Method for producing a sealed and thermally insulating barrier for a storage tank

The invention claimed is: 1. A method for producing a sealed and thermally insulating wall for a fluid storage tank, comprising the steps of: attaching a plurality of anchoring elements ( 1 ) to a support structure ( 2 ); installing modular formwork elements ( 3 ) on the support structure ( 2 ), the modular formwork elements ( 3 ) having a shape that protrudes relative to the support structure ( 2 ) and that defines, with the support structure ( 2 ) and the plurality of anchoring elements ( 1 ), mutually adjacent compartments ( 4 ) having an open side opposite the support structure ( 2 ), two mutually adjacent compartments being separated in each case by one of the modular formwork element positioned between the two mutually adjacent compartments; spraying insulating foam into said compartments ( 4 ) through the open side so as to form a plurality of insulating sectors ( 5 ) made from sprayed insulating foam withdrawing the modular formwork elements ( 3 ); arranging compressible insulating junction elements ( 8 ) in place of the modular formwork elements ( 3 ), the insulating junction elements ( 8 ) being arranged in a stressed position in which the compressible insulating junction elements ( 8 ) are compressed between said insulating sectors ( 5 ) and capable of expanding when said insulating sectors ( 5 ) contract, so as to ensure continuity of a thermal insulation layer comprising the insulating junction elements ( 8 ) and the insulating sectors ( 5 ); and attaching a sealing membrane ( 9 ) to said anchoring elements ( 1 ). 2. A method for producing a sealed and thermally insulating wall for a fluid storage tank, comprising the steps of: attaching a plurality of anchoring elements ( 1 ) to a support structure ( 2 ); installing combined elements on the support structure ( 2 ), each combined element comprising one of the modular formwork elements ( 3 ) and a compressible insulating junction element ( 8 ) housed under stress in a compressed way within the modular formwork element ( 3 ); the modular formwork elements ( 3 ) having a shape that protrudes relative to the support structure ( 2 ) and that defines, with the support structure ( 2 ) and the plurality of anchoring elements ( 1 ), mutually adjacent compartments ( 4 ) having an open side opposite the support structure ( 2 ), two mutually adjacent compartments being separated in each case by one of the modular formwork elements positioned between the two mutually adjacent compartments; spraying insulating foam into said compartments ( 4 ) through the open side so as to form a plurality of insulating sectors ( 5 ) made from sprayed insulating foam; withdrawing the modular formwork elements ( 3 ); the insulating junction elements ( 8 ) being left, in a stressed position, between said insulating sectors ( 5 ) when the modular formwork elements ( 3 ) are withdrawn, the insulating junction elements ( 8 ) being, in their stressed position, compressed between said insulating sectors ( 5 ) and capable of expanding when said insulating sectors ( 5 ) contract, so as to ensure continuity of a thermal insulation layer comprising the insulating junction elements ( 8 ) and the insulating sectors ( 5 ); and attaching a sealing membrane ( 9 ) to said anchoring elements ( 1 ). 3. A method for producing a sealed and thermally insulating wall for a fluid storage tank, comprising the steps of: attaching a plurality of anchoring elements ( 1 ) to a support structure ( 2 ); installing combined elements on the support structure ( 2 ), each combined element comprising one of the modular formwork elements ( 3 ) and a compressible insulating junction element ( 8 ), the modular formwork element ( 3 ) comprising two permanent formwork sides ( 27 ) between which one of the insulating junction elements ( 8 ) is housed under stress, and releasable means ( 28 ) for clamping the sides ( 27 ), these releasable means ( 28 ) for clamping the sides ( 27 ) being capable of clamping the two permanent formwork sides ( 27 ) against the insulating junction element ( 8 ) in a non-released state and of no longer clamping the two permanent formwork sides ( 27 ) in a released state; the modular formwork elements ( 3 ) having a shape that protrudes relative to the support structure ( 2 ) and that defines, with the support structure ( 2 ) and the plurality of anchoring elements ( 1 ), mutually adjacent compartments ( 4 ) having an open side opposite the support structure ( 2 ), two mutually adjacent compartments being separated in each case by one of the modular formwork elements ( 3 ) positioned between the two mutually adjacent compartments; spraying insulating foam into said compartments ( 4 ) through the open side so as to form a plurality of insulating sectors ( 5 ) made from sprayed insulating foam; releasing the releasable means ( 28 ) for clamping the sides ( 27 ) so as to place the insulating junction elements ( 8 ) in a stressed position in which the insulating junction elements ( 8 ) are compressed between said insulating sectors ( 5 ) and capable of expanding when said insulating sectors ( 5 ) contract, so as to ensure continuity of a thermal insulation layer comprising the insulating junction elements ( 8 ) and the insulating sectors ( 5 ); each insulating junction element ( 8 ), in its stressed position, causing the two permanent formwork sides ( 27 ) of the combined element to which it belongs to engage with the insulating sectors ( 5 ) between which said two permanent formwork sides are located; and attaching a sealing membrane ( 9 ) to said anchoring elements ( 1 ). 4. The production method as claimed in claim 1 , wherein a modular formwork element ( 3 ) has an anti-adhesion coating ( 25 ). 5. The production method as claimed in claim 1 , wherein an insulating junction element ( 8 ) comprises a profiled element having two resilient flanges ( 29 ) which, in a stressed position between the insulating sectors ( 5 ), are stressed toward one another and exert a reactive force tending to separate them from one another. 6. The production method as claimed in claim 5 , wherein the profiled element having two resilient flanges is produced from a foam made of a polymer selected from among polyurethane, melamine, polyethylene, polypropylene, polystyrene and silicone. 7. The production method as claimed in claim 1 , wherein an insulating junction element ( 8 ) comprises a strip made of a compressible material selected from among glass wool, polyester wadding, and foams of polyurethane, melamine, polyethylene, polypropylene or silicone. 8. The production method as claimed in claim 1 , comprising a step of trimming the insulating sectors ( 5 ). 9. The production method as claimed in claim 1 , wherein an anchoring element is a block ( 1 ) fitted with a member ( 13 , 14 ) for anchoring to the support structure ( 2 ) and an element ( 16 , 17 , 18 , 21 ) for attaching the sealing membrane ( 9 ), and having at least one thermally insulating layer ( 10 ). 10. The production method as claimed in claim 8 , wherein the thermally insulating layer ( 10 ) of the block ( 1 ) is made of polymer foam having a density of more than 100 kg/m3, or of wood. 11. The production method as claimed in claim 9 , comprising a step of attaching anchoring plates ( 23 ) between the adjacent anchoring blocks ( 1 ) and a step of welding the sealing membrane ( 9 ) onto said anchoring plates ( 1 ). 12. The production method as claimed in claim 1 , wherein, during the installation of modular formwork elements ( 3 ) on the support structure ( 2 ), the modular formwork elements ( 3 ) are attached to the support structure ( 2 ) and/or to the anchoring elements ( 1 ). 13. A sealed