The present invention relates to a method and a mold for making a block. More particularly, the present invention relates to a method and a mold for making a hollow core concrete block that has imprinted on one side of it a decorative pattern.
Concrete blocks, and in particular hollow core concrete blocks, have several purposes. For example, they can be stacked in order to compress the ground beneath them in advance of building on the ground. They can also be stacked adjacent to an embankment and used to construct a retaining wall in order to stabilize the embankment.
Accordingly, given the usefulness of concrete blocks in industries such as construction, research and development continues into efficient, robust, and reliable ways to construct concrete blocks.
The present invention comprises a mold and a method for making a block, such as a hollow core concrete block. The mold has two opposing side walls; a bottom wall; a front wall; a top side that has an opening through which the block can be removed from the mold; a cover that can be used to seal the top side; and a rear side through which liquid, such as concrete, can be poured into the mold. Extending from the two side walls are a pair of trunnions about which the mold is rotatable. The trunnions are positioned on the mold such that when the mold is suspended by the trunnions and the mold is empty, gravity rotates the mold from a block-removal orientation in which the top side faces upwards to a mold-filling orientation in which the rear side faces upwards. The trunnions are also positioned such that when the mold is filled with the liquid, gravity rotates the mold from the mold-filling orientation to the block-removal orientation.
Making the block using the mold can be done by sealing the mold except for the rear side; suspending the mold to transition the mold to the mold-filling orientation; pouring the liquid into the mold, letting the block cure; suspending the mold to transition the mold to the block-removal orientation; removing a cover from the top side of the mold; and then lifting the block out of the mold.
Accordingly, in a first broad aspect of the present invention, such invention comprises a mold for making a block, the mold comprising:
In the accompanying drawings, which illustrate one or more exemplary embodiments:
a) is a right side elevation view of the mold of
b) is a right sectional view of the mold of
a) is a left side elevation view of the mold of
b) is a left sectional view of the mold of
Directional terms such as “top,” “bottom,” “upwards,” “downwards,” “vertically” and “laterally” are used in the following description for the purpose of providing relative reference only, and are not intended to suggest any limitations on how any article is to be positioned during use, or to be mounted in an assembly or relative to an environment.
The variety of purposes for which concrete blocks can be used contributes to their ubiquity. In order to facilitate transport and economic manufacture, concrete blocks are often manufactured with a hollow core. These hollow core concrete blocks are often seen, for example, at construction sites and lining embankments along the sides of highways and other roads. Typically, a relatively large number of these blocks are stacked on top of each other to form walls, including retainer walls for sloped embankments. Accordingly, there exists continued demand for efficient and reliable ways to make hollow core concrete blocks in relatively large numbers.
Additionally, because hollow core concrete blocks are often used while in public view, it is desirable to make them aesthetically pleasing. To do this, a decorative textured or contoured pattern can be imprinted on to the front faces of the blocks. Imprinting the concrete blocks with the textured pattern introduces technical problems to the block manufacturing process. For example, the textured surface used to imprint the decorative pattern into the blocks can act as an obstacle when the block is being removed from a mold. Additionally, the textured surface can trap air bubbles in the blocks during the curing process, which can reduce the structural integrity of the blocks.
The following embodiments are directed at a mold and a method for making blocks, and in particular, hollow core concrete blocks 300 that have a decorative, textured face 314 (see
Referring now to
The mold 100 has six sides: a front side (i.e. front wall 108), a rear side 114/144, a top side 110, a bottom side (i.e. bottom wall 106), a left side (i.e. left side wall 102b), and a right side (i.e. right side wall 102a). Extending along three edges of the rear side 114 is a rear lip 144, while extending along three edges of the front side is a front lip 146. In
Extending forwardly from opposing sides of the front lip 146 are a right pivot plate 120a and a left pivot plate 120b (collectively, “pivot plates 120”) (see
Lining the interior side of the front wall 108 is a textured surface 116, which extends into the interior of the mold 100 when the front wall 108 is closed. The “interior” of the mold 100 refers to volume contained within the six sides of the mold 100 when the front wall 108 is in the closed position. As the textured surface 116 extends into the interior of the mold 100 when the front wall 108 is closed, any block formed using the mold will have imprinted on its front face a decorative, textured pattern corresponding to the pattern on the textured surface 116. When the front wall 108 is pivoted into the opened position, the textured surface 116 is moved outside the interior of the mold 100.
Positioned on the opposing sides of the front wall 108 are a right adjustable batter draft plate 126a and a left adjustable batter draft plate 126b (collectively, “adjustable batter draft plates 126”). Wedge-shaped portions of the batter draft plates 126 extend through apertures in the front lip 146 when the front wall 108 is closed, and the front wall 108 can be secured in the closed position by using a wedge and pin fastening system (unlabelled).
The adjustable batter draft plates 126 can be used to adjust the batter draft of the front face of the blocks formed using the mold 100. For any given one of the blocks, the “batter draft” of the block refers to the angle the front face of the block makes relative to an axis perpendicular to the bottom face of the block. As is evident with reference to the sectional views of
Each of the slots 122 in the pivot plates 120 has three positions in which the pivot pin can be retained; these three positions are labelled “1,” “2,” and “3” on the pivot plates 120. Each of the adjustable batter draft plates 126a, b includes two sets of groupings of three apertures each: the right adjustable batter draft plate 126a includes one set of apertures 130a-c and another set of apertures 131a-c, while the left adjustable batter draft plate 126b includes a third set of apertures 128a-c and a fourth set of apertures 129a-c. As indicated in the Figures, each of the apertures in the sets of apertures 128a-c, 129a-c, 130a-c, and 131a-c (hereinafter collectively referred to as the “sets of apertures 128-131”) is labelled either “1,” “2,” or “3.” Each of the apertures in the sets of apertures 128-131 can be aligned with a corresponding aperture that is present in each of the opposing sides of the front wall 108 and can be coupled to the front wall 108 by inserting batter draft adjustment bolts (not shown) through the aligned apertures to secure the respective batter draft plates 126a, 126b to front wall 108. The labels “1,” “2,” and “3” for the sets of apertures 128-131 and the slots 122 correspond to different batter drafts or different block depths. When the mold 100 is used, the pivot pins are inserted through the slots 122, and the batter adjustment bolts (not shown) inserted into the respective sets of apertures 128-131 in one of the three positions “1,” “2,” and “3.” For example, when the front wall 108 is secured in position “2,” the batter draft of the blocks formed using the mold 100 is shown by the angle of the textured surface 116 of approximately 5° as shown in
As best seen from
Referring now in particular to
Referring back to
When the mold 100 is used, it typically alternates between two orientations: (1) a mold-filling orientation (see
Once the concrete has cured in mold 100 and the block 300 is ready to be removed, the mold 100 is raised by lifting the trunnions 104a, 104b, so as to cause the mold to be raised from its position resting on a flat surface such as a floor, whereupon due to the altered (new) center of gravity of the mold 100 and formed block 300 therein, is caused to rotate 90° about trunnions 104a, 104b so as to transition to the block-removal orientation, as more fully described below. Specifically, in such block-removal orientation, mold 100 when such concrete is poured therein, is configured such that with the added concrete the center of gravity of the mold 100 and block 300 therein is such that, when mold 100 is raised by lifting on each of trunnions 104a, 104b, the mold 100 pivots about trunnions 104a, 104b, such that top side 110 of the mold 100 faces upwards and the front side 108 of the mold 100 accordingly faces forwards. Also as discussed in greater detail with respect to
In a preferred embodiment, in order for the mold 100 to transition between the mold-filling and block-removal orientations, the trunnions 104a, 104b are mounted to the side walls 102 in substantial vertical alignment with, but above, the center of gravity (not shown) of the mold 100 and block 300 therein, to ensure mold 100 will rotate, when the mold 100 is lifted by trunnions 104a, 104b, to be in the block-removal position shown in
After liquid concrete is poured into the mold 100 when in the mold-filling orientation and the block has cured and is ready to be removed, the mold 100 can again be suspended by the trunnions 104a, 104b. Because of the position of the center of gravity of the mold 100 has changed due to the added concrete, the altered distribution of mass in the mold 100 will cause, when suspending the mold 100 by the trunnions 104a, 104b, the mold 100 to rotate from the mold-filling orientation back to the block-removal orientation. When transitioning back to the block-removal orientation, the mold 100 rotates in a direction opposite to the direction in which it initially rotated from the block-removal orientation to the mold-filling orientation. Note that in the preferred embodiment, due to the position of the trunnions 104a, 104b and the positioning of counterweights if needed, regardless of what side of the mold is facing upwards, when the mold is empty and suspended by the trunnions, it rotates into the mold-filling orientation shown in
Additionally, because the center of gravity of the mold 100 changes when filled, the density of the concrete or whatever liquid is used to be used fill the mold 100, is taken into consideration when positioning the trunnions 104a, 104b on the mold 100, so as to achieve the ±90° desired rotation of the mold 100 when raised via the trunnions 104a, 104b, from the mold-filling position to the block-removal position, and vice versa. Alternatively, provision may be made on the mold to attach counterweights, to account and variably adjust for materials of different densities, in order to adjust the center of gravity in the unfilled and/or filled position, so as to achieve the desired ±90° rotation of the mold 100 when raised via the trunnions 104a, 104b, from the mold-filling position to the block removal position, and vice versa.
Although in a preferred embodiments the positioning the trunnions 104a, 104b and/or the relative positioning of counterweights to achieve the ±90° desired rotation of the mold 100 from the mold-filling position to the block removal position can easily be determined and is dependent on the location of the center of gravity of the entire mold 100 in both filled and unfilled conditions, in alternative embodiments different ways of adjusting the center of gravity of the mold 100 can be employed achieve the ±90° desired rotation of the mold 100 from the mold-filling position to the block removal position upon lifting of the mold 100 via trunnions 104a, 104b. For example, different portions of the mold 100 can be made of materials of different density so that even if the trunnions 104a, 104b are mounted in the center of the side walls 102, the mold 100 can be transitioned between the block-removal and mold-filling orientations as described above. Alternatively, the shape of the block 300 (and thus the shape of mold 100) can be adjusted to adjust the center of gravity of the mold in both the filled and unfilled conditions to thereby achieve the ±90° desired rotation of the mold 100 from the mold-filling position to the block removal position upon lifting of the mold 100 via trunnions 104a, 104b. Alternatively, as mentioned above, counterweights can be added to or removed from the mold 100 so as to cause it to rotate the mold 100 in one direction or another, depending if mold 100 is in the filled or unfilled position. Any combination of the foregoing can be used to adjust the center of gravity of the mold 100, as desired, in order to achieve the +90° desired rotation of the mold 100 from the mold-filling position to the block removal position, and the reverse −90° desired rotation from the block removal position to the mold-filling position once the block 300 has been removed.
The bottom wall 106 of the mold 100 includes protruding feet-forming members 142 into which concrete can flow so that the feet 143 formed thereby are insertable into the hollow core 302 of another block 300 on which said block 300 may be stacked, as shown in
The bottom wall 106 of mold 100 also has a removal screw 136 extending through it, which can be used to facilitate the block-removal process. More particularly, when the block is ready to be removed from the mold 100, and elongate threaded removal screw 136 can be threadably inserted via a threaded number not identified by number on bottom wall 146 into the interior of the mold 100, where it abuts against the hollow core insert 112. Continued rotation of the removal screw 136 into the mold 100 bows bottom wall 106 thereby separating it from the block, and can further help to push the hollow core insert 112 out of the mold 100 and which can be of assistance to lifting the block out of the mold 100.
Referring now to
At block 1101, the method 1100 begins with the mold 100 in the block-removal orientation. The method proceeds to block 1102 where the mold 100 is sealed. Sealing the mold 100 involves moving the front wall 108 into the closed position and inserting the hollow core insert 112 into the mold 100 through its top side 110. The front wall 108 and the hollow core insert 112 are then fastened in position using the wedge and pin fastening system. Although the depicted embodiments utilize the hollow core insert 112 to cover the top side 110, in an alternative embodiment (not depicted) any suitable type of cover can be used as a cover for the top side 110 so long as it prevents liquid concrete from escaping through the top of the mold 100. For example, in an embodiment in which solid core concrete blocks are manufactured, a flat metal plate can be used in place of the hollow core insert 112.
Following sealing, the mold 100 is transitioned to the mold-filling orientation at block 1104. As described above, to perform this transition the mold is suspended by the trunnions 104 sufficiently high to allow the mold 100 to rotate such that the front wall 108 faces downwards. Although in the method 1100 the mold 100 begins in the block-removal orientation, in alternative embodiments (not shown) the mold 100 may begin in an alternative orientation, such as with the front wall 108 facing upwards. In an alternative embodiment (not shown) in which the mold 100 begins in the mold-filling orientation at block 1100, then block 1104 may be bypassed.
Once the mold 100 is in the mold-filling orientation, liquid concrete is poured into the mold 100 through the open rear side 114.
Following curing, the block is removed from the mold 100. At block 1110, the mold 100 is again suspended by the trunnions 104 so as to cause the mold 100 to transition to the block-removal position. As discussed above, the center of gravity of the mold 100 changes once it is filled with concrete, and accordingly suspending it by the trunnions 104 causes the mold 100 to rotate in the block-removal orientation as opposed to staying in the mold-filling orientation. The top side 110 of the mold 100 is then uncovered at block 1112; when the mold 100 is being used, this corresponds to removing the hollow core insert 112 from the top side 110 of the mold 100 at block 1112. In embodiments in which the front wall 108 of the mold 100 is lined with the textured surface 116 and is movable, the front wall 108 is also moved once the mold 100 is in the block-removal orientation such that the textured surface 116 does not interfere with removal of the block from mold 100.
Following block 1112, the block 300 can be lifted out of the mold 100 via the hooks 175a, 175b in the block 300 resulting from the hook portions 138 in the hollow core insert 112.
The mold 100 may be made from any suitable material, such as stainless steel or another metallic alloy or a polymer.
While particular embodiments have been described in the foregoing, it is to be understood that other embodiments are possible and are intended to be included herein. It will be clear to any person skilled in the art that modifications of and adjustments to the foregoing embodiments, not shown, are possible.
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Translation of SU 1133102 A (date is not applicable). |
Number | Date | Country | |
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20130015601 A1 | Jan 2013 | US |