In particular embodiments, an on-site drywall fabrication system is configured to perform on-site construction of drywall (e.g., plasterboard, wallboard, gypsum panel, sheet rock, gypsum board, etc.) over at least a portion of a framed (e.g., studded) wall (e.g., comprising one or more substantially vertical studs). In particular embodiments, the on-site drywall fabrication system is configured to utilize one or more drywall installation robots to fabricate drywall substantially directly on a framed wall. Generally speaking, the on-site drywall fabrication system may be configured to generate a substantially continuous, seamless drywall panel that extends along a particular portion of a wall. The system may, for example, utilize one or more sprayers that are configured to spray a suitable fill material between a first wall material (e.g., a first wall material applied via the first wall material spool) and a second wall material.

In particular embodiments, an on-site drywall fabrication system is configured to perform on-site construction of drywall (e.g., plasterboard, wallboard, gypsum panel, sheet rock, gypsum board, etc.) over at least a portion of a framed (e.g., studded) wall (e.g., comprising one or more substantially vertical studs). In particular embodiments, the on-site drywall fabrication system is configured to utilize one or more drywall installation robots to fabricate drywall substantially directly on a framed wall. Generally speaking, the on-site drywall fabrication system may be configured to generate a substantially continuous, seamless drywall panel that extends along a particular portion of a wall. The system may, for example, utilize one or more sprayers that are configured to spray a suitable fill material between a first wall material (e.g., a first wall material applied via the first wall material spool) and a second wall material.

The present disclosure relates generally to an insulation-retaining sheet, e.g., for blown-in insulation, that includes an integral vapor-retarding membrane. In one aspect, the disclosure provides an insulation-retaining sheet including a sheet of mesh having an air permeability of at least 200 cfm per square foot; and one or more strips of vapor-retarding membrane, the one or more strips of vapor-retarding membrane being laminated to the sheet of mesh, the first side edge each of the strips of vapor-retarding membrane extending to the first side edge of the sheet of mesh, the second side edge each of the strips of vapor-retarding membrane extending to the second side edge of the sheet of mesh, wherein the insulation-retaining sheet has a plurality of open zones extending laterally from the first side edge of the sheet of mesh to the second side edge of the sheet of mesh in which no vapor-retarding membrane is laminated to the mesh.

A system for processing material has a power supply and a machine having a hopper for receiving and passing material to an auger. The auger has a shaft with an axis about which it rotates, a helical flighting mounted to the shaft, pins mounted to the helical flighting, and paddles mounted to the shaft. The radial outer edge of the helical flighting is crenelated with periodic notches that form rectangular blades on the helical flighting. The pins are rotationally and angularly aligned with leading edges of the rectangular blades. The system may include a vehicle, such as a trailer, having first and second compartments separated by a partition. The power supply is located in the first compartment and has a power supply member extending though the partition. The machine is located in the second compartment and coupled to the power supply member.

A machine for distributing loosefill insulation material. The machine includes a chute having an inlet end and an outlet end. The inlet end is configured to receive loosefill insulation material. The chute has a first portion in fluid communication with a second portion and forms an angle with the second portion. A shredding chamber includes a plurality of shredders configured to shred, pick apart and condition the loosefill insulation material. A discharge mechanism is mounted to receive the loosefill insulation material exiting the shredding chamber. The discharge mechanism is configured to distribute the loosefill insulation material into an airstream. A blower is configured to provide the airstream flowing through the discharge mechanism. The angle between the first portion of the chute and the second portion of the chute is configured to control the descent of the loosefill insulation material into the shredding chamber.

A machine for distributing loosefill insulation material from a package of compressed loosefill insulation material. The machine includes a chute having an inlet end and an outlet end. The inlet end receives compressed loosefill insulation material. The chute has a first portion and a second portion. The first portion forms an angle with the second portion. A shredding chamber receives the compressed loosefill insulation material from the chute. The shredding chamber forms conditioned loosefill insulation material. A discharge mechanism is configured to distribute the conditioned loosefill insulation material into an airstream. A blower provides the airstream. The angle between the first and second portions of the chute is configured to form a bend in the package of compressed loosefill insulation material. The bend in the package of compressed loosefill insulation material is configured to control the descent and direction of the loosefill insulation material entering the shredding chamber.

An automated drywalling system having a computing device executing a computational planner that generates, before hanging any of a plurality of drywall pieces, a plan for a configuration of a plurality of cut pieces of drywall to be disposed on studs of a target wall assembly including a plurality of seams respectively defined by adjoining edges of different pairs of drywall pieces of the plurality of cut pieces of drywall, the plan for the configuration generated based at least in part on an optimization of the plurality of cut pieces of drywall.

An automated drywalling system having a computing device executing a computational planner that generates, before hanging any of a plurality of drywall pieces, a plan for a configuration of a plurality of cut pieces of drywall to be disposed on studs of a target wall assembly including a plurality of seams respectively defined by adjoining edges of different pairs of drywall pieces of the plurality of cut pieces of drywall, the plan for the configuration generated based at least in part on an optimization of the plurality of cut pieces of drywall.

A drywall finishing apparatus includes a water reservoir connected to a water distribution element. The water distribution element applies water to a finishing pad. The finishing pad is designed to allow water to flow through and reconstitute already applied drywall mud. The reconstituted drywall mud can then be smoothed out with the finishing pad. The finishing pad creates a hydroplaning effect to glide over the drywall mud.

A machine for distributing loosefill insulation from a package of compressed loosefill insulation material is provided. The machine includes a chute having an inlet end and an outlet end. The inlet end receives the loosefill insulation material. A shredding chamber is configured to receive the loosefill insulation material from the outlet end. The shredding chamber includes a plurality of shredders configured to shred, pick apart and condition the loosefill insulation material. A discharge mechanism is mounted to receive the conditioned material. The discharge mechanism is configured to distribute the conditioned material into an airstream. A blower is configured to provide the airstream flowing through the discharge mechanism. The blower has a rotational speed that defines the volume and the velocity of the airstream. A remote control assembly is configured to communicate with the machine such that the volume and velocity of the airstream can be adjusted in a remote location.