Methods and systems for reducing sound propagation between spaces divided by a retractable wall are disclosed. A retractable wall is configured to divide a space when deployed. An edge of the retractable wall is disposed into a track with a channel when the retractable wall is deployed. A bladder is configured to inflate when the retractable wall is deployed and to press the edge of the retractable wall. In this manner, sound propagation through any gaps is reduced.

Methods and systems for reducing sound propagation between spaces divided by a retractable wall are disclosed. A retractable wall is configured to divide a space when deployed. An edge of the retractable wall is disposed into a track with a channel when the retractable wall is deployed. A bladder is configured to inflate when the retractable wall is deployed and to press the edge of the retractable wall. In this manner, sound propagation through any gaps is reduced.

A noise reduction door related to a noise reduction device in order to resolve a problem that the noise reduction door cannot meet a requirement for different noise reduction effects and different air duct resistance. The noise reduction door includes a T-shaped mechanical part, two fan-shaped mechanical parts, and a door plate. The T-shaped mechanical part and the fan-shaped mechanical part are connected to the door plate using a detachable connection mechanical part. The T-shaped mechanical part is located on a central axis of the door plate, and the two fan-shaped mechanical parts are respectively located on two sides of the T-shaped mechanical part. Therefore, the fan-shaped mechanical part on the door plate may be changed to have different installation positions and installation manners in order to obtain noise reduction doors in different forms. The embodiments of the present disclosure are applied in cabinet noise reduction.

A noise reduction door related to a noise reduction device in order to resolve a problem that the noise reduction door cannot meet a requirement for different noise reduction effects and different air duct resistance. The noise reduction door includes a T-shaped mechanical part, two fan-shaped mechanical parts, and a door plate. The T-shaped mechanical part and the fan-shaped mechanical part are connected to the door plate using a detachable connection mechanical part. The T-shaped mechanical part is located on a central axis of the door plate, and the two fan-shaped mechanical parts are respectively located on two sides of the T-shaped mechanical part. Therefore, the fan-shaped mechanical part on the door plate may be changed to have different installation positions and installation manners in order to obtain noise reduction doors in different forms. The embodiments of the present disclosure are applied in cabinet noise reduction.

A sliding apparatus for a sliding door comprises: a front top roller part including an upper outer bracket and an upper inner bracket; a front bottom roller part including a lower outer bracket and a lower inner bracket which are fitted and fixed to both lower ends of the front door while being connected to each other by a lower connecting bar, and are formed to slide in both lateral directions after moving forward; a rear roller part including rear outer brackets and rear inner brackets which are formed at both upper ends and both lower ends of a rear door formed on one side of the front door, so as to slide the rear door; a front rail part including guide rails which are formed on the upper and lower end surfaces of a rear door frame and the upper and lower surfaces of the rear inner bracket.

A sliding apparatus for a sliding door comprises: a front top roller part including an upper outer bracket and an upper inner bracket; a front bottom roller part including a lower outer bracket and a lower inner bracket which are fitted and fixed to both lower ends of the front door while being connected to each other by a lower connecting bar, and are formed to slide in both lateral directions after moving forward; a rear roller part including rear outer brackets and rear inner brackets which are formed at both upper ends and both lower ends of a rear door formed on one side of the front door, so as to slide the rear door; a front rail part including guide rails which are formed on the upper and lower end surfaces of a rear door frame and the upper and lower surfaces of the rear inner bracket.

A double glazing insulation system of the present invention is characterized by including: double glazing having a chamber formed between a pair of glass windows, a bead entrance through which air and a plurality of beads enter and exit the chamber, and an air entrance through which air enters the chamber; a storage tank for storing the plurality of beads; a bead flow pipe guiding the plurality of beads such that the beads flow; an air exhaust pipe guiding the flow of air discharged from the storage tank; an air flow pipe guiding the flow of air entering and exiting through the air entrance; and a main blower which sucks air of the chamber through the air flow pipe or through the air exhaust pipe, thereby filling the chamber with the plurality of beads or discharging the same from the chamber.

A double glazing insulation system of the present invention is characterized by including: double glazing having a chamber formed between a pair of glass windows, a bead entrance through which air and a plurality of beads enter and exit the chamber, and an air entrance through which air enters the chamber; a storage tank for storing the plurality of beads; a bead flow pipe guiding the plurality of beads such that the beads flow; an air exhaust pipe guiding the flow of air discharged from the storage tank; an air flow pipe guiding the flow of air entering and exiting through the air entrance; and a main blower which sucks air of the chamber through the air flow pipe or through the air exhaust pipe, thereby filling the chamber with the plurality of beads or discharging the same from the chamber.

The system includes a series of operable louvers mounted on a four-sided frame and connected on each side to the operating mechanism that allows for easy opening and closing of the louvers. Every part of the system that is exposing to the exterior of the building is separated from the interior part of the system by a low heat conductivity material as a thermal barrier. Each operable louver is composing of a four-sided main frame, two panes of glass (inner and outer) and a coupling mechanism on each side that connects to the operating mechanism. The main frame acts as the thermal break as well as a system that absorbs the energy created when an outside object impacts the window from the outside. The system incorporates sealing devices between all moving parts to eliminate water and air infiltration. The operating system allows for easy opening and closing of the window by rotating each louver with the crank mechanism assisted by springs.

The acoustic shutter assembly (1) includes at least one window pane (2, 3) arranged in a frame (4). At least one ventilation duct (7) is arranged in the frame between an outer ventilation opening (8) and an inner ventilation opening (9), extending between a first layer of sound absorbing material arranged at an inside (5) and a second layer of sound absorbing material arranged at an outside. A number of acoustic reflectors (12) in the form of plate material are arranged between the first and second layers of sound absorbing material so that the ventilation duct is separated into a number of respective ventilation channels (13) formed between the acoustic reflectors. Each ventilation channel changes direction at least once between the outer ventilation opening and the inner ventilation opening, thereby at least substantially blocking any linear path from the outer ventilation opening to the inner ventilation opening.