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A solar heat pump building preferably includes a building, an air barrier insulation layer, a material insulation layer and a plurality of ducts. The air barrier insulation layer includes a ceiling air barrier insulation layer and a wall air barrier insulation layer. The ceiling air barrier insulati

A solar heat pump building preferably includes a building, an air barrier insulation layer, a material insulation layer and a plurality of ducts. The air barrier insulation layer includes a ceiling air barrier insulation layer and a wall air barrier insulation layer. The ceiling air barrier insulation layer is a ceiling air gap created between a ceiling sheet and a roof panel. The wall air barrier insulation layer is a wall air gap created between the ceiling sheet and two opposing lengthwise wall panels, and two inner end wall sheets and two opposing end wall panels. Two lengthwise wall insulation layers are attached to vertical portions of the ceiling sheet. Two end wall insulation layers are attached to the two inner end wall sheets. A plurality of ducts include lengthwise ducts and end ducts, which are retained in the wall air barrier insulation layer to channel air.

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1. A solar heat pump building, comprising: two side structural walls and two end structural walls extending upward from a floor, each of the structural walls include at least one of a plurality of thermally conductive girts and thermally conductive joists, a thermally conductive sheet is attached to

1. A solar heat pump building, comprising: two side structural walls and two end structural walls extending upward from a floor, each of the structural walls include at least one of a plurality of thermally conductive girts and thermally conductive joists, a thermally conductive sheet is attached to at least one of the plurality of thermally conductive girts and the thermally conductive joists with a plurality of thermally conductive fasteners;a roof is disposed on top of the two side structural walls and two end structural walls, the roof includes at least one of a plurality of thermally conductive roof purlins and thermally conductive joist members, a thermally conductive roof sheeting is attached to at least one of the plurality of thermally conductive roof purlins and thermally conductive joist members;a wall insulation layer is disposed along an interior plane of at least one of the four structural walls to create a substantially uniform thickness wall air gap substantially a depth of the plurality of thermally conductive girts, said wall air gap is isolated from both outside air and from air inside a conditioned space in the building, wherein air is capable of circulating through said wall air gaps from substantially the floor to the roof;a heat collection coil and dehumidifier is located inside the roof; anda roof insulation layer is located supported below an interior plane of the roof to create a roof air gap substantially a depth of the plurality of thermally conductive roof purlins, wherein heated air is capable of circulating through said roof air gap from at least one of the four structural walls up a slope of an underside of the thermally conductive roof sheeting to a higher point of the roof where heat is removed from the air by said heat collection coil and dehumidifier, said heat collection coil and dehumidifier causing dense cooled air to flow downward along a lower slope of the roof air gap toward an eave to complete circulation. 2. The solar heat pump building of claim 1, further comprising: at least one damper is located within one of said wall air gaps, and said roof air gap, said at least one damper communicates with said wall air gaps in the structural walls and said roof air gap, wherein air in one of the structural walls is transferred to said roof air gap by manipulating said at least one damper. 3. The solar heat pump building of claim 1, further comprising: said heat collection coil and dehumidifier are retained inside said roof air gap. 4. A solar heat pump building of claim 1, further comprising: a multi-vent is located in a ridge of the roof, said multi-vent includes a plurality of vent modules, at least one of said plurality of vent modules includes a box unit and a cover. 5. The solar heat pump building of claim 4, further comprising: a heat collection coil and dehumidifier are retained inside said multi-vent. 6. The solar heat pump building of claim 1, further comprising: a blower for transferring air from at least one of said roof air gap and said wall air gap to at least one of an interior space of the building and outside the building. 7. The solar heat pump building of claim 1 wherein: at least one duct is horizontally oriented inside at least one of the structural walls and said wall air gap, said at least one duct has at least one opening to transfer air from said wall air gap to to said roof air gap. 8. The solar heat pump building of claim 7, further comprising: each one of said at least one duct includes at least one damper strip and at least one damper actuator, each one of said at least one duct includes at least one damper slots formed in a length thereof to slidably retain said at least one damper strip, a plurality of holes are formed through said at least one damper strip, a plurality of holes are formed through said at least one damper slot, said at least one actuator slide said at least one damper strip to allow air to flow into or out of said duct. 9. The solar heat pump building of claim 1, further comprising: a pair of subterranean air ducts being located adjacent said floor of said building, a plurality of subterranean tubing ducts are located below said floor, one end of said plurality of subterranean tubing ducts communicate with one of said pair of subterranean air ducts, the other end of said plurality of subterranean tubing communicate with the other one of said pair of subterranean air ducts, wherein at least one of inside and outside air is flowed through said plurality of subterranean tubing ducts to precondition air temperature and humidity for use within the building to reduce energy consumption. 10. A method of reducing the energy needs of a building, comprising the steps of: erecting a building having a floor, a peripheral wall and a pitched roof, said peripheral wall extending upward from the floor, said peripheral wall includes a wall air gap, the pitched roof is disposed on a top of the peripheral wall, installing at least one of a plurality of thermally conductive roof purlins and thermally conductive joists, a thermally conductive sheeting is attached to an exterior of the plurality of thermally conductive roof purlins with a plurality of thermal conductive fasteners;locating a roof insulation layer below said pitched roof to create at least one of a first roof air gap between one side of the peripheral wall and a ridge of the pitched roof, and a second roof air gap between an opposing side of the peripheral wall and the ridge, wherein heat and air is capable of naturally circulating within one of the wall air gap and the roof air gaps in at least one direction; andlocating a heat collection coil and dehumidifier inside one of said roof air gaps, said heat collection coil is capable of collecting heat energy from at least one the first roof air gap and the second roof air gap, heat is removed from hot air by said heat collection coil and dehumidifier, the cooled air inside one of the first and second roof air gaps naturally flows out of a colder side of the said heat coil and downward through one of the first and second roof air gaps to said wall air gap, the cooled air continues to flow down said wall air gap, until the air in wall gap air absorbs sufficient heat energy to rise and reverse direction to flow up to one of the first and second roof air gaps. 11. The method of reducing the energy needs of a building of claim 10, further comprising: a multi-vent including a plurality of vent modules, at least one of said plurality of vent modules includes a box unit and a cover. 12. The method of reducing the energy needs of a building of claim 10, further comprising: a blower for transferring air from at least one of said roof air gap and said wall air gap to at least one of an interior space of the building and outside the building. 13. The method of reducing the energy needs of a building of claim 10, further comprising: a pair of subterranean air ducts being located adjacent said floor of said building, a plurality of subterranean tubing ducts are located below said floor, one end of said plurality of subterranean tubing ducts communicate with one of said pair of subterranean air ducts, the other end of said plurality of subterranean tubing communicate with the other one of said pair of subterranean air ducts, means for draining said pair of subterranean tubing ducts of condensed liquid water. 14. A method of reducing the energy needs of a building, comprising the steps of: erecting a building having a floor, a peripheral wall and a pitched roof, said pitched roof is supported by a plurality of roof girts and joists, said peripheral wall extending upward from the floor, said pitched roof is disposed on a top of the peripheral wall, locating a roof insulation layer below said pitched roof and installing roof covering over a top of said pitched roof;locating a wall insulation layer along an inside plane of one of said plurality of gifts and joists to create at least one wall air gap, said wall air gap is substantially a depth of said plurality of girts and joists, air is capable of naturally circulating within said wall air gap from a lower point to a higher point adjacent an inside surface of a solar heated exterior sheeting of said peripheral wall and from a higher point to a lower point of said wall air gap on a cooler side of said peripheral wall; andmounting a heat collection coil and dehumidifier in a high point inside of said wall air gap, substantially centered between an interior surface of a exterior conductive wall sheeting and an exterior surface of said wall insulation layer, said heat collection coil and dehumidifier are mounted in said wall air gap to extract solar heat. 15. The method of reducing the energy needs of a building of claim 14, further comprising: a blower for transferring air from said wall air gap to an interior space of said building. 16. The method of reducing the energy needs of a building of claim 14, further comprising: a pair of subterranean air ducts being installed adjacent said floor of said building, a plurality of subterranean tubing ducts are installed below said floor and sloped to a low point where at least one drain is installed to remove condensation from the two subterranean tubing ducts, one end of said plurality of subterranean tubing ducts communicate with one of said pair of subterranean air ducts, the other end of said plurality of subterranean tubing communicate with the other one of said pair of subterranean air ducts.