Typically roofs are assembled on site. Walls are assembled and the rafters and other structure are assembled to form a complete roof. This is also true for glazed roof systems.
Glazed roof systems are used to form various types of roofs. These can include Georgian-style, conservatory-style and lean-to roofs. Glazed roof systems include panels supported between adjacent rafters. The rafters are supported at their upper end by a variety of structures such as a hip beam, a ridge beam, a wall plate or the like. At the opposite end, the rafters are supported by an eaves beam. This is a metal beam that has a structure adapted to support the rafter and form a seal at the lower end of the panels. The glazing is designed to prevent air and water ingress.
These units are all typically constructed on site because the eaves beam must be attached to the wall header prior to the rafters. The rafters in turn are fastened to the eaves beam with the glazing panel fastened to the rafters and hip beam. This on site construction is problematic simply because it is very labor intensive requiring a great deal of time to ensure that everything is properly installed to prevent leakage. Even with relatively small roofs, such as bay window roofs, on site fabrication is required.
It is an object of the present invention to provide a construction method which facilitates assembly of a roof structure prior to attaching it to a wall structure. It is an object of the present invention to provide an eaves beam which is easier to install and allows for pre-assembly of a roof prior to being attached to a wall structure.
Further, it is an object of the present invention to provide such an eaves beam which can be installed by inserting fasteners from the top of the supporting wall as opposed from underneath the supporting walls.
Further, it is an object of the present invention to provide an eaves beam which is more suited for a wide range of supporting walls, i.e., wood, masonry and the like.
The objects and advantages of the present invention are provided by a multi-piece eaves beam. The first lower portion is adapted to rest on a supporting wall and permits a screw to be inserted from the top of the first member through the first member into the wall structure holding it in position. An upper section of the eaves beam is then placed on the lower section and mates with the lower member. The upper member of the eaves beam is then screwed to the lower member through the side walls. This drastically improves installation efficiency.
With this construction, the roof can be pre-assembled at the factory with the hip beam or the like, rafters and upper section of the eaves beam all pre-assembled with the glazing panels attached and sealed. The preassembled roof is lowered down onto the lower section of the eaves beam which are attached to the header of a wall. This provides the efficiency of factory assembly while at the same time allows for sizing for a particular job. Because these roof sections are so light, a 10′×12′ section can be easily placed on a roof by two or three individuals without the use of cranes or the like. Further, this is well suited for the prefabricated roofs to cover bay windows.
The upper member of the eaves beam can have an upper trough member which collects moisture and channels that water to the exterior of the building thus reducing accumulation of moisture inside the walls of the structure. Further, this structure is much more versatile than a one piece system. If a particular type of wall such as a masonry wall requires modification of the eaves beam, only the lower section needs to be changed and the upper section will remain the same. Further, the eaves beam can be formed from more than two sections if desired.
The objects and advantages of the present invention will be further appreciated in light of the following detailed drawings and descriptions in which:
As shown in
As shown in
The eaves beams in turn are supported by a wall structure 29. The wall structure 29 is exemplary and can be a variety of different wall structures including a masonry structure, two by four wood structure, metal structure, or the like. As shown in
This base member 30 includes a plurality of feet 34 extended from base plate 36. It also includes grooves 38 and 40 which are designed to accept trim members 96 and 98. Extended up from the base plate 36 are inner and outer side walls 42 and 44. Upper portions 46 and 48 of side walls 42 and 44 are bent inwardly towards each other. The base walls also include a plurality of stiffening ridges 50.
The top member 32 includes an inner wall 52 and an outer wall 54. The walls 52 and 54 include lower leg members 56 and 58 which rest on base plate 36 and are spaced slightly outwardly from the walls 42 and 44 respectively of base member 30. The top portion further includes a downwardly sloping wall 60 which extends from inner wall 52 to outer wall 54. Inner wall 52 includes a plurality of barbed members 62 which are adapted to accept plastic trim 94.
The upper surface 64 of top member 32 includes a trough 66 which has a plurality of holes 68 which lead into the central hollow portion 69 of top member 32. Top wall 64 further includes a rafter support channel 70 which has a general C-shaped configuration. Outer wall 54 includes an upper ledge 72 and a lower channel 74 which are adapted to support either trim or a gutter system (neither of which is shown) if they are desired for the particular application.
The rafter supporting channel 70 supports a pivoting rafter support 78 which allows for angle adjustment or variation for the roof system. A fastener 79 extends through support 78 into channel 70 to establish the desired angle. Alternatively, a fixed angle system can be used. The support 78 further includes a plastic central member 80 which as shown in
As shown in
A roof system of the present invention can be either assembled on site or more preferably is assembled in the factory. With factory assembly, the roof including the upper member 32 of the eaves beam and everything resting on that structure including the rafters, any ridge beam or hip beam and glazed panels are all assembled.
To install the roof, the base member 30 is placed on the upper surface 31 of the wall 29. As shown, the wall 29 is wood. A plurality of screws 91 are inserted through the base plate 36 into the wall 29. After the base member 30 is fastened onto the wall 29, the assembled roof is lowered onto the walls with the top member 32 placed over the base member 30 so that the bottom edges 86 and 88 of legs 56 and 58 rest on the outer edges of base plate 30. Screws 90 and 92 are then screwed through legs 56 and 58 through walls 42 and 44 fastening the top member 32 in position. Plastic trim can then be used to finish off the inside and outside of the structure.
As shown an upper trim member 94 is placed over barbed member 62 and a lower trim member 96 is inserted into channel 38. Likewise a similar plastic trim structure 98 is attached to the exterior in channel 40. Other exterior trim or a gutter system can be applied if desired.
It is important to note that the base member can be redesigned if necessary to fit over a masonry structure or basically any other wall structure. It can be designed for either a two by four wall or a two by six wall, or other dimensions if desired. It is simply required that the base member and the top member mate and are adapted to be fastened to each other to provide for ease of installation of the product.
In addition to utilizing mating upper and lower eaves beam sections, the present invention particularly the pre-assembled glazed roof could be attached using lower brackets which would attach to the upper beam section. This would work as opposed to a continuous mating lower section. Other means to attach the upper beam section could also be employed as long as the roof could be constructed as a unitary structure supported at its base by an eaves beam and placed on a wall structure as a preassembled unit.
Further the present invention provides for drainage of any internal condensation that runs down the inside of the rafter system. This would be collected in trough 66 and run through holes 68 into the central area of 69. This would then run down sloped wall 60 and be permitted then to drain to the exterior of the building through drain holes 100. This prevents water from running down the side walls should any leak into the building or condense on the panels.
This has been a description of the present invention along with the preferred mode of practicing the invention. However, the invention itself should only be defined by the appended claims wherein
This application is a continuation of application Ser. No. 10/319,933 filed Dec. 16, 2002, entitled MULTI-PIECE EAVES BEAM FOR PREASSEMBLED GLAZED ROOF SYSTEM now pending.
Number | Date | Country | |
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Parent | 10319933 | Dec 2002 | US |
Child | 11773826 | Jul 2007 | US |