초록 ▼

A method of forming a three-dimensional frame structure is provided. The structure includes a plurality of rigid wall panels that are adhesively secured to components of a system. The components are specially designed to allow for adjusting the dimensions of a wall panel. The method generally compri

A method of forming a three-dimensional frame structure is provided. The structure includes a plurality of rigid wall panels that are adhesively secured to components of a system. The components are specially designed to allow for adjusting the dimensions of a wall panel. The method generally comprises providing a series of corner castings, and providing a series of linear extrusion members. The method also includes connecting the series of corner castings and the plurality of linear extrusion members to form a three-dimensional frame, and adhesively securing rigid wall panels to the three-dimensional frame to form the frame structure. The rigid panels may include porcelain ceramic tiles, natural stone tiles, or other panels.

대표청구항 ▼

1. A method of forming a three-dimensional frame structure for a wall, comprising: providing a series of corner castings including: two or more two-legged cube connectors, wherein legs of each of the two-legged cube connectors form a two-legged orthogonal x-y coordinate,two or more planar three-legg

1. A method of forming a three-dimensional frame structure for a wall, comprising: providing a series of corner castings including: two or more two-legged cube connectors, wherein legs of each of the two-legged cube connectors form a two-legged orthogonal x-y coordinate,two or more planar three-legged cube connectors, wherein legs of each of the planar three-legged cube connectors form a three-legged orthogonal x-y coordinate, andtwo or more orthogonal three-legged cube connectors, wherein legs of each of the orthogonal three-legged cube connectors form an orthogonal x-y-z coordinate;providing a series of linear extrusion members, wherein: each linear extrusion member comprises an opening at both a first end and a second end, with the openings being configured to slidably receive the legs of the two-legged and the three-legged cube connectors;at least two of the series of linear extrusion members serve as panel perimeter strips and comprise a receiving member that gravitationally hangs onto wing members of respective attachment clips secured to an edifice of a building to support a dead load of the three-dimensional frame structure; andat least two others of the linear extrusion members serve as corner connector strips and do not have the receiving member for the attachment clip;connecting the series of corner castings and the series of linear extrusion members to form a three-dimensional framework; andsecuring rigid wall panels to exterior surfaces of the three-dimensional framework to form the three-dimensional frame structure. 2. The method of claim 1, wherein the securing rigid wall panels to exterior surfaces of the three-dimensional framework comprises adhesively securing the rigid wall panels to the exterior surfaces of the three-dimensional framework to form the frame structure. 3. The method of claim 1, further comprising: providing a plurality of keys, with each key defining an approximately orthogonal metal component dimensioned and configured to be received within slots of selected adjacent panel perimeter strips;inserting keys into the slots of adjacent panel perimeter strips in order to orient and secure the panel perimeter strips in approximately orthogonal relation;adhesively securing a square rigid wall panel to the panel perimeter strips that have been joined together using the keys, without securing the rigid wall panel to a respective said cube connector; andhanging the square rigid wall panel onto a wall adjacent the three-dimensional frame structure;and wherein the providing the plurality of keys comprises selecting keys from the group consisting of (i) a 90-degree perimeter clip key, (ii) an 87-degree perimeter clip key, (iii) a 93-degree perimeter clip key, and combinations thereof. 4. The method of claim 1, wherein the two-legged cube connectors, the planar three-legged cube connectors, and the orthogonal three-legged cube connectors are interchangeable, without cutting, to provide different shaped corner castings. 5. The method of claim 4, wherein the linear extrusion members are provided in various lengths, off-the-shelf, to enable the connection of corner castings at a construction site, without cutting. 6. A method of forming a three-dimensional frame structure for a wall, comprising: providing a series of corner castings, with the series of corner castings comprising: two or more two-legged cube connectors, wherein legs of each of the two-legged cube connectors form a two-legged orthogonal x-y coordinate;two or more planar three-legged cube connectors, wherein legs of each of the planar three-legged cube connectors form a three-legged orthogonal x-y coordinate; andtwo or more orthogonal three-legged cube connectors, wherein legs of each of the orthogonal three-legged cube connectors form a three-legged orthogonal x-y-z coordinate;providing a series of linear extrusion members, wherein: each linear extrusion member comprises an opening at both a first end and a second end, with the openings being configured to slidably receive the legs of the two-legged and the three-legged cube connectors;at least two of the series of linear extrusion members serve as panel perimeter strips and comprise a receiving member that gravitationally hangs onto wing members of respective attachment clips secured to an edifice of a building to support a dead load of the three-dimensional frame structure; andat least two others of the linear extrusion members serve as corner connector strips and do not have the receiving member for the attachment clip;connecting the series of corner castings and the series of linear extrusion members to form a three-dimensional framework; andadhesively securing rigid wall panels to exterior surfaces of the three-dimensional framework to form the three-dimensional frame structure. 7. The method of claim 6, wherein: the series of corner castings further comprises one or more orthogonal four-legged cube connectors, wherein legs of each of the four-legged cube connectors form a four-legged orthogonal x-y-z coordinate;each of the orthogonal four-legged cube connectors comprises a cube member from which the legs of the one or more orthogonal four-legged cube connectors extend; andeach of the cube members of the one or more orthogonal four-legged cube connectors comprises a first outward-facing surface having at least one recessed portion dimensioned to receive and anchor a spacing element. 8. The method of claim 6, wherein: the series of corner castings further comprises one or more planar four-legged cube connectors, wherein legs of each of the four-legged cube connectors form a four-legged orthogonal x-y coordinate;each of the planar four-legged cube connectors comprises a cube member from which the legs of the one or more planar four-legged cube connectors extend; andeach of the cube members of the one or more planar four-legged cube connectors comprises a first outward-facing surface having at least one recessed portion dimensioned to receive and anchor a spacing element. 9. The method of claim 6, wherein: the series of corner castings further comprises one or more five-legged cube connectors, wherein legs of each of the five-legged cube connectors form a five-legged orthogonal x-y-z coordinate;each of the five-legged cube connectors comprises a cube member from which the legs of the one or more five-legged cube connectors extend; andeach of the cube members of the one or more five-legged cube connectors comprises a first outward-facing surface having at least one recessed portion dimensioned to receive and anchor a spacing element. 10. The method of claim 6, wherein: the series of corner castings further comprises: one or more planar four-legged cube connectors, wherein legs of each of the four-legged cube connectors form a four-legged orthogonal x-y coordinate;one or more orthogonal four-legged cube connectors, wherein legs of each of the four-legged cube connectors form a four-legged orthogonal x-y-z coordinate; andone or more five-legged cube connectors, wherein legs of each of the five-legged cube connectors form a five-legged orthogonal x-y-z coordinate;and wherein: each of the planar four-legged cube connectors, each of the orthogonal four-legged cube connectors and each of the five-legged cube connectors comprises a cube member from which the legs of the respective cube connectors extend; andeach of the cubes of each of the connectors comprises a first outward-facing surface having at least one recessed portion dimensioned to receive and anchor a spacing element. 11. The method of claim 6, wherein the wall panels comprise at least one of porcelain ceramic tiles, non-porcelain ceramic tiles, natural stone tiles, synthetic rigid panels, and composite rigid panels. 12. The method of claim 6, wherein the wall panels comprise at least one of layers of glass, layers of rigid metal, photovoltaic cell panels, or combinations thereof. 13. The method of claim 6, wherein: each leg of each of the corner castings has a polygonal geometry; andeach of the openings of each of the linear extrusion members defines a polygonal opening dimensioned to slidably receive respective legs. 14. The method of claim 13, wherein: each of the polygonal legs defines a four-sided profile; andeach of the polygonal openings defines a mating four-sided profile. 15. The method of claim 6, wherein: connecting the series of corner castings and the series of linear extrusion members comprises sliding the legs of the corner castings into respective polygonal openings of the linear extrusion members to provide the three-dimensional structure; andthe method further comprises slidably adjusting the positions of the linear extrusion members along the panel perimeter strips before adhesively securing the rigid wall panels to the panel perimeter strips. 16. The method of claim 15, wherein: each of the two-legged cube connectors comprises a cube member from which the legs of the respective two-legged cube connectors extend;each of the planar three-legged cube connectors also comprises a cube member from which the legs of the respective planar three-legged cube connectors extend;each of the orthogonal three-legged cube connectors also comprises a cube member from which the legs of the respective orthogonal three-legged cube connectors extend; andeach of the cubes of the two-legged cube connectors, the planar three-legged cube connectors and the orthogonal three-legged cube connectors comprises a first outward-facing surface having at least one recessed portion dimensioned to receive and anchor a spacing element. 17. The method of claim 16, wherein the cube of at least one of the orthogonal three-legged cube connectors comprises a second outward-facing surface having at least one recessed portion dimensioned to receive and anchor a spacing element, wherein the first and second outward-facing surfaces are in 90-degree relation. 18. The method of claim 16, wherein each linear extrusion member of the series of linear extrusion members includes a recessed portion for receiving a spacing element. 19. The method of claim 18, wherein: each of the spacing elements comprises a strip of elastomeric material having a base, wherein the base frictionally or slidingly fits within the respective recessed portions; andadhesively securing rigid wall panels to the three-dimensional structure comprises: inserting the base of each spacing element into selected recessed portions;placing the rigid wall panels onto the spacing elements;applying a liquid adhesive to the outward-facing surfaces of cube members adjacent to the spacing elements; andallowing the liquid adhesive to set. 20. The method of claim 19, wherein the recessed portion of each of the cube members of each of the two-legged cube connectors comprises two recessed portions residing in 90-degree relation along the first outward-facing surface. 21. The method of claim 19, wherein: the three-dimensional structure comprises three or more planar surfaces, with each planar surface having rigid wall panels adhesively secured thereto to form the frame structure. 22. The method of claim 21, further comprising: providing a plurality of keys, with each key defining an approximately orthogonal metal component dimensioned and configured to be received within slots of panel perimeter strips;inserting keys into the slots of adjacent panel perimeter strips in order to orient and secure the panel perimeter strips in approximately orthogonal relation: andadhesively securing a square rigid wall panel to the panel perimeter strips that have been joined together using the keys, without securing the rigid wall panel to a respective said cube connector. 23. The method of claim 22, wherein: the providing the plurality of keys comprises selecting keys from one of (i) a 90-degree perimeter clip key, (ii) an 87-degree perimeter clip key, and (iii) a 93-degree perimeter clip key; andthe method further comprises hanging the square rigid wall panel onto a wall adjacent the three-dimensional frame structure. 24. The method of claim 21, wherein applying a liquid adhesive to the outward-facing surfaces of cube members comprises applying the liquid adhesive around an outer perimeter of the spacing elements. 25. The method of claim 24, further comprising: securing attachment clips to the edifice of the building; andgravitationally hanging the receiving member portions of the panel perimeter strips onto respective attachment clips. 26. The method of claim 24, wherein: the frame structure is fabricated at a location remote from the building; andthe method further comprises: transporting the frame structure to the building; andsecuring the frame structure to an outside edifice of the building. 27. The method of claim 26, wherein securing the frame structure to an outside edifice of the building comprises: securing at least two bracket assemblies to an exterior surface of the building;securing a plurality of attachment clips to the at least two bracket assemblies; andhanging the receiving member of each of the panel perimeter strips onto attachment clips. 28. The method of claim 19, wherein: two or more of the corner connectors comprise parallel stiffener legs, wherein the parallel legs form slots; andthe method further comprises: providing a plurality of panel stiffeners, with each panel stiffener having a first end, a second opposing end, and an exterior surface between the first and second ends; andplacing the first and second ends of the panel stiffeners within respective slots of parallel stiffener legs such that the exterior surface of each panel stiffener faces outwardly. 29. The method of claim 28, further comprising: while adhesively securing rigid wall panels to exterior surfaces of the three-dimensional structure, also adhesively securing the rigid wall panels to the panel stiffeners. 30. The method of claim 29, wherein: each of the outward surfaces of the panel stiffeners comprises a recessed portion; andthe method further comprises placing spacers into the recessed portion of each of the panel stiffeners before adhesively securing the rigid wall panels to the panel stiffeners.