The present invention relates to the field of covering panels. More particularly, it relates to covering panels securable to a bearing substrate using mechanical fasteners and to a method of installation for same.
To facilitate installation of siding and roofing covering panels, polymer panels designed for such a use commonly include a plurality of fastener apertures each comprising an elongated slot defined in a section of each panel. In order to perform installation thereof, it is customary to drive a mechanical fastener, such as, for example and without being limitative, a nail or the like, through each slot and into a bearing substrate to which the panel is superposed, thus securing the panel thereto. The elongated slots can be configured to allow the panel to slide relative to the mechanical fastener extending through the slot and secured to the underlying bearing substrate, as the polymer material of the panel expands and contracts due to changing environmental temperatures. In order to favor movement between the panel and the mechanical fastener, the mechanical fastener should be positioned substantially in a middle of each elongated slot in order to permit the unfettered relative movement of the panel in either direction (i.e. in order to accommodate both contraction and expansion of the panel).
Unfortunately, hasty installation can lead to the misplacement of the mechanical fasteners inside the elongated slot, thereby leading to the mechanical fastener being located too close to either ends of the slots, rather than substantially in the middle thereof. When such misplacement of the mechanical fasteners occurs, relative movement of the panel in either direction with regards to the mechanical fastener can lead to abutment of the fastener with one of the slot ends, thereby resulting in unwanted buckling of the panel.
In addition to misplacement along the elongated slots, another common occurrence during installation of such panels is for fasteners to be driven too deeply into the substrate, such that the panel is effectively pinned against the bearing substrate and unable to move relative to the fastener in response to changes in the environmental temperature. Similarly to misplacement of the fastener within the slot, this alternative installation error can also lead to unwanted buckling of the panel. In some cases, the fastener can even be driven through the panel completely, for example when a pneumatic hammer is used to drive the fastener, thereby leading to no securement of the panel to the bearing substrate.
In order to alleviate some of the above-described issues, fastener centering-guides and hammer stops are known for limiting the depth to which a fastener can be driven into each elongated slot by a hammer (see for instance U.S. Pat. No. 8,020,353 granted to the Applicant). For example, one such centering-guides and hammer stop comprises a raised, rigid stop surfaces with the stop surfaces positioned about each elongated slot so as to confront the face of a hammer having a head diameter greater than the distance between the stop surfaces. The stop surfaces of such a hammer stop are elevated above each elongated slot of a distance sufficient to prevent the mechanical fastener from being driven into the slot to a depth at which the panel is prevented from moving relative to the mechanical fastener during expansion and contraction of the panel. The elongated slot can also include a visual indicator of the position along the slot where the mechanical fastener is to be inserted.
Known centering-guides and hammer stops however tend to suffer from several drawbacks. For example, known centering-guides and hammer stops are not adapted to be used in combination with pneumatic hammers. Indeed, such pneumatic hammers commonly have hammer head shapes which make it difficult to properly position the pneumatic hammer in order to insert the mechanical fastener in proper position along the elongated groove (substantially in the middle thereof) and/or at a proper height relative to the elongated groove (to ensure that the mechanical fastener discharged by the pneumatic hammer is not driven to deeply into the substrate or completely through the panel), when using panels provided with existing centering-guides and/or hammer stops. Hence, the hasty installation of a polymer panel with a pneumatic hammer can lead to the misplacement of fasteners too close to either ends of the elongated slots and/or too deep within the bearing substrate, thereby leading to unwanted buckling of the building product.
Another drawback associated with the installation of known polymer panels relates to their installation when employed in a vertical interlocking engagement with adjacent covering panels requiring an overlap of the marginal edge sections of the panels to cover and conceal the fasteners. The panels are typically planar but slanted when mounted to the bearing substrate, i.e. diagonally-extending with respect to the substrate. Thus, following installation, an upper marginal edge section abuts the bearing substrate while a lower marginal edge section is spaced apart therefrom. A relatively long section of the panel is spaced-apart from the bearing substrate when secured thereto. When pressure is momentarily applied thereon, the covering panels mounted to the bearing substrate offers some springback, i.e. they bend towards the bearing substrate when pressure is applied thereon and return to their original configuration when the pressure is removed. Such springback reduces the resemblance with natural building elements.
In view of the above, there is a need for an improved covering panel which, by virtue of its design and components, would be able to overcome or at least minimize some of the above-discussed prior art concerns.
In accordance with a first general aspect, there is provided a covering panel securable to a substrate by fasteners driven by a hammer having a hammer head. The covering panel includes a front surface, a rear surface opposed to the front surface and facing the substrate when secured thereto, and a fastener strip. The fastener strip includes a plurality of fastener apertures disposed serially along a length of the covering panel, the fastener strip being juxtaposed to the substrate when the panel is secured therewithin. The covering panel further includes a plurality of hammer stops extending from the front surface coextensively with the plurality of fastener apertures. Each hammer stop includes at least one elevated hammer head stop surface protruding forwardly from the front surface and configured so as to confront the hammer head at a distance from the fastener strip, and a hammer head alignment guide configured so as to position the hammer head with respect to a respective one of the fastener apertures.
In accordance with another general aspect, there is provided a covering panel securable to a substrate. The covering panel comprises: an upper marginal region securable to the substrate; and a covering section extending downwardly from the upper marginal region. The covering section is arcuate in a manner such that when the upper marginal region is juxtaposed and secured to the substrate, the lower region of the covering section is spaced apart from the substrate.
In an embodiment, the covering section comprises a plurality of horizontal rows of simulated building elements, each one of the rows being arcuate with an upper region of each one of the rows being closer to the substrate than a corresponding lower region of each one of the rows. The lower regions of each one of the rows can be spaced-apart from the substrate when covering panel is secured to the substrate.
In accordance with another general aspect, there is provided a covering panel securable to a bearing substrate using fasteners driven by a hammer having a hammer head. The covering panel comprises a front surface and a rear surface opposed to the front surface and facing the bearing substrate when the covering panel is secured thereto. The covering panel also comprises a fastener strip comprising a plurality of fastener apertures spaced apart along a longitudinal axis of the covering panel. The fastener strip is juxtaposed to the bearing substrate when the covering panel is secured thereto. The covering panel also comprises a plurality of hammer stops extending forwardly from a section of the fastener strip including the fastener apertures. Each one of the hammer stops is associated to a corresponding one of the plurality of fastener apertures and comprises at least one elevated hammer head stop surface protruding from the section of the fastener strip including the fastener apertures and elevated therefrom and a hammer head alignment guide abutable with a section of the hammer head to position the hammer head in a predetermined configuration with respect to the corresponding one of the fastener apertures. The at least one elevated hammer head stop surface is configured to abut with the hammer head at a distance from the section of the fastener strip including the fastener apertures.
In an embodiment, the hammer head alignment guide defines a concave surface.
In an embodiment, the concave surface is curvilinear.
In an embodiment, wherein the hammer head alignment guide is positioned below the corresponding one of the fastener apertures and comprises a shelf surface positioning the hammer head with respect to the corresponding one of the fastener apertures by gravity.
In an embodiment, the at least one elevated hammer head stop surface comprises a first elevated hammer head stop surface extending below the corresponding one of the fastener apertures and a second elevated hammer head stop surface extending above the corresponding one of the fastener apertures.
In an embodiment, the first elevated hammer head stop surface and the second elevated hammer head stop surface are substantially evenly levelled.
In an embodiment, each one of the plurality of fastener apertures comprises a main aperture and elongated fastener slots extending longitudinally from the main aperture, the elongated fastener slots having a width smaller than the diameter of the main aperture.
In an embodiment, a lower portion of the hammer head alignment guide is substantially aligned with the main aperture along the longitudinal axis of the covering panel.
In an embodiment, the covering panel further comprises a lateral flange, at least one flange hammer stop extending forwardly from a section of the lateral flange. The lateral flange comprises at least one flange fastener aperture and is juxtaposed to the bearing substrate when the covering panel is secured therewith. Each one of the flange hammer stops is associated to a corresponding one of the at least one flange fastener aperture and comprises at least one elevated flange hammer head stop surface protruding from the section of the lateral flange and elevated therefrom and a flange hammer head alignment guide abutable with a section of the hammer head to position the hammer head in a predetermined configuration with respect to the corresponding one of the at least one flange fastener aperture. The at least one elevated flange hammer head stop surface is configured to abut with the hammer head at a distance from the section of the lateral flange including the at least one flange fastener aperture.
In an embodiment, the flange hammer head alignment guide defines a concave surface.
In an embodiment, the concave surface is curvilinear.
In an embodiment, the flange hammer head alignment guide is positioned below the corresponding one of the flange fastener apertures and comprises a shelf surface positioning the hammer head with respect to the corresponding one of the fastener apertures by gravity.
In an embodiment, the covering panel further comprises a lateral section opposed to the lateral flange along the longitudinal axis of the covering panel. The lateral flange comprises at least one lateral interconnection tab having a jaw extending forwardly of a section of the lateral flange and defining a lateral engagement slot and the lateral section has a hook extending rearwardly from a section thereof. The lateral interconnection tab and the hook are configured for the lateral engagement slot of the lateral interconnection tab of a first covering panel to slidingly receive a section of the hook of a second laterally adjacent covering panel therein through substantially horizontal displacement of at least one of the first covering panel and the second covering panel.
In an embodiment, one of the at least one flange elevated hammer head stop surfaces and the flange hammer head alignment guide of each flange hammer stop are defined in a front surface of the jaw of a corresponding one of the at least one lateral interconnection tab.
In accordance with another general aspect, there is further provided a covering panel securable to a bearing substrate. The covering panel comprises an upper marginal region securable to the bearing substrate and a covering section extending downwardly from the upper marginal region and having a lower end. The covering section is arcuate along a transverse axis of the covering panel and defines a concave curvature. The lower end of the covering section is spaced apart from the bearing substrate when the upper marginal region is juxtaposed and secured to the bearing substrate.
In an embodiment, a deflection of the covering section with regards to the bearing substrate is between about 1/16 of an inch and about 1 inch.
In an embodiment, the covering section comprises a plurality of horizontal rows of simulated building elements, each one of the horizontal rows having an upper end and a lower end, each one of the horizontal rows being arcuate and defining a concave curvature. The upper end of each one of the plurality of horizontal rows of simulated building elements is closer to the bearing substrate than the lower end thereof.
In an embodiment, the combination of the curvatures of each one of the rows of simulated building elements of the covering section defines a covering section having a downwardly and outwardly extending curvature relative to the bearing substrate onto which the covering panel is secured.
In an embodiment, the lower end of each one of the rows of simulated building elements of the covering section is spaced-apart from the bearing substrate when the covering panel is secured to the bearing substrate.
In an embodiment, a deflection of each one of the rows of simulated building elements of the covering section with regards to the bearing substrate is between about 1/16 of an inch and about 1 inch.
In an embodiment, the covering panel comprises a lateral flange comprising at least one lateral interconnection tab having a jaw extending forwardly of a section of the lateral flange and defining a lateral engagement slot and a lateral section opposed to the lateral flange along the longitudinal axis of the covering panel comprising a hook extending rearwardly from a section thereof. The lateral interconnection tab and the hook are configured for the lateral engagement slot of the lateral interconnection tab of a first covering panel to slidingly receive a section the hook of a second laterally adjacent covering panel therein through substantially horizontal displacement of at least one of the first covering panel and the second covering panel.
Other objects, advantages and features will become more apparent upon reading the following non-restrictive description of embodiments thereof, given for the purpose of exemplification only, with reference to the accompanying drawings in which:
In the following description, the same numerical references refer to similar elements. The embodiments, geometrical configurations, materials mentioned and/or dimensions shown in the figures or described in the present description are embodiments only, given solely for exemplification purposes.
Moreover, although the embodiments of the covering panel and corresponding parts thereof consist of certain geometrical configurations as explained and illustrated herein, not all of these components and geometries are essential and thus should not be taken in their restrictive sense. It is to be understood, as also apparent to a person skilled in the art, that other suitable components and cooperation thereinbetween, as well as other suitable geometrical configurations, can be used for the covering panel, as will be briefly explained herein and as can be easily inferred herefrom by a person skilled in the art. Moreover, it will be appreciated that positional descriptions such as “above”, “below”, “left”, “right” and the like should, unless otherwise indicated, be taken in the context of the figures and should not be considered limiting.
Referring generally to
The covering panel 10 includes a front surface 14 and a rear surface 16. The rear surface 16 is opposed to the front surface 14 and faces the substrate 12 when the covering panel 10 is secured thereto. Along a longitudinal axis X, the covering panel 10 can be divided into a plurality of sections. It includes a covering section 17, which is a section of the covering panel 10 which is exposed when the covering panel 10 is mounted to the bearing substrate 12 in successive vertically adjacent and horizontally extending rows of covering panels 10. The covering section 17 is the section of the covering panel 10 covering the bearing substrate 12 to shield it from environmental elements such as rain, wind and the like. The covering panel 10 further includes an upper marginal edge section 18 including an upper edge 22 of the covering panel 10 and an opposed lower marginal edge section 20 including a lower edge 24 of the covering panel 10. In an embodiment, the upper marginal edge section 18 has a substantially uniform width along the longitudinal axis X of the covering panel 10 and includes a fastener strip 26 adapted to be juxtaposed to the bearing substrate 12, when the covering panel 10 is fastened thereto, as will be described in more details below. The covering section 17 extends below the adjacent upper marginal edge section 18. The upper marginal edge section 18 of a first covering panel is covered by the lower marginal edge section 20 of a vertically-adjacent covering panel when the two adjacent covering panels 10 are engaged together, with the covering section 17 of the first covering panel being exposed. The covering panel 10 also includes opposite lateral edges 28, 30, a lateral flange 32 extending from one lateral side of the covering section 17 and including one of the lateral edges 30 and a lateral section 33 extending from the other lateral side of the covering section 17, opposed to the lateral flange 32, proximate to the other lateral edge 28. Similarly to the fastener strip 26, in an embodiment, the lateral flange 32 is juxtaposed to the substrate 12 when the covering panel 10 is secured therewith.
In the embodiment shown in
In the embodiment shown, on the front surface 14 of the covering panel 10, at least in the covering section 17, there is provided one or more simulated building elements 34. In an embodiment, a section of the upper marginal edge section 18, for instance the section extending below the fastening strip 26, also includes simulated building elements 34. The front surface 14 can include any type of simulated building elements such as wood planks, slates, tiles, bricks, stones, shingles and the like, each having different textures and appearances. In the embodiment shown, the front surface 14 of the covering panel 10 is designed to represent a plurality of vertically adjacent, horizontally extending rows of shingles 36. In the embodiment shown, the building elements 34 are therefore provided along horizontal successive rows 38, each row being staggered relative to an adjacent row 38. Moreover, the lateral edges 28, 30 of the covering panel 10 are in stepped arrangement, to accommodate the staggered rows 38. One skilled in the art will understand that, in alternative embodiment (not shown), other configurations, such as, for example and without being limitative, vertical columns of building elements 34, non-staggered configuration of rows 38, or the like can also be provided.
The covering panel 10 can be made of any material known to be employed as a covering material for roofing, siding, or the like, such as, for example and without being limitative, a synthetic polymeric material. Moreover, it will be understood that while each covering panel 10 of the embodiment shown is a monolithic (i.e. a single piece) structure, such construction is only exemplary and each covering panel 10 can, in an alternative embodiment (not shown), comprise a unitary structure manufactured from two or more separate constituent components. Furthermore, the length and the height of the covering panel 10 can be varied in accordance with the user's needs.
Referring to
Referring to
Each one of the covering panels 10a, 10b and 10c has a curvature defined along the covering section 17 thereof. Covering panels 10a, 10b are configured such that when they are mounted to the bearing substrate 12 and the first covering panel 10a is positioned vertically adjacent and above the second covering panel 10b, the lower marginal edge section 20 of the first covering panel 10a overlies the upper marginal edge section 18 of the second vertically-adjacent covering panel 10b. A similar configuration is provided between the second covering panel 10b and the third covering panel 10c and any other additional covering panel 10.
Referring to
In order to ease the reading of the present description, only the reference numbers in the 10 series will be used in the description below, unless specific reference to the embodiments of
In view of the above, in both of the embodiments shown in
In an embodiment, the deflection of the covering section 17 or the deflection of each one of the rows 38 of the covering section 17 is between about 1/16 of an inch and about 1 inch. In other words, in an embodiment, the curvature of the covering section 17 can be such that when the upper marginal region 18 is juxtaposed and secured to the substrate 12, as will be described in more details below, the lower end 17b of the covering section 17 is spaced apart from the substrate 12 by a distance of between about 1/16 of an inch and about 1 inch. Similarly, the curvature of each one of the rows 38 of the covering section 17 can be such that when the upper marginal region 18 is juxtaposed and secured to the substrate 12, a lower end of each one of the rows 38 is spaced apart from the substrate 12 by a distance of between about 1/16 of an inch and about 1 inch. In an embodiment, the deflection of the entire covering section 17 or the deflection of each one of the rows 38 of the covering section 17 is independent of the height of the covering panel (i.e. the deflection of the entire covering section 17 is between about 1/16 of an inch and about 1 inch regardless of the height of the covering section 17 or the rows 38 thereof).
One skilled in the art will understand that the overall curvature defined in the covering section 17 of the covering panel 10, between the upper end 17a and the lower end 17b thereof, increases a length of the covering panel 10 abutting or being close to the bearing substrate 12 along the transverse axis Y, when the covering panel 10 is mounted thereto. In other words, such curvature results in a greater section of the covering panel 10 abutting or being close to the bearing substrate 12 as opposed to conventional substantially planar panel along the transverse axis Y. Therefore, when momentary pressure is applied on the covering panel 10, the springback effect is reduced in comparison to conventional substantially planar panel defining an oblique angle with the bearing substrate 12 when mounted thereto.
Now referring to
In an embodiment, in order to help secure the covering panel 10 to the bearing substrate 12, the fastener strip 26 includes a plurality of fastener apertures 46, spaced-apart from one another, and provided along the longitudinal axis X of the fastener strip 26. In an embodiment, the plurality of fastener apertures 46 are located along at least the upper marginal edge section 18. Each one of the fastener apertures 46 includes a main aperture 47 sized and shaped to allow the shank of the fastener 40 to move freely therethrough and into the adjacent substrate 12. In an embodiment, each fastener aperture 46 further includes elongated fastener slots 48 extending laterally from the main aperture 47 and defined by slits or elongated grooves in the layer of material of the covering panel 10. As can be seen in
Now referring to
In the embodiment shown, the vertical interconnection tab 74 further includes a plurality of recesses 61, each defining a hammer head stop surface 52a, and a corresponding contouring wall 64. Each one of the recesses 61 is positioned below a corresponding one of the fastener apertures 46. As will be described in more details below, the contouring wall 64 is positioned and configured to define a hammer head alignment guide 62.
In the embodiment shown, in the upper marginal edge section 18, the covering panel 10 further includes a plurality of spaced-apart upper ridges 58 protruding from the fastener strip 26 and each defining a hammer head stop surface 52b. In the embodiment shown, each one of the upper ridges 58 extends above a corresponding one of fastener apertures 46, i.e. between the fastener apertures 46 and the upper edge 22 of the covering panel 10. Each one of the upper ridges 58 is substantially aligned with a respective one of the recesses 61 along the longitudinal axis X. One skilled in the art will understand that, in an alternative embodiment (not shown), upper ridges 58 having a hammer head stop surface 52b and being spaced apart from the recesses of the vertical interconnection tab 74 can be provided with a different position or configuration than those of the embodiment shown. For example and without being limitative, the covering panel 10 can include a single upper ridge 58 extending continuously or discontinuously between both lateral edges 28, 30 of the covering panel 10, rather than a plurality of spaced-apart upper ridges 58, each one being substantially aligned with a corresponding one of the recesses 61.
The combination of the hammer head stop surfaces 52a of the recesses 61 of the vertical interconnection tab 74 and the hammer head stop surfaces 52b of the corresponding upper ridge 58 together define a hammer head stop 50. It is appreciated that, in an embodiment where the upper ridge 58 extends continuously over more than one recess 61 of the covering panel 10, a hammer head stop 50 is defined by the hammer head stop surfaces 52a of the recesses 61 of the vertical interconnection tab 74 and a corresponding section of the hammer head stop surface 52b of upper ridge 58.
The hammer head stops 50 are positioned relative to the corresponding ones of the plurality of fastener apertures 46 to allow positioning and alignment of the hammer head 44 above the fastener strip 26 and to limit the depth to which a fastener 40 can be driven through each fastener apertures 46 and into the bearing substrate 12. Each hammer head stop 50 includes elevated hammer head stop surfaces 52a, 52b protruding from a section of the front surface 14 of the fastener strip 26 including the fastener apertures 46. Each hammer head stop 50 is configured to be abutted by the hammer head 44, at a distance from the section of the front surface 14 of the fastener strip 26 including the fastener apertures 46. In the embodiment shown, the hammer head stop surfaces 52a, 52b are substantially aligned with and positioned on a respective side of each fastener aperture 46. The hammer head stop surfaces 52a, 52b extend forwardly of the section of the front surface 14 of the fastener strip 26 including the fastener apertures 46, i.e. along an axis extending substantially normal to the covering panel 10 and to the bearing substrate 12 to which the panel 10 is secured. In other words, the hammer head stop surfaces 52a, 52b are elevated from the section of the front surface 14 of the fastener strip 26 including the fastener apertures 46. The hammer head stop surfaces 52a, 52b are configured to be abutted by the hammer head 44 at a predetermined distance of the section of the front surface 14 of the fastener strip 26 including the fastener apertures 46, as defined by the elevation thereof. In an embodiment the hammer head stop surfaces 52a, 52b are substantially levelled to one another. It will be understood that the term “level” is used herein to refer to an elevation of the hammer head stop surfaces 52a, 52b defining the distance of the hammer head stop surfaces 52a, 52b with regards to a distance defined with the section of the front surface 14 of the fastener strip 26 including the fastener apertures 46. The hammer head stop surfaces 52a, 52b being substantially levelled allows the fastener 40 to be driven substantially perpendicularly through the fastener apertures 46 relative to the front surface 14 of the covering panel 10, when the hammer head 44 confronts or abuts both hammer head stop surfaces 52a, 52b. One skilled in the art will understand that, in alternative embodiments, the hammer head stop surfaces 52a, 52b can be unlevelled, i.e. the elevation of the hammer head stop surfaces 52a, 52b can be different from one another in order to result in the fastener 40 being driven at an oblique angle into the bearing substrate 12. Furthermore, one skilled in the art will understand that, in an alternative embodiment, the hammer head stops 50 can include only the hammer head stop surface 52a defined by the recesses 61 of the vertical interconnection tab 74.
It will be understood that the hammer head stop surfaces 52a, 52b together act so as to confront or abut and level the head 44 of a hammer 42 having a hammer head 44 diameter greater than the distance between the hammer head stop surfaces 52a, 52b of the hammer head stop 50. In view of the above, when installation of the covering panel 10 is performed using a hammer 42, such as and without being limitative, a pneumatic hammer, having a hammer head 44 diameter greater than the distance between the opposing hammer head stop surfaces 52a, 52b, the fastener 40 can be driven through the fastener apertures 46 and into the underlying bearing substrate 12 only to a depth which leaves sufficient space for the covering panel 10 to move relative to the fastener 40 during expansion and contraction of the covering panel 10.
Still referring to
Now referring to
Now referring to
In an embodiment where fastener apertures 46 are also provided along the lateral flange 32, the hammer 42 is also brought into abutting contact with the flange hammer stops 50 provided on the lateral flange 32 such that the hammer head 44 abuts or confronts the flange hammer head stop surfaces 52a, 52b to position the hammer head 44 at a distance from the section of the lateral flange 32 including the flange fastener aperture 46. Once again, when the hammer 42 is brought into abutting contact with the flange hammer stop 50, the flange hammer head alignment guide 62 further positions the hammer head 44 in the predetermined position with respect to the flange fastener aperture 46. As a result of such an alignment and positioning of the hammer head 44 by the flange hammer stop 50, the fastener 40 is able to be driven by the hammer 42 towards and through the flange fastener aperture 46 of the lateral flange 32. Similarly, the covering panel 10 is fully mounted to the substrate 12 by repeating the above described steps for each (or any other number) flange fastener apertures 46 provided on the lateral flange 32.
As mentioned above, the covering panels 10 include interlocking features that enable inter-engagement of overlying upper marginal edge sections 18 and lower marginal edge sections 20 during installation of the covering panel 10 over the substrate 12 to vertically connect adjacent covering panels 10. In an embodiment, vertically-adjacent covering panels 10 are engaged together by inserting an insertable flange (not shown) provided on the rear surface 16 of the lower marginal edge section 20 into the upwardly-extending engagement slot 76 defined between the vertical interconnection tab 74 and the connecting walls 60, as it is known in the art.
Now referring to
In the embodiment shown, horizontally-adjacent covering panels 10 are engaged together by a substantially horizontal sliding movement of adjacent covering panels 10, i.e. by a movement of adjacent covering panels along the longitudinal axis X of the panels 10. One skilled in the art will however understand that, in alternative embodiment, other ways of engaging adjacent covering panels 10 together, such as through a vertical, horizontal, or a combination of vertical and horizontal movements is also possible.
In the embodiment shown, the covering panels 10 include at least one lateral interconnection tab 82, positioned on the lateral flange 32. The lateral interconnection tabs 82 include a generally J-shaped jaw 84 extending forwardly of a section of the front surface of the lateral flange 32 towards lower marginal edge section 20 so as to define a lateral engagement slot 88 extending upwardly between the lateral interconnection tab 82 and the lateral flange 32. In the embodiment shown, the flange elevated hammer head stop surfaces 52a and the contouring wall 64 of the flange hammer head alignment guide 62 are defined in a front surface of the jaw 84. The covering panels 10 also include a substantially “L”-shaped hook 90 positioned in the lateral section 33 of the covering panels, opposed to the lateral edge 32. The hook 90 extends from the rear surface 16 of the covering panel 10, close to the lateral edge 28 thereof.
The lateral interconnection tabs 82 and the hooks are configured such that the lateral interconnection tab 82 of a first panel 10a interlocks with the hook 90 of an adjacent covering panel 10d, when the panels are joined and secured to the bearing substrate. Hence, each one of the hooks 90 is sized and shaped to be slidingly received in the lateral engagement slot 88 defined by the lateral interconnection tab 82 of an adjacent covering panel 10a (see
As can be seen in
It will be appreciated from the foregoing disclosure that the covering panel 10 disclosed herein provides inexpensive and rapid installment of a covering panel using a hammer, such as a pneumatic hammer, to drive fasteners 40 which are properly aligned, positioned, and inserted in the substrate 12 only to a depth which leaves sufficient space for the covering panel 10 to move relative to the fastener 40 during expansion and contraction of the covering panel 10.
Several alternative embodiments and examples have been described and illustrated herein. The embodiments of the invention described above are intended to be exemplary only. A person skilled in the art would appreciate the features of the individual embodiments, and the possible combinations and variations of the components. A person skilled in the art would further appreciate that any of the embodiments could be provided in any combination with the other embodiments disclosed herein. It is understood that the invention may be embodied in other specific forms without departing from the central characteristics thereof. The present examples and embodiments, therefore, are to be considered in all respects as illustrative and not restrictive, and the invention is not to be limited to the details given herein. Accordingly, while specific embodiments have been illustrated and described, numerous modifications come to mind without significantly departing from the scope of the invention as defined in the appended claims.
This application claims the benefit under 35 U.S.C. § 119(e) of U.S. provisional patent application No. 62/166,855 which was filed on May 27, 2015. The entirety of the aforementioned application is herein incorporated by reference.
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Number | Date | Country | |
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20170022719 A1 | Jan 2017 | US |
Number | Date | Country | |
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62166855 | May 2015 | US |