An air-to-air heat pump system for a heating, ventilation and air conditioning (HVAC) system for a building includes a thermally insulated cool channel for pumping external air into the building, the cool channel having a volume for mixing external air with exhaust air of the building, a warm channel for pumping internal air, the warm channel including a cellular humidifier that restores humidity to internal air, heat pump coils located in the cool channel and the warm channel, the heat pump coils configured for transferring thermal energy from the cold channel to the warm channel, a first fan located in the cool channel and a second fan located in the warm channel, wherein the first and second fans are configured for moving air within a channel, all of the foregoing provided in a monoblock or Split structure located inside, or partially inside, a thermal circuit of the building.

The present invention involves the preparation and manufacture of phenolic insulation boards for use in double-walled ductwork systems. The preparation of the phenolic insulation board, having a first and second surface each having a foil coating, includes the cutting or grooving of V-grooves into the first surface of the phenolic insulation and first foil coating. This grooving process creates a continuous piece of phenolic insulation having trapezoidal shapes along the second surface and second foil coating. The prepared phenolic insulation board can then be wrapped around an inner sheet metal duct and then covered with an outer shell. Alternatively, the prepared phenolic insulation board can be inserted between an inner duct and outer shell. Both result in a double-walled phenolic insulation ductwork systems.

An insulation assembly is provided. The insulation assembly includes a three-sided insulation envelope configured to form a cavity. The cavity is configured to receive a section of uninsulated, existing ductwork. The three-sided insulation envelope forms an opening. An insulation cap is configured to seat against the three-sided insulation envelope thereby encapsulating the uninsulated, existing ductwork and sealing the opening.

Provided are a flexible insulated air duct and a modular flexible insulated air-duct system; the flexible insulated air duct includes an air-duct main body (1); the air-duct main body (1) includes an inner air-duct layer (5) and a heat-insulating layer (4) integrally formed on the inner air-duct layer (5); the inner air-duct layer (5) is arranged inside the heat-insulating layer (4), and the heat-insulating layer (4) is a rubber/plastic material. The modular flexible insulated air-duct system made by assembling a main air duct (7), a branched air duct (8), and a connecting air duct (9) may be rapidly connected on-site using a zip fastener to form an air-duct system having any configuration.

A process for forming an insulated register box includes forming an insulation across the interior surface of a register box, placing a locating collar onto an outer surface of the register box, marking the outer surface of the register box so as to present a representation corresponding to an inner diameter of the collar, separating a portion of the outer surface of the register box from a remainder of the register box corresponding to the marked representation, penetrating the exposed insulation with the collar until an end of the collar opens to an interior of the insulated register box, and positioning the flange against the outer surface of the register box.

An air conditioning appliance or a make-up air (MUA) assembly may include an intake conduit and a secondary air duct. The intake conduit may be attachable to a housing of the air conditioning appliance. The intake conduit may define an intake passage upstream from the indoor inlet. The intake conduit may further define a secondary inlet upstream from the intake passage to permit air thereto. The secondary air duct may extend from the intake conduit outside of the housing upstream from the secondary inlet to direct air thereto.

A method for producing clad duct from a laminate is disclosed. The laminate is a sheet of thermoplastic material bonded to an insulative foam board. V-shaped grooves are formed in the foam board, opposite the sheet. The sheet is heated in the vicinity of one of the grooves, until pliable. The sheet is then bent, where it has become pliable, to close the groove. The heated and bent sheet is then cooled until it is no longer pliable and retains its bent shape. The heating, bending, and cooling steps are repeated for the other grooves until edges of the laminate are brought together. The edges are then sealed.

The present invention relates to a thermal bridge break air-conditioner tank, comprising a framework and a wall panel, wherein the framework is assembled from three-ways connectors, rims, and a middle beam assembly, the three-ways connectors and the rims being plastically integrally formed structures; a thermal bridge break structure made of a PVC material is connected to outer sides of the three-ways connectors and the rims; the framework is formed as a cubic structure; the wall panel is assembled from a panel and a plurality of external sheet metal parts, and the wall panel is disposed in the framework by shape-fitting. The air-conditioner tank according to the present invention has a good thermal bridge break performance, and meanwhile simplifies the assembling and connecting between components.

A duct for air transport comprises an inner jacket having an inlet end for connecting the duct to an air supply and an outlet end for connecting the duct to a duct for a further transport or distribution of air, and an outer jacket made of an impervious material and surrounding the inner jacket spaced therefrom. An insulating chamber is formed between the inner jacket and the outer jacket. The inner jacket and the outer jacket are adapted to conduct from the interior space of the inner jacket through the insulating chamber into the ambient atmosphere, namely in an amount of 0.02 to 100% of the total volume of air fed into the inner jacket. The area for conducting air into the insulating chamber and the area for conducting air away from the insulating chamber are spaced from each other during the operation of the duct.

Fabric silencers for air ducts are disclosed. An example air duct silencer system includes an inner tube being of a first pliable material, the inner tube defining an airway extending along the inner tube. The example air duct silencer system further includes an outer tube being of a second pliable material, the outer tube to encircle the inner tube to define an annular space between the outer tube and the inner tube. The example air duct silencer system also includes a sound absorbing material to be disposed within the annular space.