Structural joint

Information

  • Patent Grant
  • 10323359
  • Patent Number
    10,323,359
  • Date Filed
    Monday, August 13, 2018
    6 years ago
  • Date Issued
    Tuesday, June 18, 2019
    5 years ago
Abstract
The present invention relates to a expansion joint to bridge an expansion gap between two parts of concrete slabs used in floor construction, especially in the manufacture of concrete floors such as for example in industrial floors. Such expansion joints are evidently required to take up the inevitable shrinkage process of the concrete and to assure that the floor elements can expand or contract such as for example occur by temperature fluctuations and resulting in a horizontal displacement of the floor panels vis-à-vis one another.
Description
FIELD OF THE INVENTION

The present invention relates to a expansion joint to bridge an expansion gap between two parts of concrete slabs used in floor construction, especially in the manufacture of concrete floors such as for example in industrial floors. Such expansion joints are evidently required to take up the inevitable shrinkage process of the concrete and to assure that the floor elements can expand or contract such as for example occur by temperature fluctuations and resulting in a horizontal displacement of the floor panels vis-à-vis one another.


BACKGROUND OF THE INVENTION

In addition, and given the fact that such floors are often subjected to high loads, further load transfer elements are typically included in the aforementioned joint profiles to assure that the vertical load on one floor panel is transmitted to the adjacent floor panel in an optimal way and thereby preventing a vertical tilting of the floor panels with respect to each other. However, when driving over such an expansion joint with heavily loaded vehicles such as forklifts, which often have particularly hard Vulkollan wheels, the presence of such load transfer elements cannot prevent damage of the upper circumferential edges of the slabs or to the wheels, due to the undesirable shock of the vehicle when passing the groove-like gap between the floor elements. This is especially due to the fact that the joint profile making up the edges of the floor elements is made of steel and therefore much harder than the commonly soft outer circumference surface of the wheels.


In an effort to address the drawback of the groove-like gap in the existing joint profiles, alternatives have been presented wherein the edges of the floor members by means of coggings interlock with one another. See for example AT113488, JP2-296903, DE3533077 or WO2007144008. However, in as far each of said arrangements ensures that the wheels when leaving one edge are already supported on the boundary of the other; the mere presence of such cogging interlocks is insufficient to prevent damage at the upper circumferential edges of the floor elements. Vertical tilting of the floor members may still result in differences in height between the plates which gives rise to edges, further shocks and eventual damages to the floor. Consequently, also in these interlocking joint profiles load transfer elements will be required to assure that the vertical load on one floor panel is transmitted to the adjacent floor panel in an optimal way and thereby preventing a vertical tilting of the floor panels.


Such load transfer elements come in different shapes and embodiments, such as for example wedge-shaped dowels (DE 102007020816); horizontal grooves and protrusions cooperating with one another (BE1015453, BE1016147); plate dowels (U.S. Pat. No. 5,674,028, EP1584746, US2008222984) or bar dowels (EP0410079, U.S. Pat. No. 6,502,359, WO03069067, EP0609783). Irrespective of their embodiment, said load transfer elements needs to be incorporated in the floor deck adding not only to a minimum thickness for the floor, but also to additional material to be used and to complexity in construction.


In addition, metal interlocking end plates such as shown in AT113488 and JP-2-29603, still result in an abrupt change of expansion coefficient at the boundary of the floor slabs. As a consequence, these end plates tend to loosen over time with floor damage at the boundary between the concrete floor slabs at the metal end plates.


SUMMARY

It is therefore an object of the invention to provide a structural joint where no further load transfer elements are required, but still addressing the problems outlined hereinbefore.


This object is achieved in that the expansion joint itself structurally realizes load transfer. Thereto, the expansion joint according to the present invention has an upper and lower portion characterized in that the lower portion comprises a vertically oriented corrugated plate.


In a particular embodiment the expansion joint according to the present invention has an upper and lower portion each comprising a vertically oriented corrugated plate, characterized in that the corrugated plates of the upper and lower portion are out of phase to one another.


Within the context of the present invention, and as evident from the accompanying figures, the vertical orientation of the corrugated plates, is vertical with respect the floor surface, i.e. the plates are standing upright, i.e. perpendicular, with respect to the floor surface. In other words, with their thin side facing the floor surface.


In creating the upper edges of the concrete slabs, the upper portion of the expansion joint according to the present invention may further comprises a second vertically oriented corrugated plate that fits within the undulations of the vertically oriented corrugated plate of the upper portion to protect the upper edge of the opposing slab. Analogously, in creating the lower edges of the concrete slabs, the lower portion of the expansion joint according to the present invention may further comprise a second vertically oriented corrugated plate that fits within the undulations of the vertically oriented corrugated plate of the lower portion to protect the lower edge of the opposing slab.


Thus in a further embodiment of the present invention, the expansion joint of the present invention is characterized in having an upper (2) and lower (3) portion, each comprising two vertically oriented corrugated plates with undulations that fit in one another, and characterized in that the corrugated plates of the upper and lower portion are out of phase to one another.


The edge of a slab of concrete poured against the expansion joint of the present invention will have a denticulated upper portion and a denticulated lower portion both denticulations being out of phase to one another and interlocking with the denticulated upper and lower portion edge of the adjacent slab. In this way the adjacent slabs are fixed vertically to one another, but through the presence of the expansion joint, horizontal displacement of the adjacent slabs is still possible. Load transfer is realized through the dents at the edges of the concrete slabs and over an expansion width determined by the amplitude of the corrugations in the corrugated plates used in the expansion joint.


Other advantages and characteristics of the invention will become clear from the following description reference being made to the annexed drawings.





BRIEF DESCRIPTION OF THE FIGURES


FIG. 1 A perspective top view of an expansion joint according to the present invention.



FIG. 2 A perspective bottom view of an expansion joint according to the present invention.



FIG. 3 A frontal perspective view of one of the concrete slabs poured against the expansion joint according to the invention, showing the antiphase denticulated edges of the upper (12) and lower (13) portion of said slab.



FIG. 4 A top view of an expansion joint according to the invention. Within this figure the top portion of one of the concrete slabs is not shown, to expose how the dents (16) of the two concrete slabs interlock with one another.



FIG. 5 A frontal view of an expansion joint according to the invention, in an open position. In this embodiment the joint comprises two pairs of corrugated plates. One pair (4, 6) in the upper portion (2) and one pair (5, 17) in the lower portion (3). Plates (4) and (5) are connected with one another through a first binding member (8) and plates (6) and (17) are connected to one another through a second binding member (8). In this embodiment, the dowels (7) to anchor the expansion joint in the concrete slabs consist of rods longitudinally welded to the corrugated plates making up the expansion joint.



FIG. 6a A frontal view of an expansion joint according to the invention, having continuous bridging dowels (7) that longitudinally extend over the full length of the expansion joint, and which are connected to the upper and lower portion of the expansion joint.



FIG. 6b A perspective top side view of an expansion joint according to the present invention. Showing the continuous bridging dowel (7) connected at regular intervals (19) to the upper and lower portion, and the drop plate (18) positioned in between the corrugated plates at the lower portion of the expansion joint.



FIG. 6c A perspective top view of an expansion joint according to the present invention. Showing the continuous bridging dowel (7) connected at regular intervals (19) to the upper (4) and lower portion, and the binding member (8) positioned in between the upper and the lower portion of the expansion joint. It further shows the second corrugated plate (6) that fits within the undulations of the vertically oriented corrugated plate of the upper (4) portion.





DETAILED DESCRIPTION

With reference to FIGS. 1 and 2, the expansion joint according to the present invention has an upper (2) and lower (3) portion each comprising a vertically oriented corrugated plate (4, 5), characterized in that the corrugated plates of the upper (4) and lower (5) portion are out of phase to one another.


Within the context of the present invention there is no particular limitation as to the corrugation of the plates, in principle any alternating form is suitable, including wave, zigzag or dent forms. Where the amplitude and width of the corrugation between the upper and lower portion may be different, in one embodiment the corrugation of the upper and lower plates will be the same. In a particular embodiment the corrugation will consist of a waveform. In a more particular embodiment the corrugation of the upper and lower plate will be the same and consisting of a waveform.


The upper and lower corrugated plates (4, 5) will be in substantially the same lateral plane, but out of phase to one another. In particular in antiphase to one another. Said upper (4) and lower (5) corrugated plates are secured to one another, e.g. by welding (10), forced coupling with adhesive or other processes. In one embodiment the corrugated plates are secured to one another through a binding member (8) typically consisting of a metal sheet, more in particular a thin steel sheet, bound to both the upper (4) and lower (5) corrugated plates, e.g. by welding (10), forced coupling with adhesive or other processes. The presence of this binding member not only strengthens the connection between the upper (4) and lower (5) corrugated plates, but also assists in shielding eventual cross-flow of concrete from one side of the expansion joint to the other side when pouring the concrete slabs.


The expansion joint may further comprise anchoring dowels (7) to anchor the device in the slabs. The anchoring dowels may have any shape typically used. In general, the geometry of these anchoring elements does not modify the features of the invention. Also in the embodiments of FIGS. 1 & 2, the anchoring dowels (7) may be anchoring elements of any suitable shape or size. Evidently, said anchoring dowels are present on one side of either the upper (4) corrugated plate, the lower (5) corrugated plate, or even both, to anchor the joint profile in just one slab of the adjacent slabs. In an even further embodiment the anchoring dowels may bridge, and are accordingly connected to, the upper and lower portion of the expansion joint. With reference to FIG. 6, in a particular embodiment such an anchoring dowel bridging the upper and lower portion, consists of a dowel longitudinally extended over the full length of the expansion joint and meandering over the upper and lower portion of said joint. It is firmly connected at regular intervals (19) to both the upper and lower portion of the expansion joint, e.g. by welding, forced coupling with adhesive or other processes. Such continuous bridging dowel provides further stability and torsion strength to the expansion joint.


Thus in a further embodiment the present invention provides a continuous bridging dowel (7), connected at regular intervals (19) to an upper and lower portion of the side faces of the expansion joint and characterized in that it longitudinally extends and meanders over the full length of the expansion joint. In particular to the upper and lower portion of an expansion joint according to the present invention. As will be evident to a skilled artisan, the application of this continuous bridging dowel is not limited to the corrugated expansion joints of the present invention, but may as well be applied to any existing expansion joints.


With reference to FIGS. 6a and 6c, in a particular embodiment the continuous bridging anchoring dowel is further characterized in that, in between the consecutive connection points (19) to the respective upper and lower portion of the expansion joint, the dowel is V-shaped when viewed from a cross sectional front view (FIG. 6a) and when viewed from a top view (FIG. 6c). In other words, in a particular embodiment the continuous bridging dowel is further characterized in that in between each of said connection points and when viewed in cross sectional front view or top view, the bridging dowel is V-shaped.


As already explained hereinbefore, the concrete edge on the other side of the joint may further be protected by (a) second corrugated plate(s) (6), (17) that fits within the undulations (11) of the vertically oriented corrugated plate of the upper (4) portion, and/or the undulations of the vertically oriented corrugated plate of the lower (5) portion. At one side, this second corrugated plate(s) (6) and/or (17) may have further anchoring dowels (7) to anchor this second joint profile in the adjacent slab. This further anchoring dowel may again be an anchoring element of any suitable shape or size, including the continuous bridging dowel as described hereinbefore. As such the corrugated plates are each anchored in a slab part separated by the joint. In order to allow that the expansion joint comprising the second corrugated plate(s) is (are) easily installed, plates (4) and (6) are provisionally connected to one another, i.e. meaning that these plates are not firmly attached e.g. by welding, but are fixed together with sufficiently strong attachment means (9) such as bolts, clips or other adequate means, to allow the device to be installed easily. Within said particular embodiment wherein the expansion joints comprise two pair of corrugated plates, one pair (4, 6) in the upper portion and one pair (5, 17) in the lower portion, the corresponding upper and lower members of said pairs will be in substantially the same lateral plane, but out of phase to one another. In particular in antiphase to one another. Said upper and lower members are secured to one another, e.g. by welding (10), forced coupling with adhesive or other processes.


In other words, and with reference to FIG. 5, the upper corrugated plate (4) and its corresponding lower corrugated plate (5) will be in substantially the same lateral plane, secured to one another, but out of phase to one another; and the upper corrugated plate (6) and its corresponding lower corrugated plate (17) will be in substantially the same lateral plane, secured to one another, but out of phase to one another. In particular the plates (4, 5) and (6, 17) will be in antiphase to one another. Optionally, and in analogy with one of the foregoing embodiments, this embodiment may further comprise a binding member (8) present between, and secured to said corresponding upper and lower members. As in the foregoing embodiment this binding member (8) typically consisting of a metal sheet, more in particular a thin steel sheet, bound to both the upper (4, 6) and lower (5, 17) corrugated plates, e.g. by welding (10), forced coupling with adhesive or other processes. The presence of this binding member not only strengthens the connection between the upper (4, 6) and lower (5, 17) corrugated plates, but also assists in shielding eventual cross-flow of concrete from one side of the expansion joint to the other side when pouring the concrete slabs.


The corrugated plates (4, 5, 6, 17) used in the expansion profile of the present invention are preferably formed of a substantially rigid, metallic material, more preferably steel or stainless steel. As wear resistance of the concrete edges is predominant required at the upper portion, the corrugated plates of the upper portion are preferably made more wear resistant, such as using a different material or heavier (thicker—see FIG. 5) when compared to the corrugated plates in the lower portion. Accordingly, in an even further embodiment, the expansion joints as described herein are further characterized in that the corrugated plate(s) in the upper portion are more wear resistant when compared to the corrugated plate(s) in the lower portion.


As will be apparent to skilled artisan, said embodiments wherein the lower portion comprises a pair of corrugated plates has certain benefits when used in the manufacture of a floor member comprising said joints. The pair of corrugated plates in the lower portion ensures that the joints remain upright when placing. It further creates the opportunity of introducing a drop plate (18) between said pair of corrugated plates in the lower portion, thus extending the range in the thickness of floor member that can be made using the expansion joints of the present invention (see also FIG. 6) It is thus an object of the present invention to include a further drop plate to said expansion joints as described herein and having a pair of corrugated plates in the lower portion.


With reference to FIGS. 3 and 4, the edges of concrete slabs poured against the expansion joint as described herein will have an denticulated upper portion (12) and a denticulated lower portion (13) both denticulations being out of phase to one another in accordance with the phase shift of the upper (4) and lower (5) corrugated plate in the expansion joint, and accordingly interlock with the denticulated upper (14) and lower portion edge (15) of the adjacent slab. The dents (16) thus created in the adjacent concrete slabs will at the one hand realize the vertical fixation of floor and on the other hand allow a quasi continuous load transfer from one side to the other. Evidently, and as already mentioned hereinbefore, the amplitude and width of the corrugation in the lower (5) corrugated plate of the expansion joint will determine the maximally supported expansion of the expansion joint. The moment the denticulated upper portion edge of the concrete slab is retracted beyond the denticulated lower portion of the adjacent slab, the latter no longer supports the former and vertical fixation and load transfer are lost.


Where there are no particular limitation to the amplitude and shape of the corrugations in said plate, typical application in the manufacture of industrial concrete floors requires an expansion range of up to about 50 mm, in particular up to about 35 mm; more in particular up to about 20 mm. Consequently the amplitude of the corrugation should be such that upon maximal expansion of the expansion joint, the dents of the lower portion of the adjacent slab still support the dents of the upper portion of the opposing slab. Within the aforementioned range, the amplitude of the corrugation will be from about 25 mm to about 75 mm; in particular from about 25 mm to about 55 mm; more in particular from about 25 mm to about 35 mm.


In a further aspect, and based on the foregoing benefits regarding the pair of corrugated plates in the lower portion including a quasi continuous load transfer and a horizontal fixation between adjacent floor slabs, the corrugated joint in the upper portion of the expansion joint may be replaced with a straight joint.


In said case the expansion joint according to the present invention is characterized in having an upper (2) and lower (3) portion, characterized in that the upper portion provides a dividing member (4); in particular a pair of dividing members (4, 6) and in that the lower portion comprises a vertically oriented corrugated plate (5), in particular a pair of vertically oriented corrugated plates (5) and (17). As used herein, the dividing member(s) in the upper portion are there to create the upper edges and corresponding joint of the adjacent floor slabs. In principle any suitable means to create such joint can be applied as dividing members in the upper portion of the expansion joint as described herein. Again and in analogy with what has been described hereinbefore, said dividing members in the expansion profile of the present invention are preferably formed of a substantially rigid, metallic material, more preferably steel or stainless steel. As wear resistance of the concrete edges is predominant required at the upper portion, the dividing members of the upper portion are preferably made more wear resistant, such as using a different material or heavier (thicker—see FIG. 5) when compared to the corrugated plates in the lower portion.


In one embodiment said pair of dividing members in the upper portion consists of a pair of vertically oriented corrugated plates (4) and (6) wherein said pair of corrugated plates is out of phase with the pair of corrugated plates (5) and (17) in the lower portion. Again, these plates are secured to one another, either directly or by means of a binding member (8) as described herein before.


In another embodiment said pair of dividing members in the upper portion consists of a pair of straight and vertically oriented plates, such as for example a pair of L-profiles secured to the corrugated plates in the lower portion. The L-profiles of the upper portion and the corrugated plates of the lower portion are secured to one another, e.g. by welding (10), forced coupling with adhesive or other processes.


Again and in analogy with the previously described embodiments, the vertical orientation of the dividing members in the upper portion is their orientation with respect to the floor surface, i.e. the plates are standing upright, i.e. perpendicular, with respect to the floor surface. In other words, with their thin side facing the floor surface.

Claims
  • 1. An expansion joint, the expansion joint comprising an upper portion and a lower portion; wherein each of the upper portion and the lower portion comprise a first vertically oriented corrugated plate;wherein the upper portion further comprises a second vertically oriented corrugated plate that fits within undulations of the first vertically oriented corrugated plate of the upper portion; and the lower portion further comprises a second vertically oriented corrugated plate that fits within undulations of the first vertically oriented corrugated plate of the lower portion;wherein the expansion joint further comprises a first metal sheet positioned between and secured to the first vertically oriented corrugated plate of the upper portion and the first vertically oriented corrugated plate of the lower portion; and a second metal sheet positioned between and secured to the second vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the lower portion; andwherein the first vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the upper portion are positioned in antiphase to the first vertically oriented corrugated plate of the lower portion and the second vertically oriented corrugated plate of the lower portion.
  • 2. The expansion joint according to claim 1, wherein the first vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the upper portion are thicker or formed of a different material than that of the first vertically oriented corrugated plate of the lower portion and the second vertically oriented corrugated plate of the lower portion.
  • 3. The expansion joint according to claim 1, wherein a corrugation pattern of the first vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the upper portion and the first vertically oriented corrugated plate of the lower portion and the second vertically oriented corrugated plate of the lower portion is the same.
  • 4. The expansion joint according to claim 1, wherein a corrugation pattern of the first vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the upper portion and the first vertically oriented corrugated plate of the lower portion and the second vertically oriented corrugated plate of the lower portion consists of a waveform.
  • 5. The expansion joint according to claim 1, wherein the first vertically oriented corrugated plate of the upper portion and the first vertically oriented corrugated plate of the lower portion are in substantially the same lateral plane.
  • 6. The expansion joint according to claim 1, wherein the second vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the lower portion are in substantially the same lateral plane.
  • 7. The expansion joint according to claim 1, wherein the first vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the upper portion are connected to one another.
  • 8. The expansion joint according to claim 1, wherein the first vertically oriented corrugated plate of the upper portion and the second vertically oriented corrugated plate of the upper portion and the first vertically oriented corrugated plate of the lower portion and the second vertically oriented corrugated plate of the lower portion are formed of a substantially rigid material.
  • 9. The expansion joint according to claim 8, wherein the substantially rigid material is a metallic material.
  • 10. The expansion joint according to claim 8, wherein the substantially rigid material is steel.
  • 11. The expansion joint according to claim 1, further comprising a drop plate that fits in between the first vertically oriented corrugated plate of the lower portion and the second vertically oriented corrugated plate of the lower portion.
  • 12. The expansion joint according to claim 1, further comprising anchoring dowels.
  • 13. The expansion joint according to claim 12, wherein the anchoring dowels comprise a continuous bridging dowel, connected at regular intervals to an upper and lower portion of side faces of the expansion joint, and wherein the continuous bridging dowel longitudinally extends over a full length of the expansion joint.
Priority Claims (3)
Number Date Country Kind
1203314.8 Feb 2012 GB national
1215277.3 Aug 2012 GB national
1220095.2 Nov 2012 GB national
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 14/380,803, filed Aug. 25, 2014, which is a U.S. National Stage Entry of International Patent Application No. PCT/EP2013/053849, filed on Feb. 27, 2013, which designated the United States and claims priority to Great Britain Patent Application 1203314.18, filed on Feb. 27, 2012, Great Britain Patent Application 1215277.3, filed on Aug. 28, 2012, and Great Britain Patent Application 1220095.2, filed on Nov. 8, 2012, the contents of which are hereby incorporated by reference in their entirety.

US Referenced Citations (86)
Number Name Date Kind
1357713 Lane Nov 1920 A
1495305 Heltzel May 1924 A
1841039 Kleeman Jan 1932 A
1959610 Bowman May 1934 A
1978305 Eichelman Oct 1934 A
2031371 Kerr Feb 1936 A
2039144 Burgess Apr 1936 A
2074497 Voigt Mar 1937 A
2078693 Simrall Apr 1937 A
2107827 Kerr Feb 1938 A
2138817 Jacobson Dec 1938 A
2149291 Hofwolt Mar 1939 A
2150982 McFarland Mar 1939 A
2164590 Oates Jul 1939 A
2179911 Wilmoth Nov 1939 A
2205810 Carter Jun 1940 A
2224194 Mitchell Dec 1940 A
2265301 Ernest Dec 1941 A
RE21996 Oates Jan 1942 E
2278023 Robertson Mar 1942 A
2291157 Hillberg Jul 1942 A
2300995 Tufts Nov 1942 A
2351255 Fischer Jun 1944 A
2365550 Heltzel Dec 1944 A
2375361 Hillberg May 1945 A
2521643 Mathers Sep 1950 A
2552365 Bradbury May 1951 A
2642789 Brickman Jun 1953 A
2674164 Brickman Apr 1954 A
RE24172 Brickman Jun 1956 E
2822588 West Feb 1958 A
2949828 Carnes Aug 1960 A
3059553 Woolley Oct 1962 A
3344720 Hallock Oct 1967 A
3390501 Driggers Jul 1968 A
3394515 Widdowson Jul 1968 A
3394639 Viehmann Jul 1968 A
3765140 Harry Oct 1973 A
3789567 Rae Feb 1974 A
3790294 Trieste Feb 1974 A
3998016 Ting Dec 1976 A
4050207 Bertschmann Sep 1977 A
4332504 Arai Jun 1982 A
4522531 Thomsen Jun 1985 A
4557082 Dunsworth Dec 1985 A
4598517 Alvarsson Jul 1986 A
4648739 Thomsen Mar 1987 A
4833851 Ohmatsu May 1989 A
4848044 LaRoche Jul 1989 A
4888930 Kelly Dec 1989 A
4936704 Killmeyer Jun 1990 A
5028168 Conversy Jul 1991 A
5088256 Face, Jr. Feb 1992 A
5311715 Linck May 1994 A
5311716 Houssin May 1994 A
5365713 Nicholas Nov 1994 A
5366319 Hu Nov 1994 A
5479753 Williams Jan 1996 A
5607253 Almstrom Mar 1997 A
5674028 Norin Oct 1997 A
5826391 Underwood Oct 1998 A
6022169 Kim Feb 2000 A
6044602 Canavan Apr 2000 A
6128874 Olson Oct 2000 A
6502359 Rambo Jan 2003 B1
8376652 Bradford Feb 2013 B2
8677712 Edmonds, Jr. Mar 2014 B1
8739495 Witherspoon Jun 2014 B1
D710038 Keen Jul 2014 S
20040016065 Steiger Jan 2004 A1
20040107661 Michiels Jun 2004 A1
20040265057 Pearce Dec 2004 A1
20050066600 Moulton Mar 2005 A1
20050232697 Brinkman Oct 2005 A1
20060039753 Leonberg Feb 2006 A1
20060059804 Brown Mar 2006 A1
20070199267 Moor Aug 2007 A1
20080222984 Michiels Sep 2008 A1
20080313989 Ireland Dec 2008 A1
20090007512 Kerrels Jan 2009 A1
20100281808 Laiho Nov 2010 A1
20100325996 Laiho Dec 2010 A1
20120102862 Underwood May 2012 A1
20120186186 Michiels Jul 2012 A1
20140242863 Voet Aug 2014 A1
20140366472 Keen Dec 2014 A1
Related Publications (1)
Number Date Country
20180371703 A1 Dec 2018 US
Continuations (1)
Number Date Country
Parent 14380803 US
Child 16101810 US