The present disclosure relates to the building industry and in particular to a block for use in automated building construction. In one aspect, the block comprises a generally cuboid body having a top and a base, a length extending between a pair of opposed ends, and a width extending between a pair of opposed sides; the body including a plurality of hollow cores extending from said top to said base, and arranged in a row between said opposed ends; wherein each core has a rectilinear cross-sectional shape; and wherein the thickness of the block between each pair of adjacent cores is at least double the thickness of the block on all other sides of each core, so that the block is divisible into a plurality of substantially identical block portions, each portion including four walls of substantially uniform wall thickness about its core.

A device for fabricating structures of large dimensions, layer by layer.

The invention relates to a device making use of positioning an extrusion head in three dimensions by means of cables in order to deposit a pasty material continuously in thin layers, e.g. a mortar comprising either a hydraulic binder or thermoplastic compounds or thermosetting compounds or curable compounds.

The invention is for making industrial elements of very large dimensions, and more particularly for making buildings.

The present invention refers to a modular system for fast connection of habitable modules (2) based on coupling standardized shipping containers to adjusted receiving structures (3). This system is based on a connecting plate system (1), habitable modules (2), a receiving structure (3), an alveolar structure (7) to connect said receiving structure (3) and automatic systems for transport, lifting, docking and coupling. The present invention refers also to a method of fast connection of habitable modules (2) within this modular structure.

An apparatus, system, and method for lifting an assembled wall module into position for attachment to a building structure.

A construction method for building a post frame building by first constructing the roof near ground level. The roof assembly can have a removeable safety net system and be coupled to a plurality of support members, such as columns having a hinge connection to the roof assembly. Upon the roof system being lifted, the hinged columns can fold under the roof system and then be coupled to one or more anchor points established in the ground. The roof system can be raised into position at a pre-determined height using a lifting apparatus, such as a hydraulic lift.

A lifting system for a concrete component comprises a void former incorporated into the component during casting and which provides within the component a void which receives a locking pin of a lifting anchor assembly which is locked within the void by rotation of a locking pin. The lifting anchor assembly has a visual indicator to indicate when the pin is in its locked condition within the void, and a pivotal lifting shackle of the assembly is prevented from movement into a position in which lifting can take place until the pin is in its locked condition. Preferably a base of the void former is configured to retain components of a jacking system by which a concrete slab used for road repair can be jacked into a level configuration with the remainder of the roadway when it has been positioned by use of the lifting system.

A drilling rig mobility system moves a drilling rig or similar structure in an oilfield or similar environment and includes independently controllable positioning shoes attaching to the drilling rig and controllable through separate and coordinated position control commands. Each positioning shoe may be individually addressed to reposition the drilling rig. Each positioning shoe includes a hydraulic actuator and wireless control circuitry. The hydraulic actuator provides vertical and horizontal force in response to wireless control signals for wireless position and control data and instructions with a remote wireless communications device. A cylinder stomper vertically elevates the hydraulic actuator and receives and transfers the vertical force. A foot assembly transfers the horizontal force from the hydraulic actuator. A positioning shoe cylinder stomper and positioning shoe traverse cylinder provide infinitely variable position control. Rotational positioning may be manually or automatically achieved.

Embodiments of a constructions system for constructing a structure atop a foundation are disclosed. In an embodiment, the construction system includes a rail assembly. The rail assembly is configured to be mounted to the foundation. In addition, the construction system includes a gantry movably disposed on the rail assembly. The gantry is configured to translate along a first axis relative to the rail assembly. Further, the construction system includes a printing assembly movably disposed on the gantry. The printing assembly is configured to translate along a second axis relative to the gantry. The second axis is orthogonal to the first axis. The printing assembly is configured to deposit vertically stacked layers of an extrudable building material onto a top surface of the foundation to construct a structure.

A multi-story building (200) is described for manufactured homes (212) such as container homes. The building (200) includes a ground floor (202), a number of intermediate floors (204), and a top floor (206). The building (200) includes a throughway (208) on the ground floor (202) that allows passage of a transportation vehicle (210) such as a flatbed truck carrying a manufactured home (212). The transportation vehicle (210) can use the throughway (208) to position the manufactured home (212) in alignment with a hoistway (214). A hoist mounted on the roof (216) can then be used to hoist the home (212) to a desired floor (204 or 206).

Apparatus, systems, and methods for attaching an assembled wall module to a building structure, according to which a framing section, including a plurality of structural members and a first coupler connected to a first structural member of the plurality of structural members, is connected to the building structure. After connecting the framing section to the building structure, relative movement is permitted, via the first coupler, between the framing section and the building structure in a first direction. Before connecting the framing section to the building structure, a plurality of sheeting sections may be connected to the framing section. The framing section may further include a second coupler; in such instances, after connecting the framing section to the building structure, relative movement is permitted, via the second coupler, between the framing section and the building structure in a second direction, which second direction is the same as the first direction.