BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of a dry stack construction block of the present invention.
FIG. 2 is a plan view of the block shown in FIG. 1.
FIG. 3 is a cross-sectional view taken along line 3-3 of FIG. 2.
FIG. 4 is a cross-sectional view taken along line 4-4 of FIG. 2.
FIG. 5 is an elevation view taken along line 5-5 of FIG. 2.
FIG. 6 is a cross-section view taken along line 6-6 of FIG. 2.
FIG. 7 is a perspective view of a cell core of the present invention showing a block (in phantom) with the cell core installed.
FIG. 8 is a perspective view of a preferred embodiment of a second cell core or third cell core of the present invention.
FIG. 9 is a perspective view of a preferred embodiment of a first cell core of the present invention.
FIG. 10 is a perspective view of a preferred embodiment of a block assembly of the present invention with a first cell core, second cell core, and a third cell core installed in the block, and a further third cell core positioned for installation.
FIG. 11 is a plan view of three abutting blocks of a course of blocks having first, second, and third cell cores in place.
FIG. 12 is a vertical section of a portion of a wall showing two courses of block assemblies constructed to provide horizontal and vertical grout cells with reinforcing bars installed.
FIG. 13 is a vertical section view of a block showing vertical and horizontal rebar installed.
FIG. 14 is an elevation view of a dry stack wall system of the present invention with a leveling cap poured on top of the top course of block.
FIG. 15 is a plan view of an embodiment of a corner block of the present invention.
FIG. 16 is a plan view of an embodiment of a half-block of the present invention.
FIG. 17 is an elevation view of an embodiment of a window/door opening installation for the wall system of the present invention.
FIG. 18 is a plan view of an alternative embodiment of a dry stack block of the present invention having a central cell and opposing end cells.
FIG. 19 is an end elevation view of the block of FIG. 18.
FIG. 20 is a perspective view of the block of FIG. 18.
FIG. 21 is a plan view of an embodiment of a cell core used for the central cell and end cells of the block of FIGS. 18, 19 and 20.
FIG. 22 is a side view of the insert of FIG. 21.
FIG. 23 is an end view of the insert of FIG. 21.
FIG. 24 is a perspective view of the insert shown in FIGS. 21, 22 and 23.
FIG. 25 is a plan view of three abutting blocks of a course of blocks utilizing the alternative block of FIGS. 18, 19 and 20 with cell cores and vertical reinforcing bar installed.
FIG. 26 is a perspective view of a portion of a wall system of the present invention with surface bond.
FIG. 27 is a vertical cross section detail of an alternative cell core ear base.
FIG. 28 is a vertical cross section detail of an alternative cell core ear base.
DETAILED DESCRIPTION OF THE INVENTION
While the terminology used in this application is standard within the art, the following definitions of certain terms are provided to assure clarity. Units, prefixes, and symbols may be denoted in their SI accepted form. Numeric ranges recited herein are inclusive of the numbers defining the range and include and are supportive of each integer within the defined range. Unless otherwise noted, the terms “a” or “an” are to be construed as meaning “at least one of.” The section headings used herein are for organizational purposes only and are not to be construed as limiting the subject matter described. All documents, or portions of documents, cited in this application, including but not limited to patents, patent applications, articles, books, and treatises, are hereby expressly incorporated by reference in their entirety for any purpose.
Referring first to FIGS. 1-6, a preferred embodiment of a dry stack construction block 20 is shown which comprises a first and a second side wall, 21 and 22 respectively, and a central web 23 interposed between the first side wall and the second side wall. The walls and central web may be generally rectangular and generally parallel to one another and having generally the same block wall axial length 71 and wall height 72. For purposes of this application, the term “rectangular” shall be deemed to mean substantially rectangular, the term “parallel” shall be deemed to mean substantially parallel, and the term “perpendicular” shall be deemed to mean substantially perpendicular. Blocks 20 may be arranged in running courses 19 in a symmetrical staggered stack configuration 60 as shown in FIG. 14 and FIG. 27 or may be stacked in other configurations that will be known to persons skilled in the art. One advantage of the dry stack wall system 18 of the present invention is that it does not depend for its strength on the symmetrical staggered configuration utilized for a common masonry block wall.
First side wall 21, central web 23, and first and second end transverse webs 27 and 28, respectively, define the longitudinal bounds of first cell 26. As is seen in FIG. 2, the interior surfaces 29, 30 of transverse webs 27, 28, respectively, are tapered for interfacing with first cell core 11 as described below. The mold used to cast block 20 will have a complementary shape for the mold employed to form the first cell core 11, the mold for the first cell core being dimensioned to be complementary with the interior surface of wall 21, the facing surface of central web 23 and surfaces 29, 30 of transverse webs 27, 28. The first cell core, however, as more fully explained below will not follow the precise contours of transverse webs 27 and 28.
The space between central web 23 and second side wall 22 can contain two open-ended third cells 31 and 32 separated by a central second cell 33. The walls of the individual cells are created by forming the inwardly facing surfaces of central web 23 and second side wall 22. Intermediate transverse webs 34 and 35, each having reduced height, are disposed at each end of the second cell 33 and define the boundary between the second cell 33 and third cells 31 and 32, respectively.
As shown in FIGS. 2 and 3, first and second end transverse webs 27 and 28 are disposed outwardly from first and second intermediate transverse webs 34 and 35 respectively so that a single transverse plane does not pass between web 27 and web 34 or between web 28 and web 35. The height of transverse webs 27, 28, 34 and 35 is deliberately reduced and typically, stand slightly more than one-half the height of block 20. Webs 27, 28, 34 and 35 are especially designed to enable block 20 to have the strength necessary to meet the various building codes while the reduced height of the webs reduces the volume of the thermal conduction path and hence the thermal transfer between walls 21 and 22. Each web 27, 28, 34 and 35 is provided with a V- or U-shaped notch or hyper-extended draw 36 which converges to a curvilinear notch bottom 37, the interface with corresponding cell cores 26, 31, 32 and 33 of which shall hereafter be described in detail. Nonetheless, it should be noted that the V-shaped draw 36 enables the manufacturer to obtain proper compression during the molding process with stronger compaction and avoids the fracture points which inevitably result if the draw terminated in a square bottom.
Having thus described a construction block 20 whose interior dimensions can be effectively replicated throughout long manufacturing runs, refer now to FIGS. 8, 9 and 10 wherein the cell cores may be installed into the construction blocks 20.
As shown in FIG. 10, a first cell core 11 is disposed within first cell 26 in near shape-conforming relationship thereto while a second cell core 12 is disposed in near shape-conforming relationship to second cell 31, and a third cell core 13 is disposed in near shape-conforming relationship to third cells 32 and 33. For the embodiment shown, the second cell cores and the third cell cores are identical in size and shape, thereby limiting the number of types of cell cores to two. However, other embodiments may provide for the second cell cores and the third cell cores to be of different size or shape, or both. While cell cores 11, 12, 13 may be molded of any material which allows substantial control of its dimensional characteristics, in a preferred embodiment, cores 11, 12, 13 will be formed of an insulating material such as, for example, a low-density foam such as expanded polystyrene or the like whereupon the rate of thermal conduction through the resultant block wall is substantially reduced.
Referring to FIGS. 8, 9, and 10, the core axial length 24 of cell cores 11, 12, 13 may vary, but the principal construction of the cell cores will be preferably the same, that is, each will comprise a top surface 14, a bottom surface 15, a first face surface 16, a second face surface 17, a first end surface 2, and a second end surface 3. Tablet shaped body portions, namely tablet shaped first body portion 4, tablet shaped second body portion 5, and tablet shaped third body portion 6, of the first cell core 11, second cell core 12, and third cell core 13 respectively, are interposed between and formed by the respective top surfaces, bottom surfaces, first face surfaces, second face surfaces, first end surfaces, and second end surfaces. The first cell core has a pair of opposing first ear members, one first ear member 6, being integral with the first end surface of the first cell core and an opposing first ear member 6 being integral with the second end surface of the first cell core. Similarly, the second cell core has a pair of opposing second ear members, one second ear member 7 being integral with the first end surface of the second cell core and an opposing second ear member 7 being integral with the second end surface of the second cell core. Likewise, the third cell core has a pair of opposing third ear members, one third ear member 8 being integral with the first end surface of the third cell core and an opposing third ear member 6 being integral with the second end surface of the third cell core. For preferred embodiments, the ear members will be integrally molded with the body portion of the cell cores, but other embodiments may provide for the ear members to be integral with the body portion by being affixed to the body portion of the cell core in a manner which will be known to persons skilled in the art.
Hence, respective pairs of opposing first ear members 6, second ear members 7, and third ear members 8, are integrally molded with or otherwise integrally affixed to the first end surface and the second end surface respectively of the respective first, second and third cell cores. For the preferred embodiment shown, the axial length of first cell core 11 is about one-half the axial length of the second cell cores 12 and the third cell cores 13 for reasons to be hereinafter described.
Referring to FIG. 8, for the second cell core 12 and the third cell cores 13 and to FIG. 9 for the first cell core 11, each of the cell cores comprise a body portion having an ear member disposed at each end. Body portions comprise a generally vertical, planar surface 44 and a bowed inwardly tapering surface 45. Surface 45 is provided with a plurality of spaced generally parallel vertically extending ridges 46 having a concave valley portion 47 operatively interposed between them and extending from the top surface 48 of body portion 41 to the bottom surface 49 thereof. The interaction of ridges 46 with their adjacent valleys 47 will herein be referred to as “fluting” which may provide an interlocking relationship with the adjacent surface of the receiving cell to create a “custom fit” ″ of the core with the receiving cell. Optionally, body portion 41 can be scored at its horizontal mid point, designated score line 50, which extends the full height of the core to facilitate dividing the core in half for use as described below.
In an alternative form, second cell core 12 and third cell cores 13 as shown in FIG. 7 and FIG. 10 omit the fluting so as to instead provide a planar surface. Similarly, first cell cores 11 may omit the fluting.
For the preferred embodiment shown, each ear member 6,7,8 is trapezoidal shaped, having its widest dimension 51 in substantially co-planar relationship with core top surface 48, the ear member extending, when the cell core is inserted in a block, downwardly to the ear base 52 for a distance not reaching notch bottom 37 of the U- or V-shaped notch 36 defined in each of transverse webs 27, 28, 34 and 35 of the block 20, thereby creating a notch gap 1. Because the ear member base does not mate with the notch bottom, the typical compressibility, albeit typically limited, of the cell core material, allows the cell core to be urged into a proper position in the cell, thereby providing that the core top surface 48 is at or below the block top surface when the core is installed. The cell core is dimensioned so that the cell core will not extend beyond the block top surface or block bottom surface when installed, except for spurs on embodiments having spurs as described herein. When a cell core is inserted in a block, a notch gap 1 between the ear base 52 of the ear member 6,7,8 and the notch bottom 37 of its corresponding notch 36. The cell core of the present invention is not intended to provide for leveling of the blocks in each course or for the creation of a block gap between the blocks of successive courses. The trapezoidal shaped ear of the present invention provides the benefit of a tight fit between the ear and the notch 36 of the transverse web while providing the further benefit of accommodating an accumulation of crumbing in the notch bottom 37 of the transverse web which inherently accumulates during the manufacturing process for the block.
Despite attempts to manufacture blocks with uniform dimensions, variations in the block dimensions, including the dimension between the notch bottom 37 in the U- or V-shaped notch and the block bottom surface 25, are inevitable. Accordingly, since the present invention provides that when the ear members are seated in their corresponding U- or V-shaped notch, the distance from the ear base to the notch bottom can be adjusted during the insertion of the cell core to provide for an appropriate fit of the cell core, the top of the cell core being at or below the block top surface and the bottom of the cell core being at or above the block bottom surface.
As shown in FIGS. 10 and 11, continuous central web 23 of each unique block 20 employed herewith enables both halves of block 20 to be insulated by the insertion of the appropriate cell core 11, 12 or 13 therein or only one-half to be insulated while the other half is filled with aggregate to enhance the strength of the wall and provide that wall with thermal flywheel when warranted or desired. Modifications for the inclusion of reinforcing bars, grout cells, bond beams, and electrical conduit or the application of a surface bond are described below.
As earlier described, each improved building block 20 has first and second side walls 21, 22 and a central web 23 operatively disposed between the side walls in spaced generally parallel relationship to side walls 21, 22. Central web 23 and first side wall 21 define core receiving cells 26 while central web 23 and second side wall 22 define cells 31, 32 and 33 during the molding of the blocks.
As previously mentioned, one of the more imprecise dimensions of a molded construction block is the height of the block. The height of the block varies with the amount of material impressed into the mold from which the block is manufactured. Molded construction block therefore has a tendency to run slightly undersized from a standard height dimension, for example, eight inches. The variations in the dimensions of the block generally cannot be effectively compensated for by the ability to maintain more uniform control of the height of cores 11, 12 and 13 and the dimension of ear members 6, 7, 8 integrally formed thereupon. Thus, a fixed and precise height dimension generally cannot be established for the combination of a block 20 and one or more cores 11, 12, 13 when inserted therein with trapezoidal shaped ear members 42 and 43 firmly seated within the corresponding U- or V-shaped notch 36 provided in each transverse web 27, 28, 34 and 35. However, the walls of the individual cells 26, 31, 32 and 33 in block 20 can be produced with interior dimensions of sufficient uniformity so that the more uniformly dimensioned cores 11, 12 and 13 will fit the cells with sufficient intimacy for leaving an unoccupied volume of space as a notch gap 1 between the ear base 52 of the cell core trapezoidal shaped ear member and the notch bottom 37, and providing for the top of the cell cores to be at or below the top of the block.
With reference to FIGS. 1, 2, 9 and 10, first cell core 11 is disposed in first cell 26 and extends axially whereupon trapezoidal shaped first ear members 6 are firmly seated in the U- or V-shaped notch 36 defined respectively in end transverse webs 27, 28 while still leaving a notch gap 1. As shown in FIG. 10, with reference likewise had to FIGS. 1, 2, 7 and 8, second cell core 12 is disposed intimately within cell 33 in near shape-conforming relationship to the walls of the cell. The fit of second cell core 12 in cell 33 is enhanced by the light “sanding” action on ridges 46 caused by the harder inner surface of the cell as trapezoidal shaped second ear members 7 are firmly seated in the U- or V-shaped notch 36 defined respectively in webs 34, 35. trapezoidal shaped ear members 7 of second cell core 12 occupy only one-half of the notch axial length 73 of the notches 36 in the contiguous webs 34, 35 in contrast to the corresponding first ear members 6 of the first cell core 11 each of which extend completely across the notches 36 defined in contiguous end transverse webs 27, 28. Third cell cores 13 are disposed into each of the open-ended cells 31, 32 in a near intimate shape-conforming engagement with the interior walls of its corresponding cell as well as extending into intimate abutting contact with a portion of an adjacent second cell core 12. When a third cell core 13 is disposed in one of the open-ended cells 31, 32, approximately one-half of the third cell core 13 will extend beyond the bounds of the associated cell 31, 32 into the open-ended cell 32, 31 of the concrete block 20 (see FIGS. 10 and 11) adjacent thereto and in registry therewith in a block course 19.
By extending selected third cell cores 13 beyond the longitudinal bounds of the principal block 20 into the adjacent block, a block gap 70 is preferably produced between the facing ends of adjacent blocks 20 which serves to provide that the cell cores will substantially control the horizontal dimensions of each course and thereby compensate for length variations in the block arising from the manufacture of the block. For a preferred embodiment, the block gap between adjacent concrete blocks will be approximately one-eighth of an inch when the blocks are set in running courses 19 to erect a standing wall. In one preferred embodiment, first cell core 11 will measure sixteen inches and second and third cell cores 12,13 will measure eight inches in length.
Since dry stacked blocks employed in the erection of a standing wall are preferably coated with a surface bond 9 of cementious material as shown in FIG. 27, the block gap 70 between blocks 20, as described above, will readily accept the surface bond of cementious material to provide a strong gapless interlock and enhance the shear strength and lateral strength of the standing wall. The surface bond can also provide the additional benefits of obscuring vertical, longitudinal and lateral variations in the alignment of the blocks in running courses 19 and variations between adjacent courses. Since dry stacked blocks, in certain preferred embodiments are not aligned and leveled through the use of mortared joints between blocks, the surface bond can be used to obscure such alignment and leveling variations to produce a finished wall that is uniform and plumb, in addition to being significantly strengthened against shear forces and against lateral forces, such as impact forces.
The intimate line contact maintained between adjacent first cell cores 11 and between adjacent second and third cell cores 12, 13 within a running course 19 of blocks 20 further enhances the thermal resistivity of a standing wall system 18 constructed from the blocks with cell cores installed, especially when the cores are made of an insulative material.
Referring now to FIGS. 7, 8, 11 and 12, cores may be optionally provided with a pair of nodes or spurs 53 on the top thereof and complementary recesses 54 on the bottom thereof, which, as will be explained, coact with one another to create an interlock when a structure is assembled using blocks 20 and cores 11, 12, 13 in accordance herewith. When blocks 20 with cores 11, 12, 13 inserted therein are laid in running courses, each spur 53 will matingly interlock with a complementary recess 54. The interlocking of the several spurs 53 with their corresponding recesses 54 reduces the misalignment or skewing of individual blocks. Further, the interlocking of the spurs 53 and recesses 54 complements the stabilizing action of cores which extends from the open cells 31 and 32 in one block into the contiguous open cell in the block adjacent thereto. In other embodiments, no nodes or spurs 53 are present.
Sectional view of the standing wall shown in FIG. 12 also illustrates the ease with which the invention may be adapted to accommodate local building codes or the design of a structural engineer. Thus, when local building codes or structural design requirements dictate that there be continuous vertical grout columns spaced along the running length of the wall, for example at a spacing of four feet, such a column is readily created by selectively omitting second or third cell cores 12, 13 in a vertically aligned series of short cells 31, 32 or 33 to create a continuous vertical void in the standing wall so erected. Thereafter one or more vertically extending reinforcing bars 57 can be readily placed within the void thus created, when required to comply with local building code standards or with the structural design, and thereafter the void can be filled around the bars with grout to form a continuous vertical column of grout, shown as grout cell 56 in FIG. 12.
Many local building codes or structural design requirements also dictate that a bond beam be established, for example at a vertical spacing of four feet of height of the standing wall. Such a bond beam 58 (see FIGS. 12 and 13) is readily created when using the present invention and comprises a continuous horizontal beam of grout preferably formed by omitting all second and third cell cores 12, 13 from a given running course 19 of block, laying one or more horizontally-extending reinforcing bars 57 in the curved notch bottom 37 of the several intermediate transverse webs 34, 35 so as to extend across several second and third cells 31, 32, 33 and thereafter filling the void remaining with grout. Also, one or more additional horizontal reinforcing bars can be ‘floated’ on the grout after the second and third cells of the course are partially filled with grout. Preferably the first cell cores 11 are also omitted from the same running course and one or more reinforcing bars 57 are laid in the curved notch bottom 37 of the several end transverse webs 27, 28 so as to extend across several first cells 26 and thereafter filling the void remaining with grout. Again, one or more additional horizontal reinforcing bars can be ‘floated’ on the grout after the first cells of the course are partially filled with grout. By reinforcing and grouting both sides of the running course, the strength of the bond beam against side impact forces and other lateral forces from both sides of the standing wall, as well as from the vertical load, is increased. The cell cores which are disposed in the course of block 20 beneath bond beam 58 prevents the grout from migrating downwardly from the bond beam 58 into lower portions of the standing wall and eliminates the need for grout mesh. Bond beam 58 will set and lock itself to the spurs 53 protruding from cell cores disposed in the running course beneath the bond beam, thereby contributing further to the strength and stability of the wall created thereby.
As shown in FIG. 13, rebar 57 can be readily disposed both vertically and horizontally within cells 31, 32 and 33. The reduced height of transverse webs 34, 35 and the curvilinear notch bottom 37 defined therein permits the precise placement of a horizontally extending reinforcing bar 57 within the confines of a course of blocks 20. Further, the juncture of each cell 31, 32, 33 with its correspondingly adjacent web 34, 35 creates a nook 55 into which a vertically extending rebar 57 can be nested without interference with the horizontal rebar when both are required or desired.
As previously indicated, FIG. 12 illustrates the interlocking action between spurs 53 and recesses 54 of adjacent cell cores. A further function of recesses 54 occurs at the junction between the fresh footing 59 and the first running course of block 20. Thus when block 20 is laid on the footing 59 and the cell cores are placed in their designated positions, the footing material 59 rises into recesses 54 and, upon setting, will further secure the first running course of block 20 to footing 59.
Despite the interlocking of the cell cores and substantial uniformity in the manufacturing of the cell cores, depending on the level of uniformity in the manufacture of the blocks and on the skill and care exercised in the building of the dry stack block wall, the dry stack block wall system may display substantial variations in vertical, longitudinal and lateral alignment. The vertical and longitudinal alignment irregularities can be compensated for at least partially as the dry stack block wall is being built through the use of block shims. These building code approved shims can be constructed of stainless steel, galvanized steel or other materials, and can be used to correct the vertical or longitudinal alignment of individual blocks. For instances where excessive vertical or longitudinal alignment irregularities occur, mortar joints between block or courses of block can be used on a selective basis. Leveling and finishing of the wall at a design height or design top of wall elevation, can be accomplished by a leveling cap 39 as shown in FIG. 14. The leveling cap is preferably constructed of fine aggregate concrete, grout or other cementious material and is finished at the desired wall height or top of wall elevation. The use of a leveling cap permits the expedited assembly of the wall by the placement of the dry stacked block and the correction of accumulated variation in the elevation of the top of block courses by placement of the leveling cap, block shims being used as desired as the block is being stacked.
Although preferred embodiments of the wall system of the present invention, do not utilize mortar joints between blocks, mortar joints can be used between adjacent blocks of a running course or between successive running courses to assist in alignment or leveling of the courses of block. For example, mortar joints can be used between successive courses at a pre-determined or field determined spacing to control the leveling of the courses within a minimum variation, thereby reducing the amount of correction that is required from the leveling cap 39 as shown in FIG. 14.
Another aspect of this disclosure is illustrated in FIGS. 15, 16 and 17 and deals with the easy and convenient manner whereby the present invention is readily adapted to finish corners (see: FIG. 15) and to frame the openings provided for windows and doors (see: FIGS. 16 and 17).
Referring to FIG. 15, each corner block 120 comprises a first and a second side wall 121, 122 having a central web 123 disposed between the first and second side walls and extending approximately one-half the corner block wall axial length 74 of the first and second side walls to a transverse wall 124 extending between walls 121, 122 and coacting with the side walls smooth end wall 125 to define a full size grout cell 126.
The half block 220 shown in FIG. 16 is simply one-half of a block 20 (see: FIGS. 1 and 2) and comprises a first and second side wall 221, 222, respectively, having a central web 223 operatively interposed between the first and second side wall. Disposed in half block first cell 226 which is interposed between side wall 222 and central web 223 is a half block first cell core 239, which may be a first cell core 11 (as shown in FIG. 9) after it has been cut to conform to cell 226 thereof. Alternatively, the half block first cell core 239 can be separately molded. The second and third cell cores 12, 13 may be molded with a cell core score 50 and can readily and uniformly be broken for use in the half blocks 220 when required.
Referring now to FIG. 17, a typical arrangement which is especially useful for expansion joints or in framing windows and doors using the system of the present invention is shown. Vertical member 66 represents the jamb of the frame of a door or window or fireplace but which can also be the location of an expansion joint. The structure as shown comprises an arrangement involving a plurality of full size blocks 20 mounted in staggered interlocking relationship to each other in the manner already described with a plurality of half blocks 220 interposed between the full size blocks in alternating courses to create a common planar surface having a vertically extending slot 67 therein to receive a support board (not shown) for abutting and supporting member 66. Slot 67 is created by the vertical alignment of the several compartments 32 with each other.
In another embodiment of the wall system, an alternative block and alternative block configuration may be used. Referring now to FIG. 18, an alternative block 310 with no central web is shown. The block 310 has first and second side walls 312 and 314, respectively. When this block is incorporated with other blocks in a wall system, the first and second side walls, constitute the vertical inner and outer surfaces of the standing wall. Blocks may be dimensioned in width, height, and length as desired. However, this alternative block can be used to provide a block with a narrower width than the preferred block 20 with a central web.
The first and second side walls 312 and 314 are connected by two transverse block webs 316 and 317, as shown in FIGS. 18 and 19. This causes the block 310 to appear as two interconnected “H” shapes, linearly aligned with one another when the block 310 is viewed from the top FIG. 18. The upper surfaces of the webs 316 and 317 are formed as a V- or U-shape, extending downwardly from the top of the block 310. This shape is seen most clearly in the end view of FIG. 19, which shows web 316. Web 317 can be identical in configuration, and may be aligned parallel with web 316.
Referring also to FIGS. 21-24 and FIG. 25, each of the V- or U-shaped web notches 336 of the webs 316 and 317 may accept a cell core 340, placed in the blocks prior to or during the construction of the walls.
As seen in FIGS. 18 and 20, the inner surfaces of the outer face walls 312 and 314 can be thickened in the areas 318 and 320, where they are connected to the cross webs 316 and 317. This creates reinforcement columns in the wall system constructed using this embodiment of blocks, and provides for increased unit compressive strength.
First and second end cells 322 and 323 are formed on opposite sides of the central cell 321 in the center of each of the blocks 310, as seen in FIGS. 18 and 20. These end cells are centered along the longitudinal axis of the wall formed by the outer faces 312 and 314. When blocks 310, of the type shown in FIGS. 18, 19 and 20, are placed end-to-end, the void formed between the transverse webs of adjacent blocks (allowing for standard thickness of mortar 355 if dry stack construction is not used) which includes the combined space of end cells 322, 323 of the adjacent blocks, can be identical in shape and configuration to the central cell 321 formed through the center of each of the blocks. This permits the construction, in a running bond configuration, as illustrated in FIG. 25 when the insulation cell cores are placed in either of these locations.
To provide improved thermal insulation qualities for a wall constructed of the alternative embodiment blocks 310, insulation cores 340 (FIGS. 21 to 24) are inserted into the central cell 321 formed in the center of each of the blocks between the cross webs 316 and 317. The cell cores 340 also are inserted in the voids formed between adjacent blocks by the first and second end cells when they are placed end-to-end. As indicated above, the voids between two adjacent blocks can be identical in size and shape to the central cell 321, so that only one size of insulation core 340 is required. The cell cores 340 may be formed with ribs or fluting extending vertically, along the sides of the cell cores. This provides passage for moisture migration vertically in the assembled wall, when the units are placed in a “running bond” allowing each cell core 340 to align with all of the other insulation cell cores in the wall vertically.
The cell cores 340 can be manufactured of a low density foam insulation, such as polystyrene or the like. Insulation foam cores can be used to fill the voids 321, and the voids between adjacent blocks, as described above. These insulation cores enhance the insulation qualities of the blocks 310 used in the wall to significantly decrease thermal conduction from one of the wall faces 312 or 314 to the other.
Each of the insulating cell cores 340 has a pair of opposing, downwardly extending trapezoidal shaped ear members 341 and 342, one on each end. These projections are formed to fit within the V- shaped or U-shaped notches in the transverse webs 316 and 317, while leaving a notch gap between the ear base 352 and the notch bottom 359. The notch gap for this embodiment is substantially illustrated by the notch gap 1 shown in FIG. 10.
The cell cores 340 may also have a pair of spurs 345 and 346 located in its top, midway between the center and the outer edge of the corresponding ear members 341 and 342. Similarly shaped recesses 350 and 351 can be located in the bottoms of each of the cell cores 340. The recesses 350 and 351 receive the projections 345 and 346 of an insulating cell core 340 located in a lower block 310. The projections 345 and 346 and recesses 350 and 351 provide some assistance in aligning the blocks 310, in which the insulating cell cores 340 are placed, to facilitate the construction of the wall in which they are used. Thus, the projections 345 and 346 and recesses 350 and 351 permit interlock between the various insulating cell cores when they are placed atop one another as the blocks 310 are assembled to create a wall.
For walls constructed with this alternative block, local building codes may also require, as described above for preferred embodiments, vertical grout columns with structural reinforcement to be placed at regularly spaced intervals along the length of the wall. Typically, these intervals may be approximately every four feet. As with a conventional concrete block wall, these grout columns are constructed by placing reinforcing bar within vertically aligned open and un-insulated cells through all of the blocks in this position, such that voids align to form a continuous vertical void. After the reinforcing bar 330 is inserted into such voids, grout is poured into the voids to establish the required reinforced grout column. Such a construction may be employed with the blocks shown in FIGS. 18 through 20. It is obvious that where such a grout column is formed, however, no insulation cell cores 340 may be used, so that the thermal insulating characteristics of the wall are impaired at the location of each of such grout columns. Similarly, horizontal bond beams are constructed in a running course 19 by omission of all of the cell cores 340 in the running course, extending one or more horizontal reinforcing bars 357 through the blocks of the running course positioned at the notch bottom 359 of the several transverse webs, and filling the voids around the rebar in each block of the running course with grout.
Referring to FIGS. 27 and 28, alternative embodiments of the trapezoidal shaped ear member ear base 52, that can be used for the first, second or third cell cores 11, 12, 13 or for the alternative block cell core 340, are shown. The ear base 52, 352 of FIG. 27 is concave. The ear base of FIG. 28 has a w-shaped cross-section. These two variations may offer increased compressibility of the base as the base is inserted in a notch. Other variations of the trapezoidal shaped ear member ear base may be used which will provide the desired notch gap 1 and provide for the top of cell core to be at or below the top of the block when the cell core is inserted in a block.
Preferred and alternative methods of using the preferred and alternative embodiments of the dry stack insulated block and the wall system of the present invention, for the construction of standing walls and structures constructed from the standing walls, are described in or will be apparent from the foregoing description, to persons skilled in the art. However, for clarification, a summary description of preferred methods of using the block and wall system is presented below.
A construction block having one or more novel cell cores, each of the cell cores featuring a pair of trapezoidal shaped ear members, is used for the preferred method of the present invention. The shape of the cell cores and the integral ear members may be obtained from molds. Insertable cell cores with substantially uniform dimensions may fit intimately within such cells and may come into intimate contact with like cell cores in adjacent blocks in a running course of blocks, and may further come into intimate contact with similar cells in adjacent blocks in adjacent courses. The intimate contact of the insertable cell cores permit the formation of open joint gaps between blocks of running courses, which open gaps may be converted to closed gaps by coating the wall erected with the blocks with a surface bond of cementious material.
The foregoing blocks and cores are readily transformed into a dry stacked structure by providing a base surface. The base surface may be leveled. A plurality of hollow cell blocks are placed end-to-end on a first row forming a course. The blocks may be of a pre-selected length, width, and height, with first and second side walls and a central web. The central web may be operatively interposed between the first and second side walls. The first and second side walls present first and second planar surfaces to define first, second, and third cells between the first and second planar surfaces.
The first core receiving cell may have first and second end transverse webs disposed transversely across from the first and second planar surfaces at each end of the planar surfaces. The first and second end transverse webs may be spaced parallel to each other. The second cell may have first and second intermediate transverse webs disposed transversely across in parallel relationship to each other at intermediate ends thereof. The intermediate transverse webs define a second cell which is interposed between the first and second intermediate transverse webs and also define a pair of open ended third cells adjacent to the intermediate transverse webs. When the free standing block is adjacent to two other blocks forming a three block course, the open ended third cells of the block are now enclosed by the intermediate transverse webs of the adjacent blocks.
Each of the transverse webs may have a V- or U-shaped notch defined therein. The notch may have a curvilinear notch bottom disposed in a fixed pre-selected spatial relationship to the bottom surface of the block. A plurality of blocks may be oriented in a course with the open ended third cells of adjacent blocks being in registered communication with each other, the blocks in the course, together with vertically adjacent courses, defining the interior and exterior surfaces of the standing wall.
The standing wall may be assembled by placing a first cell core in each first cell. The first cell core may have a body portion substantially equal in size to the first cell with a trapezoidal shaped ear member integrally formed with the body portion at each end of the body member. The trapezoidal shaped ear members may complementary seat into the V- or U-shaped notch of the transverse web which is contiguous.
A second cell core is placed in the relatively closed second cell. Each second cell core may have a body portion substantially equal in size to the relatively closed second cell, the second cell core having a trapezoidal shaped ear member integrally formed with the body portion at each end for complementary seated engagement within the V- or U-shaped notch of the transverse web contiguous thereto. The ear members may extend outwardly from the body portion at a distance equal to one-half the notch axial length of V- or U-shaped slot.
A third cell core may be placed in one of the open ended third cells and the registered open ended third cell in the block adjacent thereto to interlock the adjacent blocks in fixed axial relationship to each other. The third cell core may be substantially identical in shape and size to the second cell core and the trapezoidal shaped ear members may be seated in V- or U-shaped slots of the contiguous transverse webs.
The foregoing steps may be repeated until an entire first row of blocks and cell cores are in place along an entire course and repeating the entire sequence for as many subsequent rows of blocks until the pre-selected length and height of the wall is achieved. Cell cores are omitted in running courses to provide for the insertion and grouting of horizontal rebar to form bond beams. Likewise cell cores or portions of cell cores, preferably second and third cell cores, are omitted from vertically adjacent cells to provide for the insertion and grouting of vertical rebar to form grout columns. A cap of grout or other structural cementious material can be poured on the top running course to compensate for accumulated elevation variations in the top running course, thereby providing a standing wall with a uniform, desired top elevation. Alignment and elevation variations of the running courses that comprise the wall may be addressed by the application of a surface bond that can be finished to a uniform and plumb finish. The penetration of the surface bond cementious material into the gaps between the blocks of a running course also may significantly strengthen the standing wall against sheer and lateral forces.
Other embodiments and other variations of the embodiments described above will be obvious to a person skilled in the art. Therefore, the foregoing is intended to be merely illustrative of the invention and the invention is limited only by the following claims and the doctrine of equivalents.