Patent Application
20100126084
The present invention relates generally to insulated concrete wall construction and more particularly to a bracing device for supporting and aligning a tall wall during forming and concrete pouring operations.
Insulated concrete forms are stay-in-place forms for energy efficient cast-in-place reinforced concrete walls. The forms comprise interlocking modular units that are dry stacked (without mortar) and filled with concrete. The modular units lock together somewhat like Lego bricks and, when assembled, create a double sided form for the structural concrete walls of a building. Most of such forms are made of foam insulation, such as expanded polystyrene, and are comprised of either separate panels interconnected with plastic or steel connectors (commonly called webs or ties) or they may be pre-formed interlocking blocks whose lateral sides are interconnected with the plastic or steel ties. Concrete is pumped into the cavity between an assembly of modules to form the structural element of the walls. Usually, reinforcing steel is added before the concrete is poured to give the resulting walls flexural strength. After the concrete has cured the forms are left in place permanently to provide thermal and acoustic insulation, among other things.
For walls up to approximately eight feet tall the most common method of construction is to stack the modules and brace the wall in the traditional manner, then pour the concrete. For walls of a greater height two options are available. The first is pouring the wall in stages. That is, when the concrete in the eight foot wall is cured the bracing is stripped and scaffolding is tied into the wall. Then the process is begun again, bracing the scaffolding and the wall for the next level. The second option is to form and brace the entire wall and make a single pour. While the second option has the advantage of employing a concrete pump truck only once, the disadvantages are severe. Furthermore, current bracing technology generally limits the height of the wall to around twenty-four feet. Because current bracing systems all depend on a vertical member such as a ladder or beam disposed flush with the wall and which is braced with a plurality of diagonal braces extending from spaced positions on the vertical member to respective anchor points on the ground, there is insufficient rigidity in a manageably sized diagonal brace to support and align a wall of greater height than 24 feet.
As commercial ICF construction has become more popular the question of how to brace and align walls over 24 feet high has become more urgent. Accordingly, the primary object of the present invention is to provide a brace and alignment tool for use in constructing tall insulated concrete form walls.
A second object of the invention is to provide bracing for insulated concrete form walls that eliminates need for diagonal members that bear against the ground for support.
Another object of the invention is to provide a bracing assembly for insulated concrete form walls that are constructed in successive levels and which can plumb a successive level of the wall by adjustment of the brace even though the previous poured level of the wall might be out of plumb.
Other objects, features and advantages of the present invention will become apparent upon a reading of the following detailed description of a preferred form of the invention taken in connection with the accompanying drawings.
The preferred form of apparatus of the present invention comprises a bracing beam comprising first and second sections that are hinged together at the mid-point of the beam. To accomplish its bracing function in constructing an insulated concrete form tall wall, the first section of the beam is disposed vertically and flush with the outside surface of the modules that comprise the wall form on that portion of the wall that has already been poured and cured. The first section of the bracing beam is secured to the poured wall by connectors, such as screws, between the first section of the beam and the webs or ties that lie imbedded in the foam insulation comprising the sides of the ICF module. Preferably, a plurality of screw or other type of connection is made between the bracing beam and each module. The second section of the bracing beam extends from the top of the poured concrete level upwardly and is connected in like manner to the ties of the ICF modules that have been stacked on the poured wall section for creating the insulated concrete form for the next successive level of the wall.
If the bracing beam were only a single piece, as in the prior art, then any amount by which the poured wall is out of plumb would be magnified for the next successive wall level. Accordingly, the hinged joint between the first and second sections of the bracing beam of the present invention allows the second section to be pivoted with respect to the first section and thereby adjusted to a plumb position. The adjustment of the second section is accomplished through the use of an adjusting beam that is positioned over and spaced apart from the bracing beam and in alignment therewith. The adjusting beam is supported in its position by a bracket that is attached to the mid-point of the adjusting beam and pivotally connected to the bracing beam at the hinge point between the two sections of the bracing beam. The pivotal connection between the adjusting beam and the bracing beam allows the adjusting beam to pivot around the same hinge axis as the first and second sections of the bracing beam. Movement of the adjusting beam to correct for plumb errors is created by manipulation of a manual adjustment devices, such as a jack screws that interconnect the distal ends of the two sections of the bracing beam with the distal ends of the adjusting beam. Operation of the adjusting devices brings the adjusting beam ends closer to or further apart from the respective ends of the bracing beam sections. The adjusting devices can be manipulated so as to rotate the second section of the bracing beam around its hinge point so that the second section and the ICF modules to which it is attached are plumb. The process of attaching a brace to a cured level of a multi-level wall in order to brace the next level is repeated so as to construct multi-level tall wall.
Depending on the length of the wall, a plurality of the bracing beams will be required along spaced intervals to provided support and alignment over the entire length of the insulated wall.
Because each level of a multi-level wall receives its bracing support and alignment from the poured level beneath it, tall ICF walls may be constructed without the limitations inherent in diagonal ground supports. Accordingly, ICF walls above 24 feet may be built utilizing the apparatus and method of the present invention.
Drawing Note: A wall section such as the one shown in the various Figures of the drawings 1 is traditionally comprised of eight courses and the present invention is conceived to operate on such an eight course wall, but the wall levels shown in the drawings are shown with only six courses for purposes of simplifying the drawings.
For a detailed explanation of a preferred form of the ICF bracing and alignment device of the present invention, reference is made to the accompanying drawings.
Turning now to
The alignment beam 20 is preferably a rigid tube of one piece, however it may comprise several sections and be formed of an I beam or similar structure. It is held in place by a bracket comprising two parallel substantially triangularly shaped plates 40 and 41 bolted at their bases to the opposing lateral sides of the central portion of the alignment beam 20. The apexes of the triangular bracket plates 40 and 41 are pivotally attached to the pivot pin 31 of the hinge that interconnects the first and second sections of the bracing beam 18, as shown best in
Providing for rotation of the alignment beam is the means by which the second section 22 of the bracing beam and its attached insulated wall are made plumb regardless of whether the base level wall 2 is plumb. Rotation of the alignment beam is realized through adjustment of the screw jack assemblies 50 and 52 located at the distal ends of the alignment beam 20, as more clearly shown in
In operation, the distal end of the alignment tube 20 is made to move toward or retreat from the bracing beam 18 depending on the direction of rotation of the screw 53. When aligning the modules of the wall level that is under construction, adjustment of the screw 53 of the jack screw assembly 50 will either push the insulated forms back in one direction or pull them out in the opposite direction until the sides of the insulated forms are plumb. When the new section of the wall that is under construction is plumb the opposing jack screw assembly 52 is adjusted so that the lower ends of the beams are fixed in a tight relationship to one another so there is no play between the two lower ends. By making these adjustments of the jack screw assemblies 50 and 52 the alignment function of the wall brace is accomplished. Re-alignment may be necessary as the concrete is poured into the forms.
Although the drawings have depicted the poured level of a multi-level wall as being that level which is disposed directly on foundation footers it is to be understood that the poured level could be any one of the upper levels of a multi-level wall.
The primary method of the invention is to use a poured and cured level of a multi-level wall as the base or foundation to support bracing and alignment for the next succeeding wall level, thereby eliminating the need for diagonal ground based supporting struts. The method includes properly aligning, or plumbing, the upper section that is under construction regardless of the condition of plumb that may exist in the base level of the wall.
