Self-supporting concrete slabs can eliminate the need for temporary backshoring, streamlining the building process and enhancing productivity. These slabs are engineered to support their own weight and additional loads without relying on external supports, reducing labor and material costs while accelerating construction schedules. The process incorporates advanced reinforcement techniques, including post-tensioning and code-compliant splicing methods, to ensure structural integrity, continuity, and compliance with building codes. By simplifying forming processes and enabling early access for other trades, self-supporting slabs offer significant economic and operational advantages, making them a superior alternative to traditional slab designs.
E04C 5/06 - Éléments d'armature en métal, p. ex. avec des revêtements rapportés de haute résistance à la flexion, c.-à-d. s'étendant essentiellement dans trois dimensions, p. ex. poutres en treillis
E04B 5/38 - Structures de planchers entièrement coulées sur place avec ou sans éléments de coffrage ou armatures avec des éléments de coffrage faisant partie du plancher avec des coffrages en forme de dalles servant en même temps d'armaturesDalles de coffrage avec armatures se prolongeant latéralement à l'extérieur de l'élément
2.
SYSTEMS AND METHODS FOR BUILDING ELEVATED STRUCTURES
Self-supporting concrete slabs can eliminate the need for temporary backshoring, streamlining the building process and enhancing productivity. These slabs are engineered to support their own weight and additional loads without relying on external supports, reducing labor and material costs while accelerating construction schedules. The process incorporates advanced reinforcement techniques, including post-tensioning and code-compliant splicing methods, to ensure structural integrity, continuity, and compliance with building codes. By simplifying forming processes and enabling early access for other trades, self-supporting slabs offer significant economic and operational advantages, making them a superior alternative to traditional slab designs.
E04B 5/04 - Structures portantes de planchers, formées essentiellement d'éléments préfabriqués avec poutres en béton ou constituées d'autres matériaux semblables à la pierre, p. ex. d'amiante-ciment
E04B 5/32 - Structures de planchers entièrement coulées sur place avec ou sans éléments de coffrage ou armatures
E04C 5/06 - Éléments d'armature en métal, p. ex. avec des revêtements rapportés de haute résistance à la flexion, c.-à-d. s'étendant essentiellement dans trois dimensions, p. ex. poutres en treillis
E04C 5/16 - Pièces auxiliaires pour armatures, p. ex. pièces de séparation, étriers
3.
SYSTEMS AND METHODS FOR BUILDING ELEVATED STRUCTURES
Self-supporting concrete slabs can eliminate the need for temporary backshoring, streamlining the building process and enhancing productivity. These slabs are engineered to support their own weight and additional loads without relying on external supports, reducing labor and material costs while accelerating construction schedules. The process incorporates advanced reinforcement techniques, including post-tensioning and code-compliant splicing methods, to ensure structural integrity, continuity, and compliance with building codes. By simplifying forming processes and enabling early access for other trades, self-supporting slabs offer significant economic and operational advantages, making them a superior alternative to traditional slab designs.
Self-supporting concrete slabs can eliminate the need for temporary backshoring, streamlining the building process and enhancing productivity. These slabs are engineered to support their own weight and additional loads without relying on external supports, reducing labor and material costs while accelerating construction schedules. The process incorporates advanced reinforcement techniques, including post-tensioning and code-compliant splicing methods, to ensure structural integrity, continuity, and compliance with building codes. By simplifying forming processes and enabling early access for other trades, self-supporting slabs offer significant economic and operational advantages, making them a superior alternative to traditional slab designs.
Construction elements, namely, splices made of metal for
connecting end to end metal rebars together; metal rebars;
metal expansion joints; all the aforementioned combined to
form reinforcing splicing systems for use in construction
and industrial sites.
(1) Construction elements, namely, splices made of metal for connecting end to end metal rebars together; metal rebars; metal expansion joints; all the aforementioned combined to form reinforcing splicing systems for use in construction and industrial sites.
Construction elements, namely, splices made of metal for connecting end to end metal rebars together; metal rebars; metal expansion joints; all the aforementioned combined to form reinforcing splicing systems for use in construction and industrial sites.
Construction elements, namely, splices made of metal for connecting end to end metal rebars together; metal rebars; metal expansion joints for floors and walls for buildings; all the aforementioned combined to form reinforcing splicing systems for use in construction and industrial sites
A splice device including a body, a first opening, a second opening, an inlet, an outlet, and a cavity. The first opening at a first end and including a first bore for fixedly attaching a first rebar of a first concrete slab to the body. The second opening at a second end and including a second bore for receiving a second rebar of a second concrete slab therethrough. The inlet being at a second longitudinal axis and the outlet being at a third longitudinal axis. The cavity is in the body and in fluid communication with the first opening, second opening, inlet, and outlet. The splice device fixedly couples the first rebar to the second rebar by filling the cavity with a fill material, which when cured to a hardened state, the fill material fixedly attaches the second rebar to the splice device at the cavity.
Systems, devices, and methods for making a wall-to-floor construction that is self-supporting. The method includes installing a splice device onto an end of a first rebar for the concrete slab; positioning a portion of a second rebar of the vertical structure into the cavity, the splice device being supported by the second rebar; forming the concrete slab, wherein the first concrete slab has contained within its material the first rebar. After forming the concrete slab, filling a fill material into the cavity through one of the inlet and the outlet. The splice device securely fixes the second rebar in the cavity and couples the first rebar to the second rebar.
A splice device including a body, a first opening, a second opening, an inlet, an outlet, and a cavity. The first opening at a first end and including a first bore for fixedly attaching a first rebar of a first concrete slab to the body. The second opening at a second end and including a second bore for receiving a second rebar of a second concrete slab therethrough. The inlet being at a second longitudinal axis and the outlet being at a third longitudinal axis. The cavity is in the body and in fluid communication with the first opening, second opening, inlet, and outlet. The splice device fixedly couples the first rebar to the second rebar by filling the cavity with a fill material, which when cured to a hardened state, the fill material fixedly attaches the second rebar to the splice device at the cavity.
E04B 1/04 - Structures constituées principalement d'éléments porteurs en forme de blocs ou de dalles les éléments étant en béton, p. ex. en béton armé, ou en un autre matériau pierreux
E04C 5/16 - Pièces auxiliaires pour armatures, p. ex. pièces de séparation, étriers
14.
SYSTEMS, DEVICES, AND METHODS FOR WALL TO FLOOR CONSTRUCTION
Systems, devices, and methods for making a wall-to-floor construction that is self-supporting. The method includes installing a splice device onto an end of a first rebar for the concrete slab; positioning a portion of a second rebar of the vertical structure into the cavity, the splice device being supported by the second rebar; forming the concrete slab, wherein the first concrete slab has contained within its material the first rebar. After forming the concrete slab, filling a fill material into the cavity through one of the inlet and the outlet. The splice device securely fixes the second rebar in the cavity and couples the first rebar to the second rebar.
E04B 1/04 - Structures constituées principalement d'éléments porteurs en forme de blocs ou de dalles les éléments étant en béton, p. ex. en béton armé, ou en un autre matériau pierreux
E04C 5/16 - Pièces auxiliaires pour armatures, p. ex. pièces de séparation, étriers
Devices, systems, and methods for constructing post-tensioned concrete slabs in a new floor construction that has a reduced gap distance between the slabs. The devices, systems, and methods can improve project construction time by reducing the time delay in accessing the floor underneath the slabs due to safety and/or weather conditions.
Devices, systems, and methods for constructing post-tensioned concrete slabs in a new floor construction that has a reduced gap distance between the slabs. The devices, systems, and methods can improve project construction time by reducing the time delay in accessing the floor underneath the slabs due to safety and/or weather conditions.
E04B 5/32 - Structures de planchers entièrement coulées sur place avec ou sans éléments de coffrage ou armatures
E04C 5/06 - Éléments d'armature en métal, p. ex. avec des revêtements rapportés de haute résistance à la flexion, c.-à-d. s'étendant essentiellement dans trois dimensions, p. ex. poutres en treillis
E04B 5/04 - Structures portantes de planchers, formées essentiellement d'éléments préfabriqués avec poutres en béton ou constituées d'autres matériaux semblables à la pierre, p. ex. d'amiante-ciment
E04B 5/17 - Structures de planchers partiellement formées sur place
A splice device including a body, a first opening, a second opening, an inlet, an outlet, and a cavity. The first opening at a first end and including a first bore for fixedly attaching a first rebar of a first concrete slab to the body. The second opening at a second end and including a second bore for receiving a second rebar of a second concrete slab therethrough. The inlet being at a second longitudinal axis and the outlet being at a third longitudinal axis. The cavity is in the body and in fluid communication with the first opening, second opening, inlet, and outlet. The splice device fixedly couples the first rebar to the second rebar by filling the cavity with a fill material, which when cured to a hardened state, the fill material fixedly attaches the second rebar to the splice device at the cavity.
E04B 1/04 - Structures constituées principalement d'éléments porteurs en forme de blocs ou de dalles les éléments étant en béton, p. ex. en béton armé, ou en un autre matériau pierreux
E04G 11/36 - Coffres, coffrages ou faux œuvre pour la fabrication des murs, planchers, plafonds ou toits pour planchers, plafonds ou toits de surface plane ou courbe
E04G 17/04 - Moyens d'assemblage ou d'immobilisation pour les éléments métalliques de coffrage ou de consolidation
23.
SYSTEMS, DEVICES, AND METHODS FOR WALL TO FLOOR CONSTRUCTION
Systems, devices, and methods for making a wall-to-floor construction that is self-supporting. The method includes installing a splice device onto an end of a first rebar for the concrete slab; positioning a portion of a second rebar of the vertical structure into the cavity, the splice device being supported by the second rebar; forming the concrete slab, wherein the first concrete slab has contained within its material the first rebar. After forming the concrete slab, filling a fill material into the cavity through one of the inlet and the outlet. The splice device securely fixes the second rebar in the cavity and couples the first rebar to the second rebar.
