and a sealing membrane ( 6 ) supported by said thermally insulating barrier ( 5 ), the thermally insulating barrier ( 5 ) comprising a plurality of insulating panels ( 9 , 57 , 58 ) retained on the supporting structure ( 3 ) and juxtaposed against at least one first and one second adjacent walls ( 1 , 2 ) of the supporting structure ( 3 ); the tank further comprising an angle arrangement ( 12 ) placed at an intersection ( 4 ) between the first and the second adjacent walls ( 1 , 2 ) and comprising: a first and a second insulating blocks ( 30 , 31 ) respectively retained on the first and second adjacent walls ( 1 , 2 ) of the supporting structure and forming a corner of the thermally insulating barrier ( 5 ); each of the first and second insulating blocks ( 30 , 31 ) comprising an outer face placed facing the supporting structure ( 3 ) and an inner face comprising metal plates ( 38 ) spaced apart from one another along the intersection between the first and the second adjacent walls ( 1 , 2 ); said first and second insulating blocks ( 30 , 31 ) comprising a layer of polymer foam ( 34 ); and a metal angle structure ( 49 , 50 , 51 ) forming a corner of the sealing membrane ( 6 ) and comprising a first and a second wings which are respectively welded onto the metal plates ( 38 ) of the first and second insulating blocks ( 30 , 31 ); each of the first and second insulating blocks ( 30 , 31 ) being associated with an adjacent panel ( 9 ) of the plurality of insulating panels ( 9 , 57 , 58 ) via a bridging element ( 44 ); said bridging element ( 44 ) being fixed straddling an edge ( 47 ), parallel to the intersection ( 4 ), of the inner face of said first or second insulating block ( 30 , 31 ) and an inner face of the adjacent panel ( 9 ), so as to oppose a mutual separation of said first or second insulating block ( 30 , 31 ) and of said adjacent panel ( 9 ), said bridging element being placed between the sealing membrane ( 6 ) and the supporting structure ( 3 ); each of the first and second insulating blocks ( 30 , 31 ) having at least one first and one second stress-relief slots ( 45 , 48 ) formed in the inner face of said first or second insulating block ( 30 , 31 ) in the thickness of the layer of polymer foam ( 34 ); the first stress-relief slot ( 45 ) extending parallel to the intersection ( 4 ), said first stress-relief slot ( 45 ) being situated so as to pass between the edge ( 47 ) of the inner face of the insulating block ( 30 , 31 ) receiving the bridging element ( 44 ) and the metal plates ( 38 ) of said insulating block ( 30 , 31 ); the second stress-relief slot ( 48 ) extending at right angles to the intersection ( 4 ), said second stress-relief slot ( 45 ) being situated so as to pass between two of the metal plates ( 38 ) of said insulating block ( 30 , 31 ). 2. The tank as claimed in claim 1 , in which the bridging elements are bridging plates ( 44 ) which each have an outer face resting against the inner face of the first or of the second insulating block ( 30 , 31 ) and the inner face of the adjacent panel ( 9 ) and an inner face supporting the sealing membrane ( 6 ). 3. The tank as claimed in claim 1 , in which each of the first and second insulating blocks ( 30 , 31 ) comprises a series of second stress-relief slots ( 48 ) extending at right angles to the intersection between the first and the second adjacent walls ( 1 , 2 ), each of said second stress-relief slots ( 48 ) being situated in a respective interval between two of the metal plates ( 38 ) of said insulating block ( 30 , 31 ). 4. The tank as claimed in claim 3 , in which the series of second stress-relief slots ( 48 ) extending at right angles to the intersection comprises at least one central second stress-relief slot ( 48 b ) and two end second stress-relief slots ( 48 a ) which extend on either side of the central second stress-relief slot ( 48 b ), the central second stress-relief slot ( 48 b ) having a depth greater than that of each of the end stress-relief slots ( 48 b ). 5. The tank as claimed in claim 1 , in which the or each second stress-relief slot ( 48 ) extending at right angles to the intersection extends from an edge ( 32 ) of the insulating block which is adjacent to the intersection to the first stress-relief slot ( 45 ). 6. The tank as claimed in claim 1 , in which the first and the second insulating blocks ( 30 , 31 ) are respectively retained on the first and the second adjacent walls ( 1 , 2 ) of the supporting structure ( 3 ) by means of a plurality of threaded studs fixed to the supporting structure ( 3 ), each of said first and second insulating blocks ( 30 , 31 ) being provided with cylindrical wells ( 33 ), each threaded stud being anchored in one of the the cylindrical wells ( 33 ); said cylindrical wells ( 33 ) being formed along the edge ( 47 ) of said each of said first and second insulating blocks ( 30 , 31 ) adjacent to an insulating panel ( 9 ). 7. The tank as claimed in claim 1 , in which the metal angle structure comprises an angle iron ( 49 ) and a pair of metal strips ( 50 , 51 ) lap-welded with the angle iron ( 49 ), one of the angle iron ( 49 ) and the pair of metal strips ( 50 , 51 ) being welded onto the metal plates ( 38 ) of the first and of the second insulating blocks ( 30 , 31 ). 8. The tank as claimed in claim 1 , in which the wings of the metal angle structure ( 49 , 50 , 51 ) are planar. 9. The tank as claimed in claim 1 , in which the plurality of insulating panels ( 9 , 57 , 58 ) have an inner face equipped with metal plates ( 16 , 17 ), in which the sealing membrane ( 6 ) comprises a plurality of corrugated metal sheets ( 18 , 28 ) which are welded onto the metal plates ( 16 , 17 ) of the insulating panels ( 9 , 57 , 58 ) and in which the metal angle structure ( 49 , 50 , 51 ) is connected by tight welding to the corrugated metal sheets ( 16 , 17 ). 10. The tank as claimed in claim 1 , in which the thermally insulating barrier is a secondary thermally insulating barrier ( 5 ) and the sealing membrane is a secondary sealing membrane ( 6 ), the tank further comprising a primary thermally insulating barrier ( 7 ) anchored to the second thermally insulating barrier ( 5 ) by retaining members ( 19 ) and a primary sealing membrane ( 8 ) supported by the primary thermally insulating barrier ( 7 ) and intended to be in contact with the fluid contained in the tank. 11. The tank as claimed in claim 10 , in which the angle arrangement ( 12 ) comprises primary insulating blocks ( 41 , 42 ) forming a corner of the primary thermally insulating barrier ( 7 ) which are each retained against one or other of the first and second insulating blocks ( 30 , 31 ) by means of studs ( 40 ) supported by the metal plates ( 38 ) of the first and second insulating blocks ( 30 , 31 ). 12. The tank as claimed in claim 11 , in which the metal angle structure ( 49 , 50 , 51 ) comprises orifices through which pass the studs ( 40 ) supported by the metal plates ( 38 ) of the first and second insulating blocks ( 30 , 31 ), the metal angle structure ( 49 , 50 , 51 ) being welded to said metal plates ( 38 ) at the periphery of said orifices. 13. A ship ( 70 ) for transporting a fluid, the ship comprising a hull ( 72 ) and a tank ( 71 ) as claimed in claim 1 placed in the hull. 14. A method for loading or offloading a ship ( 70 ) as claimed in claim 13 , in which a fluid is routed through insulated pipelines ( 73 , 79 , 76