The present invention relates generally to slab construction and particularly to concrete slab flatwork on grade, as well as suspended or structural concrete slabs.
Concrete slab is one of the main elements for the construction industry. During the curing process, concrete slab panels tend to curl up at joints and around its perimeter. Curled up slabs are unsafe and can cause the concrete panels to endure high levels of stress, which leads to cracks and maintenance issues down the road.
Differential shrinkage is the basic cause of curling. This occurs as the exposed top surface of the slab shrinks and the core of the slab does not. Concrete slabs, like many other construction materials, are not dimensionally stable when subjected to changes in the moisture content. The factors that affect the amount of curling in a concrete slab are the subbase material, concrete mix characteristics such as water/cement (w/c) ratio, cement type, aggregate type, admixture types, cement content and mix temperature.
Forming a series of saw-cut joints in a slab is one method to reduce stress due to shrinkage. Saw-cut joints are spaced according to guidelines from the cement association, and should have a depth of at least one-quarter of the slab thickness. By having a saw-cut in a concrete slab, the propagation of cracks in the slab is controlled and the weakened planes where the concrete can crack in a straight line forms. This produces an aesthetically pleasing appearance since the crack takes place below the finished concrete surface. The concrete has still cracked which is normal behaviour, but the absence of random cracks at the concrete surface gives the appearance of an un-cracked section.
Also for reducing curling in the concrete slab, the prior arts suggest to use different additives such as synthetic macro fibres, steel fibres to be added to ready-mix concrete. The cost of adding chemical additives to the concrete slab is high and it raises the construction cost. Another way to reduce curl is to reinforce the slab with large amounts of steel rebar which also increases the construction cost.
The present invention is a method and a device which is used for forming the concrete slabs in a construction industry. The present invention enables the manufacturer to pour a concrete slab in individual cells so there is no need for saw-cut contraction joints, formed construction joints, as well as adding joint filler to the joints. By the device and the method of the present invention, wide variety of shapes for the concrete cells and panels can be achieved. The most efficient way for the concrete cells and panels are in a honeycomb fashion so that each concrete slab panel has a hexagonal shape.
The present method of constructing, reinforcing, joint sealing and edge protecting of a continuous concrete slab over a prepared subgrade surface area, wherein the continuous concrete slab having a thickness, the method comprising the steps of determining a joint-spacing-length for said continuous concrete slab based on a predetermined factor of said thickness of the concrete slab; choosing a concrete-pattern-shape to prevent concrete curling after curing process; determining a polygon-side-length for said concrete-pattern-shape based on the joint-spacing-length; subdividing said prepared subgrade surface area into a plurality of said polygons using a plurality of mounting frames, wherein said mounting frames are connected and held on said prepared subgrade surface area by a plurality of mounting posts, wherein each said mounting frame having a frame-length, a frame-height, a frame-thickness, a frame-bottom end and a frame-top end; and pouring concrete onto the prepared subgrade surface area until the concrete reaches to said frame-top end; whereby the mounting frames assembly subdivide the continuous concrete slab into a plurality of said concrete-pattern-shapes by inducing formation of fine cracks along the frame-bottom end of said mounting frame and wherein said mounting frames act as saw-cuts and joint fillers between said concrete-pattern-shapes.
The present device for subdividing a continuous concrete slab into a plurality of a polygon concrete slabs over a prepared subgrade surface area to prevent curling, wherein the continuous concrete slab having a thickness, the device comprising a plurality of polygon shaped elements constructed by a plurality of mounting frames and mounting posts, wherein each said mounting frame forming a side of said polygon shaped element and each said mounting post forming a vertex of said polygon shaped element, each said mounting post having a body, a top, a bottom and a connecting means, wherein said post is perpendicularly placed over said prepared subgrade surface area; and each said mounting frame having a frame-length, a frame-height, a frame-thickness, a frame-bottom end and a frame-top end, said mounting frame connects to said post by a connecting means; whereby said mounting frames act as saw-cut lines to induce cracks and as joint sealers between said polygon shaped elements.
The present invention is a method for constructing a continuous concrete slab panel, the method comprising the steps of placing a plurality of post on a subgrade surface; connecting the post with a plurality of mounting frames, wherein the mounting frames are assembled in a honeycomb pattern and being spaced apart from each other to form a plurality of joint lines; pouring concrete onto the subgrade surface to the top edge of the mounting frames; and wherein the mounting frame acts as joint lines for crack inducer and joint filler for the concrete slab to relieve the build-up of tensile stresses within the slab.
The hexagonal shaped concrete slab reduces the curl and stresses of the concrete slab panels significantly because the material (ready-mix concrete) is spread out and cures evenly unlike the common square shaped saw-cut concrete panels. Square shaped concrete panel curls at the corners and causes high levels of stresses inside the volume of the concrete slab. The main advantage of reducing stress level as well as curling in the slab panels is to reduce reinforcement means and load transfer device at the joints.
It is an object of the present invention to provide a device and a method to reduce curl and stresses in the concrete slab panels.
It is another object of the present invention to provide a device and a method to reduce the amount of reinforcement means required in the concrete slab panels.
It is another object of the present invention to provide a device and a method to eliminate the need for load transfer devices at contraction joints as well as construction joints.
It is another object of the present invention to provide a device and a method to eliminate the need to saw-cut for the concrete slab panels in contraction joints.
It is another object of the present invention to provide a device and a method to eliminate the need for joint filler.
It is another object of the present invention to provide a device and a method to eliminate the need to use steel bar in order to reinforce the concrete slab panels.
It is another object of the present invention to provide a device and a method to allow a user to use regular concrete mixes and not expensive special mix designs.
It is another object of the present invention to provide a device and a method to reduce differential in deflection between two adjacent concrete slab panels.
It is another object of the present invention to provide a device and a method to protect the edges of the concrete panels from spalling.
It is another object of the present invention to provide a device and a method to manufacture high performing concrete slabs with low cost compare to the traditional concrete slab panels.
Other objects, features, and advantages of the present invention will be readily appreciated from the following description. The description makes reference to the accompanying drawings, which are provided for illustration of the preferred embodiment. However, such embodiments do not represent the full scope of the present invention.
Embodiments herein will hereinafter be described in conjunction with the appended drawings provided to illustrate and not to limit the scope of the claims, wherein like designations denote like elements, and in which:
The present invention is a device and a method for constructing a continuous concrete slab. The method comprises of the following steps: (a) placing a plurality of posts on a subgrade surface; (b) connecting the post with a plurality of mounting frames to form a honeycomb pattern; (c) pouring concrete onto the subgrade surface up-to the top edges of the mounting frames, wherein the mounting frame provides a spacing between the concreted in the adjacent hexagonal shapes of the honey comb, and whereby the mounting frame acts as the saw cut, a joint filler and shrinkage control joint for the concrete slab and to relieve the build-up of tensile stresses within the slab.
As shown in
Again as shown in
The post 10, 20 in the present invention can have different profile shapes as shown in
As shown in
The material of the post 10, 20 can be selected from the group consisting of a plastic, a metal, a fiberglass, a compressible foam, a rubber, a polymer, a wood and combination of any of the mentioned materials.
As shown in
Saw-cut joints should be spaced according to guidelines from the cement association, and should have a depth of at least one-quarter of the slab thickness. The mounting frame 30 of the present invention can be sized and designed to fulfil the cement association standard for specific concrete slab panels with specific thickness, strength and shapes. By having a mounting frame 30 between two adjacent concrete slabs, the propagation of cracks in the slab is controlled. The weakened planes where the concrete can crack in a straight line forms underneath the finished concrete surface.
The thickness 33 (t) of the mounting frame 30 depends on the thickness of the joint sealer for the concrete slab.
Again as shown in
Different cross sections 35 of the mounting frame 30 are shown in
The material of the mounting frame 30 is being selected from the groups consisting of a plastic, a polymer, an elastomer, a rubber, a fiberglass, a compressible foam, a metal and a wood. The characteristic of the above materials make the mounting frame 30 of the present invention a perfect candidate for acting as a joint sealer and also forming the weakened planes in the concrete slab. During the concrete pouring, the thickness (t) of the mounting frame 30 is reduced by the pressure from the mix concrete and then increases once the concrete slab is cured and dried. The elastomeric character of the mounting frame 30 fills the gap between the two adjacent concrete slabs.
Again as shown in
As shown in
Frames do not touch the ground and the poured in concrete from one side of the frame attached the concrete on the other side of the frame forming a continuous joint less concrete slab. The mounting frame 30 acts as a crack inducer and joint sealer for the concrete slab 100.
In one embodiment of the present invention, a securing means is used to secure the location of the post 10, 20 and the mounting frames 30 during the pouring process of concrete. The securing means holds the post and the mounting frame in a proper location during the pouring and curing processes.
Traditionally, a saw cut is provided on a concrete slab panel, as soon as a joint can be cut, to create a weakened plane, preferably without creating spalling at the joint. This is done so that the floor slab cracks at the saw cut instead of randomly breaking at different locations, creating an undesirable look. In the present invention the mounting frames act as a saw cut and also act as a filler to fill the gap between two adjacent slab panels. As shown in the
The length of the side mounting panels 30 depends on the thickness of the slab panel. Industry guidelines (American Concrete Institute) suggests to calculate the joint spacing (saw cuts) in a regular (low shrinkage mix) slab by
Thickness of slab panel (inch)×2.5=Joint Spacing (feet)
So the distance between the saw cuts in the present invention as shown in
For example, if the thickness of the slab panel is six inches, then the standard joint spacing would be 15 feet. Therefore when constructing a hexagon concrete panel, each mounting frame would be approximately 8.6 feet long in order to achieve 15×15 feet concrete hexagon shaped cells.
Thickness of slab panel (inch)×2.5=2x sin(60°)
If the thickness of the slab panel is 8 inches, then the standard joint spacing would be 20 feet in a regular slab, so the side mounting frames in this case would be approximately 11.5 feet long.
Thickness of slab panel (inch)×2.5=2x sin(60°)
In another embodiment of the present invention, the mounting panels 30 in units of feet is between the ranges of 1 to 2 times of the thickness of the continuous concrete slab in units of inches. For example, if the thickness of the slab panel is six inches, then the joint spacing would be 6 to 12 feet.
In general, the polygon side length is determined based on the thickness of the concrete slab. In one embodiment, the following relationship is used to determine the polygon side length:
polygon-side-length (feet)=1.25×said thickness of concrete slab (inches)/sin(polygon half angle), wherein polygon half angle is the half of the angle between two adjacent polygon sides.
The present invention allows making multiple sided individual concrete panels;
this is something that cannot be done by today's methods as saw cutting gives four sided panels.
With the present invention, the concrete panels are formed individually during the concrete placement, before the concrete sets. This is the only way one can have a honeycombed pattern slab and hexagon patterned individual panels. The frame reduces the shrinkage stress from the slab as a whole (separating the slab into smaller panels just like saw cutting), and also reduces the tensile and curling stresses in each individual panel because of the hexagon shape. The frame also holds all those panels together to make it one big slab.
Since the system reduces the stress of the whole slab as well as individual concrete panels, one can reduce the thickness of concrete that is normally needed to accommodate a given load.
As shown in
The foregoing is considered as illustrative only of the principles of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation shown and described, and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention.
With respect to the above description, it is to be realized that the optimum relationships for the parts of the invention in regard to size, shape, form, materials, function and manner of operation, assembly and use are deemed readily apparent and obvious to those skilled in the art, and all equivalent relationships to those illustrated in the drawings and described in the specification are intended to be encompassed by the present invention.
This application is a divisional application of U.S. patent application Ser. No. 15/144,711 filed May 2, 2016; which application claims the benefit of priority from provisional application No. 62/156,305 filed May 3, 2015; the entire contents of each of which are incorporated herein by reference.
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Number | Date | Country | |
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20170314212 A1 | Nov 2017 | US |
Number | Date | Country | |
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Parent | 15144711 | May 2016 | US |
Child | 15624349 | US |