For various logistical and technical reasons, concrete floors are typically made up of a series of individual cast-in-place concrete blocks or slabs referred to herein as “concrete slabs” or “slabs”. These concrete slabs provide several advantages including relief of internal stress due to curing shrinkage and thermal movement. However, there are various known issues with such concrete slabs. These issues often involve the joint between concrete slabs, or the interface where one concrete slab meets another concrete slab.
More specifically, freshly poured concrete shrinks considerably as it cures or hardens due to the chemical reaction that occurs between the cement and water. As the concrete shrinks, tensile stress accumulates in the concrete. Therefore, the joints need to be free to open and thus enable shrinkage of each of the individual concrete slabs without damaging the concrete floor. The joint openings create discontinuities in the concrete floor surface that can cause the wheels of a vehicle (such as a forklift truck) to impact the edges of the adjacent concrete slabs that form the joint and chip small pieces of concrete from the edge of each concrete slab, particularly if the joint edges are not vertically aligned. This damage to the edges of concrete slabs is commonly referred to as joint spalling. Joint spalling can interrupt the normal working operations of a facility by slowing down forklift and other truck traffic, and/or causing damage to trucks and the carried products. Severe joint spalling and uneven joints can cause loaded forklift trucks to overturn (which of course is dangerous to people in those facilities). Joint spalling can also be very expensive and time consuming to repair.
Joint edge assemblies that protect such joints between concrete slabs are widely used in the construction of concrete floors (such as concrete floors in warehouses). Examples of known joint edge assemblies are described in U.S. Pat. Nos. 6,775,952 and 8,302,359. Various known joint edge assemblies enable the joint edges to both self-open with respect to the opposite joint edge as the adjacent concrete slabs shrink during curing or hardening. One known joint edge assembly is generally illustrated in
Another issue with such joints involves the vertical movements of adjacent concrete slabs relative to each other. The concrete slabs (such as concrete slabs 90 and 96) are preferably configured to move individually, and are also preferably configured with load transferring devices to transfer loads from one concrete slab to the adjacent concrete slab. Transferring loads between adjacent concrete slabs has been accomplished using various different load transferring devices. For example, certain known load transferring devices are in the form of steel dowels or rods and dowel receiving sheaths having circular cross-sections (such as those disclosed in U.S. Pat. Nos. 5,005,331, 5,216,862, and 5,487,249). Other known load transferring devices are in the form of steel dowels or rods and dowel receiving sheaths having rectangular cross-sections (such as those disclosed in U.S. Pat. No. 4,733,513). Such circular and rectangular dowels are capable of transferring loads between adjacent concrete slabs, but have various shortcomings. For example, if such circular or rectangular dowels are misaligned (i.e., not positioned perpendicular to joint), they can undesirably lock the joint together causing unwanted stresses that could lead to slab failure in the form of cracking of the concrete slab. Such misaligned dowels can also restrict movement of the concrete slabs in certain directions. Another shortcoming of such circular and rectangular dowels is that they typically enable the adjacent slabs to move only along the longitudinal axis of the dowel. Another known shortcoming of such circular and rectangular dowels results from the fact that, under a load, only the first 3 to 4 inches of each dowel is typically used for transferring the load from one slab to the adjacent slab. This can create relatively high loadings per square inch at the edge of one or more of the adjacent concrete slabs, which can result in failure of the concrete above or below the dowel.
To solve these problems, load transferring devices such as the dowel and dowel receiving sheath disclosed in U.S. Pat. No. 6,354,760 were developed. These known load transferring devices provide increased relative movement between the adjacent concrete slabs in a direction parallel to the longitudinal axis of the joint and reduce loadings per square inch in the adjacent concrete slabs close to the joint, while transferring loads between the adjacent concrete slabs. These load transferring devices are commercially sold by the assignee of the present application. These load transferring devices have been widely sold and commercially utilized.
In certain circumstances, such as under heavy loads or in relatively thin concrete slabs, it has been found that these load transferring devices do not always move into or remain in or close to the optimal position for load transfer between the adjacent concrete slabs after the adjacent concrete slabs cure.
In certain circumstances, it has also been found that these known load transferring devices 70 and 80 can cause stress fractures to the concrete slabs or parts of the concrete slabs.
Accordingly, there is a need for improved load transfer devices and methods of using such improved load transfer devices that solve these problems.
Various embodiments of the present disclosure provide a load transfer apparatus including a load transfer plate and a load transfer plate pocket, and method of employing same that solves the above problems.
Various embodiments of the present disclosure provide a load transfer apparatus including a load transfer plate and a load transfer plate pocket that co-act to transfer vertical or substantially vertical loads from one concrete slab to the adjacent concrete slab in an enhanced manner by optimizing the position of the load transfer plate relative to the adjacent concrete slabs for load transfers between the adjacent concrete slabs.
The present disclosure recognizes that the load transfer plate will generally produce its smallest load per square inch at its widest point. The present disclosure further recognizes that the optimal position for the load transfer plate is thus generally along the vertically extending central plane between the two adjacent concrete slabs. In various embodiments, the load transfer plate and the load transfer plate pocket of the present disclosure are thus configured to cause the load transfer plate to be positioned with its widest area along or as close as possible to the vertically extending central plane between the two concrete slabs. Thus, in various embodiments, the load transfer plate of the present disclosure is self-centering. The load transfer plate and the load transfer plate pocket of the present disclosure are also configured to enable the load transfer plate to move with and as the central plane between the two concrete slabs moves.
Various embodiments of the load transfer plate of the present disclosure include one or more interior edges that define one or more slab attachment openings. These slab attachment openings enable concrete of the second slab to extend through the load transfer plate when the load transfer plate is positioned in the load transfer plate pocket and concrete that forms the second slab is poured. This causes the load transfer plate to be secured or locked to the second concrete slab after this concrete slab cures or hardens. Thus, the load transfer plate moves with the shrinkage of the second concrete slab and also moves with any other subsequent movement of the second concrete slab.
Various embodiments of the present disclosure also provide a load transfer apparatus including a load transfer plate and load transfer plate pocket that minimize stress fractures to the concrete slabs above or below the load transfer plate or load transfer plate pocket.
Various embodiments of the load transfer plate of the present disclosure includes a generally diamond shaped body having: (a) a substantially tapered first half or portion configured to be in the load transfer plate pocket at installation and move with respect to the load transfer plate pocket (that is configured to be secured in the first concrete slab); and (b) a substantially tapered second half or portion configured to be partially in the load transfer pocket at installation and partially protrude into and be secured in the second concrete slab. The body of the load transfer plate includes: (a) a substantially planar upper surface; (b) a substantially planar lower surface; (c) a first stress reducing outer edge; (d) a second stress reducing outer edge; (e) a third stress reducing outer edge; and (f) a fourth stress reducing outer edge.
The stress reducing outer edges are configured to reduce the concentrated stresses that the outer edges of the known load transfer plates place on the portions of the concrete slab when vertical loads are placed on such known load transfer plates. More specifically, the stress reducing outer edges are configured to spread the forces from a single line along the concrete slab to a wider area to reduce the concentrated stresses that the outer edges of the load transfer plates place on the portions of the concrete slab when vertical loads are placed on such known load transfer plates. These stress reducing outer edges additionally increase the amount of vertical load that can be placed on the load transfer plate before the load transfer plate causes a crack in the concrete slab above or below the load transfer plate.
Additional features and advantages of the present invention are described in, and will be apparent from, the following Detailed Description and the Figures.
Various embodiments of the present disclosure provide an improved load transfer apparatus including an improved load transfer plate and an improved load transfer plate pocket that solve the above problems. The load transfer apparatus is configured to transfer loads between a first cast-in-place slab (such a first concrete slab) and a second adjacent cast-in-place slab (such as a second concrete slab).
Referring now to
In this illustrated example embodiment shown in
It should be appreciated that in an alternative method of the present disclosure, if slab 96 is poured before slab 90, then the load transfer plate pocket 300 would be attached to a form (not shown) before the concrete slab 96 is poured such that the load transfer plate pocket 300 extends into the concrete slab 96 and would be maintained in the concrete slab 96 after the concrete slab 96 is poured and hardened or cured. If concrete slab 96 is poured before concrete slab 90, the load transfer plate 100 would be inserted in the load transfer plate pocket 300 after (or alternatively before) the concrete slab 96 is poured, and before the concrete slab 90 is poured.
In this illustrated example embodiment, the load transfer plate 100 includes a generally diamond shaped body 110 having: (a) a substantially tapered first half or portion 112 configured to protrude into and move with respect to the load transfer plate pocket 300 that is secured in the first concrete slab 90; and (b) a substantially tapered second half or portion 114 configured to be initially partially positioned in the load transfer plate pocket 300 at installation and also protrude into and be secured in the second concrete slab 96. In this illustrated embodiment, the substantially tapered first portion 112 and the substantially tapered second portion 114 are substantially equal in size and shape.
In this illustrated example embodiment, the substantially tapered first portion 112 has a largest width (measured parallel to the longitudinal axis of the joint) at the area of the first portion 112 adjacent to tapered second portion 114, and a smallest width at the point 113. In this illustrated example embodiment, the first portion 112 is uniformly tapered from the area of the first portion 112 adjacent to second portion 114 to the point 113; however, such taper does not have to be uniform in accordance with the present disclosure.
In this illustrated example embodiment, the substantially tapered second portion 114 has a largest width (measured parallel to the longitudinal axis of the joint) at the area of the second portion 114 adjacent to tapered first portion 112, and a smallest width at the point 115. In this illustrated example embodiment, the second portion 114 is uniformly tapered from the area of the second portion 114 adjacent to first portion 112 to the point 115; however, such taper does not have to be uniform in accordance with the present disclosure.
Accordingly, in this illustrated example embodiment, the load transfer plate 100 has its greatest width at the area where the substantially tapered first portion 112 and the substantially tapered second portion 114 meet or connect (i.e., along the center line or plane 116).
In this illustrated example embodiment, the load transfer plate 100 is also relatively wide compared to its thickness or height and has a length to width ratio of approximately 1:1; however, it should be appreciated that the width compared to the thickness or height may vary, and that the length to width ratio may vary in accordance with the present disclosure.
The body 110 of the load transfer plate 100 also generally includes: (a) a substantially planar upper surface 120; (b) a substantially planar lower surface 130; (c) a first stress reducing outer edge 140; (d) a second stress reducing outer edge 150; (e) a third stress reducing outer edge 160; (f) a fourth stress reducing outer edge 170; and (g) an interior edge 180 that defines a slab attachment opening 190.
The first stress reducing outer edge 140 includes: (a) a side edge 142 that extends perpendicular to the upper surface 120 and to the lower surface 130; (b) a top angled edge 144 that extends downwardly at an obtuse angle from the upper surface 120 to the side edge 142, and that extends upwardly at an obtuse angle from the side edge 142 to the upper surface 120; and (c) a bottom angled edge 146 that extends upwardly at an obtuse angle from the lower surface 130 to the side edge 142, and that extends downwardly at an obtuse angle from the side edge 142 to the lower surface 130.
The second stress reducing outer edge 150 includes: (a) a side edge 152 that extends perpendicular to the upper surface 120 and to the lower surface 130; (b) a top angled edge 154 that extends downwardly at an obtuse angle from the upper surface 120 to the side edge 152, and that extends upwardly at an obtuse angle from the side edge 152 to the upper surface 120; and (c) a bottom angled edge 156 that extends upwardly at an obtuse angle from the lower surface 130 to the side edge 152, and that extends downwardly at an obtuse angle from the side edge 152 to the lower surface 130.
The third stress reducing outer edge 160 includes: (a) a side edge 162 that extends perpendicular to the upper surface 120 and to the lower surface 130; (b) a top angled edge 164 that extends downwardly at an obtuse angle from the upper surface 120 to the side edge 162, and that extends upwardly at an obtuse angle from the side edge 162 to the upper surface 120; and (c) a bottom angled edge 166 that extends upwardly at an obtuse angle from the lower surface 130 to the side edge 162, and that extends downwardly at an obtuse angle from the side edge 162 to the lower surface 130.
The fourth stress reducing outer edge 170 includes: (a) a side edge 172 that extends perpendicular to the upper surface 120 and to the lower surface 130; (b) a top angled edge 174 that extends downwardly at an obtuse angle from the upper surface 120 to the side edge 172, and that extends upwardly at an obtuse angle from the side edge 172 to the upper surface 120; and (c) a bottom angled edge 176 that extends upwardly at an obtuse angle from the lower surface 130 to the side edge 172, and that extends downwardly at an obtuse angle from the side edge 172 to the lower surface 130.
In this illustrated example embodiment, the three part multiple angled or chamfered stress reducing outer edges 140, 150, 160, and 170 reduce the concentrated stresses that the outer edges of the load transfer plate 100 place on the portions of the concrete slab when which vertical loads are placed on the load transfer plate 100. More specifically, these three part multiple angled or chamfered stress reducing outer edges 140, 150, 160, and 170 spread the forces from a single line along the concrete slab to a wider area to reduce the concentrated stresses that the outer edges of the load transfer plate 100 place on the portions of the concrete slab when vertical loads are placed on the load transfer plate 100. These three part multiple angled or chamfered stress reducing outer edges 140, 150, 160, and 170 additionally increase the amount of vertical load that can be placed on the load transfer plate 100 before the load transfer plate 100 causes a crack in the concrete slab.
It should be appreciated that in alternative embodiments, less than off of the edges are stress reducing edges.
The load transfer plate 100 additionally includes the interior edge 180 that defines the slab attachment opening 190. This slab attachment opening 190 enables concrete of the second slab 96 to extend through the load transfer plate 100 when the load transfer plate 100 in positioned in the pocket 300 and concrete of the second slab 96 is poured. This causes the load transfer plate 100 to be locked to the second concrete slab 96 after the concrete slab 96 is cured. Thus, in this illustrated example embodiment, the load transfer plate 100 moves with the shrinkage of the second concrete slab 96 and additionally moves with various other lateral movements of the second concrete slab 96. It should be appreciated that the shape of the slab attachment opening may vary in accordance with the present disclosure. It should be appreciated that the quantity of slab attachment openings may vary in accordance with the present disclosure.
This illustrated example embodiment of the load transfer plate pocket 300 includes an attachment wall 310 and a generally triangular shaped body integrally formed and extending from the back or back face of the attachment wall 310. The body 320 of this illustrated example load transfer plate pocket 300 includes: (a) a triangular upper wall 330; (b) a triangular lower wall 340; (c) a first side wall 350; (d) a second side wall 360; (f) a plurality of first load transfer plate positioners 370a and 370b; (g) a plurality of second load transfer plate positioners 380a and 380b; (h) a third load transfer plate centering positioner 371a; (i) a fourth load transfer plate centering positioner 381a.
More specifically, the attachment wall 310 in this illustrated example embodiment includes a generally flat rectangular body 311 that defines: (a) a load transfer plate receiving opening or slot 312; (b) a first fastener opening 313; and (c) a second fastener opening 314. The load transfer plate receiving opening or slot 312 is configured such that the load transfer plate 100 can freely move through the load transfer plate receiving opening or slot 312. The first fastener opening 313 and the second fastener opening 314 are configured to respectively receive fasteners such as nails (not shown) that during installation secure and hold the load transfer plate pocket 300 to the form (not shown) before and during pouring of the first concrete slab 90 such that: (a) the attachment wall 310 extends in the same plane as the outer vertical surface of the first concrete slab 90; and (b) the rest of or the body 320 of the load transfer plate pocket 300 extends into the first concrete slab 90.
The triangular upper wall 330 is integrally formed with and extends from the back or back face of the body 311 of the attachment wall 310 above the load transfer plate receiving opening or slot 312. The triangular lower wall 340 is integrally formed with and extends from the back or back face of the body 311 of the attachment wall 310 below the load transfer plate receiving opening or slot 312. The triangular lower wall 340 is thus spaced apart from the triangular upper wall 330 such that the load transfer plate 100 can freely move between the lower wall 340 and the upper wall 330.
The first side wall 350 is integrally formed with and extends from the back or back face of the body 311 of the attachment wall 310 adjacent to one side of the load transfer plate receiving opening or slot 312. The first side wall 350 is also integrally connected to the triangular upper wall 330. The first side wall 350 is also integrally connected to the triangular lower wall 330.
The second side wall 360 is integrally formed with and extends from the back or back face of body 311 of the attachment wall 310 adjacent to the other side of the load transfer plate receiving opening or slot 312. The second side wall 360 is integrally connected to the triangular upper wall 330. The second side wall 360 is integrally connected to the triangular lower wall 330. The second side wall 360 is integrally formed with and extends the first side wall 350.
The attachment wall 310, the triangular upper wall 330, the triangular lower wall 340, the first side wall 350, and the second side wall 360 define a load transfer plate receiving chamber or area 308 that in this illustrated example embodiment is configured to receive the entire first half or portion 112 of the load transfer plate 100 and part of the second half or portion 114 of the load transfer plate as generally shown in
In this illustrated example embodiment, the width of the load transfer plate receiving chamber or area 308 of the load transfer plate pocket 300 is greater than the width of the substantially tapered end of the load transfer plate 100 at each corresponding depth along the substantially first tapered half or portion 112 of the load transfer plate 100, such that the substantially first tapered half or portion 112 of the load transfer plate 100 and part of the second half or portion 114 of the load transfer plate 100 can be positioned within the load transfer plate pocket 300 in a direction parallel to the upper surface of the first slab 96. In other words, in this illustrated embodiment, the load transfer plate 100 and the load transfer plate pocket 300 are configured and sized such that: (a) the distance X (as shown in
The plurality of first load transfer plate positioners 370a and 370b are integrally connected to and extend inwardly from the first side wall 350 toward the back face of the attachment wall 310. The plurality of first load transfer plate positioners 370a and 370b in this illustrated embodiment are flexible and thus bend when the load transfer plate 100 moves further into or expands further into the pocket or area 308 and engages the first load transfer plate positioners 370a and 370b under sufficient pressure.
Likewise, the plurality of second load transfer plate positioners 380a and 380b are integrally connected to and extend inwardly from the second side wall 360 toward the back face of the attachment wall 310. The plurality of second load transfer plate positioners 380a and 380b are flexible and thus bend when the load transfer plate 100 further moves into the pocket or area 308 and engages these first load transfer plate positioners 380a and 380b under sufficient pressure.
The plurality of load transfer plate positioners 370a, 370b, 380a, and 380b thus account for the situation where the concrete slabs are made from a concrete that first expands before it contracts. In such case, the plurality of load transfer plate positioners 370a, 370b, 380a, and 380b in this illustrated embodiment allow for such expansion and movement of the load transfer plate 100 further into the load transfer plate pocket 300 (i.e., into the interior void between the plate 100 and pocket 300). The plurality of load transfer plate positioners 370a, 370b, 380a, and 380b in this illustrated embodiment also allow for heat expansion of the load transfer plate 100 itself. In certain embodiments, one or more of the load transfer plate positioners 370a, 370b, 380a, and 380b can be configured to break off from the walls or walls of the load transfer plate pocket 300. It should be appreciated that the quantity of load transfer plate positioners can vary in accordance with the present disclosure.
The load transfer plate pocket 300 also includes load transfer plate centering positioners 371a and 381b for initially centering the load transfer plate 100 within the width of the load transfer plate pocket 300 during initial installation of the load transfer plate 100 in the load transfer plate pocket 300. The load transfer plate centering positioners 371a and 381b are spaced apart such that they engage the opposing side points of the load transfer plate 100. In certain embodiments, the load transfer plate centering positioners 371a and 381a are configured to engage first and second tips of the load transfer plate, wherein the first and second tips define a widest area of the load transfer plate, as illustrated in
In various embodiments the load transfer plate positioners 370a, 370b, 380a, and 380b and/or the load transfer plate centering positioners 371a and 381a can assist in allowing for lateral movements of the load transfer plate 100 in the load transfer plate pocket 300 (such as lateral movements which may occur after shrinkage).
The present disclosure recognizes that the load transfer plate 100 will generally produce its smallest load per square inch at its widest point. The present disclosure further recognizes that the optimal position for the load transfer plate 100 is thus generally along the vertically extending central plane between the two adjacent concrete slabs 90 and 96. The load transfer plate 100 and the load transfer plate pocket 300 of the present disclosure are thus configured to cause the load transfer plate 100 to be positioned with its widest area along or as close as possible to the vertically extending central plane between the two concrete slabs 90 and 96. The load transfer plate 100 and the load transfer plate pocket 300 of the present disclosure are also configured to enable the load transfer plate 100 to move with and as the central plane between the two concrete slabs 90 and 96 moves.
More specifically,
As indicated or mentioned above, the present disclosure further provides a method of installing the load transfer plate pocket 300 and the load transfer plate 100 for transferring loads between a first cast-in-place concrete slab and a second cast-in-place concrete slab. In various embodiments, the method includes the steps of: (1) placing an edge form on the ground or other suitable substrate; (2) attaching a load transfer plate pocket 300 to the edge form such that part of the load transfer plate pocket 300 extends into the area where the first concrete slab 90 will be formed; (3) pouring the concrete material which forms the first concrete slab 90; (4) allowing the first concrete slab 90 to cure or harden to a certain degree; (5) removing the edge form from the first concrete slab 90 such that the load transfer plate pocket 300 remains within and attached to the first concrete slab 90; (6) inserting the first portion 112 of the load transfer plate 100 into the substantially load transfer plate pocket 300 such that the second portion 114 of the load transfer plate 100 is also partially in the load transfer plate pocket 300 and protrudes into second area where the second concrete slab 96 will be formed; (7) pouring the concrete material that forms the second cast-place concrete slab 96 into the second area where the second concrete slab 96 will be formed; and (8) allowing the second concrete slab 96 to cure or harden. This method enables the load transfer plate 100 and the load transfer plate pocket 300 to be configured to enable the load transfer plate 100 to move with and as the central plane between the two concrete slabs 90 and 96 moves. This method also enables the load transfer plate 100 to be positioned with its widest area along or as close as possible to the vertically extending central plane between the two concrete slabs 90 and 96.
Referring now to
In this illustrated example embodiment, the substantially tapered first portion 1112 has a largest width (measured parallel to the longitudinal axis of the joint) at the area of the first portion 1112 adjacent to tapered second portion 1114, and a smallest width at the point 1113. In this illustrated example embodiment, the first portion 1112 is uniformly tapered from the area of the first portion 1112 adjacent to second portion 1114 to the point 1113; however, such taper does not have to be uniform in accordance with the present disclosure.
In this illustrated example embodiment, the substantially tapered second portion 1114 has a largest width (measured parallel to the longitudinal axis of the joint) at the area of the second portion 1114 adjacent to tapered first portion 1112, and a smallest width at the point 1115. In this illustrated example embodiment, the second portion 1114 is uniformly tapered from the area of the second portion 1114 adjacent to first portion 1112 to the point 1115; however, such taper does not have to be uniform in accordance with the present disclosure.
Accordingly, in this illustrated example embodiment, the load transfer plate 1100 has its greatest width at the area where the substantially tapered first portion 1112 and the substantially tapered second portion 1114 meet or connect (i.e. along a center line or plane). In this illustrated example embodiment, the load transfer plate 1100 is also relatively wide compared to its thickness or height and has a length to width ratio of approximately 1:1; however, it should be appreciated that the width compared to the thickness or height may vary, in accordance with the present disclosure.
The first stress reducing outer edge 1140 includes a somewhat semi-cylindrical, rounded, or curved side edge. The second stress reducing outer edge 1150 includes a somewhat semi-cylindrical, rounded, or curved side edge. The third stress reducing outer edge 1160 includes a somewhat semi-cylindrical, rounded, or curved side edge. The fourth stress reducing outer edge 1170 includes a somewhat semi-cylindrical, rounded, or curved side edge.
In this illustrated example embodiment, the semi-cylindrical, rounded, or curved stress reducing outer side edges 1140, 1150, 1160, and 1170 reduce the concentrated stresses that the outer edges of the load transfer plate 1100 place on the portions of the concrete slab when vertical loads are placed on the load transfer plate 1100. More specifically, these semi-cylindrical, rounded, or curved outer side edges 1140, 1150, 1160, and 1170 spread the forces from a single line along the concrete slab to a wider area to reduce the concentrated stresses that the outer edges of the load transfer plate 1100 place on the portions of the concrete slab when vertical loads are placed on the load transfer plate 1100. These semi-cylindrical, rounded, or curved outer side edges 1140, 1150, 1160, and 1170 additionally increase the amount of vertical load that can be placed on the load transfer plate 1100 before the load transfer plate 1100 causes a crack in the concrete slab.
Referring now to
The body 2110 of the load transfer plate 2100 also generally includes: (a) a substantially planar upper surface 2120; (b) a substantially planar lower surface 2130; (c) a first stress reducing outer edge 2140; (d) a second stress reducing outer edge 2150; (e) a third stress reducing outer edge 2160; and (f) an interior edge 2180 that defines a slab attachment opening 2190. In this illustrated example embodiment, the body 2110 is uniformly tapered; however, such taper does not have to be uniform in accordance with the present disclosure. In this illustrated example embodiment, the substantially tapered body 2110 has a largest width at one end and a smallest width at the point 2115. In this illustrated example embodiment, the load transfer plate 2100 is also relatively wide compared to its thickness or height and has a length to width ratio of approximately 1:1; however, it should be appreciated that the width compared to the thickness or height, may vary in accordance with the present disclosure.
The first stress reducing outer edge 2140 includes a somewhat semi-cylindrical, rounded, or curved side edge 2142. The second stress reducing outer edge 2150 includes a somewhat semi-cylindrical, rounded, or curved side edge 2152. The third stress reducing outer edge 2160 includes a somewhat semi-cylindrical, rounded, or curved side edge 2162.
In this illustrated example embodiment, the semi-cylindrical, rounded, or curved stress reducing outer side edges 2140, 2150, and 2160 reduce the concentrated stresses that the outer edges of the load transfer plate 2100 place on the portions of the concrete slab when vertical loads are placed on the load transfer plate 2100. More specifically, these semi-cylindrical, rounded, or curved outer side edges 2140, 2150, and 2160 spread the forces from a single line along the concrete slab to a wider area to reduce the concentrated stresses that the stress reducing outer edges of the load transfer plate 2100 place on the portions of the concrete slab when vertical loads are placed on the load transfer plate 2100. These semi-cylindrical, rounded, or curved outer side edges 2140, 2150, and 2160 additionally increase the amount of vertical load that can be placed on the load transfer plate 2100 before the load transfer plate 2100 causes a crack in the concrete slab.
It should be appreciated that the load transfer plate and load transfer plate pocket can be employed without the joint edge assembly of
Referring now to
In this illustrated example embodiment shown in
It should be appreciated that in an alternative method of the present disclosure, if slab 96 is poured before slab 90, then the load transfer plate pocket 3300 would be attached to a form (not shown) before the concrete slab 96 is poured such that the load transfer plate pocket 3300 extends into the concrete slab 96 and would be maintained in the concrete slab 96 after the concrete slab 96 is poured and hardened or cured. If concrete slab 96 is poured before concrete slab 90, the load transfer plate such as load transfer plate 70 would be inserted in the load transfer plate pocket 3300 after (or alternatively before) the concrete slab 96 is poured, and before the concrete slab 90 is poured.
In this illustrated example embodiment, the load transfer plate 70 includes a generally diamond shaped body 71 having: (a) a substantially tapered first half or portion 72 configured to protrude into and move with respect to the load transfer plate pocket 3300 that is secured in the first concrete slab 90; and (b) a substantially tapered second half or portion 74 configured to be initially partially positioned in the load transfer plate pocket 3300 at installation and also protrude into and be secured in the second concrete slab 96. In this illustrated embodiment, the substantially tapered first portion 72 and the substantially tapered second portion 74 are substantially equal in size and shape and meet at a center line or plane 76.
In this illustrated example embodiment, the substantially tapered first portion 72 has a largest width (measured parallel to the longitudinal axis of the joint) at the area of the first portion 72 adjacent to tapered second portion 74, and a smallest width at the point 73. In this illustrated example embodiment, the first portion 72 is uniformly tapered from the area of the first portion 72 adjacent to second portion 74 to the point 73; however, such taper does not have to be uniform in accordance with the present disclosure.
In this illustrated example embodiment, the substantially tapered second portion 74 has a largest width (measured parallel to the longitudinal axis of the joint) at the area of the second portion 74 adjacent to tapered first portion 72, and a smallest width at the point 75. In this illustrated example embodiment, the second portion 74 is uniformly tapered from the area of the second portion 74 adjacent to first portion 72 to the point 75; however, such taper does not have to be uniform in accordance with the present disclosure.
Accordingly, in this illustrated example embodiment, the load transfer plate 70 has its greatest width at the area where the substantially tapered first portion 72 and the substantially tapered second portion 74 meet or connect (i.e., along the center line or plane 76).
In this illustrated example embodiment, the load transfer plate 70 is also relatively wide compared to its thickness or height and has a length to width ratio of approximately 1:1; however, it should be appreciated that the width compared to the thickness or height may vary, and that the length to width ratio may vary in accordance with the present disclosure.
The body 71 of the load transfer plate 70 also generally includes: (a) a substantially planar upper surface 82; (b) a substantially planar lower surface (not labeled); (c) a first outer edge 86; (d) a second outer edge 87; (e) a third outer edge 88; and (f) a fourth outer edge 89.
This illustrated example embodiment of the load transfer plate pocket 3300 includes an attachment wall 3310 and a generally triangular shaped body 3320 integrally formed and extending from the back or back face of the attachment wall 3310. The body 3320 of this illustrated example load transfer plate pocket 3300 includes: (a) a triangular upper wall 3330; (b) a triangular lower wall 3340; (c) a first side wall 3350; (d) a second side wall 3360; (f) a first load transfer plate positioner 3370a;(g) a second load transfer plate positioner 3380a; (h) a first load transfer plate engager 3372a; (i) a second load transfer plate engager 3382a; (j) a third load transfer plate centering positioner 3371a; and (k) a fourth load transfer plate centering positioner 3381a.
More specifically, the attachment wall 3310 in this illustrated example embodiment includes a generally flat rectangular body 3311 that defines: (a) a load transfer plate receiving opening or slot 1312; (b) a first fastener opening 3313; and (c) a second fastener opening 3314. The load transfer plate receiving opening or slot 3312 is configured such that the load transfer plate 70 can freely move through the load transfer plate receiving opening or slot 3312. The first fastener opening 3313 and the second fastener opening 3314 are configured to respectively receive fasteners such as nails (not labeled but shown in
In this illustrated example embodiment, the body 3320 of the load transfer plate pocket 3300 further includes spaced apart nail guides 3315 and 3317 integrally connected to the back of the attachment wall 3310 for assisting in guiding the nails that secure the load transfer plate pocket 3300 to a removable form (as described herein).
In this illustrated example embodiment, the body 3320 of the load transfer plate pocket 3300 further includes braces or supports 3314 and 3315 respectively integrally connected to the nail guides 3315 and 3317 and the first side wall 3350 and the second side wall 3360 for providing additional structural bracing or support for the load transfer plate pocket 3300.
The triangular upper wall 3330 is integrally connected to the attachment wall 3310. The triangular lower wall 3340 is integrally connected to the attachment wall 3310. The triangular lower wall 3340 is spaced apart from the triangular upper wall 3330 such that the load transfer plate 70 can freely move between the lower wall 3340 and the upper wall 3330.
The first side wall 3350 is integrally connected to the attachment wall 3310 adjacent to one side of the load transfer plate receiving opening or slot 3312. The first side wall 3350 is also integrally connected to the triangular upper wall 3330. The first side wall 3350 is also integrally connected to the triangular lower wall 3330.
The second side wall 3360 is integrally connected to the attachment wall 3310 adjacent to the other side of the load transfer plate receiving opening or slot 3312. The second side wall 3360 is integrally connected to the triangular upper wall 3330. The second side wall 3360 is integrally connected to the triangular lower wall 3330. The second side wall 3360 is integrally formed with and extends the first side wall 3350.
The attachment wall 3310, the triangular upper wall 3330, the triangular lower wall 3340, the first side wall 3350, and the second side wall 3360 define a load transfer plate receiving chamber or area 3308 that in this illustrated example embodiment is configured to receive the entire first half or portion 72 of the load transfer plate 70 and part of the second half or portion 74 of the load transfer plate as generally shown in
In this illustrated example embodiment, the width of the load transfer plate receiving chamber or area 3308 of the load transfer plate pocket 3300 is greater than the width of the substantially tapered end of the load transfer plate 70 at each corresponding depth along the substantially first tapered half or portion 72 of the load transfer plate 70, such that the substantially first tapered half or portion 72 of the load transfer plate 70 and part of (such as about 10 to 15 percent of) the second half or portion 74 of the load transfer plate 70 can be positioned within the load transfer plate pocket 3300 in a direction parallel to the upper surface of the first slab 96. In other words, in this illustrated embodiment, the load transfer plate 70 and the load transfer plate pocket 3300 are configured and sized such that: (a) the distance X (as shown in
The first load transfer plate positioner 3370a is integrally connected to and extends inwardly from the first side wall 3350 toward the back face of the attachment wall 3310. The first load transfer plate positioner 3370a in this illustrated embodiment is flexible and thus bends when the load transfer plate 70 moves further into or expands further into the pocket or area 3308 and places the first load transfer plate positioner 3370a under sufficient pressure.
Likewise, the second load transfer plate positioner 3380a is integrally connected to and extends inwardly from the second side wall 3360 toward the back face of the attachment wall 3310. The second load transfer plate positioner 3380a is flexible and thus bends when the load transfer plate 70 further moves into the pocket or area 3308 and places the first load transfer plate positioner 3380a under sufficient pressure.
In this illustrated embodiment, the first load transfer plate engager 3372a and the second load transfer plate engager 3382a extend transversely to each other and are integrally connected to each other at their respective first ends and form a plate apex or corner receiving area. In this illustrated example embodiment, the first load transfer plate engager 3372a and the second load transfer plate engager 3382a extend perpendicular or substantially perpendicular to each other. In this illustrated example embodiment, the first load transfer plate engager 3372a and the second load transfer plate engager 3382a are respectively integrally connected to the first load transfer plate positioner 3370a and the second load transfer plate positioner 3380a. In this illustrated example embodiment, the first load transfer plate engager 3372a extends parallel to or substantially parallel to the first side wall 3350. In this illustrated example embodiment, the second load transfer plate engager 3382a extends parallel to or substantially parallel to the second side wall 3360. In this illustrated example embodiment, the first load transfer plate engager 3372a is configured to be engaged by the second outer edge 87 of the load transfer plate 70 as shown in
Thus, (a) the first load transfer plate positioner 3370a; (b) b second load transfer plate positioner 3380a; (c) the first load transfer plate engager 3372a; and (d) the second load transfer plate engager 3382a, better receive and engage the load transfer plate 70 and co-act to receive and position the load transfer plate 70. This configuration also accounts for the situation where the concrete slabs are made from a concrete that first expands before it contracts. In such case, this configuration in this illustrated example embodiment allows for such expansion and movement of the load transfer plate 70 further into the load transfer plate pocket 3300 (i.e., into the interior void between the plate 70 and pocket 3300). This configuration also allows for heat expansion of the load transfer plate 70 itself. In certain embodiments, one or more of the load transfer plate positioners 3370a and 3380a can be configured to break off from the walls or walls of the load transfer plate pocket 3300. It should be appreciated that the quantity and positions of the load transfer plate engager can vary in accordance with the present disclosure.
The load transfer plate pocket 3300 also includes load transfer plate centering positioners 3371a and 3381a for initially centering the load transfer plate 70 within the width of the load transfer plate pocket 3300 during initial installation of the load transfer plate 70 in the load transfer plate pocket 3300. The load transfer plate centering positioners 3371a and 3381a are spaced apart such that they engage the opposing side points of the load transfer plate 70 (as shown in
The present disclosure recognizes that the load transfer plate 70 will generally produce its smallest load per square inch at its widest point. The present disclosure further recognizes that the optimal position for the load transfer plate 70 is thus generally along the vertically extending central plane between the two adjacent concrete slabs 90 and 96. The load transfer plate 70 and the load transfer plate pocket 3300 of the present disclosure are thus configured to cause the load transfer plate 70 to be positioned with its widest area along or as close as possible to the vertically extending central plane between the two concrete slabs 90 and 96. The load transfer plate 70 and the load transfer plate pocket 3300 of the present disclosure are also configured to enable the load transfer plate 70 to move with and as the central plane between the two concrete slabs 90 and 96 moves. In this example embodiment, the concrete of the second concrete slab will engage and cause the load the load transfer plate 70 to move out of the pocket to a more centered position.
More specifically,
At a subsequent point in time when the two adjacent cast-in-place concrete slabs 90 and 96 have cured and separated (like in
As indicated or mentioned above, the present disclosure further provides a method of installing the load transfer plate pocket 3300 and the load transfer plate 70 for transferring loads between a first cast-in-place concrete slab and a second cast-in-place concrete slab. In various embodiments, the method includes the steps of: (1) placing an edge form on the ground or other suitable substrate; (2) attaching a load transfer plate pocket 3300 to the edge form such that part of the load transfer plate pocket 3300 extends into a first area where the first concrete slab 90 will be formed; (3) pouring the concrete material which forms the first concrete slab 90; (4) allowing the first concrete slab 90 to cure or harden to a certain degree; (5) removing the edge form from the first concrete slab 90 such that the load transfer plate pocket 3300 remains within and attached to the first concrete slab 90; (6) inserting the first portion 72 of the load transfer plate 70 into the substantially load transfer plate pocket 3300 such that the second portion 74 of the load transfer plate 70 is also partially in the load transfer plate pocket 3300 and protrudes into a second area to be occupied by the second concrete slab 96; (7) pouring the concrete material that forms the second cast-place concrete slab 96 into the second area to be occupied by the second concrete slab 96; and (8) allowing the second concrete slab 96 to cure or harden. This method enables the load transfer plate 70 and the load transfer plate pocket 3300 to be configured to enable the load transfer plate 70 to move with and as the central plane between the two concrete slabs 90 and 96 moves. This method also enables the load transfer plate 70 to be positioned with its widest area along or as close as possible to the vertically extending central plane between the two concrete slabs 90 and 96.
In various embodiments of the present disclosure, the load transfer plate and the load transfer plate pocket are made of various suitable materials and in various suitable manners. In certain embodiments, the load transfer plate is made of steel and suitably cut from steel sheets. In other embodiments, the load transfer plate can be otherwise formed such as by 3-D printing. In certain embodiments, the load transfer plate pocket is made of a suitable molded plastic. In other embodiments, the load transfer plate pocket can be otherwise formed such as by 3-D printing.
It should be appreciated from the above that in various embodiments, the present disclosure provides a load transfer plate for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer plate comprising: a generally diamond shaped body having: (a) a substantially planar upper surface; (b) a substantially planar lower surface; (c) a first stress reducing outer edge; (d) a second stress reducing outer edge; and (e) an interior edge that defines a slab attachment opening; said generally diamond shaped body having: (i) a substantially tapered first portion configured to protrude into a load transfer plate pocket secured in the first cast-in-place concrete slab; and (ii) a substantially tapered second portion configured to protrude into and be secured in the second cast-in-place concrete slab.
In various such embodiments of the load transfer plate, the first stress reducing outer edge includes: (a) a side edge that extends perpendicular to the upper surface and to the lower surface; (b) a top angled edge that extends downwardly at an obtuse angle from the upper surface to the side edge, and that extends upwardly at an obtuse angle from the side edge to the upper surface; and (c) a bottom angled edge that extends upwardly at an obtuse angle from the lower surface to the side edge, and that extends downwardly at an obtuse angle from the side edge to the lower surface.
In various such embodiments of the load transfer plate, the second stress reducing outer edge includes: (a) a side edge that extends perpendicular to the upper surface and to the lower surface; (b) a top angled edge that extends downwardly at an obtuse angle from the upper surface to the side edge, and that extends upwardly at an obtuse angle from the side edge to the upper surface; and (c) a bottom angled edge that extends upwardly at an obtuse angle from the lower surface to the side edge, and that extends downwardly at an obtuse angle from the side edge to the lower surface.
In various such embodiments of the load transfer plate, the generally diamond shaped body has: (e) a third stress reducing outer edge; and (f) a fourth stress reducing outer edge.
In various such embodiments of the load transfer plate, the first stress reducing outer edge has a semi-cylindrical shape.
In various such embodiments of the load transfer plate, the body defines a plurality of interior edges that respectively define separate slab attachment openings.
In various such embodiments of the load transfer plate, (i) the substantially tapered first portion; and (ii) the substantially tapered second portion are substantially equal is size and shape.
It should also be appreciated from the above that in various embodiments, the present disclosure provides a load transfer plate pocket configured to receive a load transfer plate for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer plate pocket comprising: an attachment wall defining a load transfer plate receiving slot; and a generally triangular shaped body extending from a back of the attachment wall, the body including: (a) a generally triangular upper wall; (b) a generally triangular lower wall, said lower wall spaced apart from the upper wall such that the load transfer plate can freely move between the lower wall and the upper wall; (c) a first side wall extending from the back of the attachment wall and connected to the upper wall and to the lower wall; (d) a second side wall extending from the back of the attachment wall and connected to the upper wall and to the lower wall; (f) a first load transfer plate positioner extending from the first side wall; (g) a second load transfer plate positioner extending from the second side wall; (h) a centering third load transfer plate positioner extending from the first side wall; and (i) a centering fourth load transfer plate positioner extending from the second side wall.
It should also be appreciated from the above that in various embodiments, the present disclosure provides a load transfer apparatus for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer apparatus comprising: (A) a load transfer plate including a generally diamond shaped body having: (a) a substantially planar upper surface; (b) a substantially planar lower surface; (c) a first stress reducing outer edge; (d) a second stress reducing outer edge; and (e) an interior edge that defines a slab attachment opening; said generally diamond shaped body having: (i) a substantially tapered first portion; and (ii) a substantially tapered second portion configured to protrude into and be secured in the second cast-in-place concrete slab; and (B) a load transfer plate pocket configured to receive the load transfer plate, the load transfer plate pocket including: an attachment wall defining a load transfer plate receiving slot; and a generally triangular shaped body extending from a back of the attachment wall, the body including: (a) a generally triangular upper wall; (b) a generally triangular lower wall, said lower wall spaced apart from the upper wall such that the load transfer plate can freely move between the lower wall and the upper wall; (c) a first side wall extending from the back of the attachment wall and connected to the upper wall and to the lower wall; (d) a second side wall extending from the back of the attachment wall and connected to the upper wall and to the lower wall; (f) a first load transfer plate positioner extending from the first side wall; (g) a second load transfer plate positioner extending from the second side wall; (h) a centering third load transfer plate positioner extending from the first side wall; and (i) a centering fourth load transfer plate positioner extending from the second side wall.
In various such embodiments of the load transfer apparatus, the load transfer plate and the load transfer plate pocket are configured and sized such that: the load transfer plate can be positioned in the load transfer plate pocket beyond a center line of the load transfer plate.
It should also be appreciated from the above that in various embodiments, the present disclosure provides a load transfer apparatus for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer apparatus comprising: (A) a load transfer plate including a generally diamond shaped body having: (a) a substantially planar upper surface; (b) a substantially planar lower surface; and (c) an interior edge that defines a slab attachment opening; said generally diamond shaped body having: (i) a substantially tapered first portion; and (ii) a substantially tapered second portion configured to protrude into and be secured in the second cast-in-place concrete slab; and (B) a load transfer plate pocket configured to receive the load transfer plate, the load transfer plate pocket including: an attachment wall defining a load transfer plate receiving slot; and a body extending from a back of the attachment wall, the body including: (a) an upper wall; (b) a lower wall, said lower wall spaced apart from the upper wall such that the load transfer plate can freely move between the lower wall and the upper wall; (c) a first side wall extending from the back of the attachment wall and connected to the upper wall and to the lower wall; (d) a second side wall extending from the back of the attachment wall and connected to the upper wall and to the lower wall; (e) a first centering load transfer plate positioner extending from the first side wall; and (f) a second centering load transfer plate positioner extending from the second side wall, wherein the load transfer plate and the load transfer plate pocket are configured and sized such that the load transfer plate can be positioned in the load transfer plate pocket beyond a center line of the load transfer plate.
It should also be appreciated from the above that in various embodiments, the present disclosure provides a method of for transferring loads across a joint between a first concrete slab and a second concrete slab, said method comprising: (a) placing an edge form on a ground surface; (b) attaching a load transfer plate pocket to the edge form such that part of the load transfer plate pocket extends into a first area where the first concrete slab will be formed, said load transfer pocket configured to receive a load transfer plate, said load transfer plate including a generally diamond shaped body having: (i) a substantially planar upper surface; (ii) a substantially planar lower surface; (iii) a first outer edge; (iv) a second outer edge; (v) a third outer edge; (vi) a fourth outer edge; and (vii) an interior edge that defines a slab attachment opening; (c) pouring concrete material which forms the first concrete slab; (d) allowing the first concrete slab to partially cure; (e) removing the edge form from the first concrete slab such that the load transfer plate pocket remains at least partially within and attached to the first concrete slab; (f) inserting the load transfer plate into the load transfer plate pocket such that a portion of the second half of the load transfer plate protrudes into a second area where the second concrete slab will be formed; (g) pouring concrete material that forms the second concrete slab into the second area where the second concrete slab will be formed such that part of such concrete extends through the slab attachment opening of the load transfer plate; and (h) allowing the second concrete slab to partially cure such that the load transfer plate is secured to the second concrete slab.
It should also be appreciated from the above that in various embodiments, the present disclosure provides a method of for transferring loads across a joint between concrete first concrete slab and a second concrete slab, said method comprising: (a) placing an edge form on a ground surface; (b) attaching a load transfer plate pocket to the edge form such that part of the load transfer plate pocket extends into a first area where the first concrete slab will be formed; (c) pouring concrete material which forms the first concrete slab; (d) allowing the first concrete slab to partially cure; (e) removing the edge form from the first concrete slab such that the load transfer plate pocket remains at least partially within and attached to the first concrete slab; (f) inserting a first half of the load transfer plate into the load transfer plate pocket and a portion of a second half of the load transfer plate into the load transfer plate pocket, such that a portion of the second half of the load transfer plate protrudes into a second area to be occupied by the second concrete slab; (g) pouring concrete material that forms the second concrete slab into the second area to be occupied by the second concrete slab; and (h) allowing the second concrete slab to cure.
It should further be appreciated from the above that in various embodiments, the present disclosure provides a load transfer plate pocket configured to receive a load transfer plate for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer plate pocket comprising: an attachment wall defining a load transfer plate receiving slot; and a generally triangular shaped body extending from the attachment wall, the body including: (a) a generally triangular upper wall; (b) a generally triangular lower wall, said lower wall spaced apart from the upper wall such that the load transfer plate can freely move between the lower wall and the upper wall; (c) a first side wall connected to the upper wall and to the lower wall; (d) a second side wall connected to the upper wall and to the lower wall; (e) a first load transfer plate positioner extending from the first side wall; (f) a second load transfer plate positioner extending from the second side wall; (g) a centering third load transfer plate positioner extending from the first side wall; and (h) a centering fourth load transfer plate positioner extending from the second side wall.
In various such embodiments of the load transfer plate pocket, the pocket is configured and sized such that the load transfer plate can be positioned in the load transfer plate pocket beyond a center line of the load transfer plate.
In various such embodiments of the load transfer plate pocket, the pocket includes: (i) a third load transfer plate positioner extending from the first side wall; and (j) a fourth load transfer plate positioner extending from the second side wall.
In various such embodiments of the load transfer plate pocket, the pocket includes: (i) a first load transfer plate engager connected to the first load transfer plate positioner; and (j) a second load transfer plate engager connected to the second load transfer plate positioner.
In various such embodiments of the load transfer plate pocket, the first load transfer plate engager is connected to the second load transfer plate engager.
In various such embodiments of the load transfer plate pocket, the first load transfer plate engager is connected to the second load transfer plate engager at a substantially perpendicular angle.
In various such embodiments of the load transfer plate pocket, the first load transfer plate engager extends substantially parallel to the first side wall.
In various such embodiments of the load transfer plate pocket, the second load transfer plate engager extends substantially parallel to the second side wall.
In various such embodiments of the load transfer plate pocket, the first load transfer plate engager is configured to engage a first side edge of a load transfer plate.
In various such embodiments of the load transfer plate pocket, the second load transfer plate engager is configured to engage a second side edge of the load transfer plate.
It should further be appreciated from the above that in various embodiments, the present disclosure provides a load transfer plate pocket configured to receive a load transfer plate for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer plate pocket comprising: an attachment wall defining a load transfer plate receiving slot; and a generally triangular shaped body extending from the attachment wall, the body including: (a) a generally triangular upper wall; (b) a generally triangular lower wall, said lower wall spaced apart from the upper wall such that the load transfer plate can freely move between the lower wall and the upper wall; (c) a first side wall connected to the upper wall and to the lower wall; and (d) a second side wall connected to the upper wall and to the lower wall; wherein the load transfer plate pocket is configured and sized such that the load transfer plate can be positioned in the load transfer plate pocket beyond a center line of the load transfer plate.
In various such embodiments of the load transfer plate pocket, the pocket includes: (e) a first load transfer plate positioner extending from the first side wall; and (f) a second load transfer plate positioner extending from the second side wall.
In various such embodiments of the load transfer plate pocket, the pocket includes: (g) a centering third load transfer plate positioner extending from the first side wall; and (h) a centering fourth load transfer plate positioner extending from the second side wall.
In various such embodiments of the load transfer plate pocket, the pocket includes: (e) a centering third load transfer plate positioner extending from the first side wall; and (f) a centering fourth load transfer plate positioner extending from the second side wall.
It should further be appreciated from the above that in various embodiments, the present disclosure provides a load transfer apparatus for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer apparatus comprising: (A) a load transfer plate including a generally diamond shaped body having: (a) a substantially planar upper surface; and (b) a substantially planar lower surface; said generally diamond shaped body having: (i) a substantially tapered first portion; and (ii) a substantially tapered second portion configured to protrude into and be secured in the second cast-in-place concrete slab; and (B) a load transfer plate pocket configured to receive the load transfer plate, the load transfer plate pocket including: an attachment wall defining a load transfer plate receiving slot; and a body extending from the attachment wall, the body including: (a) an upper wall; (b) a lower wall, said lower wall spaced apart from the upper wall such that the load transfer plate can freely move between the lower wall and the upper wall; (c) a first side wall extending from the attachment wall and connected to the upper wall and to the lower wall; (d) a second side wall extending from the attachment wall and connected to the upper wall and to the lower wall; (e) a first centering load transfer plate positioner extending from the first side wall; and (f) a second centering load transfer plate positioner extending from the second side wall; wherein the load transfer plate and the load transfer plate pocket are configured and sized such that the load transfer plate can be positioned in the load transfer plate pocket beyond a center line of the load transfer plate.
In various such embodiments of the load transfer apparatus, the load transfer plate defines an interior edge that defines a slab attachment opening.
In various such embodiments of the load transfer apparatus, the load transfer plate includes at least one stress reducing outer edge.
It should further be appreciated from the above that in various embodiments, the present disclosure provides a load transfer apparatus for transferring loads across a joint between a first cast-in-place concrete slab and a second cast-in-place concrete slab, the load transfer apparatus comprising: (A) a load transfer plate including a generally diamond shaped body having: (a) a substantially planar upper surface; and (b) a substantially planar lower surface; said generally diamond shaped body having: (i) a substantially tapered first portion; and (ii) a substantially tapered second portion configured to protrude into and be secured in the second cast-in-place concrete slab; and (B) a load transfer plate pocket configured to receive the load transfer plate, the load transfer plate pocket including: an attachment wall defining a load transfer plate receiving slot; and a body extending from the attachment wall, the body including: (a) an upper wall; (b) a lower wall, said lower wall spaced apart from the upper wall such that the load transfer plate can freely move between the lower wall and the upper wall; (c) a first side wall extending from the attachment wall and connected to the upper wall and to the lower wall; (d) a second side wall extending from the attachment wall and connected to the upper wall and to the lower wall; wherein the load transfer plate pocket is configured and sized such that: the load transfer plate can be positioned in the load transfer plate pocket beyond a center line of the load transfer plate.
In various such embodiments of the load transfer apparatus, the load transfer plate defines an interior edge that defines a slab attachment opening.
In various such embodiments of the load transfer apparatus, the load transfer plate includes at least one stress reducing outer edge.
It should further be appreciated from the above that in various embodiments, the present disclosure provides a method of for transferring loads across a joint between a first concrete slab and a second concrete slab, said method comprising: (a) placing an edge form on a ground surface; (b) attaching a load transfer plate pocket to the edge form such that part of the load transfer plate pocket extends into a first area where the first concrete slab will be formed; (c) pouring concrete material which forms the first concrete slab; (d) allowing the first concrete slab to partially cure; (e) removing the edge form from the first concrete slab such that the load transfer plate pocket remains at least partially within and attached to the first concrete slab; (f) inserting a first half of the load transfer plate into the load transfer plate pocket and a first portion of a second half of the load transfer plate into the load transfer plate pocket, such that a second portion of the second half of the load transfer plate protrudes into a second area where the second concrete slab will be formed; (g) pouring concrete material that forms the second concrete slab into the second area where the second concrete slab will be formed; and (h) allowing the second concrete slab to cure.
It should be understood that various changes and modifications to the presently preferred embodiments described herein will be apparent to those skilled in the art. Such changes and modifications can be made without departing from the spirit and scope of the present subject matter and without diminishing its intended advantages. It is therefore intended that such changes and modifications be covered by the appended claims.
This application is a continuation of, claims priority to and the benefit of U.S. Non-Provisional patent application Ser. No. 15/809,343 filed Nov. 10, 2017 that claims priority to and the benefit of U.S. Provisional Patent Application No. 62/422,947, filed Nov. 16, 2016, the entire contents of both of which are incorporated herein by reference.
Number | Date | Country | |
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62422947 | Nov 2016 | US |
Number | Date | Country | |
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Parent | 15809343 | Nov 2017 | US |
Child | 16807358 | US |