Simulated Masonry Wall Panel with Improved Seam Integration

Abstract

A wall covering comprised of a plurality of panels formed with a stone and mortar design. The panels are mounted in horizontal courses with a lower marginal edge region of one panel being in overlying relation to the upper marginal edge region of a panel in a previously mounted course. The upper and lower marginal edge regions have a tapered seating design which enable close positioning of the stone and mortar of two mating panels with the mortar lines between the stone being in substantially coplanar relation with each other and where a portion of the simulated stone protrudes downward in different locations so as to create a non-uniform mortar distance between simulates stones on an upper panel from simulated stones on a lower panel, thus further obscuring the seam formed between the panels.

Description

FIELD OF THE INVENTION

The present invention relates generally to wall and roof coverings primarily intended for outdoor usage, and more particularly, to wall coverings comprised of relatively large panels where each are molded or otherwise formed with simulated building elements, and particularly building elements in the form of simulated hand laid masonry, such as stone.

BACKGROUND OF THE INVENTION

Various synthetic roof and wall coverings are known, such as those formed of elongated thermoplastic wall panels that are nailed or screwed to a wall or support surface in horizontal courses or rows in partially overlapping relation to each other so as to provide a substantially water repellant, protective layer over the support surface. Such panels, which usually are identically molded, commonly are formed with a plurality of horizontal rows of simulated building elements. Since the panels are identically molded, a panel-to-panel identity can be easily noticed if the panels are not carefully installed, which can be tedious and time consuming.

Concealing the panel-to-panel identity of panels formed with simulated hand laid stone or brick patterns has been particularly difficult. In an effort to conceal the juncture between rows of simulated masonry of adjacently mounted panels, it is known to stagger the length of the rows of the simulated masonry of each panel, and to interlock the rows of adjacent panels by forming a small slot in the underside of the masonry element of one row which receives a side flange of an adjacently mounted panel. Because of the small depth of the flange receiving slot, particularly with the shorter height simulated stone or brick, the tooling required during injection molding of the panel must be so thin that it can be subjected to warpage or breakage, causing variances in formation of the slot that can impede the precision by which the panels can be inter-engaged, resulting in unslightly and unnatural gaps between the simulated masonry of the adjacent panels. Moreover, because the simulated hand-laid stone or brick are separated by simulated mortar lines, irregular or inconsistent gaps between the stone or brick at adjoining ends of the panels that are not consistent with the mortar lines throughout the panel can be particularly noticeable.

A further problem with panels formed with such simulated masonry is that the seam between adjacent panels can become visible due to molding inconsistencies and thermal expansion.

OBJECTS AND SUMMARY OF THE INVENTION

It is an object of the present invention to provide a wall covering comprised of panels formed with rows of simulated masonry that can be installed with a more aesthetic and natural appearance.

Another object is to provide a wall covering as characterized above in which the gaps between stone or brick masonry of adjacently mounted panels can be more tightly and precisely controlled for a more natural appearance and that an overlap between adjacent panels can be introduced to minimize seam visibility during thermal expansion and to more properly simulate stone panels.

Still another object is to provide a wall covering of the above kind in which the gaps between the masonry of adjacently mounted panels is defined by naturally appearing mortar lines consistent with the mortar lines separating the stone or brick masonry throughout the panels.

Yet another object is to provide a wall covering of the foregoing type in which the mortar lines between masonry of adjacently mounted panels enhances the aesthetic appearance of the juncture between the rows of simulated masonry of adjacent panels, as well as the mating engagement of the adjacent panels.

Another object is to provide a wall covering having panels of the above type which are adapted for easier installation and which enable a more robust interlocking of overlapping side marginal regions of adjacent panels.

A further object is to provide such a wall panel which facilitates precise alignment of the rows of simulated building elements of adjacent panels as an incident to installation.

Still a further object is to provide a plastic wall panel of the foregoing type which can be economically molded with more reliable and easier to use tooling.

Yet another object is to provide a plastic injection molded panel that is painted with a finishing process that gives the panel a textured surface more characteristic of natural stone or brick.

Other objects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front perspective of an illustrative wall panel in accordance with the present invention;

FIG. 2 is a rear plan view of the wall panel shown in FIG. 1;

FIG. 3 is a plan view of a wall covering comprised of a plurality of wall panels shown in FIG. 1;

FIG. 4 is an enlarged right end view of the illustrated wall panel, taken in the plane of line 4-4 in FIG. 1;

FIG. 5 is an enlarged fragmentary section of the engagement of a lowermost panel of the wall covering with a bottom starter strip, taken in the plane of line 5-5 in FIG. 3;

FIG. 6 is an exploded fragmentary section of upper and lower marginal edge regions of panels in adjacent courses, taken in the plane of line 6-6 in FIG. 3;

FIG. 6A is a fragmentary section similar to FIG. 6, showing the lower and upper marginal edge regions of the panels in engaged relation with each other;

FIG. 7 is an enlarged fragmentary section of overlying side marginal edge regions of the wall cover, taken in the plane of line 7-7 in FIG. 3;

FIG. 8 is an enlarged exploded view of adjacent wall panels showing the side marginal edge regions of the panels in separated relation to each other;

FIG. 8A is an enlarged plan view, similar to FIG. 8, showing the side marginal edge regions of the adjacent panels in engaged relation with each other.

FIG. 9 is an enlarged fragmentary section taken in the plane of line 9-9 in FIG. 8;

FIG. 9A is an enlarged fragmentary section, similar to FIG. 9, showing the side marginal edge regions in interengaged relation with each other;

FIG. 10 is a fragmentary underside perspective of the interengaged side marginal edge regions of the illustrated wall covering;

FIGS. 11 and 11A are enlarged fragmentary sections taken in the planes of 11-11 and 11-11A, respectively, in FIG. 8;

FIG. 12 is a plan view of a wall covering comprised of a plurality of wall panels showing an improved seam integration feature according to one aspect of the invention;

FIG. 13 is an enlarged right end view of one wall panel of the embodiment depicted in FIG. 12;

FIG. 14 is an exploded fragmentary section of upper and lower marginal edge regions of panels in adjacent courses, taken in the plane of line 14-14 in FIG. 12; and

FIG. 14A is a fragmentary section similar to FIG. 14, showing the lower and upper marginal edge regions of the panels in engaged relation with each other at a seam integration location.

FIG. 14B is an enlarged view of FIG. 14A, showing a non-planar projection of the lower marginal edge portion of the overlying panel so as to partially obscure a mortar line formed between panels.

FIG. 14C is an another enlarged view of the panel similar to FIG. 14B, but illustrating the non-planar projection of the lower marginal edge portion of the overlying panel located closer to the tapered seat.

FIG. 15 is an enlarged view of a portion of the panel of FIG. 12 showing an embodiment where the second lower marginal portion is located laterally to the side of the first lower marginal portion.

While the invention is susceptible of various modifications and alternative constructions, a certain illustrative embodiment thereof has been shown in the drawings and will be described below in detail. It should be understood, however, that there is no intention to limit the invention to the specific form disclosed, but on the contrary, the intention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT

Referring now more particularly to the drawings, there is shown an illustrative wall covering 10 comprising a plurality of panels 11 in accordance with the invention. The panels 11, which preferably are molded of thermoplastic material, are formed with a simulated stone and mortar design, typical of hand-laid stone masonry. The simulated stone 12 in this case is generally disposed in a plurality of parallel horizontal rows with the stones 12 being isolated from each other by simulated lines of mortar 14. The stones 12 protrude outwardly of the mortar lines 14, typical of hand-laid stone, and some of the simulated stones 12 in this instance have a width (i.e. a vertical dimension as viewed in FIG. 1), greater than other of the stones in the row. The simulated stone 12 has irregular outer surfaces consistent with natural stone, and the mortar lines 14 also have a waving, or undulating, non-planar naturally appearing outer surface configuration. While the invention has particular utility in panels formed with simulated masonry, such as hand laid stone or brick, it will be understood that the panels could be made with other forms of simulated building elements, such as shake shingles, tile, or the like.

Each illustrated panel 11 has an upper horizontal marginal edge region 18 having a substantially uniform width extending across the top of the panel immediately above the top row of stone 12, a lower marginal edge region 19 which defines a lower peripheral edge of the simulated pattern, a side marginal edge region 20 located to the right-hand side of the last simulated stone 12 in each row, and a left side marginal edge region 21 on the opposite side of the panel 11. The left side marginal edge region 21 in this case is defined by the left hand edges of the stone in the respective rows, and the right marginal edge region 20 is defined by an irregular configured flange 27 that extends outwardly from the base of the stone at the right hand ends of the rows. The panels 11 are mounted on a support surface 22, which may be a wall of a house or other building structure, in horizontal courses with the right-side marginal edge region 20 in underlying relation to the left-side marginal edge region 21 of the panel immediately to the right thereof and with the lower marginal edge regions 19 of the panels in each course overlying the upper marginal edge regions 18 of the panels in a previously installed course immediately below. The panels 11 typically are mounted beginning with the left-hand panel of the lowermost course to be installed on the wall or roof, utilizing a bottom starter strip 31, as is known in the art (FIGS. 3 and 5). Upon completion of the first course, the second course is installed, immediately above the first course, again starting from the left-hand side.

For securing the panels 11 to the support surface 22, the upper marginal edge region 18 of each panel 11 has a mounting flange 23 parallel to the support surface 22 formed with a row of elongated laterally spaced nail or screw apertures 25. In order to provide firm support for the mounting flange 23 on the wall surface during fastening, the upper marginal edge region 18 in this instance is formed with a pair of rearwardly extending horizontal sealing flanges 26 which extend substantially the length of the upper marginal edge region 18 on top and bottom sides of the nailing apertures 25 (FIG. 2). For rigidifying the sealing flanges 26, circular posts 27 interconnect the parallel flanges 26 at spaced intervals along the upper marginal edge region 18 at locations between the nailing apertures 25.

In order to positively interlock the overlapping lower marginal edge region 19 of a panel 11 with an upper marginal edge region 18 of a previously mounted panel 11 when installing the next course of panels, each panel 11 is formed with a plurality of laterally spaced rearwardly and downwardly directed interlock flanges 30 on the underside of the lower marginal edge region 19 of the panel 11 (FIGS. 2-4), which are engageable with the upper marginal edge region mounting flange 23 of the previously mounted panel 11a supported in elevated parallel relation to the wall surface 22 by the sealing flanges 26 (FIGS. 6 and 6A). For locating the upper panel in predetermined overlying relation to the previously mounted panel 11a, while permitting thermal expansion and contraction of the panels in a vertical direction, frangible locating pins 33 extend rearwardly from the lower marginal edge region 19 which are positionable into abutting relation to the upper perimeter of the upper marginal edge region mounting flange 23 (FIGS. 2 and 6).

In order for the mortar lines 14 of adjacent top and bottom panels 11 to adjoin each other in coplanar closely adjacent relation such that the simulated stone 12 of each of the panels has a substantially uniform depth for a more natural and aesthetic appearance, the lower marginal edge region 19 of the overlying panel 11 is formed with a tapered seating surface 35 (FIGS. 6-6A) adapted for mating engagement with a tapered seating surface 36 of the upper marginal edge region 18 of the underlying panel 11, as disclosed in U.S. Pat. No. 7,587,871, the disclosure of which is incorporated herein by reference. In the illustrated embodiment, the mounting flange 23 of the upper marginal edge region 18 is disposed in recessed relation to the plane of the mortar lines 14, being supported by a tapered wall 34 that defines the tapered seating surface 36 and the mortar line 14 adjacent to top row of simulated stone has a width substantially corresponding to the width of the mortar lines 14 throughout the panel. The tapered seating surface 35 of the overlying lower marginal edge region 19 intersects the sides of the stone 12 such that upon mating with the tapered seating surface 36 of the underlying panel, the depth of the simulated stone corresponds substantially to the depth of the simulated stone throughout the panels.

To enable mounting of the panels 11 in side-by-side relation with the junctures between adjacent panels less noticeable to the eye, the rows of stone 12 of each panel 11 extend in offset relation to each other so as to define staggered left and right-hand sides of the panel. Nevertheless, as indicated above, heretofore it has been difficult to mold such panels in a manner that enabled reliable inter-engagement of the overlying side marginal edge regions without unsightly or unnatural gaps between the simulated masonry of the adjacently mounted panels.

In accordance with an important aspect of the invention, the side marginal edge regions of adjacently mounted panels have an interlock arrangement which simultaneously aligns the panels during installation and which draws the side marginal edge regions into precise tight fitting relation that conceals the juncture between the adjoining panels and defines a naturally appearing mortar line between the simulated stone of the adjacent panels. To this end, the overlying left marginal edge region of each panel is formed with one or more depending hooks or standoffs that are engageable with respective outwardly opening slots in the underlying previously mounted panel which cooperate to align the overlying side marginal edge regions into precise relation to each other while simultaneously drawing the marginal edge regions into secure overlying engagement with each other. In the illustrated embodiment, the overlying left side marginal edge region 21 is formed with a pair of outwardly facing hooks 40a, 40b depending from an underside thereof, and the right side marginal edge region 20 is formed with a corresponding pair of outwardly opening hook receiving slots 41a, 41b. The hooks 40a, 40b are disposed at predetermined lateral distances from the left marginal edge 21 of the simulated stone 12, and the hook receiving slots 41a, 41b are correspondingly located and formed in the right marginal edge flange. The hook receiving slot 41a in this case is formed in the edge of the flange 27, and the hook receiving slot 41b is formed in a larger recess 44 of the flange laterally inwardly up the slot 41a.

The hooks 40a, 40b have a rigid construction, comprising a support section 45 fixed in depending relation to the underside of the left side marginal edge region 21 and a pair of wings 46 extending outwardly from opposite sides of the support section 45. The support sections 45 in this instance each have an end wall 48 facing the outer perimeter of the side marginal edge region 21 and a pair of support legs 49 extending rearwardly of the end wall 48, with the wings 46 each extending outwardly from a respective leg 49 of the support section 45. For added rigidity, the legs 49 extend in rearwardly of the wings 46 and a vertical reinforcing plate 50 interconnects each wing 46 to the respective support leg 49.

For supporting the right side marginal edge region flange 27 in elevated relation to the support surface 22 on which the panels 10 are mounted and for rigidifying the interengagement between the panels 10, the right side marginal edge region 20 is formed with pairs of parallel depending flanges 54 on opposite sides of the hook receiving slots 41a, 41b which in this case extend horizontally. For maintaining the support flanges 54 in secure engaged relation to the support surface prior to installation of the next panel, the right side marginal edge region panel 20 is formed with one or more nailing apertures 53. The nailing apertures 55 in this case have an elongated configuration oriented at an acute angle to the horizontal for facilitating multidirectional temperature expansion or contraction.

For aligning the rows of simulated stone 12 of one panel 10 with the rows of simulated stone on a previously mounted panel as an incident to engagement of the hooks 40a, 40b with the hook receiving slots 41a, 41b during installation, the hook receiving slots 41a, 41b have a V-shaped configuration that narrows in a direction inwardly toward the edge of the panel 10. For ease of installation, the hooks 40a, 40b may be positioned into the wide mouths of the slots 41a, 41b, and lateral advancement of the hooks 40a, 40b into the slots 41a, 41b will simultaneously move the panel into aligned relation to the previously mounted panel. To facilitate such interengagement and alignment, the depending legs 49 of the hook support section 45 in this case also are angled with respect to each other in a general V configuration.

For drawing the side marginal edge regions 20, 21 firmly together as the overlying left marginal edge region 21 is moved into mating engagement with the previously mounted panel 10, the wings 46 are inclined at an acute angle to the substantially horizontal plane of the panel with a trailing end of each wing 46 being disposed more closely to the underside of the panel. It can be seen, therefore, that as the hooks 40a, 40b enter the respective slots 41a, 41b the leading edges of the wings 46 move under the right marginal edge region flange 27 with the taper of wings 46 drawing the side marginal edge regions into tight close-fitting relation with each other, as the sides of the V-shaped openings 41a, 41b simultaneously guide the hooks 40a, 40b into lateral aligned relation with the previously mounted panel such that the rows of simulated masonry of the adjacent panel, are directed into properly aligned relation to each other. For locating the left side marginal edge region 21 in predetermined overlying relation to the previously mounted panel, while permitting thermal expansion and contraction of the panels 20 in a horizontal direction, frangible locating pins 52 depend from the underside of the left side marginal edge region 21 which are engageable by the right side marginal edge region flange 27.

By virtue of the foregoing side interlock arrangement of the panels 10, it can be seen that the rows of simulated stone 12 of adjacent panels can be securely and precisely located with a gap corresponding in size to that of the mortar lines 14 throughout the panels. It will be appreciated by one skilled in the art that the side alignment and locking feature may be efficiently and reliably produced by plastic injection molding. Since the side interlocks do not require a small slot or groove under the masonry building element, typical of the prior art, they may be produced without thin plate tooling that can be susceptible to warpage or breakage.

In keeping with a further aspect of the invention, the gaps between rows of simulated masonry of adjacent panels is defined by a non-planar or undulating mortar line 55 consistent with the mortar lines 14 throughout the panels, which further conceals the juncture between the panels 12 and which facilitates the interengagement of the panels at that juncture. In the illustrated embodiment, the right side marginal edge region flange 27 is formed with a slightly raised pad 56 adjacent to the periphery of the right hand ends of the simulated stone of each row, which has a non-planar undulating surface corresponding to that of the mortar lines 14 throughout the panel. The overlying left side marginal edge region 21 of each panel 10 further is formed with an undulating surface 58 complementing the surface of the pad 56. Mating of such corresponding and conforming undulating surfaces 56, 58 enable tight interfitting of the engagement panels without unsightly gaps between the mating side marginal edge regions. Instead, the mortar lines defined by the pad 56 closely follows the edges of the simulated stone 12 defined by the left side marginal edge 21 of the overlying panel and further enhance the interengagement of the overlying side marginal edge regions.

In keeping with the invention, the simulated masonry has a textured outer surface more characteristic of natural stone or brick. To this end, following molding of the plastic panels, the panels are coated with a paint mixed with suspended sand-like particles. The particles may be made of natural or man-made materials, preferably sized between 0.020 and 0.200 inches. The paint and particle mixture, which may be mixed with a suitable solvent as necessary, may be sprayed by conventional spray guns. As is known in the art, the outer faces of the stone and the separating mortar lines may be separately painted with different colors for the particular application. It will be appreciated by one skilled in the art that the resulting roughened textured surface of the simulated masonry will more closely resemble, both in appearance and feel, natural hand laid masonry.

Referring now to FIGS. 12-14, another embodiment of the invention is illustrated. Similar reference numbers are used to indicate common elements described above. In this embodiment, the panels 11, include a lower marginal edge 19 that includes a first lower marginal edge portion 19a and a second marginal edge portion 19b. The first lower marginal edge portion 19a defines a non-planar contour for portions 100 of the lower marginal edge with respect to a plane 200 that extends substantially along the lover marginal edge 19. More particularly, as shown in FIG. 12, the lower marginal edge 19 when the panel is viewed on its forward face includes portions 100 that protrude downward beyond other portions 102 which lie substantially along the plane 200 (thereby defining planar contour portions). These non-planar portions provides a visual appearance of a rough stone edge. This has the tendency to break up the visual perception of a distinct seam between upper and lower panels and provides a more natural appearance.

As shown in FIG. 13, in the area of the non-planar contour portions 100, the first lower marginal edge portion 19a protrudes downward from the second lower marginal edge portion 19b, which lies substantially along plane 200. In the areas of the planar contour portions 102, the first lower marginal edge portion 19a lies substantially along plane 200 and in lie with the second lower marginal edge portion.

FIGS. 14, 14A and 14B show the assembly of the panels 11 in this embodiment and how the projection of the first lower marginal edge portion 19a obscures the location of the seam 150. Specifically, the first lower marginal edge 19a in the non-planar region 100 preferably protrudes downward a distance D1 from the second lower marginal edge portion 19b. In order to prevent interference between panels, the projection D1 is less than the defined mortar spacing M that forms between the panels thus leaving a gap D2. Preferably the distance D1 is greater than 0.020 inches and less than 0.250 inches, and more preferably between 0.50 inches and 0.200 inches.

While FIGS. 14, 14A and 14B illustrate the non-planar first lower marginal edge portion 19a located forward of the second lower marginal edge portion 19b, it is also contemplated that the first lower marginal edge portion 19a may extend the entire width of the cross-section or be located immediately adjacent to the tapered seating surface 35, as shown in FIG. 14C, and the second lower marginal edge portion 19b may be located in the planar portions 102 on the lateral sides of the first lower marginal edge portion 19a, as shown in FIG. 15.

From the foregoing, it can be seen that a wall covering is provided that comprises plastic injection molded panels formed with rows of simulated masonry that can be efficiently installed with a more aesthetic and natural appearance. The spacing and alignment of simulated stone or brick of adjacently mounted panels can be more tightly and precisely controlled for a more natural appearance. The gaps between masonry of adjacently mounted panels, furthermore, is defined by mortar lines consistent with the mortar lines separating the stone or brick masonry throughout the panels. The simulated masonry further has a textured surface appearance more characteristic of natural stone or brick. Yet, the wall panels further are adapted for economical manufacture and more robust interlocking of overlapping side marginal edge regions of the panel.

Claims

1. A wall covering for mounting on a support surface comprising a plurality of panels each having upper and lower marginal edge regions;

said panels being mountable on said support surface in a plurality of horizontal courses with said panels in a first horizontal course having an upper marginal edge region underlying a lower marginal edge region of said panels in a second horizontal course positioned above the first horizontal course;

said panels each being formed with a simulated stone and mortar design comprising horizontal rows of stone protruding from horizontal and vertical lines of mortar separating the stone, said stone and mortar lines having outer exposed faces, said upper marginal edge region of each panel being formed with a first tapered seating surface disposed at an acute angle to the plane of said mortar lines and exposed faces of said stone, said first tapered seating surface intersecting the exposed faces of some of said mortar lines, and the lower marginal edge region of each panel being formed with a second tapered seating surface at an angle to the plane of said mortar lines and exposed faces of said stone similar to the first tapered seating surface of said upper marginal edge region, said second tapered seating surface intersecting the exposed faces of some of said mortar lines for mounted positioning in overlying relation to the first tapered seating surface of the upper marginal edge region of an underlying panel as viewed in a direction toward the support surface with mortar lines of the underlying panel in adjacent substantially coplanar relation with mortar lines of the overlying panel while permitting relative movement of the lower marginal edge region of the overlying panel with respect to the upper marginal edge region of the underlying panel as an incident to temperature expansion and contraction of the panels;

said lower marginal edge including a first lower marginal edge portion and a second marginal edge portion, the first lower marginal edge portion being located proximate to the exposed face of the stone in various locations along the lower marginal edge, the second marginal edge portion extending rearward from the first lower marginal edge portion toward a rear side of the panel, the second lower marginal edge portion including the second tapered seating, the second lower marginal edge portion extends substantially along a horizontal plane that extends along the lover marginal edge of the panel so as to define an upper edge of the mortar defined between the lower stones of the overlying panel and the upper stones of the underlying panel;

wherein the portions of the first marginal edge portion define a non-planar surface that project downward from the plane and the second lower marginal edge portions so as to overly a portion of the mortar defined between the lower stones of the overlying panel and the upper stones of the underlying panel.

2. The wall covering of claim 1 in which said simulated stone of said panels protrude substantially equal distances from said mortar lines.

3. The wall covering of claim 1 wherein the non-planar portions of the first lower marginal edge project downward a distance from the second lower marginal edge portion that is between 0.020 inches and 0.250 inches.

4. The wall covering of claim 1 in which said mortar lines of said panels are in a substantially common plane, and said simulated stone of said panels have outer exposed faces in a substantially common plane outwardly of the plane of said mortar lines.

5. The wall covering of claim 1 in which the upper marginal edge region of each panel includes a mounting flange for securing the panel on a support surface, and said mounting flange being disposed in recessed relation to the plane of said mortar lines.

6. The wall covering of claim 1 in which said tapered seating surfaces are disposed at an angle of about 30-60 degrees to the planes of said mortar lines and outer exposed faces of said stone.

7. The wall covering of claim 1 in which said upper marginal edge region of each panel including a mounting flange parallel to the plane of said mortar lines and exposed faces of said stone for securement to a support surface, a tapered wall extending upwardly and inwardly between the stone and mortar design of the panel and the mounting flange at an acute angle to the plane of the mortar lines and the exposed surfaces of said stone for supporting the mounting flange in recessed relation to the plane of said mortar lines, said upper marginal edge region tapered wall forming a tapered seating surface, and said lower marginal edge region of each panel being formed with a tapered seating surface at an angle to the mortar lines and exposed stone faces similar to that of the seating surface of the upper marginal edge region for positioning in mounted adjacent relation to the seating surface of the upper marginal edge region.

8. The wall covering of claim 1 in which said panels are formed with a horizontal mortar line adjacent a top side of an uppermost row of stone of the panel, and said tapered seating surface of said upper marginal edge region defining an upper peripheral edge of said horizontal mortar line.

9. The wall covering of claim 8 in which said lower marginal edge region of each panel is defined by a lowermost row of said stones and vertical mortar line separating the stones of said lowermost row, and said tapered seating surface of said lower marginal edge region intersects said lowermost row of stones and said vertical mortar lines in a straight line through a lower perimeter of said vertical mortar lines and a lower and reward perimeter of the stones protruding from the vertical mortar lines which line lies substantially along the plane.

10. The wall covering of claim 1 in which a lower marginal edge region of each panel is formed with a rearwardly extending and depending flange for engaging the upper marginal edge region of an underlying panel for interlocking the lower and upper marginal edge regions and for positioning the tapered seating surfaces of overlying marginal edge regions in aligned seating relation.

11. The wall covering of claim 1 in which one of said seating surfaces intersects a horizontal side of a row of said stone, and the other of said seating surfaces intersects a horizontal side of a horizontal mortar line.