US3017725A

US3017725A - Solid grouting bar and hanger element for setting slabs and method

Info

Publication number: US3017725A
Application number: US648916A
Authority: US
Inventors: Murphy John Larry
Original assignee: Individual
Current assignee: Individual
Priority date: 1957-03-27
Filing date: 1957-03-27
Publication date: 1962-01-23
Anticipated expiration: 1979-01-23

Description

Jan. 23, 1962 J. MURPHY 3,017,725

SOLID GROUTING BAR AND HANGER ELEMENT FOR SETTING SLABS AND METHOD Filed March 27, 1957 5 Sheets-Sheet l FIG. 5 FIGA F165 INVENTOR. JOHN L- MU RPHY AT TO RM E-Y Jan. 23, 1962 J. L. MURPHY 3,017,725 soun GROUTING BAR AND HANGER ELEMENT FOR SETTING SLABS AND METHOD Filed March 27, 1957 5 Sheets-Sheet 2 IN VEN TOR. JOHN L. MURPHY ATTO RQEY Jan. 23, 1962 J. L. MURPHY 3,017,725

SOLID GROUTING BAR AND HANGER ELEMENT FOR SETTING SLABS AND METHOD Filed March 27, 1957 5 Sheets-Sheet 3 INVENT FIG. 12 JOHN L. MU HY Jan. 23, 1962 J. L. MURPHY 3,017,725

SOLID GROUTING BAR AND HANGER ELEMENT FOR SETTING SLABS AND METHOD 5 Sheets-Sheet 4 Filed March 27, 1957 FIG. 16

0 H Q n.. n n:

INVEN TOR.

Joa-m L. MURPHY FIG. 17

AT TO RNEY Jan. 23, 1962 J: L. MURPHY 3,017,725

SOLID GROUTING BAR AND HANGER ELEMENT FOR SETTING SLABS AND METHOD Filed March 27, 1957 5 Sheets-Sheet 5 mvamcm. JOHN L." muggy \QA-r-rolzmay 3,017,725 SOLID GROUTING BAR AND HANGER ELEMENT vFQIR SETTING SLABS AND METHOD .Iohn Larry Murphy, 101% ,SaLeavitt St, Chicago, III. .FiiedMar. 27, 1957, SeraNo. 648,916 7 (Ilaims. (CI. su -'41s) This invention relates to a pre-formed solid grouting and hanger bar element adapted for use in water and weatherproof assembly-of straight sided slabs of building material at least the adjacent peripheral edges of which are grooved or mortised.

More particularly this invention is directed to a solution to the problem of laying up walls of slabs of dense building materials including marble, glass, terra-cotta, vitreous tile,stone, etc., to provide a weather and waterproof wall of improved durability as to the supporting back wall, of enhanced physical appearance and requiring practically'no maintenance, as periodic tuck-pointing, usually required, is done away with.

The problem heretofore met in facing building walls and exterior and interior walls of structures with extremely dense structural substances, illustratively granite and structural glass, has been the problem of fool-proof lay-up in the first instance, and water penetration into and through the mortar between adjacent slabs. Water so entering, when subject to repeated freezing and thawing,

so deteriorates the nature of the supporting wall that slabs fall off and the supporting structure soon has to be rebuilt at considerable expense. Danger of heavy slabs falling into-the street from heights makes rebuilding mandatory. Walls of granite, glass, terra-cotta, etc., are extremely attractive and the rectangular building elements themselves are practically ageless. It is believed that lack of a durable, strong, weatherproof method of hanging such facings to overlay less aesthetic load-bearing supporting means with an attractive facing has practically reduced volume use of these otherwise'desirable building products to a practical standstill.

It is the general object of this invention to prove a solid grouting and hanger, preferably constructed of non- ,corroding load-bearing structural metal, adapted for use portion of the solid groutingelement to a supporting structure.

The mode of achievingthese and other related objects will be :made more clear as the description of practical embodiments of my invention are'developed in conjunction with the attached drawings in which:

FIGURE :1 is -a front view of :alfragmentarysection of a wall face of rectilinearslabs in assembly with the solid :grouting'bar and hanger element. of the invention in place.

FIGURE 2 is an isometric'view-of a rectilinear slab of building material as is essential to the ends 'of this invention.

FIGURE 3 is a front view of a fragmentary section of a wall face of rectilinear slabs, as'in FIGURE 2, inassem- 'bly with the solid grouting bar and hanger elementin a modified form.

FIGURE 4 is aplan view of the form of the invention as illustrated in FIGURE 3.

FIGURE 5 is a plan view of the form'ofthe invention as illustrated in'FIGURE 1.

FIGURE '6 is one modification of a sectional view through VI-VI of FIGURE 4.

FIGURE 7 is also a modification of the sectional form as viewed'throug-h a section of FIGURE 4.

FIGURE 8 is a similar sectional view as described for FIGURES 6 and 7, illustrating a preferred sectional View of the solid grouting'bar and hanger of the invention.

FIGURE 9 is a side view of the'invention as illustrated in FIGURE 4.

FIGURE '10 is similar to FIGURE 9, and is a side=view of one of the modifications of the invention.

FIGURE 11 is a fragmentary sectional view -alongthe line XI--XI of FIGURE '3.

FIGURE 12 is a side view of FIGURE 6.

FIGURE 13 is an additional front view of a fragmentary sectionof a wall-face of rectilinear slabs-in assembly detailing a further feature of the invention.

FIGURE 14'is an enlarged front view of the solidbar grouting and hanger element in assembly as shown in FIGURE 13.

FIGURE 15 'is a sectional view through FIGURE '14.

FIGURE 16 is a front view of a fragmentary wall section detailing the juncture of the rectilinear slabs of FIG- URE 2 with the coping stones capping aparapet wall.

FIGURE 17 is a sectional view substantially along the line XVII-XVII of FIGURE 1.6 with one coping stone removed.

FIGURE 18 is a plan view in reduced scale of FIG. '1

showing assembly of the solid rectilinear slabsof building materials with a generally cruciform 'solid grouting and hanger element in combination with the solid bar grouting elementof FIG. 4.

FIGURE 19 is a plan view of :the generally-cruciform solid grouting and hanger element as adapted 'for random assembly of rectilinear slabs.

FIGURE 20 is a plan view-of the preferred cruciform grouting and hanger element as adapted for regular assembly of rectilinear slabs for the purposes of this invention.

FIGURE 21 is a side view of the :element :of

'URE 20.

Referring more particularly .to the drawings, a regular assembly of slabs of dense building materials 1 having their peripheral edges 3 grooved ormortised as 'at 2 is shown in FIGURE 1 held in spaced arrangement .by ,a plurality of solid grouting and hanger bar elementsS, the

load supporting structurally rigid and ,not manually bendable oppositely disposed primary vpair of legs 6 and 7 of load created by the assembly slabs, and to increase the length of path that moisture must travel in order to pass from the face of the slabs to the rear side of the slabs and into the supporting wall behind the facing created by the slab assembly.

The solid grouting and hanger element 5 illustrated in assembly in FIGURE 1 is cut at each end on exactly a 45 angle to form equilateral triangles 12 and 13 at each oppositely disposed end of the solid grouting bar. The equilateral triangle so formed has the secondary legs at the apices thereof. The length of the bar element 5 is determined by the width of leg 11 and the dimensions of the building slabs to be erected as can be seen from FIGURE 1. The length of the solid grouting element is such that when it is in assembly with elements of similar cross-section, the assembly is at least as long as the mortised slab edge.

Referring momentarily to the view along section line VIVI, a number of modifications of the invention may be considered and made clear. FIGURE 8 illustrates a preferred modification in cross section of the solid grouting bar and

hanger element

5 and 10. Note the two pairs of

legs

22 and 14, and 20 and 21 each pair of which is at right angles to the other pair and each leg of which is of load-bearing dimension. Oppositely disposed

legs

20 and 21 serve as tenons, fitting into the mortises in the peripheral grooves 2 of slabs 1. Oppositely disposed

legs

22 and 14 may determine the space between adjacent slabs in assembly, and are of load-bearing dimension. In use,

legs

22 and 14 aid in maintaining the slabs parallel to the supporting wall during construction. Extending rearwardly from the solid grouting element is an additional tertiary leg 65 of yieldable or manually bendable dimension, adapted to be formed on the job to be fastened by a variety of means to load-bearing supporting walls, etc. The yieldable leg 65 is preferably made of expanded metal lath as illustrated in FIGURE 12, and may be scalloped as is shown in FIGURE 9. The yieldable non-rigid and manually bendable leg or anchor plate 65 may also be a light gauge steel plate (as in FIGURE 15) and may be stamped with holes 64 as illustrated in FIGURE 9. The yieldable rearwardly extending leg may also be an occasional rectangular stamped sheet, discontinuous along the rear side of the solid grouting bar as shown in FIGURES l0 and 17 or continuous as shown in FIGURE 12.

The legs in the section of the solid bar grouting element and the unit which combines therewith constituting generally a solid cruciform grouting element may be ar ranged as shown in FIGURES 6, 7, 8, 9, 10, 11, 15, 19, and 21 although FIGURES 8, 9, 10, ll, 20 and 21 are preferred as stronger and more Weather resistant modifications.

FIG. 19 details a modification used in random assembly of the generally cruciform solid grouting having three

arms

66, 67 and 68 of rigid, structural, not manually bendable and load bearing dimension lying in the same plane, of the same width and of the same cross arm end sectional pattern. Two of the

arms

66 and 68 are oppositely disposed and a third arm 67 is at right angles to the oppositely disposed pair. The modification 15 of FIG- URE 20 has four arms of

load bearing dimension

16, 17, 18 and 19 having two pairs of oppositely disposed

arms

16 and 18 and 17 and 19 at right angles to one another all arms identified of the same width and thickness.

In the forms of the invention illustrated in FIGURES 19 and 20, there is superimposed upon the front and rear face and axially aligned with each of said first arms a corresponding second set of arms of diminished but nonethe-less, rigid structural, not manually bendable and load bearing width identified as 71, 72 and 81 in FIGURE 19 and 73, 74, 76 and 77 in FIGURE 20. A like set of arms is on the reverse face of the elements of FIGURES 19 and 20.

FIGURE 21 illustrates a side view of FIGURE 20 showing the like set of

arms

78, 79 and 82 on the reverse face of the cruciform grouting 15.

When the slabs and the solid grouting bar tenons are in approximate final position, the solid grouting bars are wetted or struck with the organic caulk along the apices of the meeting sides of the equilateral triangles 12 and 13 and the four units brought into contact to form a cross as shown at 15a and 16a. Excess caulk is wiped off to give a seal, yet provide sufficient tolerance between adjacent grouting elements 5 when they meet as at 16a to take up the expansion and contraction of the metal grouting bar 5.

In a preferred assembly utilizing the solid grouting and hanger element of this invention as illustrated in FIG- URES 3, 4, and 18 the solid bar grouting and hanger 10 is cut to determine its length at right angles to its longitudinal axis. In the assembly shown in FIGURES 3, l8, l9 and 20 a special solid grouting and hanger element of generally cruciform shape in both its plan and section (see FIGURES 18, 19 and 20) identified as 15 is used in conjunction with solid grouting and hanger bar 10. In laying up a plurality of slabs I as in FIGURES 3, l6 and 18 in both a horizontal and vertical dimension to create a weatherproof wall facing of, for example, granite slabs the following method is used.

The mortised edges 3 of the slab as in 1 are wetted or filled with organic caulk. An appropriate length of solid grouting 1G is cut at right angles so that its length and the length of the

arms

16, 17, 18 and 19 of the cruciform element 15 fit together as shown in FIGURE 3. Some slight gap should be considered for expansion and contraction of the metal bar elements. Assume for illustration that

slabs

1a and 1b are in place along with solid grouting bar 10a cut as shown. The top horizontal mortises of

slabs

1a and 1b are wetted or struck with organic caulk and the cruciform element 15 (whose

cross arms

16, 17, 18 and 19 have cross-arm end-sections as illustrated for the solid bar section in FIGURE 8) arm end 18 is pushed downwardly sliding oppositely disposed

legs

20 and 21 between

adjacent blocks

1a and 1b and in the mortises adjacent thereof until arm 18 contacts the upper end of solid bar grouting 10a. A rearwardly extending leg of yieldable dimension, similar to leg 65 in FIGURE 12, is bent upwardly at its free end and fastened to the supporting wall. (A gun capable of firing studs into concrete is useful.) Solid grouting and hanger bar element 10 in FIGURE 4 (shown as 10a, 10b, 10c and 10d in FIGURE 3), having a section as shown in FIGURE 8 are oriented so that the legs 20c and 10d are set in the mortise of

slabs

1b and 1a respectively. After the solid grouting elements 10c and 10d are snugly in place the yieldable rearwardly extending legs similar to leg 65 of FIGURE 12 are bent over at a angle and permanently fastened to the supporting means rearwardly of the facing under erection.

Edges 3 and mortises 2 of slabs 1c and 1d are struck with caulk and the mortise of slab 1d brought home over leg (tenon) 21d of solid grouting bar element 10d. Leg 20b of solid grouting element 10b is then set into the mortise of slab 1d and the yieldable rearwardly extending leg (corresponding to 65 in FIGURE 12) bent over at its free end away from slab 1d is fastened by firing nails through it into the leg end and the supporting wall. Thereafter, the mortise 2 of slab 1c is brought down over leg 21c of solid grouting 10c and slid toward slab 1d to fit its vertical mortise adjacent solid grouting 10b over leg 21b, and the adjacent tenon-like legs of the cruciform hanger 15 in position to enter both horizontal and vertical mortise 2 of slab 1c. The process of assembly, as described, is repeated in both a horizontal and vertical plane to complete facing the wall with a water impermeable solid facing of dense building material. Leg 22 and leg 14 of the solid grouting element 10 act as a solid grouting to space the slabs, both in their horizontal and vertical courses. When the face of leg 22 is of burnished metal, unusually attractive combinations and wall design are possible.

In some instances it is desirable that the joint between the solid bar grouting element 100 and arm 17 of the cruciform solid grouting element 15 be further protected from the potential of moisture entering the crack essential to expansion between adjacent ends of solid bar grouting. In other cases, where the slabs of building material may be quite long, joints between adjacent solid bar grouting elements as also need additional protection from the weather. This is provided by a clip element 30 shown in in place over the meeting ends of two solid grouting bar elements 10 in FIGURE 14. FIGURE 15, in section, details clip 30 as a thin sheet formed so that its peripheral section is of similar contour to that of the cross-section of solid grouting element '10. FIGURE 13 details clips 34) in place when the cruciform element 15 and the solid grouting bar 10 are used in combination. :In using the clip 30, it is slid over the one end of one arm of the-cruciform element 15, and the adjacent solid bar 10, in turn, slid into open end of clip 30. Clips must be positioned between the solid bar ends 10 or bar 10 and cross 15

arms

16, 17, 18 and 19 before the weight of the slabs are allowed to press against clip 30 ends 31, otherwise assembly is most diflicult. Once all slabs are in position as shown in FIGURE 13 movement of clips 30 are most difiicult if not impossible. By means of use of clips 30 over the meeting and mating joints the potential of moisture getting through to the supporting wall is completely eliminated and no caulk joints are then visible.

A specialized form of the invention is detailed in FIG- URES l0 and 11 wherein the solid grouting element 40 is notched along its length in the two oppositely disposed legs 42 and '43 which serve as tenons. Notches 44, assure flow of the semi-fluid caulk freely about the solid grouting element 40. Both flow of caulk and spacing of the

tenonacting legs

42 and 43 is aided by the buttons 4 5 which are pressed into

legs

42 and 43 in alternating and opposite direction. Seating of the tenons or legs '42 and 43 is thereby simplified and less play is faced in the joint during as sembly than is otherwise necessary.

A further application of the invention is detailed in FIGURES l6 and 17 which illustrate its use in setting coping stones upon the top of a parapet wall 63 in a more or less conventional building construction. As the method is particularly adaptable when remodeling older structures with new facings, as is one principal intent of the invention, this additional improvement at the same time is also desirable in order to eliminate the moisture problem from faulty grouting between coping stones.

Of greatest explanatory value is FIGURE 17 which is a sectional view along the line XVII-XVII of FIGURE 16 showing the top course of solid slabs as in FIGURE 2 in place, utilizing the herein described invention as said slabs meet with the coping stones topping supporting masonry wall 63. A groove or mortise 50 extends horizontally parallel with and a few inches rearwardly of the front face of coping

stones

51 and 52 along and upwardly in stone base 53. This groove or mortise 50 accepts the upwardly extending tenon or leg 70 of the cruciform solid grouting elements of three arms 55 of the type shown in FIGURE 19. Each adjacent end of the coping

stones

51 and 52 are further grooved or mortised, as illustrated in mortise 60 so that adjacent mortises in coping stone ends 75 and 80 are mirror images of one another. A solid grouting bar having a cross-section as shown in FIGURE 6 is fabricated so that the

legs

57 and 58 thereof fit into the oppositely disposed (mirror image) mortises 60 of

adjacent coping stones

51 and 52 ends 75 and 80. Leg '59 faces outwardly and upwardly to provide a solid grouting and spacing element between coping

stones

51 and 52. Leg 58 sets into groove 60 of end 75 of coping stone 51. The area indicated as 57 delineates the corresponding tenon-like leg 57, with coping stone 52 removed. To avoid possibility of shifting due to high winds catching under the stone (or malicious mischief) a leg 65 rearwardly extending from the solid grouting bar element in mortise 60 is extended and forced into a void left in the parapet wall during construction the void freshly filled with mortar in a plastic state prior to setting the coping stones. Additionally, the groove 60 and corresponding mirror groove in the adjacent coping stone end are wetted with an organic caulk prior to assembly of

legs

57 and 58 of the solid grouting element into the coping stone end grooves or mortises. The holes 64 of and in the yieldable anchor plate 65 when set in the said fresh mortar at the time of laying up the coping stones provide excellent bonding with the parapet wall 63 itself.

As can be visualized from the sectional view of FIG- URE 17, no matter how hard the wind and rain may blow, moisture is excluded from entering through faulty seal in the coping stones or from the installed slabs of facing material immediately adjacent thereto.

Having thus described my invention, what I claim is:

l. A combined solid metal grouting and hangar unit adapted for use in water-tight and strain-free assembly of a plurality 'of veneer-like, rectangular facing slabs whose edges are fully mortised and which slabs are non-load bearing in spaced apart relation and assembled from a load bearing wall structure; said grouting unit comprising a grouting strip of cruciform cross-section and load-bearing non-yielding, structurally rigid dimension; the vertical pair of oppositely disposed legs of said cruciform crosssection of such width as to be slideably insertable as tenons in adjacent mortises of adjacent slabs when assembled and the depth thereof to substantially fill said mortises, and a horizontal pair of oppositely disposed legs of said cruciform section integral with said vertical pair of legs, the thickness of the horizontal legs defining substantially the distance apart of adjacent slabs in assembly; the horizontal faces of the horizontal pair of legs and the vertical faces of the vertical pair of legs and the length of said grouting strip forming an extended and complete seal between the front and rear faces of said slabs in assembly; and extending outwardly from the rearward face of the horizontal leg of said cruciform grouting strip a manually bendable anchor and plate hanger means the extension of said anchor and plate hanger being such that the free end thereof may be readily deformed for attachment to loadbearing supporting wall means, to permit differential shifting by way of settlement of the load bearing wall without transfer of the full strain thereof to the assembled facing slabs of the non-load bearing wall, and to permit slap assembly with the free end of said anchor means fixed in the load bearing wall.

2. The product of claim 1, wherein the manually bendable anchor and plate hanger means is expanded metal lath.

3. The metal grouting and hanger unit of claim 1, wherein the length of the metal grouting strip is in excess of the mortised slab edge and each end thereof terminates in an equilateral triangle with the horizontally disposed legs at the apices thereof.

4. The product of claim 1, wherein the manually bendable anchor and plate hanger means is a length of perforated metal.

5. A solid metal grouting and hanger adapted to use with associated elements of similar section in water-tight assembly of a plurality of veneer-like rectangular, nonload bearing edge-mortised slabs in spaced apart relation from a load bearing wall which comprises a load hearing structure of generally cruciform pattern in both its plan and cross-arm end section; the plan thereof comprising four first arms lying in the same plane each arm thereof of the same width and thickness, a first pair and a second pair each arm of each pair of which is oppositely disposed and the first pair at right angles to the second pair of arms; centrally superimposed on both the front face and rear face of said cruciform plan a second and third set of cross arms in axial alignment said arms of the same length, but of diminished width, as compared with the arms of the first described cruciform plan; the cruciform cross-arm end section of each of said arms comprising in turn four legs, a first pair and a second pair each leg of each pair of which is oppositely disposed and the first pair at right angles to the second pair of legs, the oppositely disposed first pair of legs adapted to be inserted as tenons between the mortised edges of adjacent slabs and the second pair of legs adapted substantially to occupy and define the space between the non-mortised front and rear edges of adjacent slabs when said slabs and herein defined hanger elements are in final assembly; all of said arms and legs of non-yielding, structurally rigid, load bearing dimension; and substantially along the center line of one pair of rearwardly extending legs and substantially at right angles to the plane of said arms attached and extending rearwardly from said line of said rigid cruciform structure a manually bendable anchor plate means of yieldable dimension of sufficient length to suspend the load-bearing cruciform structure at a spaced distance from and its free end to load-bearing supporting means.

6. The product of claim 5, wherein the anchor plate means is a length of perforated metal.

7. The product of claim 5, wherein the perforated metal is expanded metal lath.

References Cited in the file of this patent UNITED STATES PATENTS 429,342 Foote June 3, 1890 695,722 Heilmann Mar. 18, 1902 787,023 Buell Apr. 11, 1905 860,682 Marshall July 23, 1907 1,374,356 Clouser et al. Apr. 12, 1921 1,771,354 Sciamanna July 22, 1930 1,813,173 Kuehn July 7, 1931 2,005,427 Lenke June 18, 1935 2,363,156 Sinner et a1. Nov. 21, 1944 2,700,434 Tofanelli Jan. 25, 1955 2,748,593 Stetter June 5, 1956