A method of reducing sound transmission in a building constructed using horizontal cross laminated timber (CLT) panels to provide a floor of the building and a floor assembly are described. In an implementation, the method includes: attaching a plurality of energy transmission control mounts to a ceiling side of one or more of the cross-laminated timber panels using fasteners; attaching a plurality of furring channels to the energy transmission control mounts; and attaching a cross laminated timber sheet to the plurality of furring channels to form an exposed ceiling layer.

A sound insulation structure for a building includes: a floor material; a ceiling material opposed to the floor material in a vertical direction with a space in a building interposed therebetween; a partition wall extending in the vertical direction and partitioning the space into a first space and a second space adjacent to each other in a horizontal direction; and at least one face material out of a floor-side sound insulation face material stuck to a portion of the floor material in a range of a thickness of the partition wall and having a coincidence frequency different from that of the floor material, and a ceiling-side sound insulation face material stuck to a portion of the ceiling material in the range of the thickness of the partition wall and having a coincidence frequency different from that of the ceiling material.

An acoustic seal for a sound flanking path between an an interior architectural separation and a mullion. The seal may be configured as an elongated rail having first and seal surfaces with adhesive elements disposed on laterally offset first and second adhesive-bearing portions thereof. When installed, the elongated rail can maintain a non-deformed state when opposing faces of the mullion and the architectural separation are separated by a distance equal to the elongated rail thickness. The elongated rail can assume a deformed state when the opposing faces of the mullion and the architectural separation are separated by a distance greater than the elongated rail thickness. In the deformed state, the longitudinal edges of the elongated rail become offset from each other in a direction normal to first and second seal surfaces. The elongated rail cross-section flexes proximate to first and second flex locations that may optionally include stress relief features.

An infill wall support clip is described. The infill wall support clip provides lateral bracing for wall panels in residential or commercial buildings. The infill wall support clip anchors to a top track of wall panels and to a bottom track of a floor truss. The infill wall support clip provides spacing between the wall panel and the floor truss such that drywall may be continuously overlaid on top of the wall panel.

The present invention relates to: a floor tile including a fabric material, and comprising a balancing layer, a noise prevention layer, a functional sheet layer, a fabric material layer, and a surface coating layer; and a manufacturing method thereof and more specifically to a floor tile including a fabric material and a manufacturing method thereof, the floor tile being a functional tile having a natural texture and a three-dimensional effect possessed by the fabric material, having excellent durability, preventing delamination of the fabric material layer, exhibiting excellent mechanical properties such as tensile strength, and enhancing cleaning facilitation.

A vibration absorption device for acoustic insulation for a building structure comprises an absorbent cushion and a vibration isolation cushion. The building structure is selected from a ceiling structure, a floor structure and a partitioning structure separating two adjacent building compartments or a building compartment and the external environment. The absorbent cushion comprises sound absorbing material and the vibration isolation cushion comprising vibration isolation material. The vibration isolation cushion overlies and is laminated to the absorbent cushion. The vibration isolation cushion is rigid relative to the absorbent cushion. The absorbent cushion is supple relative to the vibration isolation cushion. The vibration absorption device is mountable to the building structure, to isolate vibrations and to provide acoustic insulation between the two separated and adjacent building compartments.

A building connection includes a first building element and a second building element arranged at a distance from each other. The first building element is connected to the second building element by at least one connecting device. The connecting device includes a load transfer element arranged in the first building element, and a support box molded into the second building element. The support box includes an inner bottom wall surface and a support box opening facing the first building element. The connecting device further includes a first sound-absorbing element arranged on the inner bottom wall surface of the support box, and a support plate which is arranged on top of the first sound-absorbing element. The load transfer element protrudes from the first building element and into the support box through the support box opening. A filling area is molded with a filling material. The filling area includes the support box and an area between the first building element and the second building element.

An infill wall support clip is described. The infill wall support clip provides lateral bracing for wall panels in residential or commercial buildings. The infill wall support clip anchors to a top track of wall panels and to a bottom track of a floor truss. The infill wall support clip provides spacing between the wall panel and the floor truss such that drywall may be continuously overlaid on top of the wall panel.

An acoustic seal for a sound flanking path between an an interior architectural separation and a mullion. The seal may be configured as an elongated rail having first and seal surfaces with adhesive elements disposed on laterally offset first and second adhesive-bearing portions thereof. When installed, the elongated rail can maintain a non-deformed state when opposing faces of the mullion and the architectural separation are separated by a distance equal to the elongated rail thickness. The elongated rail can assume a deformed state when the opposing faces of the mullion and the architectural separation are separated by a distance greater than the elongated rail thickness. In the deformed state, the longitudinal edges of the elongated rail become offset from each other in a direction normal to first and second seal surfaces. The elongated rail cross-section flexes proximate to first and second flex locations that may optionally include stress relief features.

A composite acoustic damping batten suitable for interposition between first and second building elements, the composite acoustic damping batten comprising at least two resilient portions, each resilient portion comprising a first face and a second face, the first and second resilient portions of the at least two resilient portions being conjoined such that the first face of the first resilient portion and second face of the second resilient portion are spaced apart from each other forming opposing external surfaces of the composite acoustic damping batten; wherein the first face of the first resilient portion is configured for securable contacting engagement with the first building material; and the second face of the second resilient portion is configured for securable contacting engagement with the second building material.