AU2008346725A1 - Prefabricated building components and assembly equipments - Google Patents

Description

WO 2009/086617 PCT/CA2008/001809 27 November 2008 (27-11-2008) Prefabricated building components and assembly equipments BACKGROUND OF THE INVENTION FIELD OF THE INVENTION The present invention relates generally to building material and, more specifically, to a building process that offers better qualities in terms of value, structural integrity, and comfort and energy conservation for industrial, commercial and residential building industries. The present invention starts with a single component which is the vertical composite supporting steel member (stud), then the plate, the beam, the wall panel system, the window system, the joist system, the temperature regulated roof system and the multiple insulation patterns to create the cavities. The entire concept of utilizing the invention is that the design of all of the components and parts, the objective is focused onto facilitate the prefabrication process & to achieve energy efficiency. In the field of energy conservation, the industries are continuously making improvements to existing methods of energy conservation. 1 SI I RRTITI ITI= R|-I=IT (ill F II = WO 2009/086617 PCT/CA2008/001809 THE PRIOR ART There are other building components designed for the same purpose. Typical of these is U.S. Patent No. 3,161,267 issued to Keller on December 15, 1964. Another patent was issued to Burges on November 16, 1965 as U.S. Patent No. 3,217,455. Yet another U.S. Patent No. 3,258,889 was issued to Butcher on July 5, 1966 and still yet another was issued on February 15, 1972 to Palmer as U.S. Patent No. 3,641,724. Another patent was issued to Johnson on February 22, 1972 as U.S. Patent No. 3,643,394. Yet another U.S. Patent No. 3,736,715 was issued to Krumwiede on June 5, 1973. Another was issued to Berghuis, et al. on February 25, 1986 as U.S. Patent No. 4,571,909 and still yet another was issued on June 9, 1987 to Reynolds as U.S. Patent No. 4,671,032. Another patent was issued to McCarthy on January 1, 1991 as U.S. Patent No. 4,981,003. Yet another U.S. Patent No. 5,265,389 was issued to Mazzone et al. on November 30, 1993. Another was issued to Gular on December 14, 1993 as U.S. Patent No. 5,269,109 and still yet another was issued on June 16, 1998 to Richard as U.S. Patent No. 5,765,330. Another patent was issued to Ojala on September 21, 1999 as U.S. Patent No. 5,953,883. Yet another U.S. Patent No. 6,158,190 was issued to Seng on December 12, 2000. Another was issued to Dalphond, et al. on February 22, 2005 as U.S. Patent No. 6,857,237 and still yet another was issued on September 10, 1997 to Berreth as European Patent Application No. EP0794294. Yet another International Patent Application No. WO 2006/123005 was issued to Casan Celda on November 23, 2006. 2 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 3,161,267 Inventor: Robert R. Keller Issued: December 15, 1964 A prefabricated building panel comprising a grid formed of a multiplicity of rigid grid members mechanically connected together, each of said grid members having a web and flanges at each edge thereof extending at an angle to said web, the outer surfaces of each of said flanges being substantially flat and parallel to each other, the grid members extending in two directions and defining a multiplicity of open spaces surrounded by said grid members, said flanges at one edge of said webs defining a first set of bonding surfaces, said bonding surfaces being aligned in a single plane, a first outer sheet member extending in said plane over said grid, said first sheet member having an outer wear-resistant surface and an inner bonding surface, said inner bonding surface bonded with a layer of adhesive face-to-face to said first set of bonding surfaces, said layer of adhesive lying directly between the cooperating bonding surfaces of said first sheet member and said first set of bonding surfaces, said first sheet member extending continuously over all of said open spaces, a multiplicity of stiff, pre-formed backing sheet members one fitted in each of said open spaces in said grid, each backing sheet member having an area substantially corresponding to the area of said first sheet member lying over said open space, each backing sheet member having a planar bonding surface bonded by a layer of flexible adhesive face-to-face to said first sheet member substantially throughout said area, said backing sheet members each being thicker than said first sheet member and structurally of lesser density than said first sheet member and said grid members, the outer surfaces of said flanges on the other edge of said webs defining a second set of bonding surfaces, said second set of bonding surfaces being aligned in a single plane, a second outer sheet member adhesively secured to said second set of bonding surfaces, said second set of bonding surfaces locating said second sheet member in a spaced apart relationship to said backing sheet members, the smallest dimension of each of said open spaces parallel to said planes being substantially greater than the spacing between said planes. 3 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 3,217,455 Inventor: Joseph H. Burges Issued: November 16, 1965 In a modular panel including a pair of opposed, laterally spaced face plates and a closed border around the periphery of the face plates establishing a closed chamber between the face plates, the border having laterally spaced opposite sides, a plurality of joined border sections establishing the border, each of said border sections comprising: an outer covering of insulating material having inner and outer surfaces and a U shaped lateral cross section with opposite legs of the U-shape projecting inwardly from the periphery and terminating at innermost ends corresponding with the innermost end of the U-shaped cross-section, each leg including an enlarged portion extending toward one another; first and second longitudinal reinforcing strips each embedded in one of said enlarged portions and each fused to the inner surface of one leg of the U-shaped border section; a third longitudinal reinforcing strip having a U-shaped lateral cross-section and being disposed in the outer covering at the end of said U-shaped cross-section opposite said innermost end and fused to the inner surface of the outer covering; and a longitudinal slot in each leg of the U-shaped border section extending outwardly from said innermost ends; said face plates being received within said slots such that insulating material lies between the outer covering and each face plate, between each face plate and each of said first and second longitudinal reinforcing strips, and between each said first and second longitudinal reinforcing strips and the third longitudinal reinforcing strip so that the outer covering interrupts any direct contact between the opposed face plates and among the longitudinal reinforcing strips and the lateral path from one side to the other side of the peripheral border is of low transmission. 4 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 3,258,889 Inventor: Richard A. Butcher Issued: July 5, 1966 A prefabricated structural section comprising: (1) a frame comprising, transversely, a wooden ceiling plate and a wooden floor plate longitudinally spaced from said ceiling plate and, longitudinally, wooden studs transversely spaced from one another, extending from said ceiling plate to said floor plate and fastened to said plates by fasteners extending through said plates into said studs; (2) a panel on one side of said frame, extending longitudinally from said ceiling plate to said floor plate with one side of said panel being disposed adjacent said studs; and (3) means fastening said panel to said frame, said means consisting of rigid, cellular, polyurethane material tenaciously adhering to said ceiling plate, floor plate, studs and said side of said panel, extending from one stud to the next and from said ceiling plate to said face plate, and extending from said side of said -panel toward the other side of said frame sufficiently to substantially rigidify said section, but only part way to said other side of said frame, whereby between each pair of studs a substantial space extending from said ceiling plate to said face plate is provided for piping and wiring. 5 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 3,641,724 Inventor: James Palmer Issued: February 15, 1972 A wall construction for homes and the like developed for the construction of wall sections at locations removed from the building into which includes an integral box beam construction at the upper portions thereof with insulating and reflective material being provided as integral elements within the wall section. The box beam construction is built directly into the wall section and provides a strengthening factor to permit the placement of doors and windows at any point and permits the placement of truss rafters at any point and permits the placement of truss rafters at any point along the wall. 6 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 3,643,394 Inventor: Bobby G. Johnson Issued: February 22, 1972 A building structure module in the form of a wall panel capable of load bearing constructed of glass fiber reinforced plastic resin, semicylindrical structural members for load bearing and reinforcement and foam plastic for insulation purposes with the module having fire-retardant properties and a peripheral edge channel member to enable adjacent modules to be readily interconnected. The module is constructed by employing a procedural method so that the sequential steps are performed in a production line technique to facilitate construction of the modules. 7 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 3,736,715 Inventor: Leland J. Krumwiede Issued: June 5, 1973 A prefabricated load-supporting building panel is disclosed. The panel consists of a metal stud frame to which a sheet of moisture proof gypsum board is affixed. A thickness of molded polystyrene, supported by a peripheral casing attached to the frame, is bonded to the gypsum board. Exterior finish for the panel consists of synthetic plastic which is troweled onto a glass fiber fabric bonded to the polystyrene. 8 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 4,571,909 Inventor: Thomas G. Berghuls Issued: February 25, 1986 An insulated building has an inner structure forming the interior walls and roof of the building. Elongated wood spacer members are mounted on the exterior of the inner structure preferably with insulated fasteners. The spacer members are spaced from the exterior of the inner structure. Foam insulation covers the exterior of the inner structure to a depth generally flush with the spacer members. Sheeting is applied over the foam to cover the exterior of the building. The building is characterized by an absence of panel joints typically found in buildings of this type. Such joints permit detrimental heat transfer through the insulation. 9 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 4,671,032 Inventor: William A. Reynolds Issued: June 9, 1987 A stressed-skin building panel including structural strengthening members located alternately adjacent the two opposite skin members of the building panel, each of the structural strengthening members being spaced apart from the opposite skin member by a block of high-density rigid foam material, and the remainder of the space between the skin members being occupied by a foamed-in-place foam insulating material adhering to the skin members and structural strengthening members and providing a significant amount of strength and resistance to compressive stresses. The opposite skin members are spaced apart from one another and held together at the proper spacing during and after construction by a plurality of bridge members which form the only direct connection between the skin members by other than insulating foam material, so that the insulating quality of the panels is maximized. 10 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 4,981,003 Inventor: Grant McCarthy Issued: January 1, 1991 A unique wall panel is constructed from expanded polystyrene beads in an expanded polystyrene mold with structural members embedded in it during the molding process. The structural members are in the form of two by four studs placed at sixteen inch centers. Adjacent panels have interlocking grooves and ridges which fit together. The advantage of the present invention is that a total insulated wall is created with no cracks or spaces in the insulation. These lightweight panels can be carried to the building site, where base and top plates are applied and the panels interlocked to form a perfectly insulated wall. 11 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 5,265,389 Inventor: Mark C. Mazzone, et al. Issued: November 30, 1993 A composite building panel includes a core of a foamed polymeric insulating material, such as expanded polystyrene, having a plurality of uniformly spaced open box tubes retained in vertical grooves formed in the rear surface of the core by a two-part epoxy adhesive, the tubes being mechanically connected at their ends to one leg of continuous horizontal channels having their other leg adhesively secured to the core at horizontal slots. The front surface of the core is continuous without seams and may be coated with a variety of exterior insulation finishing system coatings. 12 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 5,269,109 Inventor: V. Rao Gular Issued: December 14, 1993 An insulated load bearing wall (10, 10') comprising panels of extruded polymer foam (20, 22, 50, 52, 54, 56) into which tubular, load carrying frame members (12, 14, 48) have been incorporated. A tongue is formed at one vertical edge of each panel (10, 10') and a groove is formed at the opposite vertical edge. The tubular frame members (12, 14, 48) are bonded to the extruded polymer foam. 13 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 5,765,330 Inventor: Michel V. Richard Issued: June 16, 1998 A pre-insulated prefab wall panel comprising of a rectangular wall frame having top and bottom rail members and a plurality of spaced apart stud members aligned between the top and bottom rail members. A polystyrene boardstock is affixed to a first side of the rectangular wall frame, thereby defining with the top and bottom rail members and the plurality of stud members a plurality of rectangular cavities, wherein each cavity has a depth of the thickness of a stud member. The prefab wall panel further has a layer of foamed-in-place polyurethane covering a portion of each cavity adjoining the boardstock, and bonding the structural wall frame to the polystyrene boardstock. The layer of polyurethane foam has a thickness which is substantially less than the depth of each cavity, whereby each cavity has available space for accommodating sub-trade installations. 14 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 5,953,883 Inventor: Leo V. Ojala Issued: September 21, 1999 An insulated wall panel comprising a bottom, a plurality of inner members, a plurality of outer members, spacers between the inner members and the outer members, an insulation layer, an exterior sheathing, a vapor barrier, a top member and a planar interior wall. The insulated wall panel has a dead air space located just inside of a cavity filled with insulation. The wall panel is adapted to be secured to the frame of a timber frame home without fasteners passing through the entire depth of the panel. Fasteners secure the inner members of the panel only to the frame without destroying the integrity of the insulated wall panel. 15 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 6,158,190 Inventor: Stephen Seng Issued: December 12, 2000 This composite building stud combines two metal shapes, inner and outer, with an insulating material to form a composite structural member having an insulating valve (R value) greater than a similar metal member normally used as a stud in a residential structure. The composite also has a strength comparable to that of a similar steel member normally used as a stud in a residential structure. One shape encompasses the other shape. The composite structural member eliminates any direct metal connections and thus eliminates any thermal shorts that reduce the overall insulating value (R-value) of the composite member. The shapes, inner and outer, with an insulating material form a composite structural member that has an interlocking shape which holds the insulating material in compression and mechanically couples the inner and outer members. 16 WO 2009/086617 PCT/CA2008/001809 U.S. Patent Number 6,857,237 Inventor: Raymond F. Dalphond, et al. Issued: February 22, 2005 A modular wall component with an insulative thermal break for preventing the creation of a continuous thermal path across the modular wall component. The modular wall component may be formed with an insulated frame structure that is fixed to an open frame structure with an insulative thermal break interposed therebetween. The insulated frame structure may be formed with a plurality of vertical track members coupled to an upper track member and a lower track member. At least one sheet of insulative material is interposed into the insulated frame structure. The open frame structure may have a plurality of vertical framing studs coupled to an upper framing track and a lower framing track. 17 WO 2009/086617 PCT/CA2008/001809 European Patent Application Number EP0794294 Inventor: Rainer Berreth Published: September 10, 1997 The wall (10) has individual bonded multi-layer elements (1), each with an insulating panel, especially a foam panel (2), with a coated surface (3) of bonded wood wool on one or both sides. Each element has one or more grooves (4), which run parallel to the coated surface on at least one end wall. At least one supporting strip (5) is pushed or glued into the groove, which may be arranged inside the panel, and may also run around its perimeter. There may also be a groove near the upper edge of the panel, and a further groove near its lower edge. 18 WO 2009/086617 PCT/CA2008/001809 International Patent Application Number WO 2006/123005 Inventor: Alfredo Casan Celda Published: November 23, 2006 The invention relates to a prefabricated element for construction, which is intended to be used as a wall covering or to form vaults between rafters in false ceilings. The inventive element is formed by a body (1, 11, 21, 31) comprising a base (5) of polymer material which supports an assembly of thin bricks (6, 12, 12a, 22). According to the invention, cavities (3) are provided between the aforementioned bricks and cavities (4) are provided between each of the bodies (1, 11, 21, 31), said cavities being covered with a filler material. The invention also relates to a method of producing the prefabricated element for construction, which is performed using a mould and which comprises the following steps consisting in: cutting the bricks to the required size and thickness, arranging the bricks in the corresponding cavities of the mould, placing filler material in the cavities between the bricks, injecting base polymer material, and stripping the part from the mould. 19 WO 2009/086617 PCT/CA2008/001809 While these building components may be suitable for the purposes for which they were designed, they would not be as suitable for the purposes of the present invention, as hereinafter described. The present invention provides a building process that offers better qualities in terms of value, structural integrity, and comfort and energy conservation for industrial, commercial and residential building industries. The present invention starts with a single component which is the vertical composite supporting steel member (stud), then the plate, the beam, the floor joist, the roof truss system and the multiple insulation patterns to create the cavities. The entire concept of utilizing the invention is that the design of all of the components and parts, the objective is focused on; to facilitate the prefabrication process and conserve energy. 20 WO 2009/086617 PCT/CA2008/001809 SUMMARY OF THE PRESENT INVENTION [0001] A primary obj ect of the present invention is to provide prefabricated building components with energy efficient saving means to facilitate the building process of industrial, commercial and residential building industries. [0002] Another object of the present invention is to provide several composite insulated members (studs) presented in their different configurations, having bonded foam as the media with rigid foam insulation and OSB strip members to in-forced the structure and air tight cavities, but they serve the same function as the vertical supporting members for exterior and interior walls. [0003] Yet another object of the present invention is to provide multiple insulation patterns to form various components to be inserted between the 2x6" studs spaced at 16" or 24" O.C., one component consists of various pieces of rigid Styrofoam members stacked together spaced apart to facilitate the formation of other insulation components. [0004] Yet another object of the present invention is to provide the composite insulated members (stud) with multiple configurations having bonded foam as the media with rigid foam insulation and OSB strip members to in-forced the structure and air tight cavities. [0005] Yet another object of the present invention is to provide vacuum insulation for use in insulation if formed is the most effective way of insulation and can yield an insulation value approximately 5-7 times that of fiber glass batts. The present invention uses two or three pieces of glass sheets depending on application, sandwiched together with thin glass strips to form the supporting edges and the seal, and glass pellets to form supporting points within the panel. A heating device is used going around four edges by applying appropriate temperature. Thus the entire unit as a whole will be sealed seamlessly with the SME glass material and all melted together as one piece, which is the glass Vacuum Insulated Panel (VIP). [0006] Yet another object of the present invention, the said glass VIP in its double and triple pane configurations are "obscured" glass panels in vacuum condition which are used as part of the wall insulation members as composite insulated wall panel and also used as 21 WO 2009/086617 PCT/CA2008/001809 "obscured" insulated glass features wall panels to bring in lights; hereinafter, part of this present invention is to implement the non-factory "repeat at will" built-in on and off vacuum system incorporated for window and wall load-bearing structures by using active forced thermal fluids, for the purpose of achieving various high level insulation values along with advancing the "obscured" to "un-obscured" and co-exist in the system for a building structure. [0007] Yet another object of the present invention is to create active thermal cavities and inactive cavities implemented strategically in between walls, in ceilings and as well in floors to improve R-value. There are 2 types of active thermal cavities depicted in the present invention, in order to avoid confusion thereinafter it is necessary to describe and distinct the differences between the two; first one is described as the "independent" active thermal cavity created in a thin hollow space minimum half of an inch in between all walls, in ceilings and in floors (also in concrete floors) depending on structural requirements, said "independent" cavities all connected together as a thorough thermal blanket covering the entire structure with forced air traveling in the cavities at a higher temperature then the air in the room, vise versa for the cool air system. The source of said thermal forced air is from the auxiliary furnace or auxiliary air conditioning unit with relatively small capacity. The second active thermal forced air cavity is described thereinafter as "in-floor" active thermal cavity which is the void space created in between and along floor joists underneath the flooring, this source of thermal forced air is generated from the main climate control unit in the present invention, the main function of this "in-floor" active thermal cavity is to regulate the floor temperature and extends it's forced air route to facilitate other two functions in the present invention; 1). in-wall forced ambient air emits into rooms eliminates existing floor mount air registers and 2). creates forced air window cavity defroster. The volume of forced air for the first "independent" active thermal cavities from the auxiliary furnace is relatively very small compares with the volume of the in-floor forced air which is from the main climate control system and it is massive volume in comparison. The concept to achieve ultimate effective R-value is that the law of physic dictates; warm air always moves to the colder side, therefore the created "independent" active thermal forced air blanket insulated to the exterior cold temperature and with higher temperature forced air in it's own path traveling "independently" than the lower temperature air in the rooms, therefore resulting the lower room temperature air would not be able to escape to the colder exterior due to the room temperature air being blocked by the higher temperature 22 WO 2009/086617 PCT/CA2008/001809 "independent" forced air blanket in the walls. Further explaining the functions of the "independent" active thermal forced air cavities; having galvanized metal sheets that inserted in between the created "independent" thermal forced air cavities, resulting the said galvanized metal sheets would be also heated by the active thermal forced air at a higher temperature, therefore the said metal sheet also forms a barrier with a higher temperature (along with the active forced air) then the air in the rooms. Room temperature air can not passes the multi thermal barriers which are higher temperature. [0008] Yet another object is to utilizing the active forced air to created a temperature regulated roof system comprises of plural sandwiched foam panels each with an active forced air cavity collecting hot air underneath the roof sheathing, all active forced air from the passages of all said foam panels flow into a central channel, then to be redirected or be blown to the outside. [0009] Still yet another object is to utilize the combined benefits of the active and inactive air passages; in the walls, in the ceilings, in the floors to rearrange the placements of the traditional mechanical system; such as furnace, water heater, sheet metal air ducting and plumbing to create an un-obstructed basement by hiding the said mechanical system to yield more enjoyable space. [0010] Additional objects of the present invention will appear as the description proceeds. [0011] The present invention overcomes the shortcomings of the prior art by providing a building process that offers better qualities in terms of value, structural integrity, and comfort and energy conservation for industrial, commercial and residential building industries. The present invention starts with a single component which is the vertical composite supporting steel member (stud), then the plate, the beam, the floor joist, the wall system, the temperate regulated roof system and the multiple insulation patterns to create the cavities. The entire concept of utilizing the invention is that the design of all of the components and parts, the objective is focused on; to facilitate the prefabrication process and conserve energy. [0012] The foregoing and other objects and advantages will appear from the 23 WO 2009/086617 PCT/CA2008/001809 description to follow. In the description reference is made to the accompanying drawing, which forms a part hereof, and in which is shown by way of illustration specific embodiments in which the invention may be practiced. These embodiments will be described in sufficient detail to enable those skilled in the art to practice the invention, and it is to be understood that other embodiments may be utilized and that structural changes may be made without departing from the scope of the invention. In the accompanying drawing, like reference characters designate the same or similar parts throughout the several views. [0013] The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is best defined by the appended claims. 24 WO 2009/086617 PCT/CA2008/001809 BRIEF DESCRIPTION OF THE DRAWING FIGURES In order that the invention may be more fully understood, it will now be described, by way of example, with reference to the accompanying drawing in which: FIGURE 1 is a top view of prior art. FIGURE 2 is an illustrated view of the present invention in use. FIGURE 2A is a top view of different configurations of the 2x6 vertical composite insulated members (studs). FIGURE 2B is a top view of different configurations of the 2x6 vertical composite insulated members (studs) with glass vacuum insulation panel (VIP) and active thermal cavities applied with the studs to increase R-value of the studs. FIGURE 2C is a view of the stud number 1 configuration. FIGURE 3 is a top and side view of other composite reinforced insulated members for the wall structure. FIGURE 3A are sectional views of composite insulated bottom and top sill plates. FIGURE 3B are sectional views of composite insulated members (nail board). FIGURE 3C is a side-end view of a horizontal window sill plate. FIGURE 4 is a side view of the present invention (multi-insulation components). FIGURE 4A is a side view of the present invention (multi-insulation components). FIGURE 4B is a side view of the present invention (multi-insulation components). 25 WO 2009/086617 PCT/CA2008/001809 FIGURE 4C is a side view of the present invention (multi-insulation components). FIGURE 5 is a sectional view of composite stud and wall assembly. FIGURE 5A is another top sectional view of composite stud and wall assembly. FIGURE 5B is another top sectional view of composite stud and wall assembly. FIGURE 5C is another top sectional view of composite stud and wall assembly. FIGURE 5D is another sectional top sectional view of composite stud and wall assembly. FIGURE 5E is another sectional top sectional view of composite stud and wall assembly. FIGURE 5F is another top sectional view of composite stud and wall assembly. FIGURE 5G is another top sectional view of composite stud and wall assembly. FIGURE 5H is another top sectional view of composite stud and wall assembly. FIGURE 51 is another top sectional view of composite stud and wall assembly. FIGURE 6 is top views of glass vacuum insulation panel (VIP) assemblies. FIGURE 6A is sectional views of glass vacuum insulation panel (VIP) wrapped around with rigid foam members. FIGURE 6B is sectional views of the present invention (VIP, rigid foam and studs). FIGURE 6C is VIP sandwiched with rigid foam and with created cavities. 26 WO 2009/086617 PCT/CA2008/001809 FIGURE 6D is a sectional view of VIP sandwiched with rigid foam. FIGURE 6E is a top view of the added glass pane on interior side of the VIP created cavity. FIGURE 6F is a top view of the added glass panes on both sides of the VIP created cavities. FIGURE 6G side & front view of the un-obscure double pane glass VIP with no vacuum condition in the cavity. FIGURE 6H side & front view of the un-obscure double pane glass VIP prefilled with light color fluid in the cavity. FIGURE 61 sectional view of the mechanical apparatus; (a programable pumping & controlling devices & reservoirs filled with fluids), shows the relationship with the double pane glass VIP. FIGURE 6J side & front view of the un-obscure double pane glass VIP prefilled with light color fluid in the cavity which interacted & connected with the programmable pumping & controlling system & reservoirs. FIGURE 6K side & front view of the un-obscure double pane glass VIP shows the light color fluid has been pumped out of the cavity to create the pressurized vacuum condition. FIGURE 6L side & front view of the un-obscure double pane glass VIP shows the cavity is filled with darker color fluid. FIGURE 6M side & front view of the double pane glass VIP, the "darker" color fluid is pumped out & a pressurized vacuum condition is created in the cavity. FIGURE 6N side view, front & back view of the un-obscure triple pane glass VIP with dual cavities, one of the cavity is pre-treated in permanent pressurized vacuum 27 WO 2009/086617 PCT/CA2008/001809 condition by forced fluid & the other cavity is for the repeatable vacuum process to be prefilled with color fluids. FIGURE 60 side view, front & back view of the un-obscure triple pane glass VIP, one of the cavity is pre-filled with light color fluid, and the other cavity is pre-treated in permanent vacuum condition with forced fluid. FIGURE 6P side view, front & back view of the un-obscure triple pane glass VIP with dual cavities interacted & connected with the programmable pumping & controlling system & reservoirs; one prefilled with light color fluid & the other is pre-treated in permanent vacuum condition by forced fluid. FIGURE 6Q side view, front & back view of the un-obscure triple pane glass VIP with dual cavities, the light color fluid is pumped out from the cavity which is also turned into a pressurized vacuum cavity, & the other is pre-treated in permanent vacuum condition by forced fluid. FIGURE 6R side view, front & back view of the un-obscure triple pane glass VIP with dual cavities, one of the cavities is filled with darker color fluid & the other is pre treated in permanent vacuum condition by forced fluid. FIGURE 6S side view, front & back view of the un-obscure triple pane glass VIP with dual cavities, the darker color fluid is pumped out from the cavity which is also turned into a pressurized vacuum cavity & the other is pre-treated in permanent vacuum condition by forced fluid. FIGURE 6T sectional view of the entire system of the un-obscure triple pane glass VIP; fluids are pumped out retained in the reservoirs which are connected with a temperature gauged self-activated heater. FIGURE 6U shows a side view & front view of a double pane glass VIP which can be used as door insulation members. 28 WO 2009/086617 PCT/CA2008/001809 FIGURE 7 is a side view of the master work frame equipment assembly. FIGURE 7A is side-view of the master work frame equipment assembly. FIGURE 7B is side-view of the master work frame equipment assembly relates to top part mechanism. FIGURE 7C is side-view of the master work frame equipment assembly relates to bottom part mechanism. FIGURE 7D is side-view of further explaining the master work frame equipment assembly. FIGURE 7E is a sectional view of the vertical wall supporting member (VWSM) mounted on one side of the main wall assembling frame, one end of the (VWSM) is mounted to the frame side "A" body. FIGURE 7F is a side view of the master work wall frame equipment assembly mounted on pivoting mechanism in horizontal position receiving studs. FIGURE 8 is a side view of the composite wall frame equipment assembly and the coordinate position of the conveying/transporting frame. FIGURE 8A is a side view of the master work wall frame equipment assembly with studs laid in place. FIGURE 8B is a vertical side view of the wall frame production assembly with wall frame skeleton on. FIGURE 8C is a vertical side view of the wall frame production assembly with insulation components and wiring installed. FIGURE 8D is a vertical interior side view of the wall frame production assembly with 29 WO 2009/086617 PCT/CA2008/001809 drywall installed. FIGURE 8E is a vertical exterior side view of the finished composite wall with wall sheathing installed. FIGURE 8F shows the protective finishing process of the finished wall. FIGURE 8G is a view showing the coordination and the process of the conveying & transporting mechanism the conveying fork is moving in to the finished composite wall from the production assembly. FIGURE 8H is a view showing the conveying fork is engaged with the finished composite wall from the production assembly. FIGURE 81 shows the conveying fork retrieving with safety strap in place. FIGURE 8J is an exploded sectional view of finished composite wall and conveying fork. FIGURE 9 shows the roof truss galvanized steel members. FIGURE 9A is a sectional and side view of the ceiling joist. FIGURE 9B is an applying example of the ceiling joist with vertical studs. FIGURE 9C is an applying example of the ceiling joist with vertical studs and ceiling insulation components. FIGURE 9D is an applying example of the ceiling truss system with insulations relative to the attic space. FIGURE 9E is a sectional view of multiple insulation patterns applied with the ceiling joist. 30 WO 2009/086617 PCT/CA2008/001809 FIGURE 9F is an applying example of multiple insulation patterns to the ceiling, the wall frame and ceiling joist. FIGURE 10 shows the half and half gable roof prefab assembly. FIGURE 1OA is a front and side view of the equipment for the gable roof truss assembly the mobile truss anchor station. FIGURE 1OB is a side view of the coordinate positions of the other equipments for the gable roof truss assembly. FIGURE 1OC is a top applying example view of the equipment for the gable roof truss assembly mobile truss stations and the anchor station. FIGURE 1 OD is a side view of applying example of the roof truss system has been installed on the equipment for the gable roof truss assembly mobile truss stations and the anchor station. FIGURE 1OE is a side view of the completed gable roof on it's vertical position. FIGURE 11 shows the hip roof to be defined in sections for production process. FIGURE 1 A shows the sectional hip roof to be assembled separately. FIGURE 1 B shows the hip roof equipment assemblies. FIGURE 1 IC is a side view of the hip roof truss assembly stations in their coordinated positions. FIGURE 1 ID is a top view of the hip roof truss assemblies with the mobile truss anchor station and other mobile stations system. 31 WO 2009/086617 PCT/CA2008/001809 FIGURE 1 iE is a front view of the hip roof truss system and the assembling process. FIGURE 1 IF is a top view of the hip roof truss system and the assembling process. FIGURE 1 IG is a finished section of a finished half hip roof truss laid on the hip roof truss equipment assembly. FIGURE 1 1H is a side view of a finished sectional half hip roof truss in vertical position. FIGURE 12 shows the forced air path of the independent active thermal air cavity. FIGURE 12A shows the forced air path of the independent active thermal cavity air blanket associates with the inactive cavity, glass VIP within the walls. FIGURE 12B shows a version of independent active thermal air insulation associated with metal sheets for building that sought for higher energy saving requirements. FIGURE 12C is an applying example of the insulation component comprising multiple active thermal cavities with sheet metals and rigid foams incorporated with studs, sheathing boards and studs. FIGURE 12D is an applying example of the independent active thermal forced air path for multi-level building. FIGURE 13 is an orthographic view of the independent active thermal forced air blanket movement in walls travels up and across the ceiling. FIGURE 13A is an applying example of the independent active thermal forced air blanket movement in ceiling travels down the opposite side walls. FIGURE 13B is an applying example of the independent active thermal cavity air blanket forced air upward movement in one of the other two sets of walls. 32 WO 2009/086617 PCT/CA2008/001809 FIGURE 13C is an applying example of the independent active thermal cavity air blanket forced air downward movement in one of the other two sets of walls. FIGURE 13D is the top sectional view of the basement concrete wall structure with a boxed-out space for housing the climate control unit. FIGURE 13E is the top sectional view of the main floor wall frame structure with a boxed-out space for housing forced air ducting system from the climate control unit. FIGURE 13F is the top sectional view of the upper floor wall frame structure with a boxed- out space for housing forced air ducting system from the climate control unit. FIGURE 13G is the side view shown the created boxed-out spaces for housing the climate control unit to allow the basement floor free of obstruction for more desirable development & the aligned multi-level vertical column boxed-out spaces for accommodating forced air ducting system reaching up & returning from all 3 levels. FIGURE 13H is the side view shown an outward ducting body is installed & connected with the climate control unit depicting the main outward active forced air path and various multi level extending outward active forced air paths. FIGURE 131 is the side view shown an inward ducting body is installed & connected with the climate control unit depicting the main inward active forced air path and various multi level extending inward active forced air paths. FIGURE 13J is the orthographic side view shown the interacted combined functions of the basement boxed-out space, the multi-level vertical column boxed-out spaces; the climate control unit; the outward & inward active forced air ducting system associated & networked with the entire multi-level active thermal forced air passages & paths. FIGURE 13K is the side & cut-off view focused on depicting an elongated horizontal boxed-out structure installed & attached to exterior multi-level flooring structures and capable of 33 WO 2009/086617 PCT/CA2008/001809 embracing pluming pipes & electrical wirings in horizontal positions. FIGURE 13L is another side view 90 degrees of FIG. 13K, shown the main plumbing pipes positioned vertically within the boxed-out spaces of the multi-level vertical column, and horizontally extends their routes to other floor levels via the elongate horizontal boxed-out structure, also illustrates the electrical wirings & water lines adapting along the extension route of the main plumbing pipes. FIGURE 13M is a top view of FIG. L further depicts the formation & relationships with the boxed-out space from the basement wall, the vertical column boxed-out spaces, the elongate horizontal boxed-out structure, main plumbing pipes and their extensions extended into the void space between floor joist. FIGURE 13N is an applying example of another independent active thermal forced air blanket movement rising up in basement from the created boxed-out space FIGURE 130 is a cut-off horizontal view of an existing prior art piece of a corrugated metal ceiling component showing the corrugated pattern creates the "void" spaces on both sides. FIGURE 13P is a cut-off horizontal view of an existing prior art typical ceiling structure illustrates the creation of the "void" spaces to be utilized as another active thermal forced air path in the present invention. FIGURE 13Q is the cut off view of a residential house comprises of a roof structure having active forced air passages system running underneath the roof sheathing above the attic. FIGURE 14 is a sectional and side view of a composite floor joist. FIGURE 14A is a sectional and side view of a composite interiorjoist side plate (OSB) for additional floor to anchor on. FIGURE 14B is a sectional and side view of an exterior composite insulated side plate 34 WO 2009/086617 PCT/CA2008/001809 (OSB) for additional floor to anchor on. FIGURE 14C is a sectional and cut off side view of the relationships and applying example of various floor members; exterior composite insulated side plate, interior joist side plate and floor joist forming the principal and sectional floor. FIGURE 14D is a front view of the non-movable station "A" of floor equipment assemblies. FIGURE 14E is a front view of station "B", "C" and "D" all movable on tracks of the floor equipment assemblies. FIGURE 14F is a side view of the principal floor assemblies relative to the floor equipment. FIGURE 14G is a side view of a assembled principle floor laid on the floor equipment assemblies . FIGURE 14H is a side view of an applying example of assembling the principal floor and two additional floors on each side on the floor equipment assemblies. FIGURE 141 is a top view without the OSB floor sheathing installed, the relationships of the four platforms (ABCD) which can assemble all sizes of principle floors and additional floors. FIGURE 15 shows the top view and sectional view of the bottom plate with openings for forced air passage and also showing the composite multiple insulation patterns applied between the 2 composite insulated studs. FIGURE 15A is a sectional and side view of the floor joist explaining the function of the floor joist creating forced air channels underneath the floor. FIGURE 15B is a top view of the exposed main floor structure without the floor 35 WO 2009/086617 PCT/CA2008/001809 sheathing board, shows the in-floor forced air circulating route and openings in the bottom plates. Also shows side view of the configured in-floor cavities. FIGURE 15C is a view an applying example of the in-floor forced air circulation extends it's path to the blocked inactive cavity created the in-wall forced air for room ambient air and the relationship with the glass VIP and the studs. FIGURE 15D is a view of the composite floor joist with openings. FIGURE 15E is a top view shown, forced air circulating areas that can be controlled and be selected; as required due to the flexibility, such as bathrooms which may have cold ceramic tile flooring. individual space between joists can be connected through strategic openings in floor joists. FIGURE 15F shows applying examples for materials being used to created in-floor cavities for forced air circulation on the composite floor joist, many types of material can be used such as rigid foam sheet, OSB members, sheet metal and corrugated materials. FIGURE 15G shown are examples for the created in-floor forced air system being applied on the existing floor joist systems such as; engineered floor joist system, galvanized steel single or double joist system and timber floor joists system. FIGURE 15H is a side view of a window forced air deforester system with the forced air deflector, snapped onto the top surface of the window frame, also showing the forced air path of the window deforester. FIGURE 151 shows a window defroster with deflector related to the in-floor forced air system, shows independent active thermal cavity air blanket, not extending to window. Also shows glass VIP vacuum insulated panel. FIGURE 15J refers to figure 151 shows the interacting relationships of adding a single pane glass to the window defroster system, independent active thermal cavity air blanket extending to window surface and glass VIP. And magnifying the benefits. 36 WO 2009/086617 PCT/CA2008/001809 FIGURE 15K refers to figure 15J further shows the combined relationships and benefits of in-floor forced air, adding a single glass pane to cavity window defroster, independent active thermal force air blanket travels up the window and the wall and the glass VIP, all to achieve the ultimate insulation effectiveness. FIGURE 15L shows a side sectional view of composite insulated wall panel further explaining the interact relations and functions of the in-floor forced air circulation extending to window defroster and in-wall forced air ambient to room. FIGURE 16 is a top view of a composite wall panel structure with hidden rain water drainage system. FIGURE 16A is a sectional view of the in-wall hidden rain drainage system. FIGURE 16B is a vertical sectional view of the hidden rain water drainage system with rectangular wall passages for 2 levels. FIGURE 16C is a top view of the hidden rain water drainage system. 37 WO 2009/086617 PCT/CA2008/001809 THE REFERENCED NUMERALS Turning now descriptively to the drawings, in which similar reference characters denote similar elements throughout the several views, the figures illustrate the Prefabricated Insulated Building Components and Assembly Equipment of the present invention. With regard to the reference numerals used, the following numbering is used throughout the various drawing figures. 1 the double pane un-obscure glass VIP body. la the cavity of the double pane un-obscure glass VIP body with no vacuum condition at this stage. lb the protruding fluid drain outlet for the double pane un-obscure glass VIP 1c pre-filled light color forced fluid 1 d the rigid foam supporting members 1 e the pressurized vacuumed cavity is created by drawing out the light color fluid 1 f the pressurized vacuumed cavity is created by drawing out the darker color fluid 2 the programmable split flow guide 3 the tubing system used to transport the fluids 4 the programmable fluid pumps that facilitates the movements of the forced fluids. 5 the reservoir for the light color thermal forced fluid. 5a the light color thermal forced fluid. 6 the reservoir for the darker color thermal forced fluid 6a the darker color thermal forced fluid. 7 the entire body of the triple pane un-obscure glass VIP in its side view 7a the "repeat at will" vacuum panel being one of the two attached bodies of the triple pane un-obscure glass VIP 7b the "permanent" vacuum panel being two of the two attached bodies of the triple pane un-obscure glass 7c the "cavity" of body 13a at the stage where no vacuum condition has been created 7d the pre-treated permanent vacuumed "cavity" of body 13b 7e the protruding nipple for vacuum process of the "permanent" triple pane un-obscure glass VIP. 38 WO 2009/086617 PCT/CA2008/001809 7f the protruding fluid drain outlet for the "repeat at will" triple pane un-obscure glass VIP. 7g the "pressurized vacuumed" cavity created by withdrawing the light colour fluid 7h the "pressurized vacuumed" cavity created by withdrawing the darker colour fluid 8 the thermal exchanger facilitated for the forced thermal fluids 5a & 6a 8a the thermal transfer line for forced fluid 1 Oa travels to & from between the reservoir 6 & the thermal exchanger 8 8b the thermal transfer line for forced fluid 5a travels to & from between the reservoir 5 & the thermal exchanger 8 9 the double pane glass VIP body to be incorporated as an insulation member for door 9a the vacuumed cavity of the glass VIP body 9 9b the opening for door knob. 9c the nipple to facilitate the vacuum process. 10 Prefabricated insulated Building Components and Assembly Equipment of the present invention 12 composite insulated vertical member (stud) 14 galvanized steel 16 oriented strand board (OSB) 18 rigid foam insulation 22 wood stud 24 prior art studs 26 fiberglass insulation 28 drywall 30 OSB floor sheathing 32 opening for plumbing and electrical 34 glass vacuum insulated panel (VIP) 36 independent active thermal cavity 38 inactive cavity 40 top sill plate 42 bottom sill plate 44 nail board 46 exterior OSB wall sheathing 48 nail 39 WO 2009/086617 PCT/CA2008/001809 50 baseboard 52 window reinforcement sill plate/header 54 flange 56 screw recess 58 spacer 60 protective wrap 62 Composite insulated wall panel assembly 64 VIP support pellet 66 VIP strip edge 68 VIP glass nipple 70 interior feature glass 72 exterior feature glass 74 master work frame assembly 76 vertical wall supporting member 77 conveying/transporting frame 78 motorized mechanism 80 first frame side 82 second frame side 84 top release bar 86 frame bottom plate 88 timber plate 90 openings for conveying fork lifts 92 bottom release bar 94 weight support 96 station bolt 98 elevating mechanism 100 guiding track of station bolt 102 tightening knob 104 top portion of main frame 106 bottom portion of main frame 108 guiding rods 110 top mounting member 112 metal member 40 WO 2009/086617 PCT/CA2008/001809 114 base 116 track support rail 118 track support leg 120 motorized track 122 conveying fork 124 video camera 126 electric motor 128 window header beam 130 electrical wire 132 receptacle box 134 light switch 136 window glass pane 138 protective foam pads 140 safety strap 142 roof truss 144 center supporting member 146 web supporting member 148 rafter beam 150 drop down ceiling joist 152 main joist section 154 drop down joist section 156 main joist flange 158 drop down flange 160 attic space 162 nut 164 bolt 166 gable roof system 168 mobile truss anchor station 172 station body structure 174 wheel 176 anchor bar 178 elevating mechanism 180 spacer 41 WO 2009/086617 PCT/CA2008/001809 182 half truss frame 184 first ceiling frame support "A" 186 second ceiling frame support "B" 188 anchor mechanism 190 bracing member 192 side plate 194 fastening bracket 196 conveyance device 198 roof sheathing and shingles 200 hip roof 204 hip end 206 third ceiling frame support "C" 208 fourth ceiling frame support "B" 210 tracks of 168 212 pivot mechanism 214 double adjoining plate 216 bridging member 218 hip truss section 220 independent thermal forced air 222 auxiliary furnace 224 concrete floor 226 solar panel 228 solar powered regulated fan 230 galvanized metal sheet 232 casing 234 concrete ceiling 236 interior wall 238 glass wall 240 added single pane glass 242 return air to furnace 246 duct 248 studs with no openings 250 studs with openings 42 WO 2009/086617 PCT/CA2008/001809 252 composite floor joist 254 interior composite floor joist 256 exterior composite joist side plate 258 safety railing 260 station "A" 262 station "BCD" 264 composite insulated reinforcement member 266 platform 268 joist frame supporting member 270 sectional floor 272 principal floor 274 bottom plate 276 rigid foam in-floor air channel 278 horizontal foam strip 280 recess/opening in bottom plate 282 recess/opening in floor joist 284 in-floor active cavity/channel 286 rigid foam cavity/channel 288 OSB cavity/channel 290 corrugated sheet cavity/channel 292 sheet metal cavity/channel 294 engineered floor joist cavity/channel 296 galvanized "C" steel single or double floor joist cavity/channel 298 timber floor joist cavity/channel 300 window forced air deflector 302 supporting point 304 snap-on device 308 window frame 310 window forced hot air 312 openings for plumbing & electrical in Studs, top & bottom sill plates, nail board, and in reinforcement members. 314 window double pane glass 316 on-wall air register 43 WO 2009/086617 PCT/CA2008/001809 318 glass single pane 320 in-floor forced air 322 rainwater drainage system 324 in wall hidden drain pipe 326 steel reinforcing member 328 rain gutter and eve through system 330 down spout 332 ground grading 334 foundation cement wall 336 roof line 338 upper floor 340 drain opening 342 drain channel 344 soffit space 346 openings for in-wall forced air in composite member 264 348 openings for active forced air in composite member 264 350 openings for in-wall forced air in composite member 40 & 42 352 openings for active forced air in composite member 40 & 42 354 openings for in-wall forced air in composite member 44 356 openings for active forced air in composite member 44. 358 boxed out upper level wall for accommodating the forced air ducting 360 space for accommodating the going-out & return forced air ducting 362 floor member for supporting the boxed out wall for upper level 364 boxed out main level wall for accommodating the forced air ducting 368 floor member for supporting the boxed out wall for main level 370 boxed-out concrete wall for housing the (furnace) 372 boxed-out space in basement 374 climate control unite (furnace) 376 in-ceiling active thermal forced air in it's outward path 378 out-going active thermal forced air travels in duct 380 air duct for out-going active thermal forced air 382 upper floor active thermal forced air in it's path 384 main floor active thermal forced air in it's path 44 WO 2009/086617 PCT/CA2008/001809 386 basement active thermal forced air in it's path 388 in-ceiling return active thermal forced air in it's path 390 upper floor return active thermal forced air in it's path 392 air duct for return active thermal forced air 394 return active thermal forced air travels in duct 396 main floor return active thermal forced air in it's path 398 basement return active thermal forced air in it's path 400 foam strip to divide the wall panel to create outward & return forced air path 402 basement concrete wall 404 main floor exterior wall 406 upper floor exterior wall 408 upper floor in-floor outward active thermal forced air path 410 upper floor in-floor return active thermal forced air path 412 main floor in-floor outward active thermal forced air path 414 main floor in-floor return active thermal forced air path 416 basement floor in-slab outward active thermal forced air path 418 basement floor in-slab return active thermal forced air path 420 elongated horizontal boxed out space 422 cut out view of a section of a plumbing pipe installed inside the horizontal boxed out space 424 an vertical section of a main plumbing pipe inside the vertical column boxed-out space raised from the ground 426 cut out horizontal sectional view of a plumbing pipe 90 degrees to pipe 422 extends out to the void space underneath the sub-floor 428 foam insulation fills up the hollow space in the horizontal boxed-out space 430 cut out section view of a piece of electrical wire installed inside the horizontal boxed out space 432 a piece of electrical wire installed vertically within the vertical column boxed out space 434 a cavity for active thermal forced air horizontally installed inside the horizontal boxed-out space 436 a cut out section view of a piece of water pipe installed inside the horizontal boxed out space 45 WO 2009/086617 PCT/CA2008/001809 438 a piece of water pipe installed vertically within the vertical column boxed-out space 440 a piece of electrical wire an extension of electrical wire 430 installed 90 degrees to the horizontal boxed-out space extends out to the void space underneath the sub-floor 442 another active thermal forced air path rising in the basement within wall panels outward from the basement boxed-out unit 444 an existing prior art piece of a corrugated metal ceiling component forming part of a ceiling & roofing structure 446 Interior "void" spaces created by the corrugated pattern itself 448 Exterior "void" spaces created by the corrugated pattern itself 450 a strategic piece of insulation sheet material in place to create the interior "void" spaces for active thermal forced air path 452 conventional roofing material 454 conventional roofing insulation material 456 upper rigid foam member in sheet form 456a lower rigid foam member in sheet form 458 forced air cavity within the insulated panel sandwiched by 2 pieces of foam member 460 forced air running within the cavity of the sandwiched foam members 462 the elongated square forced air central channel made of rigid foam 464 the cavity of the central channel to be used as forced air passage 466 forced air entering from the cavity of the rigid foam panel 468 the ceiling line 46 WO 2009/086617 PCT/CA2008/001809 DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT The following discussion describes in detail one embodiment of the invention (and several variations of that embodiment). This discussion should not be construed, however, as limiting the invention to those particular embodiments, practitioners skilled in the art will recognize numerous other embodiments as well. For definition of the complete scope of the invention, the reader is directed to appended claims. FIGURE 1 is a top view of prior art. 20 Shown are two top views of prior art 20, first depicting the existing wood frame structure with 2x6 wood studs 22, the second depicting the existing steel frame structure with 2x6 "C" studs 24 with fiberglass insulation 26 disposed between the drywall 28 and the oriented strand board 16. The present invention is intended to improve the building process and offers better qualities in terms of value, structural integrity, comfort and energy conservation for industrial, commercial and residential building industries. The present invention starts with a single component which is the composite vertical insulated supporting steel member (stud), then the plate, the beam, floor joist, the roof truss and the multiple insulation patterns to create the cavities. The entire concept of utilizing the invention is that the design of all of the components and parts, the objective is focused on one, which is to facilitate the prefabrication process. FIGURE 2 is an illustrated view of the present invention 10 in use. The prime purpose of the present invention 10 is to offer an alternative process to build residential homes in a more effective way with improved energy value factor utilizing the existing materials and the existing manufacturing facilities readily available on the market. FIGURE 2A is a top view of different configurations of the 2x6 composite insulated vertical members (studs) 12 comprising oriented strand board (OSB) members 16, galvanized steel 14 and rigid foam insulation 18. FIGURE 2B is a top view of different configurations of the 2x6 composite insulated vertical members (studs) 12 with glass vacuum insulation panel (VIP) 34 and independent active thermal cavities 36 applied with the studs to increase R-value of the studs. 47 WO 2009/086617 PCT/CA2008/001809 FIGURE 2C is a top view and side view of the stud number 1 configuration 12 comprising oriented strand board (OSB) members 16, galvanized steel 14 and rigid foam insulation 18 with glass vacuum insulation panel (VIP) 34 to form independent active thermal cavities 36 for forced air passage. Also side view shows openings 32 on the stud body for plumbing and electrical. FIGURE 3 shown both the side views and the sectional view of a 2x6 composite insulated reinforcement member 264. The reinforcement member 264 configured with OSB members 16, rigid foam members 18 and galvanized steel member 14; can be used vertically or horizontally for reinforcement along top and bottom plates for door jams and window sill plates. Also shown various openings on it's body; 346 for in-wall forced air, 348 for independent active thermal forced air, 312 for plumbing & electrical. FIGURE 3A are sectional views of the top sill plate 40 and bottom sill plate 42. Shown are two OSB members 16 sandwiched a piece of rigid foam 18 extended to both ends as insulation 18 between metal 14 and OSB members 16 to short circuit the thermal bridging effect. It can also be used as an exterior side plate for the floor joist system by increase its size 2" x 10" or 2' x 12" refers to figure 14b. Openings 350 are provided for facilitate forced air passages of heated forced air 352 for in-wall forced air and 312 for plumbing and electrical therethrough. FIGURE 3B are views of composite insulated members "nail-board" 44. Its main use serves as a nail board for installing the baseboard with a fastener such as a screw or a nail 48, due to the composite insulated vertical members (studs) 12 and the bottom plates 42 are wrapped with galvanized steel 14. It is also used as enforcement member. Shown, two OSB members 16 sandwiched a piece or rigid foam 18 with two pieces of H-shape galvanized steel 14 at both ends which inset with the two OSB strips members 16 to short circuit the thermal bridging effect. Also shown is an applying example for installing the baseboard 50 in conjunction with bottom sill plate 42, floor sheathing 46 and drywall 28. Also shown various openings on it's body; 356 for in-wall forced air, 354 for independent active thermal forced air, and 312 for plumbing & electrical. FIGURE 3C is a side-end view of a horizontal window reinforcement sill plate 52. This 48 WO 2009/086617 PCT/CA2008/001809 composite member can be used for both the top and bottom window sill plates, configuring 2 pieces of "H" shape galvanized steel 14 which contain rigid foam 18 & OSB strips 16, steel bracket flanges 54 with screw recesses 56 at both ends can be used to secure this member to other vertical members. There is no contact point between the 2 pieces of the "H" -shaped steel 14. FIGURE 4 is a side view of the present invention. Shown are side views of multiple "inactive cavities" 38 and spacers 58 which are created by stacking various thickness of sheets of rigid foam 18 and wrapped around four edges with plastic or membrane materials for durability. The larger cavities 38 shown are for accommodating in-wall electrical wiring and plumbing piping installations in conjunction align with the openings on the body of the vertical studs. Also shown is a protective wrap 60 around the casing. FIGURE 4A is a side view of the present invention. Shown are the same configurations and arrangements of figure 4 with inactive cavities 38. But multiple smaller cavities 36 are also created and incorporated in the layers of rigid foam 18, they are the independent active thermal cavities 36 which will be explained in the following figure 12. FIGURE 4B is a side view of the present invention. Shown are the same configurations and arrangements of figure 4 but without the protective casing and with both active 36 and inactive cavities 38. Sheets of foam stacked together by bonding strips of foam as spacers 58 on four edges. The following versions are for "lay and glue" and "cut to fit" awe sizes and spaces on site. FIGURE 4C is a side view of the present invention. Shown are the glass vacuum insulated panels (VIP) 34 added into the rigid foam components 18. Three insulation patterns are incorporated into the following rigid foam components 18: VIP 34, independent active thermal cavities 36, and inactive cavities 37 and together there are four insulation patterns including the rigid foam 18 itself. FIGURE 5 is a sectional view of composite stud and wall assembly 62. Composite member (stud 1) rigid foam members 18, glass vacuum insulated panel (VIP) 34. Independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires 49 WO 2009/086617 PCT/CA2008/001809 (shown also in fig 2b). Drywall 28 and sheathing 46 are installed on opposing sides thereof. FIGURE 5A is another top sectional view of wall assembly 62. Composite member (stud 2) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive cavities 38. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). Drywall 28 and sheathing 46 are installed on opposing sides thereof. FIGURE 5B is another top sectional view of wall assembly 62. Composite member (stud 3) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). Drywall 28 and sheathing 46 are installed on opposing sides thereof. FIGURE 5C is another sectional top view of composite stud and wall assembly 62. Composite member (stud 4) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). Drywall 28 and sheathing 46 are installed on opposing sides thereof. FIGURE 5D is another sectional top view of composite stud and wall assembly 62. Composite member (stud 5) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). FIGURE 5E is another sectional top view of composite stud and wall assembly 62. Composite member (stud 6) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). 50 WO 2009/086617 PCT/CA2008/001809 FIGURE 5F is another sectional top view of composite stud and wall assembly 62. Composite member (stud 7) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). FIGURE 5G is another sectional top view of composite stud and wall assembly 62. Composite member (stud 8) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). FIGURE 5H is another sectional top view of composite stud and wall assembly 62. Composite member (stud 9) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). FIGURE 51 is another sectional top view of composite stud and wall assembly 62. Composite member (stud 10) rigid foam members 18, glass vacuum insulated panel (VIP) 34, independent active thermal cavity 36 and inactive 38 cavities. Glass vacuum insulated panel (VIP) 34 & independent active thermal cavity 36 can be applied within the studs as application requires (shown also in fig 2b). FIGURE 6 is top views of glass vacuum insulation panel (VIP) 34 assemblies. The melted glass has four support pellets 64, four glass strip edges 66 and glass nipple 68. FIGURE 6A is sectional views of single and double panel VIP 34 wrapped around with rigid foam 18 edges. Also explaining the formation of triple pane VIP 34. FIGURE 6B is sectional views of the present invention. Shown is the VIP 34 with and without the rigid foam insulation 18. Also demonstrates the unified function & application of various studs 12 of the present invention 51 WO 2009/086617 PCT/CA2008/001809 FIGURE 6C is VIP 34 sandwiched with rigid foam 18 and associate with other rigid foam members creating inactive cavities 38. Also demonstrates the unified function & application of various studs 12 of the present invention FIGURE 6D is a sectional view of VIP 34 sandwiched with rigid foam 18 as spacers creating single inactive cavity 38 between the OSB exterior wall sheathing 46 and the drywall 28. Also demonstrate the unified function & application of various studs 12 of the present invention FIGURE 6E is a top view of different composite insulated vertical members (stud) 12 spaced on-center and VIP 34 and the rigid foam 18 as spacers are configured to form an independent active thermal cavity 36 on the interior side of the VIP 34 by installing a piece of single pane glass 70 adjacent to the interior side of the VIP 34 in between the on-center studs 12 . Also demonstrate the unified function & application of various studs 12 of the present invention. FIGURE 6F is a top view of the composite insulated vertical members (stud) 12 and VIP 34. The composite vertical insulated members (stud) 12 and rigid foam members 18 as spacers, (refers to FIGURE 6E) by installing another piece of single pane glass 72 adjacent to the exterior side of the VIP 34 creating an inactive cavities 38, therefore cavities are created on either side of the VIP 34 with feature glass. The sheathing 46 and the drywall 28 are applied to the composite insulated vertical members (stud) 12. Also demonstrate the unified function & application of various studs 12 of the present invention FIGURE 6G illustrates the side and front view of the body the un-obscured double pane glass VIP 1. la is the cavity of the body of the VIP 1 at this stage it is with no vacuum condition, and lb shows the protruding fluid drain outlet. FIGURE 6H shows the side and front view of the body of the un-obscured double pane glass VIP 1, with its cavity refer to Figure 1 as la, now it is pre-filled with lighter color fluid Ic for the purpose of preparing & precondition the latter pressurized vacuum process to be performed. lb is the protruding fluid drain outlet. 52 WO 2009/086617 PCT/CA2008/001809 FIGURE 61 shows the sectional view of the mechanical apparatus comprises programmable pumping, controlling devices, tubing & a dual reservoir filled with fluids. As illustrated; 1 d shows the rigid foam supporting members to be used to cushion the weight of the glass VIP body set on the frame structure. lb is the protruding fluid drain outlet connected with the split-flow control valve 2; this is performed by tubing 3 which transports all fluids, the tubing 3 splits its way and connects with two programmable pumps 4. The tubing 3 then extend their ways; one runs into the reservoir 5, which retains with the light fluid 5a and the other runs into reservoir 6 which retains the fluid 6a. Reservoir 5 is not filled to its full capacity in order to leave enough room for the return fluid from the to-be-connected body of the VIP 1 & its cavity 1 a both shown in dotted lines; demonstrating the relationship with the incorporated mechanical apparatus. FIGURE 6J shows the side view and front view of the body of the un-obscured double pane glass VIPI connected with the mechanical apparatus. As illustrated, the mechanical apparatus embraces the programmable pump 4 with controlling device connected by tubing 3 with the dual reservoir 5 & 6 being filled with fluids 5a & 6a. Id illustrates the rigid foam supporting members that are used to cushion the weight of the VIP panel set on the frame structure. lb is the protruding fluid drain outlet which helps to drain the last drop of the fluid back into reservoirs to reduce the mixing of the residual of the light color fluid 5a & the darker color fluid 10a to minimum. 2 is the split-flow control valve to guide the separated light color fluid 5a and darker color fluid 6a to return to their own designated reservoirs 5 & 6. 3 is the tubing that connects the protruding fluid drain outlet 1b; the split flow valve 2; the programmable pump 4; and the dual reservoir 5 and 6. The cavity of the VIP body 1 at this preconditioned stage has been pre-filled with light colour fluid Ic, refer to Figure 2. The reservoir 5 is purposely left almost empty just to retain enough fluid in level to cover the end of the tubing 3 to maintain the consistency of the fluid that relates to creating the vacuum effect in the latter procedure. It also to give room for the light colour fluid 4 when being drawn in and mixed with the fluid in the reservoir 5 to become as fluid 5a. It is an easier procedure to initiate the "repeat at will" vacuum process at the outset. Meanwhile, the reservoir 6 is fully filled with darker fluid 6a, and readily available for its turn. FIGURE 6K shows the side and front view of the body of the un-obscured double pane 53 WO 2009/086617 PCT/CA2008/001809 glass VIP 1 and the incorporated mechanical apparatus in function. le illustrates the stage of the cavity of the VIP 1, in which it is pressurized and vacuumed out by withdrawing the light colour fluid 1 c to become 5 a; refer to Figure 4. At this point the fluid 1 c/5 a has been pumped back and retained in the reservoir 5 shows that it is full. The darker fluid 6a, also remains in the reservoir 6, and readily available for its turn. The embodiment of the un-obscured double pane glass VIP 1 at this stage is in the cycle of performing the "repeat at will" pressurized vacuum condition. FIGURE 6L shows the side and front view of the body of the un-obscured double pane glass VIP 1 and the incorporated mechanical apparatus in function, Also illustrated, is the darker color fluid 6a; where it is pumped in and filled in the pressurized vacuum space of the cavity of the body of VIP 1. The reservoir 6 is purposely left almost empty just to retain enough fluid in level to cover the end of the tubing 3, to maintain the consistency of the fluid as it relates to creating the vacuum effect. It also gives room for the return of the darker colour fluid 6a which is in the cavity of the body of the VIP 1 and cycled to be pumped back into the reservoir 6. Meanwhile, the reservoir 5 is fully filled with the light colour fluid 5a, and readily available for its turn. FIGURE 6M shows the side and front view of the body of the un-obscured double pane glass VIP 1 and the mechanical apparatus is in function. As illustrated, at this stage the cavity If of the body of the VIP 1 is pressurized and vacuumed out by withdrawing the darker colour fluid 6a, which has been pumped back and retained in the reservoir 6 shows that it is full, and the light colour fluid 5a, also remains in the reservoir 5 and readily available to be used. This double pane glass VIP 1 embodiment at this stage is in "repeat at will" pressurized vacuum condition. A double pane forced fluid pressurized vacuum insulation panel VIP 1 is transformed into an unique window unit. FIGURE 6N shows the side view of the un-obscured triple pane glass VIP 7 configured to create two attached side-by-side bodies 7a & 7b separated by the middle pane glass sheet. Body 7a shows its front view with a non-vacuumed cavity 7c having a fluid drain outlet 7f, and on the other side of the middle-pane glass sheet; body 7b of the VIP 7 with a cavity 7d shows as the back view of the VIP 7. Hereby, it is important to depict that the cavity 7d of body 7b at this stage is in a pre-treated "permanent" pressurized vacuumed condition of which can be achieved by selecting various processes of prior arts available on the market place and it will be maintained as "permanent" pressurized vacuumed condition 54 WO 2009/086617 PCT/CA2008/001809 through out this continuing patent description. 7e is the nipple provided to facilitate the aforementioned prior art factory vacuum process. FIGURE 60 shows the side view, front view & back view of the un-obscured triple pane glass VIP 7 depicts two separate attached bodies, and 7d is the cavity of the body 7b which is pre-treated and it is in its prior art process "permanent" pressurized vacuumed condition and 7e is the nipple. The space of the cavity 7c, refer to Figure 8; of the body 7a with fluid drain outlet 7f , at this stage is prefilled with the light color fluid 5a. This "prefilled" process is to pre condition the "repeat at will" vacuum process latter to be performed by utilizing the cavity of the body 7a to be incorporated with a programmable mechanical apparatus. FIGURE 6P shows the side view, front view & back view of the un-obscured triple pane glass VIP 7 with dual body/cavity incorporated with the mechanical apparatus; refer to Figure 3. As illustrated, the sectional view of the mechanical apparatus comprises programmable pumping & controlling devices. Id shows the rigid foam supporting members to be used to cushion the weight of the glass VIP body set on the frame structure. 7f is the protruding fluid drain outlet connected with the split-flow control valve 2, this connection is performed by tubing 3 which transports all fluids, the tubing 3 splits its way and connects with two programmable pumps 4. The tubing 3 then extend; one runs into the reservoir 5, which retains with the light fluid 5a and the other runs into reservoir 6 which retains the darker fluid 6a. 7d is the cavity of the body 7b, which is pre-treated in permanent pressurized vacuum condition and 7e is the nipple. The light color fluid 5a as described in Figure 9 was used to pre-fill & precondition the cavity of body 7a; at this stage the pressurized vacuum process can begin and be achieved at anytime by withdrawing the fluid 5a back into the reservoir 5 which is not filled to its full capacity at this point in order to leave enough room for the return light color fluid 5a from the cavity of the body 7a. While the reservoir 6 filled with fluid 6a is in it's dormant mode. FIGURE 6Q shows the un-obscured triple pane glass VIP 7 with dual body/cavity incorporated with the mechanical apparatus. As illustrated, the incorporated programmable pumping and controlling devices and dual reservoir is filled with fluids. 7g a illustrates the stage of the cavity of the body 7a is in "repeat at will" pressurized vacuumed condition by the effect of withdrawing the light colour fluid 5a, which is pumped back and retained in the reservoir 5 shows that it is full, and the darker colour fluid 6a also remains in the reservoir 6, while the pre 55 WO 2009/086617 PCT/CA2008/001809 treated "permanent" pressurized vacuumed cavity 7d of body 7b remain in tact. A double pressurized vacuum insulation panel VIP 7 is created within one triple pane glass body. FIGURE 6R shows the un-obscure triple pane glass VIP 7 with dual body/cavity incorporated with the mechanical apparatus. The darker color fluid 6a, is being pumped in, and fills the "repeat at will" pressurized vacuumed cavity of body 7a. The reservoir 6 is purposely left almost empty just to retain enough fluid in level to cover the end of the tube 3 to maintain the consistency of the fluid, which relates to creating the repeat vacuum effect and also to give room for the return of the darker colour fluid 6a from the cavity of body 7a. Meanwhile, the reservoir 5 is fully filled with light colour fluid 5a, it is readily available for its turn, while the pre-treated "permanent" pressurized vacuumed cavity 7d of body 7b remains in tact. FIGURE 6S shows the un-obscured triple pane glass VIP 13 with dual body/cavity incorporated with the mechanical apparatus. As illustrated, connected programmable pumping and controlling devices, and the dual reservoir is filled with fluids. 15a illustrates the stage of the cavity of the body 13a is in "repeat at will" pressurized vacuumed condition by withdrawing the darker colour fluid 1Oa, at this point the fluid 1Oa is being pumped back and retained in the reservoir 10, and shown that it is full. The light colour fluid 9a also remains in the reservoir 9 in full. The dual body/cavity of the triple pane VIP 13 at this stage are both in pressurized vacuumed condition. One is "permanent" vacuumed condition & the other is functioning as "repeat at will" vacuumed condition. A double pressurized vacuum insulation panel VIP 13 is created within one triple pane glass body and transformed into an unique window unit. FIGURE 6T depicts the triple pane glass VIP 7 that is incorporated with the mechanical apparatus and the thermal apparatus as it becomes one window system. 8 illustrates the heat or cold thermal exchanger depending on climate condition, 8a is the thermal transfer line for fluid 6a and 8b is the thermal transfer line for fluid 5a. FIGURE 6U shows the side & front view a double pane glass VIP 9 to be implemented as an insulation member for doors; 9a is the pre-treated vacuum cavity and 9b is the opening for door knock. This double pane glass door VIP 9 is to be inserted in the exist metal door frame to become an efficient insulation member which is one of the weakest point in terms of negative thermal transfer. 56 WO 2009/086617 PCT/CA2008/001809 FIGURE 7 is a side view of the present invention. Shown is a side view of the master work frame equipment assembly 74 having a vertical wall supporting member (VWSM) 76 on each side. Several huge aluminum (MWF) master work frames 74 (sizes can be flexible according to local market requirements) to be installed and created permanently on the floor for assembling the exterior walls and interior walls. These AMWF 74 are built for flexibility to station and work around easily, the motorized mechanisms 78 allows it to pivot in vertical, horizontal and upward and downward positions at ease controlled by an electrical remote device. At first the MWF 74 lays in horizontal level to receive the top and bottom sill plates and all studs to be laid flat (horizontal as well) on the MWF 74 and be spaced 16"or 24" o.c., then it will be adjusted at a workable waist level to allow workers to work on both sides of the wall at the same time, to fasten and install all the top and bottom sill plates, windows and door headers and spaced studs all in place according to specifications. The MWF 74 further comprises a first frame side 80, a second frame side 82, a top release bar 84, a frame bottom plate 86, a timber plate 88, an opening for conveying fork lifts 90, a bottom release bar 92, station bolts 96 and weight supports 94. FIGURE 7A is side-view of the present invention. The MWF 74 is shown rotating from the vertical position to the horizontal position. Also shown is the up and down elevating mechanism 98. FIGURE 7B is side-view of the present invention. Shown is the relationship between the MWF 74 and the top release bar 84 disposed on the top portion 104 thereof showing a side view of the top release bar 84, the station bolt guide track 100 and tightening knob 102 screwed onto the station bolt 96. FIGURE 7C is side-view of the MWF 74 of the present invention. Shown is a side view further explaining the bottom release bar 92 and its relationship with the bottom portion of the main frame 106, the station bolt 96 and its guiding track 100. FIGURE 7D is side-view of the present invention. The horizontal depiction of the stud 12 shows the ends thereof seated in their respective top 84 and bottom 92 release bars. This arrangement allows all studs 12 to be positioned horizontally at a workable level. The release 57 WO 2009/086617 PCT/CA2008/001809 bars also provide support for the assembling process. The vertical depictions demonstrate the relationship of the stud 12 with the top 84 and bottom 92 release bars during installation of drywall 28 and OSB exterior wall sheathing 46 during the installation process. FIGURE 7E is a sectional view of the vertical wall supporting member (VWSM) 76 mounted on one side of the main wall assembling frame, one end of the (VWSM) 76 is mounted to the body of the first frame side 80. Shown cut off top view of both ends of the VWSM 76 mounted on the main frame holds the wall assembly 62 in upright position while the top and bottom release bars are disengaged through assembling process. The VWSM 76 of both ends are adjustable moves horizontally with the guiding rods 108 according to sizes of wall specifications. Also shown are the top mounting member 110, the metal member 112 to hold the wall and the base members 114. FIGURE 7F is a side view of the master work wall frame equipment assembly 74. The master work frame 74 is in horizontal position and is lowered to workable level. The studs 12 are to be placed within the frame 74 and to be fastened in place on specification. FIGURE 8 is a side view of the composite wall frame equipment assembly 77 that has two primary functions: conveying and transporting the finished structure to storage and providing a monitoring system posting live video clips of the production process which allows the buyer to view the process live on-line with a password. Shown is a horizontal track support 116 supported by a leg 118 extending from each end thereof. A motorized track 120 is disposed on the underside of said track support 116 along which a conveying fork 122 travels. A video camera 124 is disposed on the interior portion of each leg 118 and oriented towards its respective work area at the vertical wall assembly member 74 to deliver live streaming video to an internet server. An electric motor 126 drives the conveyor fork 122 back and forth along the track 120. FIGURE 8A is a side view of the master work wall frame equipment assembly 74 with studs 12 laid in place. The master work frame 74 is in horizontal position and is lowered to a comfortable workable level. All plates, headers and studs 12 are to be assembled to form the skeleton of the composite insulated wall frame. 58 WO 2009/086617 PCT/CA2008/001809 FIGURE 8B is a vertical side view of the wall frame production assembly. Shown is the master work frame 74 secured in the upright position the vertical wall support members 76. A wall skeleton with window opening is assembled with a window header beam 128, ready to receive other parts and components such as; insulation members, window components, electrical wiring and boxes, etc. Are all to be installed in place strictly according to specification on the blueprint. There are two sets of blue prints of the same wall reflecting both sides perspective. FIGURE 8C is a vertical side view of the wall frame production assembly 62. Shown is the vertical side view of the insulation components 18 filled between studs 12. Electrical wiring 130, receptacle boxes 132 and light switches 134 are installed. FIGURE 8D is a vertical side view of the wall frame production assembly 62. Shown is the vertical view of the interior side of the finished composite wall with drywall 28 installed, window installed, exposing all electrical boxes 130 and switches 134, wirings 130 for connection. FIGURE 8E is a vertical exterior side view of the finished composite wall 62. Shown is an exterior view of the finished composite wall 62 with OSB exterior wall sheathing 46 installed, exposing electrical wiring 130 for connections. The completed composite wall 62 is ready to be moved away from the master work frame wall assembly by inserting the conveying fork blades into the blade openings 90. FIGURE 8F shows the protective finishing process. Shown is a cut off view of the finished composite wall 62 with window 36 installed. Two protective foam pads 138 sandwich the window frame. OCB exterior wall sheathing 46 also provides a backing for the foam pads 138. Provides protection for transportation and installation on sites. FIGURE 8G is a view of the wall frame production assembly. The composite wall 62 is completed and is ready to be removed from within the frame work. The conveying fork 122 is driven along the conveying track 120 by the electric motor 126 to remove the wall 62. FIGURE 8H is a view of the wall frame production assembly. Shown is the conveying 59 WO 2009/086617 PCT/CA2008/001809 fork 122 engaged to transfer the completed wall assembly 62. As previously mentioned, the cameras 124 are monitoring the entire process. FIGURE 81 shows the conveying fork 122 retrieving the composite wall 62 with safety strap 140 in place. The window is protected by the foam protection pads 138. FIGURE 8J is a sectional view of wall 62 and master frame work. Shown is a clear sectional view of the compositions within the wall 62 and the completed composite wall has been retrieved from the master work frame by the conveying fork 122. Shown are the top sill plate 40, the rigid foam protective pads 138, the window 136, the OSB sheathing 136, the drywall 28 and the bottom sill plate 42. FIGURE 9 shows the roof truss 142 galvanized steel members comprising a center supporting member 144, a web supporting member 146 and a rafter beam 148. FIGURE 9A is a sectional view of the drop down ceiling joist 150 having an extended upper main joist section 152 and lower drop down joist section 154 with ends that terminate prior to the ends of the main joist section 152 thereby defining extensions at the ends of the main joist section 152 which has galvanized steel 14 flanges 156 projecting perpendicularly from the bottom thereof that are to be seated on the top sill upon construction of the structure. The drop down section 154 further includes a drop down flange 158 on its bottom portion thereby defining a space between the two flanges for the inclusion of rigid foam cavity members. An OSB strip 16 forms the core of the joist 150 to short circuit the thermal transfer from metal to metal and provide support for the payload of the "drop down" on which the insulation member and the ceiling drywall are placed. FIGURE 9B is an applying example of the drop down ceiling joist 150. Shown is the main joist section 152 on top plates 40 and the drop down section 154 of the joist rests on top and between the composite vertical supporting members (studs) 12 and supports the rafter beam 148. FIGURE 9C is an applying example of the ceiling joist 150. Shown is the main joist section 152 on top plates 40 and the drop down section 154 of the joist rests on top and 60 WO 2009/086617 PCT/CA2008/001809 between the composite vertical supporting members (studs) 12 and supports the rafter beam 148. The independent active thermal cavity 36 and inactive cavity 38 are shown as well as the VIP 34 and rigid foam insulation 18. FIGURE 9D is an applying example of the ceiling joist 150 relative to the attic space 160. Shown is a sectional view of rigid foam member 18 with an inactive cavity 38 installed into the slot between roof rafters 148. The drop down section of the ceiling joists 150 receive rigid foam insulation member 18 with an inactive cavity 38 set in between the slots. The heavier weight glass VIP 34 rests on the metal flanges of the joist 150, and the web support member 142 connected and bolted the roof rafters 148 and the joist 150 as one piece with nut 162 and bolt 164. FIGURE 9E is a sectional view of multiple insulation patterns applied with the ceiling joist 150. Shown are sectional views of multiple insulation patterns of rigid foam insulation 18 and glass VIP 34 forming an independent active thermal cavities 36 and inactive cavities 38 which can be applied due to the interact benefit of the configuration of the drop down section of the joists 150. FIGURE 9F is an applying example of the wall frame and ceiling joist 150. Shown is a broader scope of relationships between the drop down section of the ceiling joists 150, rafter beams 148 , glass VIP 34, rigid foam members 18, independent active thermal cavities 36 and inactive cavities 38. FIGURE 10 shows the half and half gable roof 166 prefab assembly. The gable shape roof 166 can be divided into 2 parts by splitting it in the middle for the purpose of delivering and installation. FIGURE 1OA is a front and side view of the equipment for the gable roof truss assembly mobile truss anchor station 168 comprising station body structures 172, an elevating mechanism 178 having adjustable heights for various roof pitches, an anchor bar 176 with spacers 180 to adjust O.C. specifications for rafter beams to be attached on and wheels 174 on a track. 61 WO 2009/086617 PCT/CA2008/001809 FIGURE 1OB is a side view of the equipment for the gable roof truss assembly mobile truss anchor station 168. Shown is a side view of the relationships of mobile truss anchor station 168 and anchor mechanism 188, ceiling frame support "A" 184 and "B" 186. Dotted lines illustrate half of the truss frame 182 rests on position. FIGURE 1OC is a top applying example view of the equipment for the gable roof truss assembly mobile truss anchor station. Shows top view of half gable roof truss assembly 166, mobile truss anchor station 168. Ceiling frame support "A" 184 and "B" 186. Rafter beams 148, bracing members 190, side plates 192 and ceiling joists 150 installed. Shown, a top view of rafter beams 148 attached on anchor bar, dotted lines illustrate ceiling joists 150 are placed directly on same positions underneath the rafter beams 148. FIGURE 1OD is a side view of the equipment for the gable roof truss assembly mobile truss anchor station 168. Shown are the half gable roof truss assembly 182 mobile truss anchor station 168 ceiling frame support "A" 184 and "B" 186 after beams, bracing web members 146, side plates and ceiling joists 150 installed and secured with fastening brackets 194. FIGURE 1OE is a side view of the completed half gable roof 182 with the roof sheathing and shingles 198 installed. The mobile anchor station 168 has been removed and make room for this flipped over position. This half gable roof 182 is ready to be conveyed away. By means of overhead conveying device 196 or hydraulic crane. FIGURE 11 shows the hip roof 200 equipment and assembling process. FIGURE 11 A shows the hip roof 200 equipment and assembling process. The hip roof 200 comprises two half gable sections 182 and two hip ends 204. FIGURE 1 B shows the hip roof 200 equipment and assembling process. Ceiling frame supports "C" 206 and "D"208 are the same configuration as support "B" 186. Dotted lines show a ceiling joist 150 resting on the members anchor mechanism 188 can be adjusted up and down for roof pitches FIGURE 1 IC is a side view of the truss assembly station 168. Ceiling frame support "C" 206 with O.C. spacers moves on tracks to and from center. This ceiling frame support "A" 62 WO 2009/086617 PCT/CA2008/001809 184 is stationed on the floor permanently. A mechanism 188 allows it to pivot 90 degrees to up right position. Anchor mechanism 188 can be adjusted up and down for roof pitches. Rafter beams 148 from high center point slope down to the low corners of the roof squire. Ceiling joists 150, spacers 180 and vertical support members 214 are also shown. FIGURE 1 ID is a top view of the mobile truss anchor system 168. This top view shows the relationship and coordination of mobile truss anchor station 168, ceiling frame support "A" 184, "B" 186, "C" 206 and "D" 208. The two added members "C" 206 and "D" 208 include spacers 180 and run on tracks 210 toward and away opposite from each other. FIGURE 1 iE is a top view of the hip truss mobile anchor station 168. This top view shows the relationship and coordination of mobile truss anchor station 168, ceiling frame support "A" 184, "B" 186, "C" 206, "D" 208. The vertical support members 214 are set on frame support "A" 184. Also shown are the relationships with the rafter beam 148, the ceiling joist 150 and the pivot mechanism 212. FIGURE 1 IF is a top view of the hip truss mobile anchor station 168. Shown are mobile truss anchor station 168, ceiling frame support "A" 184, "B" 186, "C" 206, "D" 208. Dotted lines illustrate ceiling joists 150 placed under the rafterbeams 148 rest on ceiling frame support "C" 206 and "D" 208. Also depicted are ceiling frame supports "A" 184, and "B" 186, the side plates 192, the bridging members 216 and the double adjoining plates 214. FIGURE 1 IG is a finished section of a half of the hip truss mobile anchor station 168. Shown is a finished section of a half hip truss section 218 with the roof sheathings and shingles 198 installed. FIGURE 11H is a side view of a finished sectional half hip roof 218. Shown is a finished section of a half of the hip truss assembly 218 ceiling frame support "A" 184. A completed half sectional hip roof 218 with roof sheathing board and shingles. The mobile truss anchor station has been removed out of the way to make room for this flipped over process. This sectional half roof is ready to be conveyed away by means of overhead conveying device 196 or hydraulic crane. 63 WO 2009/086617 PCT/CA2008/001809 FIGURE 12 shows the forced air 220 path of the independent active thermal air cavity 36. The forced air 220 travels through a dedicated auxiliary furnace 222 and passes through the sealed independent active thermal cavities 36 that form a channel throughout the various walls, floors and ceiling of the structure including an independent active thermal cavity 36 in the concrete floor 224. The attic roof and walls are insulated with rigid foam insulation 18 and a solar powered fan 228 is energized by a solar panel 226 disposed on the roof to regulate the attic temperature. Also shown an auxiliary air condition unit 223 which generates cooling forced air using the same forced air path 220 by switching the thermal control. FIGURE 12A shows the forced air path 220 of the independent active thermal cavity air blanket 36 associates with the inactive cavity 38, glass VIP 34 within the walls. The forced air 220 path is similarly configured as depicted in figure 12 with the addition of the inactive cavities 38 combining with the glass VIP 34 and foam insulation 18. The present invention uses two or three pieces of glass VIP sheets 34. A heating device is used going around four edges by applying appropriate temperature. Thus the entire unit as a whole will be sealed seamlessly with the SME glass material and all melted together as one piece. Also shown is the auxiliary air conditioning unit 223. FIGURE 12B shows a version of active thermal air insulation for building that sought for higher energy saving requirements comprising a casing 232 with multiple independent active thermal cavities 36, galvanized metal sheets 230 and rigid foam insulation 18. FIGURE 12C is an applying example of the insulation component comprising multiple independent active thermal cavities 36 with sheet metals 230 and rigid foams 18 incorporated with studs, sheathing boards and studs. FIGURE 12D is an applying example of the heated forced air path. Heated forced air 220 from the furnace 222 travels in a circulated pattern in the created independent active thermal cavities 36 provides three effective means of heating the building; first, on the main floor, heated forced air travels under the floor skin and heats up the concrete floor 224. Heat rises. Second; forced air continually travels in the created independent active thermal cavities 36 in interior walls to maintain comfort temperature within rooms. Third; forced air continually travels across the ceiling in created independent active thermal cavities 36 heats up the 64 WO 2009/086617 PCT/CA2008/001809 concrete ceiling 234 which is the same concrete slab for the immediate upper flooring, and this concrete floor slab 224 is also heated by a separate in floor independent active forced air cavity 36 system. Actually that the same concrete floor slab 224 separates the lower and upper floor is heated by two separate systems of the same type. The top level ceiling 234 which is shown, it is heated by double layers independent forced air thermal cavities 36. Also shown are the rigid foam insulation panels 18, the glass VIP 34, inactive cavities 38, glass walls 238, added single panes of glass 240 rising ambient heat from the floor 234 and return air 242 to furnace showing the active thermal cavity air blanket forced air movement in walls, travels up the main floor, upper floor and across the attic to the opposite side walls. FIGURE 13 is an orthographic view of the thermal cavity air blanket forced air 220 upward movement in walls. Shows the independent active thermal cavity 36 air blanket forced air 220 movement in walls, travels up the main floor, upper floor and across the attic to the opposite side walls as directed by the ceiling joists 150, the vertical studs 12, the top plates 40, the bottom plates 42, OSB floor sheathing 30, and the forced air enters in from the ducts 246 underneath main floor between floor joists in the basement. The rigid foam component 18 shows a sectional view in the attic with an independent active cavity 36 for forced air 220 in horizontal movement across and above the ceiling reaching the top plates 40 of the opposite side wall. FIGURE 13A is an applying example of the independent active thermal blanket cavity 36 forced air 220 downward movement in opposite side wall having a similar configuration therewith (refer to figure 13 for details). Active thermal cavity 36 air blanket, forced air 220 movement in opposite side wall, travels across the attic, down into the wall of the upper floor, main floor, then returns to auxiliary furnace in basement. Forced air 220 returns in from ducts 246 underneath the basement wall. FIGURE 13B is an applying example of the independent active thermal cavity 36 having air blanket forced air 220 movement in one of the other two sets of walls. Shown, forced air 220 travels up in the wall of the main floor, no openings in studs 248 for horizontal movements. As the forced air reaches the upper floor, openings in studs 250 allow the forced air 220 travels horizontally, note that in the far left diagram, forced air 220 being strategically channeled to return to the auxiliary furnace in the basement through the ducts 246. 65 WO 2009/086617 PCT/CA2008/001809 FIGURE 13C is an applying example of the independent active thermal cavity 36 air blanket forced air 220 movement in one of the other two sets of walls. Shown, forced air 220 travels up in the wall of the main floor, no openings in studs 248 for horizontal movements. As the forced air reaches the upper floor, openings in studs allow the forced air 220 travels horizontally, note that in the far left diagram, forced air 220 being strategically channeled to return to the auxiliary furnace in the basement through the ducts 246. FIGURE 13D shown: the top sectional view of a basement wall structure 402 with a boxed out wall 370; created within is a boxed-out space 372 from the basement floor for housing & consolidating the climate control unit 374; the climate control unit 374 comprises an outward forced air duct body 380 and an inward forced air duct body 392. FIGURE 13D shown: the top sectional view of a basement wall structure 402 with a boxed out wall 370; created within is a boxed-out space 372 from the basement floor for housing & consolidating the climate control unit 374; the climate control unit 374 comprises an outward forced air duct body 380 and an inward forced air duct body 392. FIGURE 13E shown: the top sectional view of a main level wall structure 404 with a boxed-out wall 358 creating a boxed-out space 366 aligned on top with the basement wall structure 402 shown in FIG. 13D; the focus herein is the main floor boxed-out space 366 aligned with the basement boxed-out space 372 forming a vertical column. Refer to FIG. 13G. FIGURE 13F shown: the top sectional view of an upper level wall structure 406 with a boxed-out wall 364 creating a boxed-out space 360 aligned on top with the main level wall structure 404 shown in FIG. 13E; the focus herein is the upper level boxed-out space 360 aligned with the main level boxed-out space 366 forming a three level vertical column boxed-out space additionally aligned to the basement boxed-out space 372, forming a multi-level vertical column of boxed-out spaces. FIGURE 13G is an example that relates to FIGS. 13D, 13E & 13F. Depicted is a whole side view of the formation of the multi-level vertical column boxed-out spaces joining and aligning the basement wall structure 370, which has a boxed-out space 372, the main level boxed-out structure 364, which has a boxed-out space 366, and the upper level boxed-out 66 WO 2009/086617 PCT/CA2008/001809 structure 358, which has a boxed-out space 360; therein clearly depicted is the basement boxed out space housing the climate control unit 374 that frees the basement floor of obstructions to allow for more desirable development and spaces free of conventional cumbersome ducting systems. FIGURE 13H is a side view example, shown is the installed forced air "outward" ducting system body 380 in the basement boxed-out space 372, extending its way up in the aligned multi-level vertical column boxed-out spaces (formation of boxed-out spaces 360, 366 & 372, refer to FIG. 13G) to the main and upper floors, reaching up to the ceiling level, and connecting with various outward passages to each floor level. The active thermal forced air main paths 378 are within the outward ducting system body 380 and move up from the climate control unit 374, which is housed in the basement boxed-out space 372, and clearly depicts the relationships of the various outward active thermal forced air paths from the basement level up. 416 is the basement in-slab active forced air path; 386 is the lower horizontal active forced air path; 412 is the in-floor active forced air of the main floor; 384 is the lower horizontal active forced air path; 408 is the in-floor active forced air path of the upper floor; 382 is the lower horizontal active forced air path; 376 is the in-ceiling active forced air path. FIGURE 131 is an example showing the installed forced air "inward" ducting system body 392 that extends its way up in the aligned multi-level vertical column boxed-out spaces connected from the climate control unit 374 in the basement floor rising up to the main floor and upper floor and reaching up to the ceiling level and connected on the way to various outward passages from each floor level. The active thermal forced air main paths 394 moving within the inward ducting body 392 returns to the climate control unit 374, which is housed in the basement boxed-out space 372 and clearly depicts the relationships of the various "inward" active forced air paths from the ceiling level down; 388 is the in-ceiling forced air path; 390 is the upper horizontal forced air path of the upper floor; 410 is the in-floor forced air path of the upper floor; 396 is the upper horizontal forced air path of the main floor; 414 is the in-floor forced air path of the main floor; 398 is the upper horizontal forced air path of the basement; 374 is the concrete floor in-slab forced air path. FIGURE 13J is a completed consolidated side view of FIGS. 13H & 131 and clearly depicts the combined functions and relationships of: the utilization of the boxed-out space 372, 67 WO 2009/086617 PCT/CA2008/001809 multi-level vertical column boxed-out spaces (formation of boxed-out spaces 360, 366 & 372 refer to FIG. 13G), and the outward and inward forced air ducting systems; it demonstrates all outward & inward active thermal forced air paths connecting & circulating together as a completed system. The arrayed composite insulated wall panels on each floor shown are divided in half by a foam strip 400 to create the horizontal lower outward and upper inward forced air passage pattern. For the basement concrete floor this Figure shown depicts the active forced air path 416 that travels outward in the in-slab concrete floor and shows the inward active forced air path returning to the climate control unit 374. For the basement level this Figure shown depicts the active forced air traveling outward through the 12 in-stud openings into a lower horizontal active forced air path 386, then moving upward through a designated section of an unobstructed wall panel into an inward upper horizontal active forced air path 398 within the same divided and arrayed vertical wall panel cavities. For the main level in-floor the Figure shown depicts the active forced air path 412 traveling outward in the in-floor underneath the sub-floor and between the floor joists; it also shows the inward active forced air path 414 returning to the climate control unit 374. For the main floor, the Figure shown depicts the active forced air traveling outward through 12 in-stud openings in a lower horizontal active forced air path 384, then moving upward through a designated section of an unobstructed wall panel into an inward upper horizontal forced air path 396 within the same divided and arrayed vertical wall panel cavities. For the upper level in-floor, the Figure shown depicts the active forced air path 408 traveling outward in the in-floor underneath the sub-floor and between the floor joists; it also shows the inward active forced air path 410 returning to the climate control unit 374. For the upper floor, the figure shown depicts the active forced air traveling outward through 12 in-stud openings in a lower horizontal active forced air path 382, then moving upward through a designated section of an unobstructed wall panel into an inward upper horizontal active forced air path 390 within the same divided and arrayed vertical wall panel cavities. For the ceiling level the Figure shown depicts the active forced air path 376 traveling outward in the ceiling cavities; it also shows the inward active forced air path 388 emerging into the main forced air path and returning to the climate control unit 374. FIGURE 13K is a side view showing the positions to floors of a cut-off view of 2 horizontal boxed-out structures 420, each braced within a cut-off horizontal view of a piece of main plumbing pipe 422, angled 90 degrees at a certain length and connected with another vertical piece of main plumbing pipe 424. 68 WO 2009/086617 PCT/CA2008/001809 FIGURE 13L is a side view, showing a 90 degree angle view of FIG. 13K. It more clearly depicts the relationships and functions of the elongate horizontal boxed-out structures 420 in FIG. 13K, which is associated with the horizontal pipe piece 422 and vertical pipe piece 424. The pipe piece 424 rises up from the ground stresses in the vertical column boxed-out space then elbows horizontally with its extension pipe piece 422, which is braced within the elongate horizontal boxed-out structure 420; another pipe piece 426 with a cut-off view is also elbowed 90 degrees with the pipe piece 422 to extend its length in the void space underneath the sub-floor & between the floor joists. Also refer to FIG. 13K. The configuration of the elongate boxed-out structure 420 created within its horizontal hollow space comprises insulation 428; a horizontal pipe piece 422; water line 430; electrical wiring 436 and an active thermal forced air path 434. FIGURE 13M is a top view of the main floor and further depicts the relationship of the multi-level vertical column boxed-out space associated with the elongate horizontal boxed-out structure 420 bracing within the horizontal pipe piece 422, the electrical wire 430, the water line 436 and the elbowed vertical pipe piece 424. 426 is an elbowed extension pipe of 422, displayed underneath the sub-floor & between floor joists, 434 is the extension piece of the electrical wire of 430. 440 is the elbowed extension piece of the water line 436. FIGURE 13N is a side view demonstrated another active thermal forced air path 441 , therein emphasizing the forced air path 441 starting in the basement level; forced air moves outward from the climate control unit 374 which is located in the boxed-out space 372, travel horizontally through openings in the lower section of the wall panels, them rising up through openings & passages reaching up to the ceiling passages/cavities then travel across the ceiling to the opposite wall, then return to the climate control unit 374 in basement in the same movement pattern. FIGURE 130 is a horizontal cut-off view of an existing corrugated metal ceiling component 444 which is widely used as an interior part of the roofing structure in the commercial & industrial buildings, 446 is the interior "void" spaces and 448 is the exterior "void" spaces of which have never been used, the present invention therein to utilize these said "void" spaces by running forced air through to create an active thermal forced air path in each one of these corrugated "void" spaces. 69 WO 2009/086617 PCT/CA2008/001809 FIGURE 13P is a horizontal sectional view further illustrates the formation, configuration and the relationships of the active thermal forced air system to be integrated into a typical roof structure which comprises of an existing corrugated metal ceiling component 444 having exterior insulation 454 in place to create exterior "void" spaces 448 and the exterior roofing material 452 installed on the top, the interior ceiling material 450 to be added to create the interior "void" spaces 446; "void" spaces 446 & 448 therein are the spaces/cavities for the forced air path. FIGURE 13Q is a sectional view further illustrates the insulated attic structure which comprises of foam insulation members 456 & 458 sandwiched together as composite insulated panels creating a cavity to become the passage 460 for the active forced air 462, said panels are to be installed on the roof rafter member (refer to Figure 9D in the parent application) installed directly underneath the roof sheathing board. The central channel 464 is also made out of rigid foam member configured in an elongated square body installed at the top and center of the interior roof structure laying 90 degree from one end to the other against and attached to the said panels which are positioned from both sides of the roof, and said panels having openings on each high-pitch end matching the openings on each side of the central channel 464 and to be aligned together to each other then forming connected forced air passage 460 and passage 466 to allow forced air to enter from each said panel into the central channel 462. The function of the central channel 462 is to collect and centralize all forced air gathered and entered from all said panels then to be dissipated to the outside or be re-directed to whichever sources to be utilized. This structure is particularly designed for unwanted hot air to be dissipated for hot climates. FIGURE 14 is a sectional view and a side view of a composite floor joist 252 with opening/recesses 282 for forced air passage and openings 32 for plumbing and electrical, comprising OSB members 16 and galvanized steel structural members 14. FIGURE 14A is a sectional view and a side view of a composite interior floor joist 254 with openings/recesses 282 for forced air passage and openings 32 for plumbing and electrical, OSB members 16 and galvanized structural members 14. This interior floor joist 254 is for additional floor to be anchored on (refers to FIGURE 14C). FIGURE 14B is a sectional view and a side view of an exterior composite insulated 70 WO 2009/086617 PCT/CA2008/001809 joist side plate 256 for floor joist 252 to be anchored on (refers to FIGURE 14C) comprising OSB members 16, rigid foam insulation 18 and galvanized steel structural members 14 and openings 32 for plumbing and electrical. FIGURE 14C is a sectional view of the relationships of floor members and demonstrate the formation of a principal floor 272 and a sectional floor 270; on the left shown side view of the composite floor joist 252 with openings 282 for in-floor forced air passage and openings 32 for plumbing and electrical, joists 252 to be anchored between composite exterior joist side plate 256 and composite interior joist 254 (both in cut off view) forming the sectional floor 270. On the right shown the cut off view of two pieces of composite floor joists 252 spaced apart on-center having foam members 18 installed beneath the floor sheathing 46 to create the void space for in-floor forced air cavity 284 thereof; forming the principal floor 272 and sectional floor 270 structures completed with drywall 28. FIGURE 14D is a front view of the non-movable station 260 "A". The platform 266 when hoisted up 5 to 6 feet above ground for workers to work the surface and underneath. The safety railing 258 heights can be easily adjusted. FIGURE 14E is a front view of the mobile stations 262 "B", "C" and "D" all movable on their wheels 174 on tracks. The safety railing 258 when hoisted up 5 to 6 feet above ground for workers to work the surface and underneath. The platform 266 heights can be easily adjusted. FIGURE 14F is a side view of the principal floor assembly. The motorized floor joist assembling station "A" 260 with an adjustable platform 266 for desired heights is stationary and not moveable. Motorized floor joist assembling station "B" 262 has an adjustable platform 266 for desired heights and mobile on tracks. The side plates 264 secure to the floor joist 252 and the supporting members 268 are 90 degrees to the joists 252 FIGURE 14G is a side view of the principle floor assembly. Shown are the joist side plates 264 mounted on the floor joist 252 and resting on the platforms of the two stations 260 "A" and 262 "B". Once the floor is completed with sheathing board installed, station "A" 260 will be retreated and moved out of the way, and the finished floor will be laid on these 71 WO 2009/086617 PCT/CA2008/001809 supporting members 268, then the conveying equipment will move in, hoist up the floor and move to storage for shipment. FIGURE 14H is a side view of the principal floor 272 and two additional floors 270 on each side including pre-installed in-floor forced air channels 284. FIGURE 141 is a top view without the OSB floor sheathing installed, the relationships of the four platforms (ABCD) 260, 262 which can assemble all sizes of principle floors and additional floors. Also shown are supporting members 268 on wheels and tracks. FIGURE 15 shows the top view of the sectional bottom sill plate 42 with openings 350 for in-floor forced air passage. The position of the studs 12 and rigid foam members 18 forming the in-wall and in-floor forced air circulation with relationship to the independent active thermal cavity 36, and glass VIP 34. This opening 350 in bottom sill plate 42 opens up and connects to blocked inactive cavity 38 (not shown refers to FIGURE 15C). Also shown, the top view and side view of the stud 12. This in-floor forced hot air is used for these following examples, said in-floor forced air travels through and up the opening 350 in the bottom sill plates 42, and out to the rooms through said blocked inactive cavities 38 in walls. The size of these outlets 350 can be adjusted to control the volume of the air flow. In-floor forced hot air travels underneath the floor in created channels, it also heats up the floor. FIGURE 15A is a sectional and side view of the floor joist 252 explaining the function of the floor joist 252 creating in-floor forced air channels 284 underneath the floor 30. Also shown are openings 32 for plumbing and electrical, rigid foam 18, OSB members 16, opening 282 on top part of floor joist 252 for in-floor forced air traveling through horizontally. FIGURE 15B wherein the lower illustration is a top view of the exposed main floor structure without the floor sheathing board 46 showing the in-floor forced air circulating route with the in-floor forced air 320 from the main furnace entering through the main duct 246 into the created rigid foam air channel system 276 between the floor joists 252. Openings 280 in bottom plates 274 are for in-floor forced air 320 to travel through and up to window & wall air register outlets into the room refers to FIG. 15C). The upper illustration demonstrates a sectional view of created forced air channels 284 underneath the floor, further explaining the 72 WO 2009/086617 PCT/CA2008/001809 configuration and arrangement of the components and openings relate to the in-floor and in wall forced air system. FIGURE 15C is a view of an applying example of the in-wall and in-floor forced air circulation and the relationships of inactive cavity 37, independent active thermal cavity 36 and glass VIP 34. In-floor forced air 320 moves from the main air duct 246 through the created in-floor forced air channel 284 between the floor joists comes out above the floor from the recess 280 in the bottom plate 274. The vertical wall stud 12 rests on the bottom plate 274 shows cut off view of the position of the foam strip 278 on the side of the stud. The horizontal partition foam strip 278 blocks off the inactive cavity 38 and creates the in-wall forced hot air route from this blocked off inactive cavity 38. Also shown is the relationships of OSB exterior wall sheathing 46, rigid foam members 18 and drywall 28. FIGURE 15D is a view of the composite floor joist 252 with openings 282 and openings 32. These openings 282 are only needed when forced air is to be directed in another direction. For example: to travel horizontal to next adjacent channel. FIGURE 15E is a top view shown, forced air circulating areas that can be controlled and be selected; as required due to the flexibility, such as bathrooms which may have cold ceramic tile flooring. Individual space between joists 252 can be connected through strategic openings 282 in floor joists 252 and bottom plate 274 with openings 280 which facilitate the in-floor forced air 320 travel up the walls and windows then emit ambient air into the room. Top view exposed floor structure without the floor sheathing board, shows the in-floor forced air circulating route from the main duct 246 and through the created void space 284 between the floor joists 252. FIGURE 15F shows applying examples for created in-floor cavities for in-floor forced air circulation on any type of floor joists or floors, such as engineered floor joists, galvanized steel "C" channel floor joists, timber floor joists, as well as concrete floor. The materials can form a rigid foam cavity/channel 286, corrugated sheet cavity/channel 290, galvanized sheet metal cavity/channel 292 or an OSB cavity/channel 288 as illustrated. Choice of materials depending on applications. This system of the present invention can be applied on most any type of existing floor joist system, with excellent flexibilities; for commercial floorings and 73 WO 2009/086617 PCT/CA2008/001809 vast area concrete flooring. Example: temperature rises through the floor sheathing to warm the floor and room space above, thus creates the effects of in-floor heating in a very economic way. It offers excellent benefit particularly for warming up floorings such as ceramic tile floor and hardwood floors and concrete floor. FIGURE 15G shown are applying examples of the present invention on the existing engineered floor joist system 294, galvanized steel single or double joist system 296 and timber floor joists system 298. FIGURE 15H is a side view of a window forced air deflector 300, snapped onto the top surface of the window frame 308. Also shown are the window sill pane 306, the snap-on device 304, the supporting point 302 and the window defroster forced air rout 310. FIGURE 151 shows the applying example and the relationships of a window defroster with deflector 300, shows the independent active thermal cavity air blanket (active thermal cavity) 36 not extending to window double pane glass 314. In-floor forced air 320 from in floor cavity 284 moves through between floor joists, travels up to the interior surface of the glass window 314, then showing in-floor forced air 320 when reaching the window sill plate to be designated as window defroster forced air 310 rises ambient entering in the room. Also shows the positions of the glass VIP 34 and the independent forced air cavity 36 not passing through window sill to the window. FIGURE 15J shows the interacting relationships (refers to FIGURE 151) of adding a single pane glass 318 to the window defroster. In this formation the independent active thermal cavity air blanket 36 is separated and not connected with other cavities; window deflector 300 and extended to glass VIP 34 thereby magnifying the benefits to the double pane glass window 314. FIGURE 15K refers to FIGURE 151 & 15J shown a connected upper wall section with a cavity window defroster adding a single glass pane 318 adjacent to said double glass pane 314 forming the independent active thermal cavity 36 therebetween shows the extending route of the independent forced air thermal blanket 220 running up and pass the openings in the window sill plates into the created cavity 36 between window 314 and glass pane 318 while the in-floor forced air 320 coming up from in-floor cavity 284 on the other side of the single pane 74 WO 2009/086617 PCT/CA2008/001809 glass 318 is directed thereto by the forced air deflector 300 and rises into the room to achieve the ultimate insulation effectiveness of the window. FIGURE 15L shown a broader scope explaining the relations and functionality of the in-floor forced air 320 system facilitates the extended benefits of cavity window defroster; the in-wall forced air flow for room air ambient and the directed in-floor heating. The in-floor forced air 320 is generated by the main climate control and separated from the independent active forced air system. Herein shown the side sectional view of a composite wall structure comprises cavity window defroster refers to FIGURES 15C & 151; in-wall and in-floor forced air 320 circulation. The in-floor forced air 320 travels upward from the in-floor cavity channels 282 and is delivered to the window 136 to become window defroster forced air 310. Also shows the same in-floor forced air 320 path travels up into the blocked cavities in the wall and emits into the room via in-wall air registers. Shows foam strip 278 blocking the inactive cavity and air register 316. FIGURE 16 is a top view of a composite insulated wall panel structure with rain water drainage system 322. The rain water drainage system 322 includes an in-wall drain pipe 324 with double piping to insure no water leakage and is secured therein by a steel reinforced supporting member 326. Also shown is the studs 12, OSB exterior sheathing 30, rigid foam insulation 18, drywall 28, VIP 34 and active thermal cavity 36. FIGURE 16A is a sectional side view of the in-wall hidden rain drainage system 322. Shown is the relationship between the roof line 336, the rain gutter and eve through system 328, the in wall hidden down pipe 324, the down spout 330, the foundation cement wall 334 and the ground grading 332. FIGURE 16B is a vertical sectional view of the hidden rain water drainage system 322 with rectangular wall passages. Shown is the relationship between the roof line 336, the rain gutter and eve through system 328, the in wall hidden down pipe 324, the upper floor 338, the down spout 330, and the ground grading 332. FIGURE 16C is a top view of the hidden rain water drainage system 322. All drain openings 340, drain channels 342, down pipes 324 and openings on top 40 and bottom plates 75 WO 2009/086617 PCT/CA2008/001809 42 are rectangular shapes to accommodate the corner space between walls as is the rain gutter and eve through system 328 Also shown is the soffit space 344, and reinforcing steel supporting member 326. It will be understood that each of the elements described above, or two or more together may also find a useful application in other types of methods differing from the type described above. While certain novel features of this invention have been shown and described and are pointed out in the annexed claims, it is not intended to be limited to the details above, since it will be understood that various omissions, modifications, substitutions and changes in the forms and details of the device illustrated and in its operation can be made by those skilled in the art without departing in any way from the spirit of the present invention. Without further analysis, the foregoing will so fully reveal the gist of the present invention that others can, by applying current knowledge, readily adapt it for various applications without omitting features that, from the standpoint of prior art, fairly constitute essential characteristics of the generic or specific aspects of this invention. 76

Claims (51)

1. The combined formation and the method and the configuration and the usage of the composite insulated building components and assembly equipments for prefabricating building sections for a structure to specification having improved multiple composite insulation patterns of preventing unwanted thermal transfer from component to component and from interior space to exterior space and providing a more efficient means for distributing thermal forced air throughout the structure as a new & efficient insulation value while facilitating on-site construction comprising: a) at least one metal (aluminum) master work frame installed and erected on the floor of the fabrication site; b)a plurality of composite insulated vertical studs that are assembled on said metal (aluminum) master work frame forming the skeleton frame-work of composite insulated wall panels; c) a plurality of composite insulated top & bottom sill plates that are assembled on said metal (aluminum) master work frame forming the skeleton frame-work of said composite insulated wall panels; d) a plurality of said composite insulated wall panels that are constructed on said metal (aluminum) master work frame; e) a composite wall frame equipment assembly associated with said metal (aluminum) master work frames for conveying and transporting the finished composite walls to storage; f) a composite floor equipment assembly comprising a principal and a plurality of auxiliary floor assemblies; g) a plurality of composite floor joists & floors that are constructed on said assemblies; h) at least one composite roof truss & ceiling joist equipment assembly comprising; i) a principal mobile truss anchor station for assembling said roof truss to various height according to the pitch of the roof and adjusting on-center specifications for the rafter beams to be attached thereto: 77 WO 2009/086617 PCT/CA2008/001809 I) at least one composite roof truss & ceiling joist equipment assembly comprising a plurality of roof truss mobile assembly stations and a non mobile station for disposing composite ceiling joists to various on-center specifications and length; and II) a plurality of composite insulated roof trusses and insulated ceiling joists that are constructed on said assemblies; j) a plurality of thermal forced air (heating & cooling) active cavity systems disposed in a plurality of composite insulated components that form a sealed conduit being further described as a thermal blanket between said composite insulated components to provide complete and efficient heating or cooling coverage throughout said structures upon the completion thereof; k) a plurality inactive cavity systems disposed in a plurality of composite insulated components that form a sealed conduit between said composite insulated components to provide complete and efficient heating or cooling coverage throughout said structures upon the completion thereof; and 1) an on-line monitoring system posting live streaming video to the internet thereby enabling authorized persons to monitor the construction from any internet accessible electronic device once an appropriate password is entered.

2. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 1, wherein said multiple composite insulation patterns comprise; a) a plurality of rigid foam members forming composite insulation components; b) created forced air thermal active cavity or cavities formed in between a plurality of sealed insulation members; c) created inactive cavity or cavities formed in between plurality of insulation members; d) glass vacuum insulated panel (VIP) members; e) glass insulated panel (VIP) associated with an added clear glass pane on the interior or exterior side of the VIP spaced apart to create thermal forced air passages; f) a clear glass pane added on the interior side of the clear glass wall panel commonly used on existing industrial & commercial building spaced apart to create a thermal forced air passage; and g) at least one galvanized steel-sheet member implemented as a divider(s) or 78 WO 2009/086617 PCT/CA2008/001809 temperature barrier(s) within a created forced air thermal active cavity to form multiple active thermal cavities;

3. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 2, wherein said composite rigid foam insulated components of said multiple insulation patterns comprises; a) sandwiched plurality of rigid foam members spaced apart with partially or completely sealed conduits bonded on edges with foam strips or sealed with membranes on edges to create inactive cavity or cavities to become as one unit with no forced air to channel through; b) sandwiched plurality of rigid foam members spaced apart with partially or completely sealed conduits bonded on edges with foam strips or sealed with membranes on edges to create active thermal forced air cavity or cavities having passages for forced air to channel therethrough; and c) said created active & inactive cavities can be combined together to become as one component (unit) by separating them with at least one rigid foam member and herein to claim their configurations.

4. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 1, wherein said glass vacuum insulated panel (VIP) comprises a plurality glass panels spaced apart by supporting pellets and glass nipples and having a plurality of glass strip and glass edges melted together with appropriate heat forming said panels as one vacuum unit to increase the R-value of said VIP members; a) to dispose as insulation members being as part of the composite insulated vertical stud to form as one structure; b) to dispose as insulation members being as part of the composite insulated top and bottom sill plates to form as one structure; c) to dispose as part of the insulation members of the composite floor joists system; d) to dispose as part of the insulation members of the composite insulated wall panel; e) to dispose as part of the insulation members of the composite ceiling and attic insulation component; and f) to dispose as insulated feature wall to bring in natural light by adding single pane glass on the exterior side and or on the interior side creating hollow spaces as thermal 79 WO 2009/086617 PCT/CA2008/001809 cavities channeling forced air through said cavities to provide and increasing R value.

5. The composite insulated building components and assembly equipment recited in claim 1 wherein said cavities are active and inactive cavities; a) created thin hollow spaces between choices of insulation members or materials not limited to rigid foam members described as cavity and or cavities within walls and floors and ceilings and within any composite structural members disposed as means of insulation to regulate and to provide increased R-values therein; b) inactive to allow for the passage of electrical wire, cable and plumbing therethrough; c) inactive within the composite wall panel of the present invention and in any composite structural members forming any composite wall panel acting as a mean of insulation value; and d) active for allowing the passage of thermal (heating or cooling) forced air therethrough in order to yield the benefit of the differences of the thermal effects also being described as a thermal blanket in this present invention used as a means of increasing or regulating R-value; e) active and inactive cavities to be disposed within any types of walls not limited to said composite insulated wall panel of this present invention disposed as insulation value and for regulating climate control as thermal blanket covering partial and/or entire building; f) active thermal cavities in conjunction with forced air which is not limited to hot and or cool forced air and or any temperature forced air within any building structures and or components to carry away unwanted temperature within walls to regulate and maintain desirable room temperate and increase R-value. g) another active thermal cavity in conjunction with forced air channel travel through the created in-floor void spaces between floor joists directly underneath the floor sheathing as forced air passages to be disposed as thermal active cavities/channels for in-floor heating or cooling means and for facilitating the window defroster and in wall forced ambient air in the room via registers; h) source of forced air from climate control system(s) associated with the active cavities can be directed separately from an auxiliary climate control unit and or from main climate control unit; and 80 WO 2009/086617 PCT/CA2008/001809 i) any single and or plurality of forced air systems in conjunction & associated with created cavity or cavities related to this invention to be utilized and be used by any means related to climate control and regulating temperatures and thermal transfer and providing insulation or increasing insulation R-value covering and connecting partial or entire building structure.

6. The composite insulated building components and assembly equipment recited in claim 5, wherein said thermal active cavities mate with respective active cavities disposed in connected any composite structural members and any composite insulation components to allow for the passage of forced thermal air of (heating or cooling or room temperature) to be channeled throughout the entire framework of any building structures including channel through beneath any type of flooring & ceiling structures including concrete flooring & concrete ceiling structures and any type of structural walls disposed as insulation means and to regulate and to increase the R-value comprising; a) a single galvanized metal-sheet is disposed between the thermal active cavity in walls or in ceilings acts as a thermal barrier for increasing R-value; and b) a plurality of galvanized metal-sheets are disposed in the thermal active cavity to create multiple thermal active cavities act as a multiple thermal barriers to increase R-value.

7. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 1 and wherein said composite insulated vertical stud members comprising: a) at least a plurality of 10 composite insulated vertical studs of each formed by 2 identical parts fastened as one; b) said any one of the 10 configurations formed by 2 identical parts can be mixed & matched with any of each 9 others of the present invention to form as different ones; c) said plurality of composite insulated vertical studs configurations not limited to the said ten illustrated configurations; d) glass vacuum insulated panels (VIP) disposed within said composite insulated vertical stud to form as one structure; e) a plurality of rigid foam members disposed within said composite insulated vertical stud; f) configured galvanized steel members forming as the structural members; 81 WO 2009/086617 PCT/CA2008/001809 g) at least one oriented strand board member disposed within said composite insulated vertical stud forming as part of the structure; h) a plurality of openings through out the body being as passages for forced air and for plumbing & electrical needs; and i) the combined configurations of the 10 and the mixed & match of the composite insulated vertical studs.

8. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 1 and wherein said composite insulated top and bottom sill plates comprise at least one of the following; a) configured galvanized steel members; b) a plurality of rigid foam members; c) glass insulated panel (VIP) members; d) thermal active cavity or cavities; e) inactive cavity or cavities; f) a single or plural strips of OSB member disposed within the said composite insulated top and bottom sill plate being as part of the structure; g) a plurality of openings through out the body being as passages for forced air; and h) configurations of said plurality of composite insulated top & bottom sill plates.

9. The composite insulated building components and assembly equipments for prefabricating a structure recited in claim 1 and wherein said composite insulated wall panel comprises; a) a plurality of composite insulated vertical studs; b) a plurality of composite insulated top and bottom sill plates; c) a plurality of composite insulation components of multiple insulation patterns to be disposed and filled between the on-center spaces of the skeleton frame which is constructed by said composite insulated vertical studs and said composite insulated top & bottom sill plates; d) thermal active cavities created between said insulation components in walls for forced air to channel through as a thermal blanket; e) inactive cavities created between said insulation components in walls with no forced air to channel through; f) a plurality of composite insulation components forming part of the structure of said 82 WO 2009/086617 PCT/CA2008/001809 composite insulated vertical studs and said composite top & bottom sill plates; g) within said composite wall panels to provide passages (cavities) for forced air functioning as window defroster; h) within said composite wall panels functioning to provide thermal forced air passages (cavities) to emit forced air from in-wall to eliminate on-floor air register outlets. i) orientated strand board sheathing on the exterior portion of the said assembled composite wall panel; and j) sheet rock on the interior portion of said assembled composite wall panel.

10. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 5 and wherein said composite floor joists and created in-floor thermal active cavities comprising at least one of the following; a) configured galvanized steel members; b) a plurality of OSB strips members; c) strategic openings on the body of said floor joists to allow passage for forced air and for electrical and plumbing needs; d) created void space (forced air channels) not limited choices of partition materials being used; e) the created in-floor void spaces between & along floor joists directly underneath the floor sheathing to be disposed as thermal active cavities for in floor heating or cooling means to further facilitate the window defroster and the in-wall forced ambient air for rooms thereto; and f) the entire formation of the configurations of a plurality of composite floor joists and sheathing and created void space and window defroster and in-wall forced air system.

11. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 1 and wherein said composite insulated ceiling joists with a drop down section assemble a composite insulated ceiling comprising; a) a plurality of composite rigid foam insulation components; b) configured OSB members; c) the configurations of the ceiling joist with a drop down section & the composite multiple insulation ceiling formation. 83 WO 2009/086617 PCT/CA2008/001809 d) a composite ceiling comprising active thermal cavity & cavities with insulation values; e) a composite ceiling comprising inactive cavity & cavities with insulation values; f) a composite ceiling comprising glass vacuum insulated panels VIP; and g) configured galvanized steel members and galvanized metal-sheet members as thermal barriers;

12. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim land wherein said composite roof insulated truss (rafter beam) members provide slots to embrace a plurality of rigid foam members forming single or plural cavities as insulation components directly underneath the roof sheathings and a plurality of composite roof trusses rafter beams and their configurations;

13. The composite insulated building components and assembly equipment for prefabricating a structure recited claim 12; wherein said composite ceiling joists with a drop down section assemble a composite insulated ceiling and wherein said roof truss (rafter beam) members provide slots to embrace a plurality of composite rigid foam insulation members forming at least one cavity as insulation components directly underneath the roof sheathings together create an unique sealed temperatures regulated composite attic space for improved attic and ceiling R-value.

14. The composite insulated building components and assembly equipment for prefabricating a structure recited in claim 9 and wherein said active thermal forced air system and said composite insulated wall panel together comprise a window defroster system that has a thermal blanket traveling across the interior of said window by providing forced air through a forced air passage in the lower part of said window frame and said window sill plate for delivery to said window via a forced air deflector that directs said air toward the window surface; a) said forced air is channeled from the main climate control system travels through created void spaces (channels) in between & along floor joists underneath the floor through openings on the body of the composite insulated bottom sill plates reaching up the cavities formed in the composite insulated components in walls between disposed composite insulated vertical studs and through openings in window sill plate; and 84 WO 2009/086617 PCT/CA2008/001809 b) to claim the created in-wall void space being utilized as forced air passages for window defroster.

15. The composite insulated building components and assembly equipment recited in claim 14, wherein said window defroster system with the extension of said in-wall active thermal forced air heating system further creates a window heating & insulation system functioning simultaneously with the said window defroster system by adding a clear single glass pane to the interior side of the window pane creating a thin hollow space as cavity or cavities between the added single clear glass pane and the interior side of said window pane by directing active thermal forced air traveling through said created thin hollow space (cavity or cavities) for added insulation means to the window and at the same time the window defroster system is functioning simultaneously on the other (interior) side of the said added single clear glass pane having a separate forced air path.

16. The composite insulated building components and assembly equipment recited in claim 15, wherein said independent forced air heating system further creates a forced air system applies to existing commercial & industrial buildings with extensive "composite clear glass vacuum insulated wall panels" as building exterior wall structures to separate the exterior & the interior wherein by adding a single clear glass pane on the interior side of the said "composite clear glass vacuum insulated wall panel" creating a thin hollow space as cavity or cavities between said "composite clear glass vacuum insulated wall panel" and said added single clear glass pane by directing thermal forced air traveling through said created thin hollow space (cavity or cavities) as added insulation means to the existing "composite clear glass vacuum insulated wall panels" to regulate and to improve R-value.

17. The composite insulated building components and assembly equipment recited in claim 9, wherein assembly of said wall panel is accomplished by the following steps: a) laying bottom sill and said top sill in spaced apart parallel fashion on said master work frame; b) placing said vertical composite members therebetween and perpendicularly thereto at distances according to specification; c) mechanically raising said aluminum master work frame to a comfortable level for workers; d) fastening said vertical composite members to said top sill and said bottom sill by 85 WO 2009/086617 PCT/CA2008/001809 two workers, one on each side; e) rotating said master work frame and said wall frame into a vertical position; f) installing any required electrical wire and boxes and associated components with one worker on each side thereof; g) installing horizontal composite members to rough in any required doors and windows; h) installing rigid foam insulation therein; i) installing OSB sheathing on the exterior portion of said wall frame; and j) installing drywall on the interior portion of said wall frame.

18. The composite insulated building components and assembly equipment recited in claim 1 and wherein said master work frame comprises: a) a substantially rectangular work frame; b) a pair of opposing motorized mechanisms for raising and lowering and rotating the wall structure; c) a horizontal track rail disposed above said work frame, d) a conveying fork lift suspended from said track rail; e) a motor for moving said conveying fork; and f) a pair of opposing video cameras oriented towards the work area and disposed on either side of said wall frame to upload the entire building process thereof live on steaming video.

19. The composite insulated building components and assembly equipment recited in claim 18 and wherein said conveying fork moves along said track rail powered by a remote control unit to transport said completed wall unit to storage.

20. The composite building components and assembly equipment recited in claim 19 and wherein said windows are protected by rigid form pads disposed on each side thereof during transport and storage.

21. The composite insulated building components and assembly equipment recited in claim 1 and wherein said roof truss is fabricated in two symmetrical mating halves each comprising: a) a center supporting member; 86 WO 2009/086617 PCT/CA2008/001809 b) a plurality of roof truss web supporting members; c) a roof rafter beam; and d) a slot for fitting an insulation member.

22. The composite insulated building components and assembly equipment recited in claim 1 and further including at least one drop down ceiling joist comprising: a) an elongate main joist portion; b) a drop down joist portion subjacent to said main joist portion and having ends terminating prior to the ends thereof; c) a galvanized steel plate substantially covering the sides and top of the entire length of said main joist portion with flanges extending perpendicularly from the bottom edges thereof; d) a galvanized steel plate substantially covering the sides and bottom of the entire length of said drop down joist portion with flanges extending perpendicularly from the bottom edges thereof; and e) an OSB strip integral with each said joist portion to separate said galvanized steel plates to short circuit the thermal transfer from metal to metal and provide support for the payload of "drop down" on which the ceiling and drywall are placed.

23. The composite insulated building components and assembly equipment recited in claim 22, wherein the extended ends of said main portion of said drop down joist is seated on the top plates of said studs and said drop down portion resides therebetween.

24. The composite insulated building components and assembly equipment recited in claim 21 and wherein said structure has a half and half roof gable system.

25. The composite insulated building components and assembly equipment recited in claim 24, wherein said gable roof system is fabricated by a mobile truss anchor station comprising: a) a station support structure; b) a vertical elevating mechanism to adjust to various according to the desired roof pitch; c) an anchor mechanism to support said center supporting member of said truss; d) a first ceiling frame support that is stationary and disposed below said anchor 87 WO 2009/086617 PCT/CA2008/001809 mechanism onto which said ceiling joists are seated for fabrication; and e) a second ceiling frame support with on-center spacers that is mobile and moves on tracks to and from center.

26. The composite insulated building components and assembly equipment recited in claim 25 and wherein fabrication of said half gable on said mobile truss anchor station comprises the steps of: a) seating said ceiling joists horizontally on the spaced apart ceiling frame supports; b) securing the rafters and side plates and bracing members thereto; and c) installing truss structure web members, fastening brackets, roof sheathing and shingles to complete the assembly.

27. The composite insulated building components and assembly equipment recited in claim 26, wherein said stationary ceiling frame support pivots said truss assembly 90 degrees and said mobile ceiling frame support is removed so conveying equipment can roll in for transporting the completed truss.

28. The composite insulated building components and assembly equipment recited in claim 21, wherein said structure has a hip roof system comprising a pair of mating half gable sections and a pair of hip ends to attach to the ends of said gable roof.

29. The composite insulated building components and assembly equipment recited in claim 28 and wherein said mobile truss assembly further includes third and fourth mobile ceiling frame supports which are mobile and configured similar to said second ceiling frame support and are spaced apart and parallel to one another and perpendicular to said first stationary and second mobile frame ceiling supports and are used for fabricating said hip sections.

30. The composite insulated building components and assembly equipment recited in claim 29 and wherein said mobile ceiling frame supports further include spacers disposed on the top portions thereof.

31. The composite insulated building components and assembly equipment recited in claim 1 and wherein said forced air system further includes an independent auxiliary 88 WO 2009/086617 PCT/CA2008/001809 furnace to feed thermal (heated) forced air into said system through a duct.

32. The composite insulated building components and assembly equipment recited in claim 1 and wherein said forced air system further includes an independent air conditioning to feed thermal (cool) forced air into said system through a duct.

33. The composite insulated building components and assembly equipment recited in claim 32 and wherein the forced air path of the thermal cavity air blanket associates with the inactive cavities and glass VIP within the walls floors and joists to provide comprehensive coverage throughout the entire structure.

34. The composite insulated building components and assembly equipment recited in claim 33 and wherein active thermal cavity insulation further includes galvanized steel dividers for buildings that seek higher energy saving requirements.

35. The composite insulated building components and assembly equipment recited in claim 33, wherein the attic of said structure includes a solar powered fan to regulate attic temperature and the solar power for said fan is harvested by at least one solar panel disposed on the roof.

36. The composite insulated building components and assembly equipment recited in claim 33, wherein each floor of said structure has an independent forced air (hot) thermal blanket supplied by its own independent furnace.

37. The composite insulated building components and assembly equipment recited in claim 33 and wherein each floor of said structure has an independent forced (cool) air thermal blanket supplied by its own independent air conditioning unit.

38. The composite insulated building components and assembly equipment recited in claim 1 and wherein floor sections comprising a plurality of composite floor joists are fabricated on a principal floor assembly.

39. The composite insulated building components and assembly equipment recited in claim 38, wherein said principal floor assembly comprises: 89 WO 2009/086617 PCT/CA2008/001809 a) a stationary motorized floor joist assembly station with a height adjustable platform; b) a mobile motorized floor joist assembling station having a height adjustable platform oriented towards the platform of said stationary station; and c) a pair of supporting members linearly disposed between the two floor joist assembly stations an in a 90 degree relation with said floor joists.

40. The composite insulated building components and assembly equipment recited in claim 39 and wherein the ends of a plurality of composite floor joists are laid out on said platforms and the floor is constructed thereon complete with sheathing board.

41. The composite insulated building components and assembly equipment recited in claim 40 and whereupon completion of said floor and the platforms are lowered to rest on said supporting members and said mobile assembly station is removed.

42. The composite insulated building components and assembly equipment recited in claim 41 and wherein said supporting members have wheels on tracks to enable them to be spaced accordingly depending on the length of said floor joists and positioning of said mobile assembly station.

43. The composite insulated building components and assembly equipment recited in claim 1 and further comprising a hidden drain water system that is not visible.

44. The composite insulated building components and assembly equipment recited in claim 43, wherein said hidden drain water system comprises: a) a rain gutter and eve through system disposed at the bottom of the roof line; b) at least one hidden down pipe leading from said gutter and extending downward through the walls of said structure that is double piped to insure no leakage; c) drain recesses in said rain gutter; d) a drain channel to receive drain water from said drain recess and transfer it to said down pipe; and e) a down spout at the bottom of said down pipe exiting said structure.

45. The composite insulated building components and assembly equipment recited in 90 WO 2009/086617 PCT/CA2008/001809 claim 44, wherein all drain recesses, drain channels and down pipes are rectangular to accommodate the corner space between walls.

46. The composite insulated building components and assembly equipments recited in Claim 1, 31, 33, 36, & 38 in conjunction with the active thermal forced air system to claim the method; formation; configuration and usage of a boxed-out space to accommodate and relocate the climate control unit; the electrical panel and wiring and the plumbing system are to be housed and consolidated within the boxed-out space in a basement facilitated to free up desirable development space with no obstructions along with others; such as the conventional cumbersome ducting system and to simplify the plumbing routes. a) the vertical column multi-level boxed-out spaces aligned with the above said basement boxed-out space in claim 46 accommodating outward and inward ducting systems connected from the climate control unit functioning for the active thermal forced air circulation system, therein claiming the method; formation; pattern; configuration; usage and function; b) to claim the method; formation; pattern; configuration and usage of the aligned vertical column boxed-out spaces applied to a multi-level building to consolidate the electrical panel and electrical wiring running vertically and horizontally and extending to each level and to specific spots therein at ease of a building; c) to claim the method; pattern; formation; configuration and usage of the aligned vertical column boxed-out spaces of a multi-level building permits the plumbing system running vertically and horizontally to extend to each level and specific spots therein at ease of a building; d) to claim the method; formation; pattern; configuration and usage of the aligned vertical column boxed-out spaces of a multi-level building associated with outward and inward ducting systems facilitating at least one in-wall active thermal forced air path which travels horizontally in the lower and upper parts of a wall panel by way of openings, passages, cavities and channels created in studs and wall panels in wall "to and from" the climate control unit; e) to claim the method; the formation; the pattern the configuration and the usage of the aligned vertical column boxed-out spaces of multi-level building associate with the active thermal forced air paths which travel horizontally through created openings; passages; cavities and channels underneath the claimed void spaces of the sub-floor surface in and between floor joists "to and from" the climate control unit; 91 WO 2009/086617 PCT/CA2008/001809 f) to claim the method; formation; pattern; configuration and usage of the aligned vertical column boxed-out spaces of a multi-level building associated with the active thermal forced air path that travels horizontally through openings; passages; cavities and channels created in and between ceiling joists within a ceiling "to and from" the climate control unit; g) to claim the method; formation; pattern; configuration and usage of the aligned vertical column boxed-out spaces of a multi-level building associated with the active thermal forced air paths that travel horizontally through channels; openings; cavities; passages and singular or plural piping systems created within a concrete slab floor to provide in-slab heating without utilizing any form of liquid "to and from" the climate control unit; h) to claim the method; formation; configuration and usage of the horizontal boxed out spaces aligned horizontally at 90 degrees along with floor joists functioning, hosting and directing pipes or tubes, water lines and electrical wiring to appropriate positions via and underneath the claimed void spaces cited in claim 10 and which are underneath the sub-floor and between floor joists, the said horizontal elongated boxed-out spaces run in opposite directions on the exterior walls connected at 90 degrees with the aligned vertical column boxed-out spaces at each floor level; i) to claim the method; formation; configuration and usage of the horizontal boxed-out spaces cited in claim "46 h" that have an insulated hollow body and in which comprises at least one of: passage; channel or cavity for running the active thermal forced air through and not limited to and connecting with other openings; channels or passages for extending and connecting the active thermal forced air system; j) to claim the combination of the method; formation, configuration and usage of: the boxed-out spaces in the basement; the vertical column boxed-out spaces; the horizontal boxed-out spaces; the climate control unit; the outward and inward ducting system; the active thermal forced air system and associated passages; cavities; and channels in walls, ceilings, and void spaces underneath the sub-floor and concrete in slab floor; the horizontal flow pattern of the active thermal forced air in the lower and upper parts of wall panels, which are divided by a form strip not limited by other means to form the forced air circulation flow; k) to claim the combination of the method, formation, configuration and usage of the active thermal forced air system in this present invention which is to be used to circulate forced air in cavities; passages; channels; openings; piping; and tubing; and 92 WO 2009/086617 PCT/CA2008/001809 is not limited to types of materials to be used and the function(s) to be utilized for any purpose of regulating hot or cold climate control in ceilings, walls, all types of floor for in-floor heating, and forced air window insulation and forced air window defrosting; 1) to claim the combination of the method; pattern; formation; configuration and usage of the active thermal forced air system in this present invention and which is not limited to a single cavity and applies to plural cavities of multiple forced air flow; and is not limited by specific or certain temperature degree settings within walls; ceilings or floors; whether positioned in single or in plural form & configuration close to the interior or exterior side of walls of residential or commercial/industrial buildings for the purpose of regulating temperatures and/or climate controls and the formation; creation; configuration and pattern of the space of the cavity or cavities with the materials being used are not to be limited with rigid foam; and such width of cavity spaces are not to be limited depending on application; m) to claim the combination of the method; pattern; formation; configuration and usage of the in-active cavities system in this present invention and which is not limited to a single cavity and applies to plural cavities between walls; ceilings & floors; whether positioned in single or in plural form or configuration close to the interior or exterior side of walls of residential or commercial/industrial buildings for the purpose of regulating temperatures and/or climate controls with the materials being used are not to be limited with rigid foam; and such width of cavity spaces are not to be limited depending on application; n) to claim the combination of the method; pattern; formation; configuration and usage of the active thermal forced air system in this present invention therein not to be limited the pattern of the air path movements either in the pattern of horizontal and vertical or in the combined patterns of horizontal and vertical within walls & ceilings & floors; o) to claim the combination of the method, pattern, formation, configuration and usage of the active thermal forced air system in direct conjunction with the corrugated metal components to be used in ceiling & wall structures of which the "void" spaces on one side or on both sides of the corrugated configuration to be utilized as the active thermal forced air path and not to be limited on any wall & floor corrugated structures for commercial and or industrial buildings. 93 WO 2009/086617 PCT/CA2008/001809

47. the configuration & the formation & the methodology & the utilization of the double pane un-obscured all glass VIP incorporated with a programmable mechanical apparatus utilizing a heat exchanger able to facilitate the "repeat at will" pressurized vacuum process performing filling and retrieval functionality of active forced thermal "coloured" fluids to achieve "on & off' vacuum insulation generating a two stage insulation value and automated/manual temperature regulating process and create a combined vacuum & active forced thermal fluids window treatment system.

48. the configuration & the formation & the methodology & the utilization of the triple pane un-obscured all glass VIP panels having a dual body with dual cavity incorporated with a programmable mechanical apparatus utilizing a heat exchanger able to facilitate the "repeat at will" pressurized vacuum process performing filling and retrieval functionality of the active thermal forced coloured fluid to achieve vacuum effects generating a three stage insulation value with automated/manual temperature regulating process and creates a simultaneously functioning "permanent" & "repeat at will" vacuum conditions along with the active forced thermal fluids window treatment system; a) the functionality of any double and/or triple pane un-obscure or obscure all glass VIP utilizing "coloured" fluid or fluids as customizable window treatment and/or for window insulation with or without vacuum process or condition; b) any glass VIP filled with active forced thermal "coloured" fluids being used to block Ultra Violet light and being used as window insulation; c) the functionality of active forced thermal fluid used in glass panels within any window structures for insulation and regulating temperatures is in either vacuum condition or non-vacuum condition; d) any active forced thermal fluid being used in panels within wall structures for insulation and regulating temperatures is either in vacuum condition or in non vacuum condition; e) the un-obscure & obscure glass VIP to be utilized as insert-member within door structure for improving insulation; f) the methodology of utilizing the active forced thermal fluid to achieve "repeat at will" vacuum condition and/or to regulating temperature for insulation purposes in large wall structures not limited to the type of materials to be used.

49. the composite insulated building components and assembly equipments (recited in 94 WO 2009/086617 PCT/CA2008/001809 claim 1, 31, 33, 36, & 38) in the parent application in conjunction with the active thermal forced air system to claim the combination and the interaction of the configuration & the formation & the methodology & the utilization of the vertical and horizontal boxed-out space system able to accommodate and relocate the climate control unit and the electrical panel and wiring and the water/plumbing system all are to be housed and consolidated within the insulated space of the boxed-out system created and raised from the foundation in the basement facilitated to yield more desirable development space to reduce and or to eliminate obstructions associated with the conventional cumbersome heating & ducting system and to simplify the plumbing routes and to facilitate at least one active thermal forced air to travel more effectively in the active thermal forced air system in and around the multi-level structure of buildings; a) the outward and inward active forced air circulation insulated ducting systems facilitating for at least one in-wall active thermal forced air cavity which extends its way and connects vertically and or horizontally to all composite wall panels and in floors and ceilings by way of traveling through created openings or passages or cavities and or channels "to and from" the climate control unit particularly in the boxed-out space; b) the active thermal forced air paths that travel vertically and horizontally through channels or openings or cavities or passages or piping systems created within a concrete slab floor to provide in-slab heating without utilizing any form of liquid "to and from" the climate control unit particularly in the boxed-out space; c) the combination and the interaction of the method and formation and configuration and usage of the active thermal forced air system in this present invention which is to be used to circulate active thermal forced air in cavities; passages; channels; openings; piping; and tubing; and is not limited to the types of materials to be used and the function(s) to be utilized for any purpose of regulating hot or cold climate control in ceilings and walls; activating thermal forced air for all in-floor heating and forced air window insulation and forced air window curtain for defrosting; d) the active thermal forced air system combines with the in-active cavity system in the parent application and this present invention and which is not limited to a single cavity and applies to plural cavities of multiple forced air flows; and is not limited by specific or certain temperature degree settings within walls; ceilings or floors whether 95 WO 2009/086617 PCT/CA2008/001809 positioned in single or in plural form & configured close to the interior or exterior side of walls of residential or commercial/industrial buildings for the purpose of regulating temperatures and/or climate controls and the formation; creation; configuration and pattern of the space of the cavity or cavities with the materials being used are not to be limited with rigid foam; and such width of cavity spaces are not to be limited to specific depending on application; e) the active thermal forced air system in this present invention therein not to be limited the pattern of the active thermal forced air path movements either in the pattern of horizontal and vertical or in the combined patterns of horizontal and vertical within walls & in ceilings & in all types of floors; f) the method; formation; configuration and usage of the vertical & horizontal boxed-out spaces aligned horizontally at 90 degrees against along with floor joists facilitates the effective arrangement of laying & installing & directing pipes or tubes; water lines and electrical wiring to appropriate positions via between floor joists and facilitates the active thermal forced air travel through the claimed void spaces (cited in claim 10. in the parent application) which are underneath the sub-floor and between floor joists.

50. the combination and the interaction of the configuration & the formation & the methodology & the utilization of the active thermal forced air circulation system in direct conjunction with the corrugated metal components to be used in ceilings, & floors & wall structures of which the "void" spaces on one side or on both sides of the corrugated configuration to be utilized as the active thermal forced air path transforming into a 3 stages composite insulation structure comprises a dual corrugated forced air path sandwiched the corrugated metal member to be utilized as a "heat sink" and not to be limited on any walls & floors corrugated structures for commercial and or industrial buildings for the purposes of regulating temperature and or for climate controls.

51. the combination and the interaction of the configuration & the formation & the methodology & the utilization of the active thermal forced air system applies directly to the roof line underneath the roof sheathing wherein composite insulated rigid foam panels created in between the foam members having at least one active forced air cavity/passage at one end connected 90 degree against with the openings on the side of an elongated central channel gathering and allowing all forced airs channeled from said multiple composite 96 WO 2009/086617 PCT/CA2008/001809 insulated rigid foam panels flow into the cavity of said openings of the elongated central channel to be dissipated and be redirected for the purposes of regulating the temperature and or for climate controls. 97 WO 2009/086617 AMENDED CLAIMS PCT/CA2008/001809 received by the International Bureau on 05 May 2009 (05.05.2009) The following claims are new and desire to be protected by letters patent as set forth in the appended claims: 1. The configuration and formation of the assembly equipments and their processes of prefabricated building sectional structures according to specifications of having various composite insulated supporting members/components that are then assembled into sectional structures for roofs and walls and floors of which are incorporated & made of the improved partial or all of the composite multiple insulation patterns that prevents unwanted thermal transfer from component to component and further prevents unwanted thermal transfer from the interior space to the exterior space therefore providing an unprecedented effective solution for directing active thermal/cool forced air via cavities/passages/channels/paths/openings that are built throughout any building structures as an innovative & efficient insulation method with higher insulation value while facilitating the thermal transition from active heating mode (with main climate control units) to passive heating mode (with auxiliary climate control units) forming a thermal forced air blanket covering the entire building structure as well as going in floors & in-walls & in-ceilings and further the desired effects of the aforementioned assembled components & prefab processes for a building structure which consists of individual thermal/cool forced air systems including but not limited to a roof forced air system and an attic forced air system and a ceiling forced air system and a wall/window forced air system and a floor forced air system working together in a connected active forced air networked system by means of the active thermal/cool forced air cavities/passage/channels/paths/openings which is including but not limited to the claim of just thermal active forced hot air but also applies to the usage of cool active forced air for hot climates providing a more efficient means for distributing thermal/cool forced air throughout any building structures as an innovative & efficient higher insulation value while providing the ability for on-site construction with prefab-sectional structures and components comprising of: a) at least one set of roof truss assembly equipment consisting of a principal mobile truss anchor station & one floor-mount station & 3 ceiling frame support stations mobile with wheels on tracks; AMENDED SHEET (ARTICLE 19) qRt WO 2009/086617 PCT/CA2008/001809 b) at least one metal master work frame assembly equipment for prefabricating sectional wall structures and a wall-frame assembly for conveying and transporting the finished composite insulated sectional walls which employed the multiple insulation patterns to storage and/or installed and erected on the floor of the fabrication site; c) at least one set of floor assembly equipment consisting of 4 floor joists assembly stations one is a principal floor-mount station and 3 auxiliary assembling stations movable with wheels on tracks; d) the multiple insulation patterns comprise of primary insulation material & active forced air cavity and an inactive cavity and the glass Vacuum Insulated Panel (VIP) and forced air cavities associate with galvanized steel sheet(s); e) a prefabricated roof truss system of it's sectional structures consisting of all or part of multiple insulation patterns; f) a prefabricated wall system of it's sectional structures consisting of all or part of multiple insulation patterns; g) a prefabricated floor system of it's sectional structures consisting void-spaces created by various floor joist formations; h) a window system consists of active forced air insulation & window active forced air defroster as air curtain; i) the basement sectional walls and concrete floor system consisting of all or part of the multiple insulation patterns; j) a multitude of structural members comprise roof trusses & ceiling joists & vertical supporting studs & top/bottom plates & headers & sill plates & floor joists and insulated wall panels; k) a network of active forced air passages provide flexibility to create various flow-paths in conjunction with the multiple insulation patterns and the assembled structural members to create the thermal blanket/envelop; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 1) the active forced air cavities along with galvanized steel sheets creating multiple insulation barriers to enhance the efficacy of the multiple insulation patterns; m) the inactive cavities enforcing and made part of the multiple insulation patterns; n) a network of active forced air passages/openings/channels/paths/cavities in all systems of in-walls & in-floors & in-ceilings & in-windows to provide means to eliminate the standard prior art cumbersome sheet metal ducting systems and then facilitate to free up more useful space in the residential basement and on each floor of the commercial & industrial buildings; o) a network of active forced air system in conjunction with the multiple insulation patterns capacitate at least one auxiliary independent climate control unit (which consumes a friction of energy compares to main climate control) facilitate the passive heating mode on each floor for residential & commercial & industrial building structures; p) the flexible active forced air flow-paths for residential & commercial & industrial buildings; q) various functions of the obscure & un-obscured glass Vacuum Insulated Panels VIP; r) the void spaces to be utilized for active forced air passages for residential & commercial and industrial buildings; s) the boxed-out basement space and boxed-out vertical & horizontal column structures networking the boxed-out space system consists of all or part of the multiple insulation patterns; t) the hidden rain drainage disposed within wall structure; 2. The composite insulated building components and assembly equipments for prefabricating building sectional structures cited in claim I wherein the method of constructing modular roof truss structures including the steps of constructing the equipments to assemble and prefabricate the "half' sectional roof structures with directions of how the rafter members & the AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 ceiling joists & the support web members are to be assembled into a %2 sectional roof truss structure in hip & gable style of roof and a combination of hip/gable style of roof structure and further configured to put "halves" roof truss formations together comprised of; a) a mobile truss anchor station assembly equipped with a height adjustable elevating mechanism mounted on 2 aligned positioned apparatuses allowing for various roof pitches and affixed with a longitudinal anchor bar with spacers to adjust to O.C. specifications for the aligned and arrayed rafter-members & for the center support members to be attached on and having wheels on tracks for mobility and; b) four elongated ceiling frame support stations all installed with adjustable O.C. spacers all aligned at the same level/heights opposite to each other of which all are positioned in a roof-square formation where one is a permanent floor mount ceiling frame support station installed directly right at the front of the aforementioned mobile truss anchor station cited in claim 3a and facing the other 3 with the O.C. spacers of the said permanent floor mounted ceiling frame support station having the ability to be aligned vertically with all the other O.C. spacers affixed on the mobile truss anchor station assembly and also having a mechanism to allow it to pivot 90 degrees to upright position when completion to flip the half sectional roof truss upright for ease of transportation and storage and; c) the other 3 ceiling frame support stations with O.C. spacers installed all run on tracks with wheels providing flexibility to move toward and away from each other allowing them to assemble various sizes of roof footprint-squares by laying the ceiling joists with one end on the floor mounted frame support station and the other end on the opposite mobile frame support station and with all said ceiling joists placed in O.C. spacers then all rafter-members are further positioned and aligned in the O.C. spacers adjusted with the same O.C. specification on the longitudinal anchor bar of the mobile anchor truss station thereby allowing to adjust the pitch heights to specification as well as all supporting web members can also be positioned in place to specification forming the /2 gable roof and further to which the hip roof can be assembled by positioning 2 rafter members start from one high "center" point on the longitudinal anchor bar of the mobile truss anchor station and then slope down to the 2 lower far corners of the roof square on the opposite mobile frame support station thereby having all the ceiling joists laid in place on specification on the floor mounted frame support station & on the opposite mobile frame support stations forming the hip roof slope and all supporting web members AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 will be fastened & positioned in place to specifications forming the hip roof and the formations of each structural apparatus of the roof equipment assembly can perform the function of assembling the hip & gable roof or the combination style of both; 3) The composite insulated building components and assembly equipments for prefabricating building sectional structures cited in claim I wherein the method of constructing modular wall structures including the steps of constructing a master work-frame (MWF) along with instructions of how all the prefabricated wall components are to be assembled into sectional walls and then how each sectional wall is transported after completion and then further having the whole process digitized and available to be viewed and monitored by buyers on line; a) the wall panel assembly equipments consist of a rectangular master work frame (MWF) and on both sides of its parallel exterior edges each affixed on a floor-mounted vertical wall-supporting member (VWSM) aligned opposite towards each other equipped with a motorized mechanism allowing the aforementioned MWF to pivot in a vertical/horizontal and upward/downward positions at ease controlled by a prior art electronic remote device and when positioned in the workable horizontal height to receive the top and bottom sill plates and all studs and wall panels and window & door headers and plumbing/electrical fixtures and window frames all which are to be laid flat and to be assembled on the MWF and spaced at 16"or 24" O.C. including but not meant to be limited on other O.C. specifications and thus when said mechanism rotates and stands the MWF in an upright vertical position wherein drywalls & OSB wall sheathings and all other necessary detailing works can then be performed and; b) the MWF further comprises of a top & bottom release bar installed outwardly on the top & bottom edge of the MWF with manual adjustable mechanisms mounted on both of their ends which perform the function of holding in place the studs/plates/composite insulated panels/headers and window frames all in spaced positions during the assembling process and further perform the function to disengage and release the sectional wall when completed and; c) the MWF is further comprised of 2 vertical wall supporting members (VWSM) which consist of a top mounting member and a base mounting member and to which both (VWSM) are mounted on opposite sides of the MWF assembly with guiding rods affixed to each side of the main frame and with both bodies of the VWSM having a AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 couple of metal holding members which are adjustable and can move horizontally with the guiding rods loosely affixed to the main frame performing the function to engage & disengage the uncompleted & completed sectional wall in position determined by the needed wall specification sizes and; d) the MWF is further comprised of a timber plate with openings for inserting the transport fork lift along with weight supporting members positioned underneath while the loaded MWF rotates in its vertical position. e) the wall frame production assembly is comprised of a horizontal supporting apparatus with supporting legs on both sides extending from each end and a motorized track is installed on the underside of said support legs which to allow a conveying fork to travel along and a video camera placed on the interior portion of each leg and oriented towards its respective work area of the vertical wall assembly member to deliver live streaming video to an internet server for observation while an electric motor drives the conveyor fork back and forth along the track with two primary functions of conveying and transporting the finished wall structures to storage and providing a monitoring system posting live video clips of the production process which allows the buyers to view the process live on-line with a password. 4. The composite insulated building components and assembly equipments for prefabricating building sectional structures cited in claim I wherein the design of equipments and a method of constructing modular floor structures comprising the steps of assembling floor structures in the prefab process of various floor joists & floorings to be assembled into various sizes of sectional floors and the steps performed by 4 floor joists assembling stations all with the same configurations and functions except where one is a non-movable floor-mounted and 3 others are movable with wheels & on tracks are comprised of; a) each one of the four said 4 floor joist assembly stations comprises of a stretched leveled platform with safety railings installed on & connected with 2 positioned apparatuses with synchronized elevating mechanism able to be hoisted up 5 to 6 feet above ground for workers to work on the floor surface and underneath and; AMENDED SHEET (ARTICLE 19) 103 WO 2009/086617 PCT/CA2008/001809 b) of the 4 floor joist assembly stations one is the floor-mounted described as "non movable" and the other three are the "movable" stations with wheels & on tracks all to be placed and oriented in four directional positions in a perpendicular & parallel square formation as for example wherein the non-movable floor-mounted station in the "north" position stays immobile as one of the three movable stations in the "south" position has flexible mobility and can move toward and away from the "north" floor-mounted station allowing formations of various lengths and width of floor joists to be laid on their 2 opposite platforms for a sectional principal floor to be assembled with various specifications while the other two movable stations can be placed at the "east and west" formation with the geared mobility of wheels & tracks with which they can move swiftly toward to and away from each other in formations allowing additional sectional floors to be assembled on both sides of the north and south longitude formation and in further any addition sectional floor can be built on by the movable "east & west" auxiliary assembly stations then attached to the principal floor and; c) various lengths of floor joists can be laid on the longitude platforms according to O.C. specifications to be assembled as the sectional principal floor(s) and the elevating mechanism also allows the sub-floor sheathings and the void spaces and all necessary components to be installed on surface and/or underneath at ease and; d) various sizes of sectional additional floor(s) can be assembled with the flexible mobility of the 2 opposing movable floor joists auxiliary assembly stations by laying various lengths of floor joists in array with all their ends on one latitudinal-platform and all other ends attached to the side plate of the frame of the laid longitudinal floor joists of the principal floor and all additional floors also can be assembled on the east & west latitude formation of the 2 movable floor joists auxiliary assembly stations by moving the 2 said stations toward and away to adjust to specifications at which completed sectional additional floor can be assembled separately and be shipped out separately; 5. The composite insulated building components for prefabricating a structure cited in claim 1 wherein the formation & function of the Multiple Insulation Patterns employ rigid foam as prime insulation material illustrated in this present invention including but is not meant to be limited by other rigid or soft in nature insulation materials which can easily be used to substitute the rigid foam as insulation materials being utilized to facilitate the creation of AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 multiple insulation patterns which consists of 5 focal subjects being as part of this invention generating insulation efficiency such as "the active forced air cavities & inactive cavities & glass VIP and active forced air associates with galvanized metal sheet(s) and including and not meant to be limited the rigid or soft primary insulation material itself as being part of the "Multiple Insulation Pattern" depicted in this present invention comprises; a) a single or series of rigid foam members not limited to other insulation materials either rigid or soft in nature can be employed as prime insulation materials placed within the structures of the vertical studs and wall panels to embrace other insulation means to constitute multiple insulation patterns to be part of the ceiling & wall panel structure; b) at least one forced air active cavity being created by & within the insulation materials including but not to be limited by sandwiching multiple rigid foam sheets spaced apart by foam strips as edges forming at least a single or multiple cavities to be as part of the multiple insulation patterns; c) at least one forced air active cavity can be created by & within insulation materials including but not be limited by running forced hot or cold air through nor by running room temperature air to regulate the temperature or for climate control being part of the multiple insulation pattern; d) at least one forced air active cavity created by & within insulation materials including but not meant to be limited by sandwiching multiple rigid foam sheets spaced apart by foam strips with edges forming a single cavity and having at lease one galvanized steel sheet be placed within the single cavity and be as part of the multiple insulation patterns; e) at least one obscured glass VIP at choice depending on application to be disposed in between insulation materials including but not meant to be limited by sandwiching multiple rigid foam members or spray foam to be as part of the multiple insulation patterns; f) at lease one inactive cavity to be created between insulation materials including but not to be limited by using rigid foam member as insulation materials with no forced air to channel through to form as part the multiple insulation patterns; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 g) the flexible formation of the multiple insulation patterns to be disposed in the vertical studs and wall panels are not limited by their thickness or sizes and singularity or plurality and their orderly disposition of each other and extends to their usages as presented in this present invention for energy conservation purposes; 6. The composite insulated building components cited in claim I wherein the formation & function of a roof forced air system with inclusion of roof line system and attic system and the ceiling system and said roof forced air system is comprised of; a) the formation of the forced air roof line is created where the rafter-members are configured at their stretched elongate top portion having 2 back-to-back "C" channels facing outwardly on both sides and at their bottom center having a protruding flange at which on both surfaces are for the web supporting members and the center supporting members to be attached on and be fastened then followed by a plurality of rigid foam insulation panels each with a cavity to be installed along & between a plurality of arrayed rafter-members snugly fitted into the "C" channel slots from one low-pitch end to the high-pitch end along the pitch (roof line) and then directly under the center peak of the roof line creating a large insulated blow-out channel made of rigid foam sheet members disposed perpendicular to the arrayed rigid foam panels with their cavities connected respectively with the openings of the insulated blow-out channel; b) the function of the forced air roof line is to position an array of plurality of rigid foam insulation panels as cited in claim 6a each configured by at least 2 sheets of rigid foam members sandwiched together with 2 foam strips as long edges sealed to form a cavity with 2 open-ends in between and with their lower-pitch ends open for incoming air and the higher-pitch ends connected with respective openings to a large rigid foam insulated blow-out channel installed perpendicularly inside and under the highest pitch level through the rafter-member collecting (sucking) all unwanted-temperature air coming in from the low-pitch-ends into the cavities then running up toward the high pitch-ends into the large blow-out channel which is designed readily for a solar powered blower to be installed to direct and dispel the unwanted air collected and to wherever is needed or appropriate and further the aforementioned roof-line panels with active forced air cavities in conjunction with the blow-out channel hereby to claim their functions AMENDED SHEET (ARTICLE 19) 106 WO 2009/086617 PCT/CA2008/001809 including but not meant to be limited to install or be used on the prior art engineered wood truss system for the same purposes; c) the formation & the function of the drop-down ceiling joist whose core body is one OSB strip member with an extended full length upper section on both ends and the lower body is the drop-down section with both lower-ends that equally terminated prior to the ends of the extended upper sections creating a 90 degree cut-off at both ends of the drop down section establishing 2 equal extensions at both ends of the full length upper section which also has a full length galvanized steel member shaped with a recess at both edges along with a set of outward facing 90 degree flanges grooved-to-fit the recesses on the top of the full length upper section of the OSB strip member to become as one upper section-body with the 2 extensions of the face-down side of the 90 degree flanges to be seated on the top sill plates on walls whereupon during assembling of the whole building structure and the top face up strip/space of the 90 degree flanges where the payload of the attic portion of the composite insulated panels (inactive cavity & glass VIP & rigid foam members) will rest while the lower drop down section of the OSB will have 2 galvanized steel drop-down 90 degree angled flanges back-to-back positioned flush with the bottom-edge to match the length of the OSB drop-down bottom portion creating a strip-space on both flanges of the drop-down OSB positioned with multiple ceiling joists ready for the inclusion of the rigid foam cavity members to be seated and the entire OSB strip member having the longer upper section and the middle shorter lower drop-down section with a 90 degree cut-off at both ends forms the core body of the ceiling joist while the 2 upper & lower galvanized steel members attached on the OSB beam member have "zero" contact to each other short-circuiting the thermal transfer from metal to metal (ceiling to attic) and further provide support for the payload of the drop down section where the ceiling portion of the insulation members consist of active forced air cavities and the ceiling drywalls are installed on the ledges of the face-down 90 degree flanges and the attic section of the composite insulated ceiling panels consist of rigid foam/inactive cavity/glass VIP and hereby further to claim the ceiling drop-down section in conjunction with the ceiling panels consist of multiple insulation patterns to be installed & be used onto the prior art timber ceiling joists functioning being as part of the an active forced air thermal blanket; d) the formation of the roof structure web is to position an array of galvanized steel web members with both their ends made able to be fastened by means of nuts & bolts onto AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 the protruding elongate flanges of the rafter-members and then the other ends of the steel web members fastened with the top part of the ceiling joists also able to be secured by means of nuts & bolts to form the web of the roof-truss frame and having the 2 halves of said roof-truss frame" they can then be secured by joining and bolting each of their center support members together to become one entire piece of roof truss structure with the attic space in between the webs; e) the formation & the combined functions of the roof system comprises "roof-line & attic & ceiling" with a completed roof structure consists of the roof rafter-members embraced in rigid foam insulated panels with open-ended forced air cavities and a blow out channel at the top center to collect unwanted-temperature air flows and with the upper part of the ceiling joists configured to accommodate the composite insulated panels with inactive cavity & obscure glass VIP in the "attic" and the drop-down section of the ceiling joists above the ceiling line comprises with the rigid foam panels facilitate the active thermal forced air cavities/passages and inactive cavity as insulation and then closing off the entire attic and the open areas with insulation members and utilizing a programmable exhaust fan installed on the insulated side wall of the attic space and the attic is readily designed to be easily sealed off and be humidity and temperature regulated by an alternative green energy generated fan and further defining additional function of the ceiling joists with the drop-down sections seat on the top sill plates on walls dividing the attic space and the room space under the ceiling line of the room with un-precedent insulation R-values and hereby further to claim the said roof system comprises of roof-line & attic & drop-down ceiling including but not to be limited to be installed & be used in conjunction with the prior art engineered timber roof truss system functioning with the same purposes to provided improved insulation & regulated the temperature & the climate control; 7) The prefab-building structure as cited in claim 1 wherein the functions of the active forced air wall system with at least one completed sectional wall consisting of composite insulated wall panels & composite insulated vertical studs & insulated top/bottom sill plates and window headers of which all employ partial or all of the multiple insulation patterns depending on application and specification requirements having thermal/cool active forced air travel through and be directed in the cavity/cavities associated with multiple openings on top/bottom plates all of which can be networked and connected with other cavity/cavities & openings in AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 other thermal/cool active forced air systems within the same building structure such as ceiling system & other sectional walls & floor system & window system & basement wall system to provide thermal/cool active forced air insulation forming a thermal/cool forced air blanket/envelope wrap around the whole building structure and also for in-floor heating thereby transitioning from active heating mode to passive heating mode applying the flexibility of the thermal/cool active forced air flow-paths of which can be directed to run from vertically upward/downward and further be rerouted to run opposite directions horizontally simply by pre affixing horizontal partition-strip materials parallel within the cavity/cavities on the vertical wall panel bodies that are coordinated with grouped openings precut on the vertical stud bodies to create the upper/mid/lower sections horizontal flow-paths and that the active forced air wall system can be assembled on the wall assembly equipments of this present invention and the plumbing & electrical fixtures can be also be pre-installed within the sectional wall panels through connected spaces in the inactive cavities and built-in the individual vertical studs & wall panels cited in claim 2 and the wall system comprises; a) a series of composite wall panels employing rigid foam members illustrated in this present invention including and not meant to be limited by other rigid or soft insulation materials being used to substitute the rigid foam as insulation materials to facilitate the creation of multiple insulation patterns of which constitute various insulation means to structure the wall panels forming the sectional wall and the functions of the sectional walls depending on the selection of including partial or all of the multiple insulation patterns to be incorporated into and forming the wall panels; b) a composite wall consists of at least one obscured glass VIP to be disposed in between insulation materials not to be limited by sandwiching of rigid foam members or spray foam being as part of the insulation patterns of the sectional wall panels; c) another composite wall consists of at least one forced air active cavity created within the insulation materials including not meant to be limited by sandwiching rigid foam sheets spaced apart by foam strips as edges forming a single or multiple cavities being as part of the insulation patterns of the sectional wall panels; d) another composite wall consists of at least one forced air active cavity can be created by & within the insulation materials including and not meant to be limited by running forced hot or cold air through nor by running room temperature air to regulate the AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 temperatures or for climate control being as part of the insulation patterns of the wall panels; e) another composite wall consists of at least one forced air active cavity created within insulation materials including and not meant to be limited by sandwiching rigid foam member spaced apart by foam strips as edges forming a single cavity and having at least one galvanized steel sheet be disposed within the single cavity being as part of the insulation patterns of the wall panels; f) another composite wall consists of multiple forced air active cavities created within the insulation materials including and not meant to be limited by sandwiching rigid foam sheets spaced apart by foam strips as edges forming multiple cavities therein-between disposed with multiple galvanized steel sheets being as part of insulation patterns of the wall panels; g) another composite wall consists of at lease one inactive cavity to be created between insulation materials not meant to be limited by using rigid foam member as insulation materials with no forced air to channel through to form being as part the insulation patterns of the wall panels; h) another composite wall consists of partition-strips materials horizontally pre-affixed to the vertically-run forced air cavity/cavities in the up-right rigid foam bodies of the wall panels within the cavities to create horizontal active forced air passages within the wall panel coinciding and connected with the openings in the bodies of the vertical studs; i) a plurality of composite vertical studs consist of partial and/or all multiple insulation patterns incorporated with composite wall panels and insulated top/bottom plates to form the sectional wall; j) a plurality of insulated top & bottom plates consist of partial and/or all multiple insulation pattern incorporated with composite wall panels and composite vertical studs to form the sectional wall; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 k) the configuration of the sectional wall illustrated in this present invention which specifications in terms of measurements of the width/length/height and O.C. disposition are not meant to be limited and/or restricted to certain specifications due to various building requirements in order to yield the maximum energy efficient effects; 8. The composite insulated building components cited in claim 1 wherein the composite insulated vertical studs employ the multiple insulation patterns with the rigid foam members illustrated in this present invention including but are not to be limited by other rigid or soft insulation materials being used to substitute the rigid foam as insulation materials in order to facilitate the creation of which consists of "active & inactive cavities" and the rigid foam members serve to sandwich the glass VIP thereof at least one of the 10 composite insulated vertical studs in this present invention are to be used as a plurality of vertical studs and placed as supporting and load bearing members for the wall panels in order to construct the sectional wall and the said 10 studs all bearing various unique configurations are all designed under one principal of short-circuiting the thermal transfer from one side to the other by means of zero "metal contact" and in conjunction with the effects of the multiple insulation patterns and each of these 10 said vertical studs having their opposite identical-galvanized-steel-structural counterpart-members" (IGSSCM) can be fastened together as one structure by means of using appropriate industrial adhesive or be screwed together at least with one OSB strip member to reinforce and maintain the integrity of the structural strength to become one piece and in addition with the said 10 composite insulated vertical studs formed by 2 IGSSCM can be fastened as one structure and therefore any "half' ones of the 10 stud-configurations formed by 2 IGSSCM can be mixed & matched with any one of each 9 different other halves of all the 2 IGSSCM to form as different configurations and the 10 multiples of the composite insulated vertical studs are not to be limited to the configurations of the ten illustrated configurations due to their uniqueness of being capable of creating additional mix & match multiple configurations in the present invention and at least one of the 10 composite vertical insulated studs in this present invention are to be illustrated & used as supporting and load bearing members for the wall panels to construct the sectional walls and the composite vertical studs may comprised of all or selective following; a) one obscured glass VIP of the multiple insulation patterns to be placed in-between as insulation materials of the vertical stud; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 b) at least one active forced air cavity of the multiple insulation patterns to be created by either rigid and or soft insulation materials; c) one galvanized steel sheet member to be placed in the forced air cavity at choice depending on requirements which is part of the multiple insulation patterns to be utilized to increase the R-value d) the thermal active forced air cavity created in studs with open ends are connected with other forced air systems in the same building structure; e) at lease one inactive cavity to be created within the studs by and between either rigid and or soft insulation materials with no forced air to channel through to form as part of the multiple insulation patterns and further the inactive cavities provide accesses to be utilized as passages for electrical wirings & plumbing fixtures; f) the flexible formation of the above multiple insulation patterns to be disposed in the studs are not be limited by their thickness/sizes and singularity/plurality and their orderly disposition of each other and extends to their usages as presented by the described & illustrated formation(s); g) a plurality of composite vertical studs having grouped openings on their bodies consisting of multiple insulation patterns; h) plurality of composite vertical studs having "no" openings on their bodies consisting of multiple insulation patterns; i) the configuration of the vertical studs illustrated in this present invention which specifications in terms of measurements of the width/length/height are not to be limited and/or restricted to certain specifications due to various building requirements between residential and commercial/industrial in order to yield the maximum effects. 9) The composite insulated building components cited in claim 1 wherein the formation of the top & bottom plates having two identical elongate 90 degree galvanized steel members inwardly placed in opposite upright positions and spaced apart at least one inch from AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 each other followed by having a composite insulated member consisting of 2 OSB strips members sandwiched and glued with a strip of rigid foam member placed in-between and fit snuggly and then screwed on the 2 "no contact" surfaces of the galvanized steel members to become one complete component with top & bottom plates functioning as claimed by constituting as part of the wall structures designed to "short circuit" the thermal transfer with no metal contact and to be used for load bearing walls or non-load bearing walls to be mounted on top and bottom of sectional walls to maintain the integrity of a sectional wall having multiple strategic openings along the bodies acting as passages to accommodate forced air flow in & out from opposite directions depending on configurations and specifications. 10. The composite insulated building components cited in claim 1 wherein the active forced air floor system comprises of main floor joists & exterior floor joists & interior floor joists of the invention and is also associated with other prior art floor joists to facilitate the "void spaces" beneath the sub-floor sheathing forming passages for in-floor active forced air flows hereby the active forced air floor system comprises of; a) the method & formation of the main OSB floor joists of this present invention wherein along its elongate OSB body having 2 galvanized steel members of which both fitted with a recess one mounted on the top edge and the other mounted on the bottom edge of an elongate main OSB floor joist body and the top galvanized steel member of it's both sides of the recess configured with a set of 2 outwardly facing back-to-back "C" slots sharing the same "top ledge" with the previously mentioned recess in between as one piece and on both inner walls of the "C" slots there are small openings on each side aligned through with the precut openings on the upper part of the OSB floor joist body and the bottom mounted galvanized steel member configured with 2 outwardly facing upright 90 degree flanges sharing the "bottom part" of the OSB floor joist body with the recess in between as one piece grooved-in/mounted on the bottom edge of the OSB floor joist body and large precut openings are also located on the mid-section along the elongate OSB body between the top and bottom galvanized steel members made ready for plumbing-pipes and electrical-wirings needs; b) the formation & the function of the interior floor joists consist of at least one OSB strips members forming as a floor joist body and further disposing two galvanized steel members of which one configured with a recess and a "C" slot on one side sharing the AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 same wall of the recess grooved-in/mounted at the upper edge of the OSB floor joist body and the other galvanized steel member with a projecting flange oriented to the same side of the "C" slot sharing the same bottom ledge of a recess grooved-in/mounted at the lower edge of the said OSB floor joist body and with upper & lower parallel projecting flanges positioned on the same side are designed functioning to anchor and embrace the main OSB floor joists cited in claim I0a to be arrayed in perpendicular position to the parallel arrayed main floor joists and; c) the formation & the function of the exterior floor joists consist of at least one rigid foam strip member being sandwiched-in with at least 2 OSB strips members formed as a composite insulated body and further having two identical galvanized steel members each configured with a projecting flange and a recess of which one recess grooved in/mounted at the upper edge and the other grooved-in/mounted at the lower edge of the composite insulated body and with aforementioned upper & lower parallel-projecting flanges placed on the same side designed to anchor and embrace the main OSB floor joists cited in claim 10a to be arrayed in perpendicular position to the parallel arrayed floor joists and; d) the functions and installment of the active forced air floor system associate with the main OSB floor joists cited in claim I Oa and described herein is by installing the sub floor sheathings on the arrayed laid-out main OSB floor joists while the "C" slots of the said main OSB floor joists are designed to facilitate the creation of the void-spaces directly underneath the sub-floor surface along and between the arrayed main floor joists by affixing thin sheet partition member on the lower ledge of the said "C" slots while sub-floor sheathing is installed thereon creating void-spaces for active forced air passages and then by directing active thermal forced air moving up through from one end of the floor joist reaching to the other end passing the openings on the sub-floor sheathings and on the bottom plates in which before connecting with the short-passages in the wall panels and functioning as active forced air in-floor heating wherein before that same air was emitted out to room atmospheres via air-registers associated with the short-passages installed above the baseboard and meanwhile other flow-paths of the same forced air flows from the void-spaces are flowing through passages in & from other wall panels and keep moving up in their flow-paths passing through the openings aligned with the lower part of the window structures and into the window sill plates then the forced air pushes into the openings functioning as forced air window defrosting AMENDED SHEET (ARTICLE 19) A A A WO 2009/086617 PCT/CA2008/001809 curtains all while other forced air flows in the void-spaces are being directed and rerouted perpendicularly to other passages to walls & windows via precut openings positioned in the said "C" slots on the upper part of the floor joists and as an additional claim the return forced air can be collected and be rerouted via rigid foam flow-guides installed underneath the sub-floor at the end of the main floor joists against the exterior side plates and the space there-beneath the partitioned void-spaces can be partitioned as well to become as a return-channel for air flows returning to the climate control units; (e) the void-spaces created on the bodies the prior art engineered "I" beam floor joists having top & bottom wood members both mounted on a OSB strip member as the main body and with sub-floor sheathings installed thereon and closed-off on the top wood member (approximately at least 1" in thickness) of the "I" beams and then by implementing multiple thin sheet members affixed on the face-down ledges of the top wood member of each floor joist then to be used as partitions create stretched-narrow spaces of the same thickness as the top wood members directly beneath the sub-floor and facilitates the claim that the void-spaces within can be utilized as in-floor active forced air passages by running active forced air throughout and be connected with various passages & openings with other systems in the present invention; (f) the void-spaces created from the prior art single metal "C" channel floor joists wherein with sub-floor sheet-members installed thereon and closed-off on the top-ledge of the single "C" channel floor joists and then by placing multiple thin sheet partition members affixed on the face-down ledges of the implemented long strip members (wood or foam of at least 1 inch thickness) on either side of each "C" channel using as spacers to space apart from the sub-floor sheet members to create stretch-narrow spaces/cavities beneath the sub-floor facilitating the claim that the void-spaces within can be utilized as in-floor active forced air passages by running forced air through and functioning as in floor heating and forced air window defrosting curtains; (g) the void-spaces created from the prior art back-to-back double metal "C" channel floor joists where with sub-floor sheet-members installed and closed-off on the top ledges of the back-to-back double "C" channel floor joists and then by implementing multiple thin sheet partition members affixed on the face-down ledges of the installed long strip members of at least one inch in thickness on either side of said double "C" channel using as spacers to space apart from the sub-floor sheet members thereby create AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 stretch narrow spaces/cavities beneath the sub-floor as void-spaces wherein it can be utilized as in-floor active forced air passages by running thermal forced air through functioning as in-floor heating and facilitate the forced air window defrosting curtains; (h) the void spaces created from the prior art timber wood floor joists where with sub floor sheet-members installed and closed on the top-ledges of said wood floor joists and with long strip members to be placed on the top edge on either side of said timber wood floor joist as spacers followed by affixing multiple sheet partition members on the face down ledges to space apart from the sub-floor sheet members thereby creating stretch narrow spaces/cavities beneath the sub-floor as "void spaces" where it can be utilized as in-floor active forced air passages by running thermal forced air through functioning as in-floor heating and facilitate the forced air window defrosting curtains; (i) the integrated formation and the multiple functions of the active thermal cavities in conjunction with forced air travel through the in-floor void-spaces between the floor joists placed directly underneath the floor sheathing for forced air passages functioning as active forced air cavities/channels/passages for in-floor heating or cooling and for the active forced air window defrosting functioning to eliminate condensations and as in wall forced ambient air vented into the room via registers on walls above baseboard level thereby furthering the claim of the function of eliminating cutting holes on floors for the floor air-registers and eliminate the destructions on floorings and serving to maintain the floor bodies integrity; 11. The composite insulated building components cited in claim 1 wherein the formation of the active forced air window system consists of multiple active forced air cavities/passages and adding a single un-obscured glass sheet associated with existing prior art (argon gas filled double or triple pane) window structures applicable to all styles and types of windows including & not to be limited the casements & sliders thereby creating an active forced air window insulation and a forced air window defroster functioning simultaneously as one active forced air window system comprises; a) the method & formation of the window active forced air system comprises of 2 separate active forced air flow-paths wherein a single sheet of an un-obscured glass is installed on the interior side of said prior art double pane window of which then creates AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 a triple pane window setting with a thin hollow space utilized as the "active forced air cavity/passage" where in-between exists 2 sets of positioned in-line precut openings aligned perpendicular with one set facing-up on the lower window frame/sill plate which connected with the forced air passages of the lower wall panels and the other set facing down on the upper window frame/sill-plate which connected with the forced air passages in the header & the upper wall panels and of those 2 sets upper & lower precut openings both being in-lined within the said "active forced air cavity/passage" and by running active forced air through the said active forced air cavity/passage to create the active forced air insulated window while another line of positioned precut openings are on the outer-side of the previously mentioned single glass sheet located on the outer part of the lower window frame/sill-plate towards the room-interior and with precut openings receiving active forced air flows which are connected with the active forced air passages in the wall panels under the window frame/structure in which also further connected with the active forced air passages from the "floor system" that runs underneath the sub floor in the "void space" along the floor joists and it is distinguished & separated not being as the same forced air flow that are running simultaneously through in the active forced air cavity/passage in between the prior art double pane window and the single glass sheet and as this active forced air flow is from the "wall system" and; b) the method of directing streams of active forced air flow-path to and pass the window system functioning as the active forced air flow from the wall system cited in claim 11 a to insulate a window and connected to other systems wherein one of the active forced air flow travel upward through the passages in the wall panels from a lower floor level to move up through the rigid foam flow-guides disposed between the main floor joists passing the aligned openings on the floor sheathing then sill plates and into the passages in the lower wall panels under the window then continuing to pass through the lower window sill-plate/frame into the active forced air cavity/passage created in between the prior art window and the added piece of un-obscured glass sheet then on its path upward into and through the openings on the upper window frame/sill-plate into the passages within the header member & the upper wall panels wherein the active forced air travels into the cavities/passages in the "forced air ceiling system" for a one floor bungalow building or keep on moving upward through passages into the upper floor level for 2 storey building through rigid foam "flow-guides" in floor joists and/or continue into another "upper floor wall system" and then move into a connecting "ceiling active forced air system" of a 2 storey structure; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 c) the functions of the active forced air passages of a window defrost system uses a separate stream of forced air flow in the floor system which travel horizontally in the void-spaces underneath the sub-floor between the floor joists reaching up and passing the precut openings on the floor sheathings and the bottom plates then moving up into the narrow passages under the surface of the wall panel beneath the window and of such narrow passages are actually narrow "recesses" crafted out and disposed on the very surface of rigid foam members on the wall panels created when installed drywalls closed-on the surface of the wall panels them become the narrow passages and the streams of forced air flows move along upward into the said narrow passages then into the openings on the sill-plate/frame of the lower part of the window structure therein being forced out from the openings via air-flow defectors which are disposed inline on the window frame functioning pushing the forced air flow upward through and moving close to the surface of the single glass pane then dissipate into the room atmosphere and at the same time behind the single pane un-obscured glass sheet is the other active forced air stream from the wall system running in the cavity functioning simultaneously as active forced air flow to insulated the window; 12. The composite insulated building components of the forced air basement wall system cited in claim 1 wherein the active forced air passages can be directed horizontally and vertically within the wall panels and the active forced air floor system in the basement concrete slab floor can be easily connected with the basement wall system of which comprises of; a) a plurality of composite insulated vertical studs having openings on the bodies to facilitate the flow-through of the active forced air and these openings can be strategically grouped along separately on the lower and/or upper part of vertical stud bodies to facilitate multiple horizontal forced air flows and in addition a series of studs without openings on their bodies are also used to block and/or reroute the flows from horizontal flow-passages to vertical flow-passages functioning on the same sectional walls or connected with other sectional walls of the same building structure; b) a plurality of arrayed composite insulated vertical wall panels and multiple composite insulated vertical studs of which only some have coordinated grouped openings cited in claim 8 employ partial or all of the multiple insulation patterns of this AMENDED SHEET (ARTICLE 19) lip~ WO 2009/086617 PCT/CA2008/001809 present invention forming composite sectional basement walls comprised of at least one inactive cavity and at least one active forced air cavity where multiple horizontal forced air flows can be created by implementing parallel partition strip-members separating each selected vertical cavity in the vertically-run wall panels into upper/middle/lower sections connecting between panels by means of coordinating the studs with grouped openings and studs without openings and also be able to implementing various lengths or sections of partition strip-members affixed horizontally in the active forced air cavities to manipulate and coordinate horizontal and vertical forced air movements as needed within the cavities of vertical panels; c) a plurality of top and bottom plates to be installed as part of the sectional wall are configured the same both having collective multiple openings connected with the cavities of wall panels to facilitate forced air flows travel upward or downward into wall panels from both directions; d) the basement floor active forced air passages are created underneath the surface of the concrete slab by means of implementing various types of tubing or piping forming a network for the movements of the active thermal forced air flows connected by an auxiliary climate control unit and the forced air movements in the tubing or piping network are not limited to only functioning underneath the concrete slab but can also be connected with the air passages within the basement wall panels by means of extending and connect the tubing or piping network into the basement wall panels via the openings in the bottom plates as cited in claim 12c; 13. The composite insulated building components cited in claim I wherein the active forced air system in this present invention which is to be used as forced air thermal blanket/envelope to circulate forced hot and cold air in cavities & passages & channels & openings & piping & tubing within any wall/ceiling/floor/window wrap around partial or entire building structure and be used in any type of composite or non-composite wall structures for residential or commercial/industrial buildings running hot or cold temperature forced air in the cavities and/or having room temperature forced air to carry away or blocking unwanted temperature in the cavities within walls to regulate and maintain desirable room temperate and increase R-value comprises of; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 a) an active forced air system in conjunction with inactive cavities to be placed within any types of walls including and not limited to composite insulated wall panel depicts in this present invention and can be utilized as insulation value and for regulating climate control as a thermal blanket/envelope covering partial and/or entire building including all floors and all ceilings; b) the creation of the active forced air cavities in this present invention including other soft and or rigid insulation materials to be used and is not limited as illustrated by assembling sandwiched rigid foam sheet members spaced apart with sealed conduits bonded on edges with foam strips and; c) the formation of the active forced air system to achieve high insulation values and of it's cavities & passages including and are not limited to any specific types of insulation materials and/or structural materials either soft or rigid that are being used to create the active forced air cavities such as including but not to be limited by using rigid foam & spray foam & fiber glass & lose cellulose & obscured glass sheets and any other forms of structural materials including but not limited their forms in sheets or in blocks or in layers or in cubes or in corrugated-sheet forms to form any structures in order to create & embrace the active forced air cavities/passages/channels/openings/hollow spaces/paths and by running active forced air through for the purposes of regulating the temperatures of hot or cold and for increasing the insulation value in any building structures; d) the functions of the active forced air system is for the purpose of regulating hot or cold climate control in ceilings & in walls & in any types of floors and for in-floor heating to utilize the void-spaces under the floor sheathings and applying active forced air system as forced air window insulation and forced air window defrosting to eliminate condensation and facilitate to eliminate on-floor air registers and eliminate cutting holes on floorings for that purpose; e) another active thermal cavity in conjunction with active forced air travel through the created in-floor void-spaces between floor joists directly underneath the floor sheathing as forced air passages to be used as active thermal forced air cavities/passages forcing in-wall ambient air into the room via air registers installed on walls above the baseboards; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 f) the active forced air cavity not to be limited to a single cavity and applies to multiple cavities of forced air flows and not to be limited by any specific or certain temperature degree settings within walls and ceilings and floors whether positioned in single formation or in multiple formations due to various applications & requirements; g) the formation of the space created for the active forced air cavities are not to be limited by specific width measurements or by specific cubic volume depending on application requirements and; h) the active forced air system is to be disposed and configured either close to the interior or exterior side of walls to yield the most desirable insulation effects depending on applications and requirements for residential or commercial/industrial buildings for the purpose of regulating temperatures and/or climate controls; i) the active forced air system used in direct conjunction with the existing prior art for corrugated metal components to be used in ceiling & wall structures of which the void spaces on one side or on both sides of the corrugated configuration are to be utilized as the active thermal forced air paths and not to be limited on any wall & floor corrugated structures for commercial and/or for industrial buildings. j) the active thermal forced air paths that travel through channels or openings or cavities or passages or piping or tubing systems created within concrete slab floors to provide in-slab thermal active forced air heating in order to eliminate any form of cumbersome & expensive in-slab liquid being used as the in-floor heating system and be replaced with active forced air; k) the active forced air system in this present invention is not to be limited to the pattern of the air flow movements including either in the pattern of horizontal or vertical or in the combined patterns of horizontal/vertical within walls & ceilings & floors; 1) the forced air cavities/openings/channels/passages constitute a network of air flow paths of it's own within the roof & attic & ceiling & all walls & floors systems apply to the residential & commercial & industrial building structures to facilitate the elimination of cumbersome prior art (conventional existing) sheet metal ducting systems through the AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 inter-connected network of the created active iorcec air cavities/openings/channels/passages/paths and; m) the source of thermal/cool active forced air can be separated or directly generated from auxiliary climate control unit(s) and is not limited to be generated also from the main climate control system(s); 14. The composite insulated building components and assembly equipment cited in claim 1 wherein the inactive cavities comprise; a) the creation of the inactive cavities in this invention is not limited as illustrated by assembling sandwiched rigid foam sheet members spaced apart with sealed conduits bonded on edges with foam strips or sealed with membranes on edges to create inactive cavity or multiple-cavities to become as one single unit/panel with "no forced air" to channel through and hereby further to claim the single cavity and/or multiple cavities within a single panel to be utilized as in-wall and in ceiling and in-structure insulations to be positioned close to the interior or exterior side of walls and not limited to single cavity or multiple cavities created within any wall structure and created by any type of formations or rigid or soft materials nor limited to the cubic-volume space or sizes to yield insulation value or regulate temperatures related to climate control for any building structures; b) the other function of inactive cavities is to allow for the passages of electrical wirings and cables and plumbing and to be positioned in any building structural members forming within any composite wall panel acting as a mean of insulation value; 15. The composite insulated building components cited in claim 1 wherein the formation of the active forced air cavities associated with galvanized steel sheets is to create a forced air heat sink insulation effect for improved insulation values in the walls of the building structures including and not meant to be limited to the claims of other conductive materials being used to create the same active forced air heat sink insulation effect associates with such as aluminum/tin-foil sheets and other conductive materials made with ceramic or glass and/or with clay compounds/elements and including but not to be limited by the use of galvanized steel AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 sheet to create heat sink effect that is associated with active forced air cavity/cavities wnere an or in-part are to be utilized to yield insulation value or regulating temperatures related to climate control for any partial and/or entire building structures and; a) another formation of a single active forced air cavity created by and in-between insulation materials including but not to be limited to rigid foam sheet members spaced apart to create the said cavity inserted with at least a single sheet of galvanized steel installed to separate the said cavity in 2 halves thereby forming 2 active forced air cavities acting as dual active forced air cavities associated with a single galvanized steel sheet in-between for the purposes of distributing thermal/cold forced air through and acting as multiple insulation barriers to yield the desire R-value; b) another formation of a single cavity created by and in-between insulation materials including but not be limited to rigid foam sheet members installed with 2 spaced apart sheets of galvanized steel each to be bonded on the surface of the opposite sides of the insulation materials which are the interior opposite walls of the single cavity forming a forced air cavity between 2 spaced apart galvanized steel sheets for the purpose of distributing thermal/cold forced air through to affect the temperatures on galvanized steel sheets bonded on both sides of walls of the insulation materials to yield insulation value; c) yet another formation within one insulated wall panel consists of multiple forced air cavities of at least two cavities with each cavity individually to be disposed/inserted with a single galvanized steel sheet in-between to separate each "individual cavity" and therefore made into 2 halves then herewith each half becoming one cavity and then repeated so on & so forth to multiply the number of cavities by inserting a galvanized steel sheet in between of each single cavity forming multiple forced air cavities with the insertion of multiple galvanized steel sheets one for each individual cavity all within one wall panel/structure creating multiple forced air heat sink insulation effects by distributing thermal/cold forced air through to yield desire R-value; d) yet another formation of a single forced air active cavity created by insulation materials with two sheets of galvanized steel placed/inserted in-between which are spaced apart when inserted to separate the single cavity into 3 halves thereby forming 3 forced air active cavities within the original width and size of the single cavity and by AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 distributing thermal/cold forced air through it creates multiple force air neat sm1K insulation effects to yield desire R-value; 16. The composite insulated building components cited in claim I wherein the active forced air cavities/passages/openings/channels facilitate and constitute various active forced air flow-paths networking with each other and be individually and strategically connected with selected forced air system(s) of the roof/ceiling/all walls/all floors/all windows wherein the flow-motions of their directions are flexible including and not limited to upward/downward and horizontal/vertical patterns to accommodate various building structural requirements of which various active forced air flow-paths comprise of; a) the flexibility of the forced air flow-motion built within at least a single assembled composite insulated sectional-wall consists cavities/passages facilitate at least 2 separate active forced air flow-paths moving simultaneously in opposite-flow-directions thereby one moving vertically upward while the other returning-forced air moving vertically downward therein-merging into the designated wall panels of the same assembled sectional wall aligned with the boxed-out column/space for return forced air flows moving downward returning to the auxiliary climate control unit; b) the flexibility of the forced air flow-motion built within at least a single assembled composite insulated sectional-wall consists cavities/passages facilitate at least 2 separate active forced air flow-paths moving simultaneously in horizontal-opposite-directional flows thereby one moving horizontally through partitioned lower-section of the wall panels while the other returning-forced air moving horizontally to opposite direction therein-through partitioned upper-section of the same sectional-wall merging into the designated wall panels in the mid-section of the same assembled sectional wall aligned with the boxed-out column/space for return forced air flows moving downward vertically returning to the auxiliary climate control unit; c) the flexibility of the forced air flow-motion built within at least a single assembled composite insulated sectional-wall consists cavities/passages through along partitioned lower and upper sections facilitate at least 2 separate-horizontal flow-paths on arrayed wall-panels and be rerouted individually sharply moving vertically upward or downward through designated partitioned vertically-run wall-panels and at least one horizontal AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 flow-path therein-merging into the designated wall panels in the mid-section o1 ine same assembled sectional wall aligned with the boxed-out column/space for returning forced air flows moving downward vertically returning to the auxiliary climate control unit; d) an active forced air flow starts from the auxiliary climate control unit in concrete basement floor following the flow-path travel through a network of tubing/piping web installed under the surface of the entire concrete slab then returning to the auxiliary heater; e) another active forced air flow starts from the auxiliary climate control unit in concrete basement floor following the flow-path traveling through a network of tubing/piping web under the surface of the entire concrete slab then continue moving along the flow-path which is connected with the wall system via the openings on the bottom plates travelling up to the wall panels of the basement sectional walls then continue it's flow-paths moving to other systems eventually returning to the auxiliary climate control unit; f) another active forced air flow starts from the boxed-out wall (as the north principle wall hereby is necessary for a clearer oriented depiction) wherein the auxiliary climate control unit is situated in the boxed-out space in the basement and the forced air flow path departing from the boxed-out space divides into 2 separate forced air flow-paths simultaneously moving horizontally to opposite directions of the said basement "north principle wall" through the opposite partitioned "lower" sections reaching to both opposite ends of said basement "north principle wall" passing the grouped openings on both the corner-studs then through and exit into the partitioned lower sections of the "east & west walls" along to their wall-ends then reaching through the grouped openings on both of their corner-studs into the "south wall" which is directly opposite to the "north principle wall" therein this south wall has no horizontal partitions wherein the 2 forced air flow-paths meet and to further illustrate that the 2 active forced air flows have traveled in a pattern of going around 2 complete half squares simultaneously since separately departing from the boxed-out space and joint at the mid point at which the 2 active forced air flow-paths merged and continue their paths moving upward passing through the flow-guides under the main-floor surface reaching up to the main-level "south wall" and keep moving upward into the flow-guides under the upper-floor and then into and through the upper-level "south wall" reaching the openings at the top of AMENDED SHEET (ARTICLE 19) WO 2009/086617 .PCT/CA2008/001809 the wall panels then forcing the flows into the cavities/passages witnin me ceiling s drop-down section then moving across the ceiling channeled downward through the designated return-wall-panels on the upper-level "north principle wall" and moving further downward into the flow-guides under the upper-floor and then travel into the main-level "north principle wall" designated return-wall-panels into the flow-guides under the main-floor returning back to the auxiliary climate control unit in the "north principle wall" in the basement boxed-out space; g) another active forced air flow starts from the boxed out "north principle wall" where the auxiliary climate control unit is situated in the boxed-out space in basement and the forced air flow departing the boxed-out space divides into 2 separate active forced air flow-paths moving horizontally to opposite directions along the partitioned opposite "middle" sections of the "north principle basement wall" reaching to both of their opposite corners of both the wall-ends wherein passing the grouped openings on both the opposite corner-studs through and exit into both of their partitioned "middle" sections of the "east & west walls" then moving along all the way to their wall-ends on each opposite side then the 2 opposite moving forced air flow-paths are blocked by the corner studs which have no middle grouped openings before reaching through the "south wall" around the corners therefore the 2 opposite active forced air flow-paths be rerouted can only move freely upward into the flow-guides in the floor joists under the main-floor into and passing the "east & west" main-level walls and moving upward into the flow guides under the upper-floor into the upper-level "east & west" walls and through openings simultaneously forcing into and across the ceiling's drop-down cavities/passages and then be redirected downward and merging into the designated return-wall panels of the north principal wall returning to the auxiliary climate control unit; h) another active forced air flow starts from the basement "north principle wall" where the auxiliary climate control unit is situated in the boxed-out space in basement and the active forced air flow departing the auxiliary climate control unit is divided into 2 separate flow-paths moving horizontally in opposite directions along the partitioned "upper" sections of the "north principle wall" and these 2 separate active forced air flow-paths reaching the end-corner studs at both opposite ends of the "north principle wall" thereat be blocked by their end-corner studs of both on either opposite side (with no upper grouped-openings) thereby forcing the 2 opposite active forced air flow-paths AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 moving upward into the flow-guides under the main-floor into and pass the "nortn principle " main-level wall and continue moving upwards into the flow-guides under the upper-floor into the "north principle " upper-level wall and through openings into and across the designate-ceiling panel paralleled to the "north principle wall" in the cavities/passages of the ceiling drop-down section and then be redirected downward merging into the designated wall panels in the mid-section of this north principal wall aligned with the boxed-out column/space for returning forced air flows moving downward returning to the auxiliary climate control unit; i) another active forced air flow starts from the basements "north principle wall" where the auxiliary climate control unit is situated in the boxed-out space in basement and the active forced air flow departing the boxed-out column/space networking with at least one horizontal boxed-out column-space stretch across the building structure having openings connected through the exterior floor joist into the "void spaces" of the main floor joists via flow-guides; j) the flexibility of the forced air flow-motion in the boxed-out system within the networking vertical boxed-out spaces facilitate & contribute the flexibility to extend the forced air flow-paths and connect to the wall panels of the attached portion of the sectional wall of each floor/level which is located in-front & covered by the vertical boxed-out column; k) the flexibility of the forced air flow-motion in the boxed-out system within the networking vertical boxed-out column/spaces facilitate & contribute the flexibility to extend the forced air flow-paths and connect to the cavities/passages in the drop-down ceiling of the attached "top" portion of the sectional wall which is located in-front & covered by the vertical boxed-out column; 17. The composite insulated building components cited in claim I wherein the obscured & un-obscured glass vacuum insulated panels VIP are comprised of; a) the method and the formation of the "obscured" glass vacuum insulated panel herein known as glass VIP consists of two or three pieces of obscured glass sheets stacked and spaced apart to form single or double thin hollow vacuum cavity/cavities assembled AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 together with thin glass strips to form the supporting edges and scattered glass pellets to form supporting points in-between the cavity/cavities of the spaced glass sheets and then a prior art programmable heating apparatus is employed mechanically going around all four edges by applying appropriate temperature of heat and through this simple process the entire unit as a whole will be sealed seamlessly with the SME glass material except the "nipple(s)" that has a small opening readily for the vacuum treatment-process thereafter to be made as a double pane or triple pane "obscured" glass VIP and; b) the usages and functions of the obscure double and triple panes glass VIP included being used as vacuumed-insulation members and be as part of the composite insulation wall panel in-walls and in ceiling and in-studs and also to be used as an obscured glass VIP feature-wall and; c) the method and the formation of the "permanent vacuumed" un-obscured double panes glass VIP consists of two pieces of un-obscured glass sheets stacked and spaced apart to form a single thin hollow space/cavity sandwiched together with 4 thin glass strips to form the supporting edges and scattered glass pellets to form supporting points in the space/cavity between the glass sheets and further on the bottom edge/strip a glass nipple (for vacuum process) is installed by utilizing prior art programmable heating apparatus that is employed mechanically going around the four glass strips/edges by applying appropriate temperature of heat and through this simple process the entire unit as a whole will be sealed seamlessly with the clear glass materials and all melted together as one piece except the "nipple" that has a small opening readily for the completion of the vacuum-process of which by employing the prior art process thereafter a "permanent vacuumed" double pane un-obscured glass VIP is made and; d) the method and the formation of the "repeat-at-will" on site vacuum process facilitate by utilizing un-obscured" double panes glass VIP which consists of 2 pieces of un-obscured glass sheets spaced apart and sandwiched together to form a single thin hollow space/cavity with 4 thin glass strips to form the supporting edges and scattered glass pellets to be the supporting points within the space/cavity between the glass sheets and on the bottom edge/strip a protruding glass "fluid-drain" for facilitating the repeat at-will vacuum process is installed and a prior art programmable heating apparatus is employed mechanically going around by applying appropriate temperature of heat on four edges/strips and through this simple process the entire unit as a whole will be sealed AMENDED SHEET (ARTICLE 19) lip WO 2009/086617 PCT/CA2008/001809 seamlessly by heat with clear glass material and all melted together as one piece except that the protruding glass "fluid drain" has an opening for the connection of a prior art mechanical apparatus comprising of a fluid pump & a programmable flow split-valve & a control device & a thermal fluid reservoir with dual containers having one filled with light color fluid and the other filled with dark color fluid and; e) the method and the formation of the dual vacuum functions generated within one un obscured triple pane glass VIP of which one is the "permanent" glass VIP and the adjacent other is the "repeat-at-will" on site glass VIP all are facilitated by utilizing an "un-obscured" triple pane glass VIP which consists of 3 un-obscured glass sheets stacked and spaced apart sandwiched together to form a double thin hollow spaces/cavities with 4 + 4 thin glass strips to form the all-around supporting edges with scattered glass pellets to be supporting points within the double spaces/cavities between the 3 clear glass sheets and then a prior art programmable heating apparatus is employed mechanically going around by applying appropriate temperature of heat on all 4 + 4 thin glass strips/edges and through this simple process the entire unit comprising of 2 side by side adjacent bodies/cavities as a whole will be sealed seamlessly by heat with clear glass materials and all melted together as one piece except on both bottom edges of the both adjacent glass bodies there be one glass "nipple" installed on one of the two bottom-edges to be made ready for the "permanent" vacuum process and on the other adjacent bottom edge a protruding glass "fluid-drain" for "repeat-at-will" vacuum process is also installed and this "fluid drain" is to be connected with a mechanical apparatus comprised of a fluid pump & a programmable flow split-valve & a control device & a thermal fluid reservoir with dual containers and thus an "un-obscured" triple pane glass VIP unit is formed of which consists of side by side adjacent bodies with dual vacuum functions in addition one with thermal fluid window treatment; f) the function and usage of the "repeat-at-will" vacuum process facilitate by utilizing the un-obscured double pane glass VIP along with the thermal fluid window treatment thereby must first be filled to full capacity of the created space/cavity with appropriate type of fluids including but not limited to thermal fluid by a programmable pumping device and withdraw the pumped-in fluid completely then this fluid returning to it's designated reservoir to create a pressurized vacuum condition in the cavity to provide vacuumed condition as insulation value and as an additional function a thermal fluid of choice either lighter or darker color can be pumped back to fill the vacuumed AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 space/cavity wherein lighter color fluid is for minimum privacy and darker coior umu i for maximum privacy and also providing an insulated window treatment usage including and not limited as insulated window-wall structures and associated with the function to perform "repeat-at-will" vacuum process on site and ; g) another functions and usages of the un-obscure double panes glass VIP also can be used by adding a clear glass sheet spaced apart to it's double pane formation thereby creates a forced air cavity with two additional functions of which one is by running active forced air through within the cavity to become forced air insulation & on the other side of the said clear glass sheet towards the interior room space another active forced air flow rising up from the window sill via a deflector directing the forced air flow adhere to the glass surface functioning as active forced air curtain; h) the functions and usages of the un-obscure triple panes glass VIP having dual bodies/cavities facilitated to perform dual vacuum functions of which one is a permanent "un-obscure" glass VIP used as for vacuumed-insulation window and the other cavity associated with a fluid drain thereby must first be filled to full capacity of the created space/cavity with appropriate type of fluids including but not limited to thermal fluid by a programmable pumping device and withdraw the pumped-in fluid completely then returning this fluid to it's designated reservoir to create a pressurized vacuum condition in the cavity therein to provide vacuumed condition as insulation value and as an additional function a thermal fluid of choice either lighter or darker color can be pumped back to fill the vacuumed space/cavity wherein lighter color fluid is for minimum privacy and darker color fluid is for maximum privacy and also providing an insulated window treatment usage including and not limited as insulated window-wall structures and associated with the function to perform "repeat-at-will" vacuum insulation process on site and; i) another function and usage of the triple pane un-obscured glass VIP with their two opposite-sided cavities as one unit which can be rotated in the fashion that the permanent vacuum cavity facing the interior rooms while the opposite-side of the forced fluid "repeat-at-will" cavity to be used facing the exterior side and this setting is readily to be utilized for the fluids carrying away the unwanted temperature to a prior art heat exchanger if needed and the said rotation is vice versa; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 j) another function of the obscured & un-obscured glass VIP hereoy to claim LM technologies of the permanent & repeat-at-will vacuum processes including for all windows and window feature-walls applications and not meant to be limited applying to all doors to be utilized for temperature & climate control to achieve desire insulation value. 18. The composite insulated building components recited in this present invention wherein the existing (prior art) installation of the corrugated metal ceilings & wall panels currently widely used as interior parts of roof/ceiling/wall structures creating corrugated spaces on both sides of the exterior and the interior hereby to claim these never used corrugate "void spaces" to be utilized efficiently by implementing sheet material members with minimum insulation value installed to cover these exterior & interior corrugate "void spaces" and by running thermal/cool forced air through to create active thermal/cool forced air paths integrated into these corrugated type of roof/ceiling and wall structures to provide additional insulation values which have been neglected therefore these industrial "void spaces" are transformed and utilized for better insulation values; a) the existing interior "void spaces" for existing building structures by implementing a plurality of sheet material members including but not limited to soft or rigid insulation materials installed on the interior side of the existing corrugated metal ceiling panels create "void spaces" thereby running active forced air through to create thermal/cool forced air insulation; b) the interior "void spaces" for new building structures by implementing a plurality of sheet material members including but not limited to soft or rigid insulation materials installed on the interior side of the corrugated metal ceiling panels create "void spaces" thereby running active forced air through to create thermal/cool forced air insulation; c) the exterior "void spaces" for new building structures by implementing a plurality of sheet material members including but not limited to soft or rigid insulation materials installed on the exterior side of the corrugated metal roof panels create "void spaces". AMENDED SHEET (ARTICLE 19) 131 WO 2009/086617 . . . PCT/CA2008/001809 19. The composite insulated building components recited m this present imvuntiu wherein the functions & the implementation comprise of the inactive cavity & the active forced air flows running in-walls & in-ceilings & in-floors & in-roofs & in-windows along with the obscured & un-obscured glass VIP to produce unprecedented energy efficiency for commercial & industrial buildings thereby transiting from active heating mode to passive heating mode made possible by facilitating and utilizing the setting of each level has it's own forced air system of which activated by it's own independent heating/cooling climate control units for individual level for commercial & industrial buildings to significantly reduce the capacity and or environmental impacts of the conventional gigantic climate control systems along with the cumbersome net-worked sheet metal ducting systems in terms of energy consumptions and freeing up more useful spaces; a) the active forced air system for each individual level for the commercial & industrial building structures independently provides wrap around thermal blanket in which the active forced air flow-paths moving through in-floors & in-walls & in-windows & in ceilings then returning to the independent climate control unit through disposed cavities/passages/tubing/piping for each individual floor/level; b) the active thermal forced air flow leaving the independent climate control unit of each individual level starting it's flow-path going in-concrete-floor tubing & piping warming up the concrete floor then moving along and up the in-windows passages and the in-walls passages then forced into the in-concrete-ceilings (concrete slab) tubing & piping therein warming up the concrete ceiling slab and the said process repeat itself in every level and of it's forced air flow generated by it's independent climate control unit and at the same time beyond & above the ceiling of the same immediate concrete slab is the flooring of the upper level of the said (concrete slab) which separates the lower & upper level and then another independent climate control unit of the upper level circulate active thermal forced air flow & warming up the same in-concrete-floor via tubing & piping therefore the said same structural (concrete-slab) serving as the ceiling for the immediate-lower level and also serving as the flooring for the immediate-upper-level both are simultaneously heated up by 2 separate independent active forced air flows from 2 independent systems of their own floor of which one is independently for the lower level and the other is independently for the upper level so on and so forth for multi-storey buildings to create concrete heat sink effect for each "in-concrete ceiling/floor" slab; AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 c) a plurality of the active forced air flows running through the ceuimg via om, tubing or piping disposed in the concrete ceiling/floor layer in addition including but not limited to the active forced air flows running through the cavities which are installed attached to the lower part of the concrete slab as ceiling active forced air cavities created by implementing rigid or soft sheet insulation materials attached to the concrete slab to create the ceiling active forced air passages/cavities; 20. The composite insulated building components cited in claim I wherein the boxed-out space in the basement is designed & created by it's cubic volume space with an off-the-floor square where the boxed-out space is used to accommodate the climate control units and the electrical panel and wiring and the plumbing hot water system all together are to be relocated and consolidated within the boxed-out space freeing up more usable and desirable basement development area with no obstructions to the floor-square and to eliminating the conventional cumbersome ducting system and to simplify the plumbing routes all in complement to the insulated vertical column boxed-out spaces and the insulated horizontal boxed-out spaces forming a network of spaces to accommodate and strategically connect with all the other active forced air systems of the present invention such as roof/ceiling/wall/floor systems to facilitate the flexibility and coverage of the forced air passages networks and; 21. The composite insulated building components recited in claim I wherein basement boxed-out column space networking with the vertical & horizontal boxed-out column comprise of; a) the aligned vertical column & horizontal column boxed-out spaces are structured in conjunction with the basement boxed-out space as part of the outer-part structure attached to the wall structure with strategic openings for forming a network of spaces which also applies to multi-level buildings and in addition to multi-level single houses and consolidate the plumbing piping & hot/cold water lines & electrical wirings to be extended & routed vertically and horizontally to specific spots through openings and spaces into the main floor joists for the ease of installation and further contributed to eliminate the conventional cumbersome and bulky sheet metal ducting systems contrasting the usage of the active forced air systems which provides in-ceiling and in AMENDED SHEET (ARTICLE 19) WO 2009/086617 PCT/CA2008/001809 walls and in-floor forced air flows utilizing passages/openings/channels/UVIiv anu u spaces; b) the vertical & horizontal column multi-level boxed-out spaces constructed as the insulated outer-part structures attached to the main wall structure and the vertical column extended and aligned perpendicular with the basement boxed-out space cited in claim I and then networked with the horizontal boxed-out column on each floor level aligned parallel at the same level along with floor joists having strategically connected openings functioning & accommodating outward and inward active forced air passages connected from the auxiliary climate control unit(s) in the basement boxed-out space also provide passages for the active thermal forced air to travel & circulate to ceiling & walls & floors & windows systems by means of networked openings/passages/cavities/piping/channels & void spaces then returning to the auxiliary climate control unit(s) and further to claim that such arrangement is readily to implement including but not meant to be limited to have the climate control unit(s) to be disposed on individual floor/level within the space of the vertical boxed out column; 22. The composite insulated building components recited in this present invention wherein the hidden drain water system comprises of: a) a rain gutter and eve system positioned at the bottom of the roof line and a drain channel to receive rain water from drain recesses and transfer it to down pipes; b) at least one hidden down pipe leading from gutter and extending downward through and built within the corner therein of 2 walls jointed for any building structure and the down pipe is double piped to insure no leakage; c) wherein all drain recesses and drain channels and down pipes including and not meant to be limited either in rectangular or in circular shape to accommodate the corner space where 2 walls joint. AMENDED SHEET (ARTICLE 19)