A method of and system for producing Class-A fire-protected oriented strand board (OSB) sheets. Each Class-A fire-protected OSB sheet has: a core medium layer made of wood pump, binder and/or adhesive materials; a pair of OSB layers bonded to the core medium layer; a clean fire inhibiting chemical (CFIC) coating on the surface of each OSB layer, made from CFIC liquid applied to the surface by dipping the OSB sheet into the CFIC liquid in a dipping tank, allowing shallow surface absorption into the OSB layers and ends of the core medium layer at atmospheric pressure; and a moisture, fire and UV protection coating spray coated over the the CFIC coating to provide protection against moisture, fire and UV radiation from Sunlight, which is quickly dried by passing through a drying tunnel on the production line.

A method of and system for producing Class-A fire-protected oriented strand board (OSB) sheets. Each Class-A fire-protected OSB sheet has: a core medium layer made of wood pump, binder and/or adhesive materials; a pair of OSB layers bonded to the core medium layer; a clean fire inhibiting chemical (CFIC) coating on the surface of each OSB layer, made from CFIC liquid applied to the surface by dipping the OSB sheet into the CFIC liquid in a dipping tank, allowing shallow surface absorption into the OSB layers and ends of the core medium layer at atmospheric pressure; and a moisture, fire and UV protection coating spray coated over the the CFIC coating to provide protection against moisture, fire and UV radiation from Sunlight, which is quickly dried by passing through a drying tunnel on the production line.

A method of and system for producing wood-framed buildings having Class-A fire-protection and defense against total fire destruction during the construction phase, and certifying and documenting the same. The system includes a reservoir for containing a supply of clean fire inhibiting liquid chemical (CFIC) liquid for spray application over over the interior surfaces of raw and treated lumber and sheathing used in a completed section of a wood-framed assemblies in a wood-framed building during its construction phase; a liquid spray pumping subsystem operably connected to the reservoir tank containing the supply of CFIC liquid. A hand-held liquid spray gun, operably connected to the liquid spray pumping subsystem, is used to for spray CFIC liquid from the reservoir tank onto the exposed interior wood surfaces of lumber and sheathing used to construct each completed section of the wood-framed building, to form a CFIC coating on the treated interior wood surfaces providing Class-A fire-protection to the completed section of the wood-framed building.

A method of and system for producing wood-framed buildings having Class-A fire-protection and defense against total fire destruction during the construction phase, and certifying and documenting the same. The system includes a reservoir for containing a supply of clean fire inhibiting liquid chemical (CFIC) liquid for spray application over over the interior surfaces of raw and treated lumber and sheathing used in a completed section of a wood-framed assemblies in a wood-framed building during its construction phase; a liquid spray pumping subsystem operably connected to the reservoir tank containing the supply of CFIC liquid. A hand-held liquid spray gun, operably connected to the liquid spray pumping subsystem, is used to for spray CFIC liquid from the reservoir tank onto the exposed interior wood surfaces of lumber and sheathing used to construct each completed section of the wood-framed building, to form a CFIC coating on the treated interior wood surfaces providing Class-A fire-protection to the completed section of the wood-framed building.

Prefabricated Class-A fire-protected mass timber building components are first sprayed or curtain-coated with clean fire inhibiting chemical (CFIC) liquid, in an automated prefabricated wood building factory environment, to provide Class-A fire-protection under the ASTM 84E test standard. Thereafter, the prefabricated Class-A fire-protected mass timber building components are sprayed or coated again with a different chemical liquid so as to provide added UV-light, moisture and termite protection to the Class-A fire-protected CLT building components. Preferably, a multi-axis robotic spray system is used for spraying CFIC liquid over all of the surfaces of the prefabricated mass timber. Machine vision systems can be used to collect video data of the spraying operations, analyzing the collected video data against preconstructed reference models, and providing guidance as required to achieve predetermined standards of quality control (QC) along the production line.

A cloud-based system network for verifying and documenting prefabricating Class-A fire-protected wood-framed buildings produced from a prefabricated Class-A fire-protected wood-framed building factory system supporting multiple production lines for producing Class-A fire-protected wood-framed components including wall panels, floor panels, stair panels, floor trusses, and roof trusses for use in constructing custom and pre-specified prefabricated Class-A fire-protected wood-framed buildings. The system network includes (i) a data center with web, application and database servers for supporting a web-based site for hosting digital images of barcoded/RFID-tagged certificates attached to prefabricated Class-A fire-protected wood-framed building components, and other certification documents, and (ii) mobile smart-phones used to capture digital photographs and video recordings of Class-A fire-protected wood-framed building sections, and upload the captured digital images to the data center, for each prefabricated wood-framed building project, so that building purchasers, insurance companies, builders, architects and other stakeholders can review such certifications and documentations during the prefabrication of wood-framed buildings from the factory system.

An Internet-based system network for supporting the delivery, certification and remote inspection of fire-protection provided to wood-framed and mass-timber building construction sites, as well as prefabricated wood-framed and mass timber buildings and components within a prefabricated building factory. The system network also manages the supply of clean fire inhibiting chemical (CFIC) totes from a chemical factory or warehouse to (i) wood-framed building construction job sites, as well as (ii) factories manufacturing prefabricated fire-protected wood-framed and mass-timber buildings and components (e.g. modules and panels) using data centers and a network of wireless mobile computing devices.

The invention relates to a process for producing a thermoformable and/or embossable particle/polymer composite using a substrate S based on shredded polymer-coated paper and a thermoplastic polymer P, therewith providing a new method of recycling/upcycling paper waste. Furthermore, a process for the manufacturing of a molded article obtained from the paper-based particle/polymer composite and its use as an element in buildings or in furniture are disclosed.

A system and method for a fire-retardant insulation product are provided, along with a fire-retardant chemical formulation. An insulation product provided includes cellulose fibers and a fire-retardant chemical formulation. The fire-retardant includes calcium chloride.

A cloud-based system network for managing the supply chain management operations associated with shipping clean fire inhibiting chemical (CFIC) totes from a chemical factory or warehouse to a network of lumber factories producing Class-A fire-protected lumber, and/or wood-framed building construction job sites with interior wood surfaces being spray-treated with Class-A fire protection during the construction phase. The system network includes a data center with web, application and database servers for supporting one or more mobile applications running on mobile computing devices (e.g. smart-phones and tablet computers). The mobile applications were configured for (i) scanning barcode symbols and/or RFID-tags on CFIC totes, measuring the weight of such CFIC totes at the chemical factory and/or warehouse, capturing GPS coordinates of the CFIC totes and recording such data within the centralized supply chain management database, and also for (ii) scanning barcode symbols and/or RFID-tags on CFIC totes at the destination factory, warehouse and/or construction job site, measuring the weight of such CFIC totes, detecting GPS coordinates, comparing recorded weights, and enabling automated inventory replenishment.