The term “timber” by itself as used herein typically refers to a wood member suitable for use in the construction of a building or the like. Several main types of wood construction are generally known. These construction types use forms of timber available from logs to sawn/shaped timbers to branches and even leaves. These construction types also utilize various wall coverings from plant-based coverings to timber materials to earthen materials, such as mud or stone. One type of wood construction is thatch construction, which is generally a traditional construction type. Other types include post-and-beam frame construction, walls with bamboo/reed mesh and post (waffle and daub), wooden frames with or without infill, and stud-wall frames with plywood/gypsum board sheathing. Two other types are wood panel construction and log construction.
The origin of log building construction is uncertain. The first log structures are thought to have been built in Northern Europe about 3500 BC. Early techniques involved stacking tree trunks on top of each other and overlapping the corners resulting in some of the first log cabins. The strength of log structures was improved with interlocking corners made by notching the logs near the ends and overlapping the log in the notches. Such interlocking corners brought the logs closer together making it easier to seal the structure against the weather by stuffing the spaces between logs with moss or other materials.
Logs used in construction are often peeled of their bark. When using younger logs with a significant taper over length, such logs may be hewn to reduce the taper. Logs may also be hewn or otherwise cut to make them square or rectangular instead of round. Traditionally, round log building were often considered temporary until a more permanent structure could be built. But square log craftsmanship is considered the original permanent home design. Some advantages of square log over round include:
Square logs are typically made from the heart of a tree where shrinkage is minimal (typically less than 1 inch) as opposed to round logs with shrinkage of up to 5 inches. Thus, dealing with log shrinkage is much easier when using square logs.
Square logs can be fitted to better avoid water problems and associated rot than round logs. This results in longer building life. For example, square log homes over 500 years old are said to be common in Europe.
Square logs can be drilled for wiring and plumbing runs between courses while round logs, due to their shape, require chases or other methods of hiding wires and plumbing.
Unlike square logs, round logs tend to catch dust due to their shape. Round logs also make interior decorating more difficult due to their shape. Square logs, on the other hand, tend to be much easier for people to live with and keep clean. The term “square log” as used herein generally refers to a log or beam or timber or the like, composed of natural wood or any other material or combination of materials suitable for building construction, of some length, sections of which are substantially and consistently rectangular in shape, where one example of rectangular is square. Note that conventional square logs are made from natural wood and are typically fabricated as a single piece out of tree trunks.
For these advantages and more, modern log buildings built with square logs tend to enjoy a higher appraised value than round log buildings. In fact, the larger the square logs, the higher the value—and the cost. One reason for this is that square logs are generally cut from the heart of a tree and larger trees for making larger square logs tend to be scarce and expensive.
In recent times, log buildings have become increasingly popular for vacation cabins and even for homes. Various building techniques are combined to make such homes appealing and attractive. As a result, there is an increasing interest in and demand for log buildings and the timbers required to construct them. At the same time, the availability of old-growth timber suitable for producing larger logs is increasingly scarce and expensive.
The following presents a simplified summary of the disclosure in order to provide a basic understanding to the reader. This summary is not an extensive overview of the invention nor does it identify key/critical elements of the invention or delineate the scope of the invention. Its sole purpose is to present some general concepts in a simplified form as a prelude to the more detailed description that is presented below.
The detailed description discloses techniques for building construction using fabricated timbers. In one example, such timbers are fabricated using conventional 2× (two-by) lumber to produce a square log appearance. These fabricated timbers are then stacked to form outside and/or inside walls such as for a building. The fabricated timbers and walls are configured to sustain the vertical and lateral loads anticipated for a building such as a cabin, house, garage, barn, office building, or the like. A building constructed of such timbers appears to be built of square logs. Variations provide for chinking between courses of timbers, or for timbers stacked without chinking. The height of each log course can be as little as a few inches to well over a foot or more. With one variation, the height of a log course can appear to be several feet or more. The terms “stacked” and “stacked one atop another” and the like as used herein typically refer to multiple objects (e.g., fabricated timbers) where one such object is placed on the bottom, and another such object is placed on top of the bottom object, and so forth until a top object is placed on the top of the stack of objects, thus forming a vertical stack of the multiple objects.
The disclosed techniques can be used with any type of building foundation including crawl space, slab-on-grade, and full basement, and with any type of roof structure. Further, construction using pre-manufactured fabricated timbers requires far fewer steps over conventional log and stick frame structures, as illustrated in Table 1 below.
In Table 1, an ‘X’ indicates a required construction step. Table 1 indicates that construction based on fabricated timbers takes far fewer steps than conventional stick-frame construction (and is thus correspondingly less labor intensive), but is also simpler and less labor intensive that conventional log construction. The various letters other than ‘X’ indicate the following:
Further, the R-value achievable by fabricated timbers typically ranges from 2.5 to 4 per inch of wall thickness, depending on the insulating material used inside and the height of the fabricated timber. For example, a fabricated timber using a 2×12 wood horizontal member typically provides an R-value of about R-40. In general, the taller each timber is in a wall, the greater the R-value provided by the wall. Further, taller and wider timbers tend to be more desirable because they can be made to have the appearance of tall and wide conventional logs which are very desirable due to the scarcity and high cost.
In addition, insulating materials that can be used in fabricated timbers may range from straw to conventional fiberglass wool, shredded paper (cellulose), or any other material that can provide a desired R-value, thus providing relatively low-cost, high-R-value walls. On the other hand, a conventional square logs typically provide an R-value of less than 2 per inch of log thickness. And a conventional 2×6 stick-frame wall typically provides approximately R-value of about 20. Thus, given fabricated timber construction, buildings that are far more heat-efficient can be easily and inexpensively constructed that also use far fewer materials and construction steps than conventional stick-frame construction, and at significantly lower cost and higher thermal efficiency than conventional log construction, yet with the high appraised values of high-quality conventional log construction. The term “R-value” as used herein is a conventional term that typically refers to the capacity of a material to resist heat flow.
Many of the attendant features will be more readily appreciated as the same become better understood by reference to the following detailed description considered in connection with the accompanying drawings.
The present description will be better understood from the following detailed description considered in connection with the accompanying drawings, wherein:
a is a diagram showing an end view 100a of an example fabricated timber with a 3-dimensional view 100b of the same example fabricated timber illustrated in
a is a diagram showing a top view of an example fabricated timber 100.
b is a diagram showing an end view of the example fabricated timber 100.
a is a diagram showing an end view 600a of an example alternate fabricated timber with a 3-dimensional view 600b of the same example alternate fabricated timber illustrated in
Like reference numerals are typically used to designate like elements in the accompanying drawings.
The detailed description provided below in connection with the accompanying drawings is intended as a description of the present examples and is not intended to represent the only forms in which the present examples may be constructed or utilized. The description sets forth at least some of the functions of the examples and/or the sequence of steps for constructing and operating the examples. However, the same or equivalent functions and sequences may be accomplished by different examples.
Although the present examples are described and illustrated herein as being implemented for building construction, the techniques described are provided as examples and not limitations. As those skilled in the art will appreciate, the present examples are suitable for application in a variety of different types of construction or the like.
a is a diagram showing an end view 100a of an example fabricated timber with a 3-dimensional view 100b of the same example fabricated timber illustrated in
One vertical member 110 is typically disposed length-wise atop the left side L of horizontal member 130, and the other vertical member 120 is typically disposed length-wise atop the right side R of horizontal member 130, as illustrated in
In some examples, vertical members 110 and 120 are fastened to horizontal member 130 using fasteners (e.g., 150) such as nails, screws, bolts, staples, pins, dowels, pegs, spikes, ties, strapping, adhesive, or the like. In one particular example, fastener 150 represents conventional 16d nails every n inches on center. The term “every n inches on center” as used herein refers to a fastener (e.g., a nail) installed so as to fasten the vertical member to the horizontal member as illustrated in
Note that the horizontal and vertical members of a fabricated timber form a channel 180. This channel may be used for installing utilities such as electrical wires, gas and/or water lines, ducting, and the like. This channel may optionally be filled with insulation. Blocking may be added at the ends to keep insulation in, or ends may be covered with plastic, cardboard, or any other suitable material or the like to retail any insulation inside the fabricated timber. The term “blocking” as used herein typically refers to pieces of wood or other material (e.g., 224) disposed between members (e.g., 110 and 120) to provide support, attachment sites, or brace against lateral-torsion buckling, or the like.
The composition of fabricated timbers (e.g., 100) as described herein is not limited to wood, but may be plastic, fiber-cement, metal, laminated materials, composites, or the like, or any combination of such. In one example, conventional 2× lumber has been shown to be an inexpensive and readily available choice of materials that is simple to work with and that only requires commonly-available skills and tools. The term “2× lumber” or “two-by lumber” as used herein generally refers to softwood or conifer sized to nominal standardized dimensions as commonly used in construction of wood-buildings and the like, where the number ‘2’ in “2×” typically refers to the nominal pre-dried 2-inch thickness of the lumber which typically measures about 1.5 inches once dried. Such 2× lumber used in the construction of fabricated timbers and the like is typically kiln dried or the like. Note that other types and sizes of lumber may also be used in fabricated timbers, including hardwood, rough-cut wood, or wood of thicknesses less than or greater than about 1.5 inches, etc. The only factor limiting the composition of a fabricated timber 100 is that it should possess certain attributes as described herein below.
In the example where members 110, 120, and 130 are each separate members, one attribute that these members should possess is a common shrinkage characteristic. The term “shrinkage characteristic” as used herein refers to expected amounts and directions of shrinkage over time and/or under particular conditions for a particular material (e.g., wood, etc). Further, should the material from which members (e.g., 110, 120, and 130) are fabricated include a grain (as with e.g., wood, fiber-cement, etc), the grain of each member should be oriented in substantially the same plane, such as a horizontal plane. Such grain alignment may result in shrinkage over time that is relatively consistent in direction and amount between each of the members. Further, any given member (e.g., 110, 120, and 130) may actually comprise multiple separate members of various lengths positioned end-to-end resulting in an overall length of l. The term “grain” as used herein typically refers to an overall direction of a pattern of fibers or the like of a material such as that from which members of a fabricated timber are comprised.
The term “fabricated timber” as used herein refers to a statutory article(s) of manufacture constructed according to various example methods described herein and that is configured for possessing various attributes specified herein. The term “fabricated timber” does not refer to any pre-existing article(s) of manufacture or the like. Nor does it suggest any pre-existing method(s) of construction or the like.
In one example of a fabricated timber 100, a vertical member (e.g. 120) is disposed atop a horizontal member (e.g., 130) such that the outer portion of the vertical member overhangs the horizontal member resulting in a reveal, such as reveal r 140. Either or both vertical members may be disposed to provide such a reveal r 140. Such a reveal is typically from 0% up to about 50% of the thickness tv of the vertical member. Such a reveal can be used for, among other things, a location for chinking or the like and/or running wiring, plumbing, and/or other utilities or the like as described below. In one example, a reveal up to ¾ inch (about ¼ inch being preferred) is provided for chinking or the like. The term “reveal” as used herein typically refers to a side of an opening between an outer surface and an inner surface. An example of such a side of an opening is provided by r 140 with respect to the outer surface of member 120 (opposite Fi) and to the inner surface Fo of member 130.
In another example of a fabricated timber 100, a vertical member (e.g. 120) is positioned atop a horizontal member (e.g., 130) such that no reveal is provided, but such that the outer face of the vertical member is substantially flush with the outer side of the horizontal member instead. Such a “no reveal” configuration may provide for stacked timbers that have an appearance of a square log with a height that is the combined height of the stacked timbers where the horizontal interfaces between the stacked logs are dressed so as to be substantially non-visible. Other “no reveal” configurations are also acceptable, as described below.
The term “dressed” (“dressing”, “dress”, and the like) as used herein typically indicates treating the outside faces of individual or stacked fabricated timbers and/or interfaces of stacked fabricated timbers to have a desired appearance. For example, it may be desirable for the outside faces of fabricated timbers to have the appearance of a square log, a peeled log, and/or a rough-hewn log, or the like. In one example, the outside faces and/or interfaces of such timbers may be distressed using a chainsaw or the like to produce an appearance of a rough-hewn log. Interfaces may be filled with wood filler or the like to hide them before or after distressing. Such dressing or distressing may be performed prior to timbers being stacked, or after stacking, or both. The term “desired” as used herein typically refers to some quality or characteristic or the like that is expected as a result of some action, design, planning, or the like.
Other aspects of the term “dressed” as used herein may include staining, tinting, painting, or otherwise coloring, finishing, and/or otherwise treating the faces, visible portions, and/or interfaces of fabricated timbers. Other examples may include sealing and/or waterproofing or the like. Another example may include chinking, such as with conventional chinking, cement, sand mortar, flexible vinyl chinking, or the like. Conventionally, chinking is used to seal gaps between logs. In the case of fabricated timbers, chinking is primarily used for aesthetic reasons and to obtain a conventional chinked appearance or the like.
Various attributes that a fabricated timber 100 configured for building construction should possess include the capability of sustaining various loads including at least dead loads, live loads, and environmental loads. The noun “building” as used herein typically refers to a structure (generally enclosed by walls and a roof) constructed to provide support and shelter for an intended occupancy. The term “occupancy” as used herein typically refers to the purpose for which a building or other structure, or portion thereof, is used or intended to be used. The term “load” as used herein typically refers to forces or other actions upon a building that result from the weight of building materials and the like, building occupants and/or their possessions, objects supported by the building, environmental effects, differential movement, restrained dimensional changes, and the like. The term “dead loads” as used herein typically refers to substantially permanent loads such as the weight of materials of construction incorporated into a building or structure including but not limited to walls, floors, roofs, ceilings, stairways, built-in partitions, finishes, and all other similarly incorporated construction materials, and all equipment and the like affixed to the building or structure, but not including live loads or environmental loads. In one example, a fabricated timber may be configured to sustain a desired dead load of at least fifteen pounds per square foot. The term “live loads” as used herein typically refers to loads produced by occupancy of a building or structure that do not include dead loads or environmental loads. In one example, a fabricated timber may be configured to support a desired live load of at least thirty pounds per square foot. The term “environmental loads” as used herein typically refers to loads that act on a building or structure as a result of weather, topography, or other natural phenomena including but not limited to wind, snow, rain, ice, seismic activity, temperature variations leading to thermal expansion or the like, ponding, dust, fluids, floods, and lateral pressures from soil, ground water, bulk materials against the building, and the like, but not including dead loads or live loads. In one example, a fabricated timber may be configured to support a desired environmental load of at least ten pounds per square foot. In another example, a fabricated timber may be configured to support at least the desired dead load, live load, and environmental load combined. The term “support” as used herein with respect to a fabricated timbers typically indicates a capability to bear desired loads plus a safety factor without exceeding a yield strength of the fabricated timber or, in other words, while maintaining its elasticity.
a is a diagram showing a top view of an example fabricated timber 100. This top view shows portions of example horizontal member 130 and example vertical members 110 and 120, as also shown in
b is a diagram showing an end view of the example fabricated timber 100. This end view shows portions of example horizontal member 130 and example vertical members 110 and 120, as also shown in
In one example, bottom fabricated timber 100i may include an optional additional member (e.g., 316) that may be fastened to the top of its horizontal member inside the timber via fasteners (e.g., 314) and further attached to the foundation via a nut and washer or the like (e.g, 318), thus locking down the bottom fabricated timber 100i to the foundation.
Example wall 300 extends upward to the desired height by stacking and attaching fabricated timbers one atop another starting with a bottom fabricated timber (e.g., 100i) up through the top fabricated timber (e.g., 100t). The fabricated timbers are typically stacked so as to be level horizontally and to be substantially plumb. Such stacking can typically be performed by two or three people (workers) without the use of a crane or other heavy equipment or the like. The holes in the horizontal members may be sufficiently aligned vertically so as to allow tie-down fasteners (e.g., 312 & 320) to pass through each stacked fabricated timber while remaining substantially plumb vertically. In one example, the holes are drilled or otherwise formed by the workers as the timbers are stacked. One method of finding the correct location for each hole is to place the next timber in the desired horizontal position above the lower timber and atop the applicable and substantially plumb tie-down fasteners, beat the horizontal member of the next timber against the tops of the tie-down fasteners so as to form discernible marks on its bottom at the locations where the tie-down fasteners touch the horizontal member, and then drill or otherwise form the holes according to the marks. This method typically allows for the holes to be formed by the workers at the required locations along the horizontal member of the next timber at the job site without complex design or measurements or the like.
Regarding the tie-down fasteners, these fasteners may be attached to or embedded in foundation 310 at their lower ends, that extend through the courses of stacked fabricated timbers forming a wall, and that are fastened to the top of the wall thus maintaining the wall in a high degree of force over time against the foundation (e.g., 310). Such tie-down fasteners may be configured to maintain the high degree of force on the wall, even in the event of shrinkage of the wall's fabricated timbers and in the event that various forces are applied to the wall, including environmental forces such as wind, earthquake, shifting, flooding, and the like.
In one example, each tie-down fastener may be a threaded rod, or a plurality of threaded rods (e.g., 320) coupled together by coupler nuts (e.g., 322). A bottom rod, also known as an anchor bolt, (e.g., 312) may be embedded in or otherwise attached to the building's foundation (e.g., 310) via conventional means. The bottom rod may be sufficiently long to pass through the first course of fabricated timbers (e.g., 100i) and may be coupled via a coupling nut (e.g., 322) or the like to a second rod (e.g., 320) that is sufficiently long to pass through at least a second course of fabricated timbers, etc., until a final rod or top portion of a single rod passes into and/or through a top fabricated timber (e.g., 100t). In one example, a tie-down fastener and related components may terminate against the horizontal member of the top fabricated timber. In another example, wall cap members 332 and 334 may cap the final course of fabricated timbers and allow for the tie-down fastener(s) to hold the stacked courses of fabricated timbers against the building foundation (e.g., 310). Member 332 may be optional. Member 334 may be the same width as a horizontal member (e.g., 130) or extend up to the entire width of a fabricated timber (e.g., 100t). The desired holding force may be achieved via a tensioner mechanism (e.g., 333) such as a spring or the like positioned atop a washer or plate (e.g., 331) locked in position via the rod (e.g., 320) by a nut (e.g., 336) and washer (e.g., 335) or other suitable locking device(s). Any other suitable tensioner mechanism may alternatively/additionally be used to provide the desired force on the wall 300. In one example (not illustrated), the tensioner mechanism may be installed on top of wall top cap (e.g., 332 and 334). In another example, the tensioner mechanism may be installed inside the top fabricated timber 100t against its horizontal member as illustrated in
Each course of fabricated timbers of a wall is typically attached to the previous course.
Prior to attaching a next fabricated timber to the previous fabricated timber, gaps and the like between the two may be substantially removed. In one example, this is done by compressing the next fabricated timber against the previous fabricated timber sufficient to remove such gaps. Such may be accomplished using existing tie-down fasteners to force the next fabricated timber toward the foundation until gaps and the like between the next fabricated timber and the previous fabricated timber are substantially eliminated. Given a threaded rod tie-down fastener, a plate or the like may be slid down the rod against the top of the next fabricated timber, and a nut tightened against the plate to remove any gaps. Then, while under compression with gaps substantially removed, the next fabricated timber may be attached to the previous fabricated timber.
As one fabricated timber is stacked atop another, one or more beads of caulking and/or glue or the like may be applied. In one example, a bead of caulking may be applied along the length of a top of a fabricated timber's vertical members (e.g., 110 and 120) prior to stacking another fabricated timber on top of it. Such a bead may be applied along the inside and/or outside edge(s) of the vertical members, or along any other portion of the vertical members. One such bead may be formed from a caulking or the like that is configured to remain flexible over time, though cycles of hot and cold seasons, and to seal out moisture, bugs, air, and/or other substances and/or objects, and be further configured to maintain such a seal given settling, movement, shrinkage, or the like of the fabricated timbers. Another such bead may be similarly applied that is formed of glue or construction adhesive or the like.
A wall constructed of fabricated timbers that supports angled trusses may also include weight distribution members that typically approximate the shape of a right triangle, as illustrated in
Block 402 typically indicates determining a total desired load plus a safety factor that the fabricated timber should support without exceeding its yield strength. The total desired load may be a minimum, and is typically comprised of a determined desired minimum dead load (block 410) plus a determined desired minimum live load (block 420) plus a determined desired minimum environmental load (block 430). Each of these determined loads may be based at least on the overall design, occupancy, and physical environment of the building. Alternatively, desired average, maximum, or other loads may be used instead of desired minimum loads.
Block 440 typically indicates determining a composition of each of the various members of the fabricated timber. Such determining may be based at least on the determined desired loads (e.g., block 402) and aspects of the design, occupancy, and physical environment of the building comprising the fabricated timber. Such determining may also take into account a desired outside dressing and/or desired inside dressing of the fabricated timber. Note that the various members of a fabricated timber need not be of the same composition. Nor need one fabricated timber (or various members thereof) used in a building be of the same composition as another fabricated timber (or various members thereof) used in the building.
Block 440 also typically indicates determining a thickness of the various members of the fabricated timber, such as members 110, 120, 130, and 224. Such determining may be based at least on the determined desired loads (e.g., block 402) and aspects of the design, occupancy, and physical environment of the building comprising the fabricated timber. Such determining may also take into account a desired outside dressing and/or desired inside dressing of the fabricated timber. Note that the various members of a fabricated timber need not be of the same thickness. Nor need one fabricated timber (or various members thereof) used in a building be of the same thickness as another fabricated timber (or various members thereof) used in the building.
The end result of the determinings indicated by block 440 is generally that the compositions and thicknesses of the various members of the fabricated timber have been determined. Another aspect (not explicitly indicated in
Block 442 typically indicates various aspects of constructing a fabricated timber. Block 450 typically indicates disposing a first vertical member atop a horizontal member. In one example, the first vertical member 110 is typically disposed length-wise atop the left side L (or the right side R) of horizontal member 130, as illustrated in
Block 460 typically indicates disposing a second vertical member atop a horizontal member. In one example, the second vertical member 110 is typically disposed length-wise atop the right side R (or the left side L, whichever side the first vertical member is not disposed on), of horizontal member 130, as illustrated in
Block 470 typically indicates forming one or more holes in a horizontal member of a fabricated timber. In one example, each hole is formed so as to enable a tie-down fastener to pass through the fabricated timber via the hole. As fabricated timbers are stacked to form a wall, holes formed in each timber are typically aligned with holes formed in any timbers above and below such that a tie-down fastener can to pass through each set of aligned holes in a substantially vertical orientation, as partially illustrated in
Block 480 typically indicates installing a fabricated timber's blocking. One example of such blocking is illustrated in
Further, one or more beads of caulking or glue or the like may be applied as a part of the attaching. In one example, a bead of caulking may be applied along the length of a top of a fabricated timber's vertical members (e.g., 110 and 120) prior to stacking another fabricated timber on top of it. Such a bead may be applied along the inside and/or outside edge(s) of the vertical members, or along any other portion of the vertical members. One such bead may be formed from a caulking or the like that is designed to remain flexible over time, cycles of hot and cold, and to seal out moisture, bugs, air, and or other substances and/or objects, and be further designed to maintain a seal given settling, movement, and/or shrinkage of the fabricated timbers. Another such bead may be formed from glue or construction adhesive or the like.
Block 520 typically indicates optionally extending a tie-down fastener(s) to pass through a next fabricated timber used to construct the wall. In one example, tie-down fasteners may be extended as described in connection with
Block 530 typically indicates optionally installing utilities such as electrical wires, gas and/or water lines, ducting, and the like. In one example, electrical wires, water lines, gas lines, ducting, etc, may be run horizontally through the channel (
Block 540 typically indicates optionally installing insulation. In one example, insulation is installed in the channel (
Once a particular course of fabricated timbers have been stacked and attached, any desired utilities have been run, and any tie-down fasteners have been installed and/or extended, then that course of fabricated timbers is typically complete and a next course may be attached. Block 550 typically indicates determining if there is at least one additional course to be added to the wall being constructed. If so, method 500 continues again at block 510. Otherwise method 500 continues at block 560.
Block 560 typically indicates installing a wall cap at the top of a fabricated timber-based wall. In one example, a wall cap may be fabricated and installed as described in connection with
Block 570 typically indicates installing tensioner mechanisms to any tie-down fasteners. In one example, such may be installed inside a fabricated timber. In another example, such may be installed on wall caps at the top of a wall.
Block 580 typically indicates optionally installing chinking in any reveals of the constructed wall, such as reveal 140 of
a is a diagram showing an end view 600a of an example alternate fabricated timber with a 3-dimensional view 600b of the same example alternate fabricated timber illustrated in
Alternate fabricated timbers (e.g., 600) may be fabricated to be insulated and fully enclosed either at a fabrication site or on a job site. Holes for tie-down fasteners may also be formed either at the fabrication site or on the job site. Blocking may be used to enclose the ends of an alternate fabricated timber, and may be built in at approximately two foot or greater intervals along the length of the timber. Blocking in both fabricated timbers and alternate fabricated timbers may also include holes configured to provide runs for utilities along the length of the inside of alternate fabricated timbers. An alternate fabricated timber may include conduit(s) installed in one or more sets of utility holes in the blocking, the conduit(s) typically extending from one end of the timber to the other. Such conduits may be used to run utilities through alternate fabricated timbers. Blocking in alternate fabricated timbers need not be included on either side of holes formed for tie-down fasteners. Further, horizontal members 130 and/or 190 may include channels or grooves along the length of their outer faces (not shown), the channels configured to provide a run for electrical wiring or the like.
In one example, the tensioner mechanism and related components may be installed on top of the wall top cap. In another example, the tensioner mechanism may be installed inside the top fabricated timber 600t against its bottom horizontal member.
Another variation may be how blocking is locked into place in an alternate fabricated timber. In one example, blocking in alternate fabricated timbers may be installed at four-foot or less intervals. Fasteners may be installed via the top and bottom horizontal members of an alternate fabricated timber as opposed to via the vertical members. This approach has the advantage of fasteners not being visible on the outside vertical faces of an alternate fabricated timber.
Another variation may be how a tensioner mechanism and related components are configured. In one example, a plate 733 or the like may be used in conjunction with a tensioner mechanism and a washer 335 and nut 336. Plate 335 is typically configured to distribute forces from any tensioner mechanism(s) (e.g., 734) down the vertical members of alternate fabricated timbers to the foundation. Plate 335 may be made of metal or any other material configured to provide the required force distribution. In one example, plate 335 is a steel plate between ⅛″ and ½″ in thickness that extends substantially across the width of the mating surface of the bottom horizontal member. In another example, plate 335 may alternatively be formed of angle iron or the like, or I-beam or channel or the like.
Other variations may also include how a bottom course of alternate fabricated timbers is attached to a foundation, how a tie-down fastener is attached to an alternate fabricated timber, etc. Further, alternate fabricated timbers (e.g., 600) may be used in combination with fabricated timbers (e.g.,
Solid tall wood timbers tend to be very expensive because old growth trees of sufficient size are scarce. Therefore, tall timbers tend to be desirable.
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Number | Date | Country | |
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20130081343 A1 | Apr 2013 | US |