Methods and apparatus are discussed for an electric powered personal transportation vehicle with electric motors powered by one or more batteries. A set of universal battery mounting hole locations and a reserved space for one or more battery housings exist on a board for the personal transportation vehicle. The reserved space on the board for the one or more battery housings that house one or more battery packs is set to not interfere with an operation of the motors or the wheels. A first battery pack containing the one or more batteries differs in at least one of i) a different amp-hour capacity, ii) a different length, width, or height, and iii) a different shape than another battery pack designed to be physically contained in the one or more battery housings and electrically connect with corresponding electrical connections in the one or more battery housings.

A personal transport system is provided including, in an embodiment, an electrically powered vehicle, a companion remote control, and a companion mobile phone application. The vehicle includes an operator-supporting deck, one or more deck-mounted trucks, one or more axle-mounted wheels on each of the one or more trucks, one or more batteries, and a deck lighting system. The one or more batteries power a motor configured to drive the wheels by way of a pulley system, at least one battery of which is disposed under a battery enclosure. The battery enclosure has a first light indicator system, and the companion remote control has a second light indicator system, each of which is configured for communicating with the operator. The deck lighting system includes a light strip of light-emitting diodes disposed in a groove of the deck configured to change state to communicate with the operator or others sharing a road.

Some embodiments of the present disclosure relate to roofing systems. In some embodiments, the roofing system includes a deck, a roofing material, and an underlayment configured to be positioned between the roofing material and the deck. In some embodiments, the underlayment comprises a foil layer and an adhesive layer that is attached to the foil layer and configured to be attached to the deck. Methods of manufacturing roofing systems are also disclosed.

A building panel, which includes a decorative assembly including a glass assembly which includes first and second layers of glass and a clear interlayer between said first and second layers of glass, said glass assembly being compliant with safety code ANSI Z97.1, said glass assembly having opposed first and second surfaces, said first surface of said glass assembly being defined by said first layer of glass and being an outermost surface of said glass assembly, and said second surface of said glass assembly being defined by said second layer of glass; and a decorative sheet having opposed first and second surfaces, said first surface of said decorative sheet being in contact with said second surface of said glass assembly, said decorative sheet being directly attached to said second surface of said glass assembly without an adhesive between said decorative sheet and said second layer of glass; and a protective backing sheet having opposed front and rear surfaces, said front surface being in contact with said second surface of said decorative sheet, and said second surface of said backing sheet being on an opposite side of said backing sheet from a side on which said glass assembly is situated.

Some embodiments of the present disclosure relate to roofing systems. In some embodiments, the roofing system includes a deck, a roofing material, and an underlayment configured to be positioned between the roofing material and the deck. In some embodiments, the underlayment comprises a foil layer and an adhesive layer that is attached to the foil layer and configured to be attached to the deck. Methods of manufacturing roofing systems are also disclosed.

A co-extruded hemp composite board (CHB) is provided. By combining hemp feedstocks with virgin and/or recycled binder materials and subsequently coextruding them into a coextruded extrudate sheet, an environmentally friendly alternative to traditional construction materials is created. Secondary feedstocks and waste products from other production streams may be added during the coextrusion process to enhance the physical characteristics of the coextruded extrudate sheet as well to reduce waste/cost of production and create a more environmentally friendly construction material. The coextruded extrudate sheet produced using such materials possesses superior physical properties when compared to traditional construction materials due to the structural characteristics of dispersed hemp feedstocks; the complete encapsulation of hemp feedstocks in the binder material; and the lower hygroscopic and higher pest resistance properties of hemp feedstocks. A downstream extrusion arrangement may be used to pattern the extrudate sheet and/or create molded shapes that are difficult to achieve in traditional construction materials, increasing the customization potential of finished CHB products relative to traditional construction materials.

The invention relates to an insulated panel, in particular a wall panel or roof panel, including a foamed core layer and a cover layer affixed to the foamed core layer. The invention also relates to an insulating covering, in particular a wall covering or floor covering, including a plurality said insulated panels.

Disclosed is a method for producing a structural element by joining together at least two separately produced parts where at least one part is made of concrete by cutting it from a volume of concrete and where all parts extend over the entire length of the structural element; a method for producing a staircase by joining together at least two separately produced staircase parts, which are cut from a volume of material and extend over the entire length of the staircase, and a structural element and a staircase which have been produced in this way.