Patent Grant
9091068
The present application is a National Phase entry of PCT Application No. PCT/AU2012/000706, filed Jun. 20, 2012, which claims priority to Australian Application No. 201190404, filed Jun. 20, 2011, said applications being hereby incorporated by reference herein in their entirety.
This invention relates in general to concrete wall production, and more particularly to a wall stud, and wall construction system, preferably made from plastic.
To erect a vertical concrete wall, pre-cast tilt-up concrete panels are commonly used. Another commonly used technique is to use formwork in-situ to support the concrete and reinforcing bars until the concrete has set and cured, after which the formwork is removed.
An alternative way of constructing walls is to manufacture hollow panels which can be manufactured off site, delivered to the building site, erected and filled with concrete on site. These hollow panels consist of two formwork wall board sheets separated by spacers which hold both the vertical and horizontal bars in correct alignment and facilitate the flow of concrete. These panels are then sacrificed as they remain in place and their surface acts as the interior and exterior surfaces of the wall. When erecting these hollow panels, vertical aluminium or galvanised steel studs can be used to support the formwork wall board sheets and position and hold the horizontal and vertical steel reinforcing bars within the formwork prior to the concrete being poured. Aluminium and steel stud frames have the disadvantage of being heavy making the panels difficult to handle. Panels are also prone to distortion due to the flexibility of the studs. In addition, the steel frames can be prone to rusting as the outer edge of the steel studs are not covered by concrete, only by the formwork wall board sheet. Further, the aluminium frames can corrode when in contact with concrete.
Another way of constructing walls is to position box or cube shaped spacers between opposing formwork boards in a spaced relationship. Vertical and horizontal reinforcing rods are then placed through each of the wall spacers to keep the wall construction aligned while the concrete is poured. Operators using this system often misalign or incorrectly place the box shaped spacers making it difficult to place the reinforcing bars in the formwork. Further, due to this wall construction system requiring a disposable template for the accurate positioning of box spacers, the system is difficult to automate.
Discussion or mention of any piece of prior art in this specification is not to be taken as an admission that the prior art is part of the common general knowledge of the skilled addressee of the specification in Australia or any other country.
It would be advantageous to provide an improved, inexpensive, easily constructed and lightweight means of constructing a concrete wall.
According to one aspect of the present invention there is provided a wall stud for positioning between an opposing pair of formwork boards. The wall stud includes a body, a plurality of ribs and two side walls located on opposing sides of the body, each side wall having an inner face and an outer face. The stud body has at least one opening adapted to receive at least one reinforcing rod, thereby advantageously accurately holding the reinforcing rods in place. The stud body is positioned approximately in the centre of the inner face of each side wall so that a horizontal cross-section of the stud is substantially an H shape. Each of the plurality of ribs is located between the two side walls on a side of the body substantially perpendicular to the body. The outer faces of the side walls are securable to a said formwork board.
Preferably the body, the plurality of ribs and the two side walls are integrally formed to form the wall stud.
The outer face of the side wall preferably has an etched surface. The outer face may also have at least one cut away part, preferably in the shape of a dove tail.
The wall stud preferably also includes two joiner sections located at opposing ends of the wall stud.
According to another aspect of the present invention there is provided a wall stud assembly including: at least one wall stud as described above; and a stud joiner clip for securing the joiner section of the wall stud to another wall stud.
The wall stud and stud joiner clip are preferably formed from a polymer material such as plastic, or other such material. This advantageously makes the wall stud and stud joiner clip light weight, easy to install, very rigid and ensures they will not rust or corrode.
According to yet another aspect of the present invention there is provided a method of wall construction including the steps of: erecting at least one formwork structure including an opposing pair of formwork boards and at least one wall stud assembly as described above located in spaced relationship between the formwork boards; placing reinforcing rods through at least one opening of each of the wall studs; and filling the cavity in between the formwork boards with wall material, preferably concrete.
The method may also further include the step of securing at least a pair of said wall studs together using said stud joiner clip.
According to still a further aspect of the present invention there is provided a wall constructed according to the method described above.
The wall construction installation according to the present invention advantageously reduces the weight of the formwork structure, ensures accurate placement of horizontal and vertical reinforcing bars and because of their rigid structure prevent distortion, twisting and shear movement of the panels, facilitating construction of the concrete wall.
It will be convenient to further describe the invention with respect to the accompanying drawings which illustrate preferred embodiments thereof. Other embodiments of the invention are possible, and consequently, the particularity of the accompanying drawings is not to be understood as superseding the generality of the preceding description of the invention.
Embodiments of the method of wall construction, the wall stud, and wall stud assembly, including a stud joiner clip will now be described with reference to the accompanying drawings.
The body 3 of the wall stud 1 is positioned such that it is in the centre of the inner faces 6 of the side walls 5, thereby forming a substantially “H” shape when viewed from above, as shown in
As shown in
Thin ribs 4 extend from the body 3 between the inner faces 6 of the side walls 5. The portion of the ribs not bordered by the body and side walls are curved and substantially ‘C’ or ‘U’ shaped as shown in
The outer faces 7 of the wall stud 1 are secured to the formwork boards using an adhesive, for example, glue. The outer face 7 can be etched or roughened in some way, for example by sanding. This allows for better glue adhesion between the outer face of the wall stud and the formwork board. Since the outer face is rough and not smooth, there is greater surface area for the glue to cover or adhere to; in addition, the glue can seep into crevices on the stud side wall for better adhesion to the formwork board.
The outer face 7 of the stud side wall 5 may also have at least one cut away part 11 as shown in
Wall studs are often manufactured in many standard sizes. When constructing a low wall, only one regular stud may be needed. However, for a taller wall an extra long stud or many regular sized studs are often needed. In conventional methods of wall construction it is difficult to ensure studs placed above one another are correctly aligned and stable. As seen in
Preferably the wall stud and stud joiner clip are made of polymer and more preferably plastic. This system is therefore very lightweight and thus easy to install. Furthermore, polymer and plastic does not react with the concrete or other materials used to create the wall. Therefore, the wall studs, wall stud spacers, and wall stud joiner clips of the present invention do not rust or corrode over time.
A wall stud assembly includes a wall stud as described above and may further include a stud joiner clip for securing the joiner section of the wall stud to another wall stud.
A formwork structure can be pre-assembled and transported to a worksite, alternatively it can be built on the worksite if required.
In constructing a wall, as shown in
This arrangement is lightweight which makes the formwork boards and their installation very easy and quick. This arrangement also facilitates the flow of concrete around the reinforcing bars thereby minimising voids and ensuring maximum strength for the concrete wall. Distortion or twisting of the formwork panels, that the studs are connected to, is prevented because of the unique “H-shaped” cross-sectional stud which provides rigidity between the formwork boards.
The wall studs create a rigid wall panel prior to concrete pouring, which prevents twisting and shear movement of the formwork structure.
Furthermore, the cavities in the body of the stud allows accurate placement of the reinforcing bars, to ensure proper concrete coverage of the bars.
The outer face 107 of the side walls 105 is securable to the formwork board. The joiner sections 110 are adapted to receive a stud joiner clip (not shown) for securing said wall stud to another wall stud.
The large openings 108 or cavities in the body 103 of the stud also have an open symmetrical shape. The wall stud 100 in this embodiment also has a frame which is a substantially “H” cross-sectional shape. As is illustrated in this embodiment, the openings 108 can be of any symmetrical open shape which are adapted to receive and accurately place at least one reinforcing rod and allows wall material to be poured into, and flow freely between the studs. This invention overcomes a number of the disadvantages of other wall construction methods and systems. One of the most advantageous features of this wall construction system is that all the elements used to construct a wall are symmetrical. As shown in the figures, the wall stud 1, 100 is symmetrical, having a substantially “H” horizontal cross-section. The wall stud joiner clip 22 is also symmetrical as shown in
In comparison to constructing a wall using other methods and systems, this method is easier, more accurate and more robust. In existing systems which use plastic spacers there is not enough safety margin during concrete pour in high labour cost countries. For example in the boxed spacer system, boxed spacers can be placed 90 degrees out of line making it difficult to place the reinforcing bars in the formwork. Also the boxed spacer method for constructing a wall requires a disposable template for accurate positioning of boxed spacers and this method is difficult to automate and streamline.
The present invention overcomes this disadvantage because all the elements are symmetrical making it very easy and quick to place the elements correctly together.
This system and method is more robust during concrete pour than those of the prior art. This is because the studs are essentially continuous and therefore a greater area of formwork board is protected by the stud, where the stud side wall is in contact with the formwork board, than some other methods and systems; particularly, compared to the boxed spacer wall constructions.
A pre-packaged wall construction kit including a plurality of wall studs as described above and a plurality of wall stud clips as described above may be used.
In another embodiment, the inner face 6 of the side walls 5 are adapted to receive a stud spacer 23 (shown in
During wall construction the stud spacer 23 may assist separation of the wall studs accurately placing them between the formwork boards. The stud spacers have an opening for accurately holding reinforcing bars in place.
The wall stud spacer 23 is also symmetrical as shown in
In another embodiment, the wall stud assembly may further include a wall stud spacer for securing a pair of wall studs in a spaced relationship. The stud spacer is adapted to receive at least one reinforcing rod (which is vertical or horizontal depending on the orientation of the formwork).
In constructing a wall, the wall studs are secured accurately in place by a plurality of stud spacers. Reinforcing rods 15 are placed through the openings of the wall stud body 3 and the wall stud spacer 23. The cavity in between the formwork boards is then filled with wall material 14, preferably concrete. The formwork boards, held in place by the studs and spacers, remain in place after being filled with concrete or other material acting as the finished internal or external wall surface.
The wall stud spacer in this embodiment further assists to hold the studs accurately in position, ensuring no distortion or twisting of the formwork panels. The studs and spacers create a rigid wall panel prior to concrete pouring, which prevents twisting and shear movement of the formwork structure.
The spacers may also assist to accurately place the reinforcing bars (usually vertical bars) inside the wall. The open structure of the spacers allows concrete to flow more easily between the separated formwork boards.
Further, spacers which are easily slotted into the guides on the stud can be used to arrange the studs in a spaced relationship. The spacers can then be secured to the body of the studs. This ensures the studs are accurately positioned in the formwork because the spacers are the requisite size for spacing of the studs.
It will be appreciated by persons skilled in the art that other embodiments and arrangements of the method and system are also possible within the spirit and scope of the invention described herein or as claimed in the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2011902404 | Jun 2011 | AU | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/AU2012/000706 | 6/20/2012 | WO | 00 | 12/19/2013 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2012/174589 | 12/27/2012 | WO | A |
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