Hubbry Logo
Framing (construction)Framing (construction)Main
Open search
Framing (construction)
Community hub
Framing (construction)
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Framing (construction)
Framing (construction)
Framing (construction)
View on Wikipedia
from Wikipedia

Prefabricated framing walls at a construction site with tower cranes
The erection of a wooden frame in Sabah, Malaysia
The construction frames of a residential subdivision in Rogers, Minnesota in 2023

Framing, in construction, is the fitting together of pieces to give a structure, particularly a building, support and shape.[1] Framing materials are usually wood, engineered wood, or structural steel. The alternative to framed construction is generally called mass wall construction, where horizontal layers of stacked materials such as log building, masonry, rammed earth, adobe, etc. are used without framing.[citation needed]

Building framing is divided into two broad categories,[2] heavy-frame construction (heavy framing) if the vertical supports are few and heavy such as in timber framing, pole building framing, or steel framing; or light-frame construction (light-framing) if the supports are more numerous and smaller, such as balloon, platform, light-steel framing and pre-built framing. Light-frame construction using standardized dimensional lumber has become the dominant construction method in North America and Australia due to the economy of the method; use of minimal structural material allows builders to enclose a large area at minimal cost while achieving a wide variety of architectural styles.

Modern light-frame structures usually gain strength from rigid panels (plywood and other plywood-like composites such as oriented strand board (OSB) used to form all or part of wall sections), but until recently carpenters employed various forms of diagonal bracing to stabilize walls. Diagonal bracing remains a vital interior part of many roof systems, and in-wall wind braces are required by building codes in many municipalities or by individual state laws in the United States. Special framed shear walls are becoming more common to help buildings meet the requirements of earthquake engineering and wind engineering.

History

[edit]

Historically, people fitted naturally shaped wooden poles together as framework and then began using joints to connect the timbers, a method today called traditional timber framing or log framing. In the United States, timber framing was superseded by balloon framing beginning in the 1830s. Balloon framing makes use of many lightweight wall members called studs rather than fewer, heavier supports called posts; balloon framing components are nailed together rather than fitted using joinery. The studs in a balloon frame extend two stories from sill to plate. Platform framing superseded balloon framing and is the standard wooden framing method today. The name comes from each floor level being framed as a separate unit or platform. The use of factory-made walls and floors has shown an increase in popularity due to the time-saving and cost-efficiency. (Pre-fabrication) Walls are made usually in facilities and then shipped to the different job sites. This process of framing has improved the speed of framing on site.

Framed construction was rarely used in Scandinavia before the 20th century because of the abundant availability of wood, an abundance of cheap labour, and the superiority of the thermal insulation of logs. Hence timber framing was used first for unheated buildings such as farm buildings, outbuildings and summer villas, but for houses only with the development of wall insulation.[3]

Elements of a balloon frame

Walls

[edit]

Wall framing in house construction includes the vertical and horizontal members of exterior walls and interior partitions, both of bearing walls and non-bearing walls. These stick members, referred to as studs, wall plates and lintels (sometimes called headers), serve as a nailing base for all covering material and support the upper floor platforms, which provide the lateral strength along a wall. The platforms may be the boxed structure of a ceiling and roof, or the ceiling and floor joists of the story above.[4] In the building trades, the technique is variously referred to as stick framing, stick and platform, or stick and box, as the sticks (studs) give the structure its vertical support, and the box-shaped floor sections with joists contained within length-long post and lintels (more commonly called headers), support the weight of whatever is above, including the next wall up and the roof above the top story. The platform also provides lateral support against wind and holds the stick walls true and square. Any lower platform supports the weight of the platforms and walls above the level of its component headers and joists.

In some countries, framing lumber is subject to regulated standards that require a grade-stamp, and a moisture content not exceeding 19%.[5]

There are four historically common methods of framing a house.

  • Post and beam, which is now used predominantly in barn construction.
  • Braced frame construction, also known as full frame, half frame,[6] New England braced frame,[7] combination frame[8] an early form of light framing which survived into the 1940s in the northeastern United States,[9] defined by the continued use of girts, corner posts, and braces, most often mortised, tenoned, and pegged with nailed studs.[8]
  • Balloon framing using a technique suspending floors from the walls was common until the late 1940s, but since that time, platform framing has become the predominant form of house construction.[10]
  • Platform framing often forms wall sections horizontally on the sub-floor prior to erection, easing positioning of studs and increasing accuracy while cutting the necessary manpower. The top and bottom plates are end-nailed to each stud with two nails at least 3+14 in (83 mm) in length (16d or 16-penny nails). Studs are at least doubled (creating posts) at openings, the jack stud being cut to receive the lintels (headers) that are placed and end-nailed through the outer studs.[10]
Moisture barrier sheathing with flashing tape

Wall sheathing, usually a plywood or other laminate, is usually applied to the framing prior to erection, thus eliminating the need to scaffold, and again increasing speed and cutting manpower needs and expenses. Some types of exterior sheathing, such as asphalt-impregnated fiberboard, plywood, oriented strand board and waferboard, will provide adequate bracing to resist lateral loads and keep the wall square (construction codes in most jurisdictions require a stiff plywood sheathing). Others, such as rigid glass-fiber, asphalt-coated fiberboard, polystyrene or polyurethane board, will not.[4] In this latter case, the wall should be reinforced with a diagonal wood or metal bracing inset into the studs.[11] In jurisdictions subject to strong wind storms (hurricane countries, tornado alleys) local codes or state law will generally require both the diagonal wind braces and the stiff exterior sheathing regardless of the type and kind of outer weather resistant coverings.

Finally, the outside of the wall sheathing will usually be covered with siding, to protect it from the elements and for decorative reasons.

Corners

[edit]

A multiple-stud post of at least 3 three studs, is generally used at exterior corners and intersections to secure a good tie between adjoining walls. It provides nailing support for interior finishes and exterior sheathing. Corners and intersections, however, must be framed with at least two studs.[12]

Nailing support for the edges of the ceiling is required at the junction of the wall and ceiling where partitions run parallel to the ceiling joists. This material is commonly referred to as dead wood or backing.[13]

Exterior wall studs

[edit]

Wall framing in house construction includes the vertical and horizontal members of exterior walls and interior partitions. These members, referred to as studs, wall plates and lintels, serve as a nailing base for all covering material and support the upper floors, ceiling and roof.[4]

Exterior wall studs are the vertical members to which the wall sheathing and cladding are attached.[14] They are supported on a bottom plate or foundation sill and in turn support the top plate. Studs usually consist of 1+12-by-3+12-inch (38 mm × 89 mm) or 1+12-by-5+12-inch (38 mm × 140 mm) lumber and are commonly spaced at 16 inches (410 mm) on center. This spacing may be changed to 12 or 24 inches (300 or 610 mm) on center depending on the load and the limitations imposed by the type and thickness of the wall covering used. Wider 1+12-by-5+12-inch studs may be used to provide space for more insulation. Insulation beyond that which can be accommodated within a 3+12-inch stud space can also be provided by other means, such as rigid or semi-rigid insulation or batts between 1+12-by-1+12-inch horizontal furring strips, or rigid or semi-rigid insulation sheathing to the outside of the studs. The studs are attached to horizontal top and bottom wall plates of 1+12-inch lumber that are the same width as the studs.[5]

Interior partitions

[edit]

Interior partitions supporting floor, ceiling or roof loads are called loadbearing walls; others are called non-loadbearing or simply partitions. Interior loadbearing walls are framed in the same way as exterior walls. Studs are usually 1+12 in × 3+12 in (38 mm × 89 mm) lumber spaced at 16 in (410 mm) on center. This spacing may be changed to 12 or 24 in (300 or 610 mm) depending on the loads supported and the type and thickness of the wall finish used.[12]

Partitions can be built with 1+12 in × 2+12 in (38 mm × 64 mm) or 1+12 in × 3+12 in (38 mm × 89 mm) studs spaced at 16 or 24 in (410 or 610 mm) on center depending on the type and thickness of the wall finish used. Where a partition does not contain a swinging door, 1+12 in × 3+12 in (38 mm × 89 mm) studs at 16 in (410 mm) on center are sometimes used with the wide face of the stud parallel to the wall. This is usually done only for partitions enclosing clothes closets or cupboards to save space. Since there is no vertical load to be supported by partitions, single studs may be used at door openings. The top of the opening may be bridged with a single piece of 1+12 in (38 mm) lumber the same width as the studs. These members provide a nailing support for wall finish, door frames and trim.[12]

Lintels (headers)

[edit]

Lintels (or, headers) are the horizontal members placed over window, door and other openings to carry loads to the adjoining studs.[4] Lintels are usually constructed of two pieces of 2 in (nominal) (38 mm) lumber separated with spacers to the width of the studs and nailed together to form a single unit. Lintels are predominately nailed together without spacers to form a solid beam and allow the remaining cavity to be filled with insulation from the inside. The preferable spacer material is rigid insulation.[14] The depth of a lintel is determined by the width of the opening and vertical loads supported.

Wall sections

[edit]

The complete wall sections are then raised and put in place, temporary braces added and the bottom plates nailed through the subfloor to the floor framing members. The braces should have their larger dimension on the vertical and should permit adjustment of the vertical position of the wall.[11]

Once the assembled sections are plumbed, they are nailed together at the corners and intersections. A strip of polyethylene is often placed between the interior walls and the exterior wall, and above the first top plate of interior walls before the second top plate is applied to attain continuity of the air barrier when polyethylene is serving this function.[11]

A second top plate, with joints offset at least one stud space away from the joints in the plate beneath, is then added. This second top plate usually laps the first plate at the corners and partition intersections and, when nailed in place, provides an additional tie to the framed walls. Where the second top plate does not lap the plate immediately underneath at corner and partition intersections, these may be tied with 0.036 in (0.91 mm) galvanized steel plates at least 3 in (76 mm) wide and 6 in (150 mm) long, nailed with at least three 2+12 in (64 mm) nails to each wall.[11]

Braced frame

[edit]

Braced frame construction, also known as full frame, half frame,[6] New England braced frame,[7] combination frame,[8] is an early form of light framing developed from the heavier timber framing which preceded it. It is defined by the continued use of girts, corner posts, and braces. The pieces are mortised, tenoned, and pegged with the studs nailed to the girts and sills.[8] Due to the early introduction of sawmills (as early as 1635 in New Hampshire),[15] as early as 1637 timber frames in the northeastern English colonies in North America made use of light studs between the heavier corners. Norman Isham wrote, "sometimes the frame was covered with vertical boarding applied to the sills, plates, and girts without any intermediate framing, but in a greater number of houses the spaces between the heavier timbers are filled with lighter vertical sticks called studs."[16] The growth of a nail-making industry in the early 19th century made the frame even faster to assemble, with some of the first machines developed in the late 1700s in Massachusetts. Jacob Perkins of Newburyport, Massachusetts, invented a machine which could produce 10,000 nails a day.[15]

Three-decker buildings in New England were commonly constructed with this form, which is noted on period building permits as "mortised frame."

Its use survived into the 1940s in the northeastern United States,[9] when it was gradually replaced by the platform frame.

Balloon framing

[edit]
An unusual example of balloon framing: The Jim Kaney Round Barn, Adeline, Illinois, U.S.

Balloon framing is a method of wood construction used primarily in areas rich in softwood forests such as Scandinavia, Canada, the United States up until the mid-1950s, and around Thetford Forest in Norfolk, England. The name comes from a French Missouri type of construction, maison en boulin,[17] boulin being a French term for a horizontal scaffolding support. It was also known as "Chicago construction" in the 19th century.[18]

Balloon framing uses long continuous framing members (wall studs) that run from the sill plate to the top plate, with intermediate floor structures let into and nailed to them.[19][20] Here the heights of window sills, headers and next floor height would be marked out on the studs with a story pole. Once popular when long lumber was plentiful, balloon framing has been largely replaced by platform framing.

It is not certain who introduced balloon framing in the United States. However, the first building using balloon framing was possibly a warehouse constructed in 1832 in Chicago, Illinois, by George Washington Snow or Augustine Deodat Taylor.[21][15] Both men arrived in Chicago from New England, where the use of light framing timber was already common.[16] Architectural critic Sigfried Giedion cited Chicago architect John M. Van Osdel's 1880s attribution, as well as A. T. Andreas' 1885 History of Chicago, to credit Snow as 'inventor of the balloon frame method'.[22][23] In 1833, Taylor constructed the first Catholic church in Chicago, St. Mary's, using the balloon framing method; this building was moved and rehabbed multiple times before burning in the Great Chicago Fire.[24]

In the 1830s, Hoosier Solon Robinson published articles about a revolutionary new framing system, called "balloon framing" by later builders. Robinson's system called for standard 2×4 lumber, nailed together to form a sturdy, light skeleton. Builders were reluctant to adopt the new technology; however, by the 1880s, some form of 2×4 framing was standard.[25]

Alternatively, a precursor to the balloon frame may have been used by the French in Missouri as much as 31 years earlier.[17]

Although lumber was plentiful in 19th-century America, skilled labor was not. The advent of cheap machine-made nails, along with water-powered sawmills in the early 19th century made balloon framing highly attractive, because it did not require highly skilled carpenters, as did the dovetail joints, mortises and tenons required by post-and-beam construction. For the first time, any farmer could build his own buildings without a time-consuming learning curve.[26]

It has been said that balloon framing populated the western United States and the western provinces of Canada. Without it, western boomtowns certainly could not have blossomed overnight.[27] It is also likely that, by radically reducing construction costs, balloon framing improved the shelter options of poorer North Americans.[citation needed] However, balloon framing did require very long studs, and as tall trees were exhausted in the 1920s, platform framing became prevalent.[28]

Balloon framing presents challenges in firefighting, since many older balloon-framed buildings lack firestops or fire blocking in the open framing cavities, and a fire can spread vertically in a short time. Since the floor framing and wall framing cavities interconnect, fire can rapidly spread throughout the structure. Many balloon-framed buildings predate the introduction of building codes that mandate fire blocking, and a fire can spread from basement to attic in minutes.[29]

The main difference between platform and balloon framing is at the floor lines. The balloon wall studs extend from the sill of the first story all the way to the top plate or end rafter of the second story. The platform-framed wall, on the other hand, is independent for each floor.[30]

Materials

[edit]

Light-frame materials are most often wood or rectangular steel, tubes or C-channels. Wood pieces are typically connected with nail fasteners, nails, or screws; steel pieces are connected with pan-head framing screws, or nuts and bolts. Preferred species for linear structural members are softwoods such as spruce, pine and fir. Light frame material dimensions range from 38 by 89 mm (1.5 by 3.5 in); i.e., a Dimensional number two-by-four to 5 cm by 30 cm (two-by-twelve inches) at the cross-section, and lengths ranging from 2.5 metres (8.2 ft) for walls to 7 metres (23 ft) or more for joists and rafters. Recently,[when?] architects have begun experimenting with pre-cut modular aluminum framing to reduce on-site construction costs.

Wall panels built of studs are interrupted by sections that provide rough openings for doors and windows. Openings are typically spanned by a header or lintel that bears the weight of the structure above the opening. Headers are usually built to rest on trimmers, also called jacks. Areas around windows are defined by a sill beneath the window, and cripples, which are shorter studs that span the area from the bottom plate to the sill and sometimes from the top of the window to a header, or from a header to a top plate. Diagonal bracings made of wood or steel provide shear (horizontal strength) as do panels of sheeting nailed to studs, sills and headers. [citation needed]

Light-gauge metal stud framing

Wall sections usually include a bottom plate which is secured to the structure of a floor, and one, or more often two top plates that tie walls together and provide a bearing for structures above the wall. Wood or steel floor frames usually include a rim joist around the perimeter of a system of floor joists, and often include bridging material near the center of a span to prevent lateral buckling of the spanning members. In two-story construction, openings are left in the floor system for a stairwell, in which stair risers and treads are most often attached to squared faces cut into sloping stair stringers.[citation needed]

Interior wall coverings in light-frame construction typically include wallboard, lath and plaster or decorative wood paneling.[citation needed]

Exterior finishes for walls and ceilings often include plywood or composite sheathing, brick or stone veneers, and various stucco finishes. Cavities between studs, usually placed 40–60 cm (16–24 in) apart, are usually filled with insulation materials, such as fiberglass batting, or cellulose filling sometimes made of recycled newsprint treated with boron additives for fire prevention and vermin control. [citation needed]

In natural building, straw bales, cob and adobe may be used for both exterior and interior walls.

The part of a structural building that goes diagonally across a wall is called a T-bar. It stops the walls from collapsing in gusty winds. [citation needed]

Pressure-treated wood (Green Treated wood) is a type of wood that is used when a bottom plate is exposed to outside moisture, while even when in contact with concrete.

Roofs

[edit]
Main article: Roof
Trusses lying on the ground
An early step in framing a roof in the United States c. 1955. The carpenter is carrying two roof rafters joined to a ridge pole to set them in place on the far end of the structure.

Roofs are usually built to provide a sloping surface intended to shed rain or snow, with slopes ranging from 1:15 (less than an inch per linear foot of horizontal span), to steep slopes of more than 2:1. A light-frame structure built mostly inside sloping walls which also serve as a roof is called an A-frame.

In North America, roofs are often covered with shingles made of asphalt, fiberglass and small gravel coating, but a wide range of materials are used.[31] Molten tar is often used to waterproof flatter roofs, but newer materials include rubber and synthetic materials. Steel panels are popular roof coverings in some areas, preferred for their durability. Slate or tile roofs offer more historic coverings for light-frame roofs.

Light-frame methods allow easy construction of unique roof designs; hip roofs, for example, slope toward walls on all sides and are joined at hip rafters that span from corners to a ridge. Valleys are formed when two sloping roof sections drain toward each other. Dormers are small areas in which vertical walls interrupt a roof line, and which are topped off by slopes at usually right angles to a main roof section. Gables are formed when a length-wise section of sloping roof ends to form a triangular wall section. Clerestories are formed by an interruption along the slope of a roof where a short vertical wall connects it to another roof section. Flat roofs, which usually include at least a nominal slope to shed water, are often surrounded by parapet walls with openings (called scuppers) to allow water to drain out. Sloping crickets are built into roofs to direct water away from areas of poor drainage, such as behind a chimney at the bottom of a sloping section.

Structure

[edit]

Light-frame buildings in areas with shallow or nonexistent frost depths are often erected on monolithic concrete-slab foundations that serve both as a floor and as a support for the structure. Other light-frame buildings are built over a crawlspace or a basement, with wood or steel joists used to span between foundation walls, usually constructed of poured concrete or concrete blocks.

Engineered components are commonly used to form floor, ceiling and roof structures in place of solid wood. I-joists (closed-web trusses) are often made from laminated woods, most often chipped poplar wood, in panels as thin as 1 cm (0.39 in), glued between horizontally laminated members of less than 4 cm by 4 cm (two-by-twos), to span distances of as much as 9 m (30 ft). Open web trussed joists and rafters are often formed of 4 cm by 9 cm (two-by-four) wood members to provide support for floors, roofing systems and ceiling finishes.

Platform framing was traditionally limited to four floors but some jurisdictions have modified their building codes to allow up to six floors with added fire protection.[32]

Post frame garage connected to traditional frame house

Post frame building

[edit]
Main article: Post-frame construction

See also

[edit]

Literature

[edit]
  • Canada Mortgage and Housing Corporation (2005). Canadian Wood-Frame House Construction. ISBN 0-660-19535-6.

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Framing (construction)

View on Grokipedia
from Grokipedia
Framing in is the of assembling a building's to provide support, stability, and shape, bearing vertical loads from floors, walls, and roofs as well as lateral forces from and earthquakes. It involves connecting linear members such as studs, joists, beams, rafters, and trusses, typically using dimension , products, , or , to create walls, floors, and roofs that transfer loads to the foundation. The history of framing dates to ancient timber framing techniques, which originated in around 200 BC and were widely used in medieval for constructing durable post-and-beam structures with mortise-and-tenon . In the , balloon framing emerged in the United States, first documented in in 1832 with George Snow's warehouse, enabling faster and less skilled construction using lighter dimensional and mass-produced nails instead of heavy timbers. In the 1930s, platform framing evolved as an improvement, building each story independently on a platform of floor joists to enhance safety and address the scarcity of long , becoming the dominant method for residential buildings by the mid-20th century. Key techniques in framing include platform framing, the most common for modern homes, where walls are erected on subfloors and each level serves as a base for the next; balloon framing, characterized by continuous vertical studs spanning multiple stories; and post-and-beam or , which uses large, spaced timbers for open interiors and aesthetic appeal in traditional or commercial applications. Advanced house framing, also known as optimum , optimizes these methods by spacing studs up to 24 inches on center, aligning framing members to minimize thermal bridging, and reducing headers in non-load-bearing walls to conserve materials and boost energy efficiency while complying with building codes. Materials for framing prioritize strength, durability, and availability, with —such as visually graded softwoods like Douglas Fir-Larch or —dominating residential light-frame due to its renewability and ease of use, often pressure-treated for moisture-prone areas. framing offers non-combustible, termite-resistant alternatives for commercial and high-rise buildings, while provides superior load-bearing capacity for heavy structures; designs follow standards like the National Design Specification for Wood , incorporating factors for load duration, repetitive member use, and shear resistance in walls and diaphragms.

History

Origins in timber framing

Traditional timber framing is a construction method that employs large, heavy timbers joined together without nails or metal fasteners, relying instead on intricate woodworking techniques to create rigid structural skeletons for buildings. Key characteristics include the use of hand-hewn beams—timbers squared from logs using axes and adzes—and mortise-and-tenon , where a protruding tenon on one piece fits into a mortise hole on another, often secured with wooden pegs for added strength and flexibility. This approach allows for the assembly of expansive, load-bearing frames that support walls, roofs, and floors, emphasizing the natural properties of wood such as its tensile strength along the grain. The origins of timber framing trace back to ancient civilizations, with the earliest known examples of mortise-and-tenon joinery appearing in the period around 5200 BC, as evidenced by the wooden well at Altscherbitz near , . The technique spread widely across the , , and , including sophisticated applications in ancient using teak timbers pegged with and in for dating back to prehistoric times. In ancient , timber framing was widely employed in architecture and civilian buildings for its rapid assembly and cost-effectiveness, forming frameworks that supported infill walls of or brick. During the medieval period in , timber framing became prevalent in pre-industrial buildings, particularly in constructing durable barns for agricultural storage and the intricate roof structures of . Examples include the massive oak-framed barns at Cressing Temple in , dating to the 13th century, which featured straight timbers joined with notched-lap joints and passing braces to span wide interiors without internal supports. Cathedral roofs, such as those employing hammerbeam trusses in structures like , showcased advanced framing to achieve vast, open spans while distributing weight to stone walls below. The method's advantages stem from the large cross-sections of timbers, which provide exceptional durability against and seismic activity, often outlasting associated elements. In fires, these substantial members develop a protective char layer on the exterior, preserving the unburned core and maintaining structural integrity longer than smaller wooden elements or some non-combustible alternatives. However, traditional is highly labor-intensive, requiring skilled carpenters for hand-hewing and precise , and results in significant material waste as much of the log's rounded exterior is removed to create squared beams. Specific examples of timber framing include the English post-and-beam system, which evolved in the medieval era with vertical posts supporting horizontal girders and braces forming a grid-like frame, as seen in half-timbered houses and halls. This tradition was adapted in colonial America from the onward, where abundant forests enabled the construction of sturdy barns, meeting houses, and homes using similar post-and-beam configurations until the early , when shifts toward lighter framing methods began to emerge due to industrialization.

19th and 20th century innovations

The marked a pivotal shift in wood framing from heavy timber construction to lighter, more efficient systems, driven by industrial advancements that facilitated rapid in growing American cities. framing emerged in the 1830s in , attributed to builder George Washington Snow, who utilized continuous vertical studs made from lighter dimensional produced by improved sawmills capable of cutting uniform 2x4s and similar sizes. This replaced traditional mortise-and-tenon with nailed connections, enabled by the of wire nails starting in the early 1800s, allowing for quicker assembly by less-skilled labor. The first documented -framed building was Snow's 1832 warehouse near the , which demonstrated the method's viability for economical in treeless regions. By the late 19th and early 20th centuries, platform framing began to supplant balloon framing, evolving as a safer alternative that framed each story independently with shorter studs and built floors as platforms for subsequent levels. This transition gained momentum around the , influenced by the development of standardized production in the early 1900s, which ensured consistent dimensions for mass-scale building. The first U.S. model building codes, introduced by the International Conference of Building Officials in 1927, further promoted these lighter framing systems by mandating fire safety measures and structural standards that favored nailed, dimensionally uniform wood elements over complex . Technological advances in nailing techniques and milling continued to reduce reliance on skilled , aligning with broader industrialization trends. Platform framing became the dominant standard in the United States following , propelled by the postwar housing boom that demanded rapid, scalable for suburban expansion in the and . Its inherent advantages, such as built-in firestops from platforms that limited vertical spread in multi-story buildings and easier on-site handling of shorter components, enhanced and efficiency during this era of widespread single-family home development. By the mid-20th century, these innovations had transformed wood framing into a versatile, cost-effective method integral to modern residential architecture, supporting load paths through repetitive stud walls while minimizing material use.

Structural Principles

Load-bearing elements and paths

In framed construction, vertical loads include dead loads from the permanent weight of building materials such as walls, , , and finishes; live loads from temporary occupancy and use, like and furniture; and snow loads from accumulated on roofs. Horizontal loads encompass wind forces acting laterally on the structure and seismic forces from ground motion, which induce shear and overturning. Primary load-bearing members—studs in walls, joists in floors, and rafters in roofs—transfer these vertical loads downward through compression while distributing horizontal loads via connections to maintain stability. Studs function as vertical columns bearing axial loads from above, joists span horizontally to support floor or assemblies, and rafters carry roof sheathing and transfer forces to exterior walls. The concept of load paths describes the continuous route through which forces travel from their point of origin, such as the , to the foundation, ensuring all structural elements align to support the imposed demands. areas represent the surface area assigned to each member for load calculation; for instance, a floor joist spaced 16 inches on center supports a tributary width equal to its spacing, influencing the total load it carries based on uniform distribution. Span calculations for these members rely on prescriptive tables rather than complex formulas, with basic rules allowing common wood joists—like 2x10 No. 2 grade Douglas Fir-Larch at 16 inches on center—can span up to approximately 15 feet 3 inches under typical residential dead load of 10 psf and live load of 40 psf (AWC Span Tables), with modulus of elasticity around 1.6 million psi. Continuous load transfer is critical, achieved through overlapping elements and mechanical fasteners like nails or straps that create a seamless chain from rafters to top plates, studs to sills, and ultimately to footings, preventing localized overloads. in design, such as multiple parallel studs or alternative paths via interior walls, enhances resilience against failure modes including —where slender studs compress and bow under vertical loads exceeding their capacity—and shear, where horizontal forces cause sliding or racking in joints. These principles ensure the structure's integrity by distributing loads evenly and accommodating variations in force application. Historically, early depended on the mass and interlocking of heavy timbers for inherent stability against loads, with minimal emphasis on defined paths due to the robustness of materials like beams. This approach evolved in the 19th and 20th centuries toward lighter and platform framing, incorporating allowable stress design methods that prioritized engineered load paths for efficiency and safety. Modern building codes, such as the International Building Code, mandate continuous load paths for all vertical and horizontal forces, integrating seismic and wind provisions to reflect lessons from events like the .

Bracing and shear walls

In wood light-frame construction, bracing systems are essential to resist lateral forces such as and seismic loads, preventing deformation where panels shift parallel to themselves, which could lead to structural instability. Diagonal members, typically installed at 45 to 60 degrees across sections, provide this resistance by forming triangular geometries that stiffen the frame; for instance, 1x4 let-in braces are notched into studs and secured with two 8d at each , offering an ultimate shear capacity of 600 pounds per brace in an 8-foot section. Let-in bracing involves embedding these diagonal elements directly into the stud framework, while alternatives like metal straps or T-braces enhance tension resistance and are often used around openings or in roofs to transfer forces to the diaphragm; metal T-braces, for example, achieve 1,400 pounds of tension capacity per unit. These methods integrate with vertical load paths by distributing horizontal forces to foundations, ensuring overall stability without relying solely on vertical elements. Shear walls represent a more rigid evolution of bracing, functioning as continuous vertical diaphragms that resist in-plane shear through sheathing fastened to the framing. In light-frame , plywood or (OSB) sheathing is nailed to studs at specified spacings, creating a monolithic panel; the International recommends a minimum thickness of 3/8 inch for such panels when applied directly to framing as exterior siding, with span ratings up to 16 inches on center to meet shear capacity demands (IBC 2306.3). Nailing patterns, typically using 6d or 8d common nails at 6-inch edge and 12-inch field spacings, ensure the sheathing acts compositely with the studs, achieving yield capacities of 700 pounds per linear foot for single-layer diagonal sheathing or higher for wood structural panels under cyclic loading. These walls must maintain aspect ratios of 2:1 or less for full design capacity, with reductions applied for taller configurations up to 3.5:1, and include blocking and hold-downs at boundaries to prevent uplift and . Recent IBC updates (2021 and 2024) emphasize enhanced anchorage and damping systems for improved performance in high-seismic regions. The transition from traditional braced frames to modern shear walls in light-frame wood construction began in the mid-20th century, shifting from discrete diagonal bracing or horizontal sheathing—common until the 1940s for shear resistance—to continuous sheathing post-World War II, driven by the need for greater stiffness and efficiency in residential building. This evolution was informed by early testing programs, such as those in the by the Forest Products Laboratory, which demonstrated that sheathed panels outperformed let-in braces under repeated loading, leading to their incorporation into standards like the Uniform Building Code. In larger structures, braced frame configurations like T-bracing (two diagonals forming a T shape) or K-bracing (opposing diagonals forming a K) persist for open bays, providing targeted resistance while allowing architectural flexibility, though shear walls remain dominant in low- to mid-rise buildings for their superior dissipation. The underscored the vulnerabilities of inadequate bracing in light-frame buildings, with numerous failures attributed to insufficient capacity and poor detailing. For example, soft-story collapses, such as at the Northridge Meadows apartments where the garage level pancaked due to minimal shear resistance from walls and open configurations, resulted in 16 fatalities and highlighted the risks of irregular distribution. Diagonal cracking and racking in older wood-frame s, often relying on brittle or without reinforcement, led to widespread deflection and partial failures in multifamily low-rise structures, prompting code revisions that reduced allowable shear values for such materials (e.g., to 90 pounds per foot) and mandated sheathing for enhanced performance. These events emphasized the need for balanced bracing across stories to avoid concentration of forces, influencing modern designs to prioritize continuous shear paths.

Framing Types

Balloon framing

Balloon framing is a method of light-frame wood construction characterized by continuous vertical studs that extend the full height of the building from the to the roof plate, typically spanning two or more stories without interruption. These studs, often 2x4 or 2x6 dimensional , are spaced at 16 to 24 inches on center and nailed directly to the at the foundation and to double top plates at the roof level. Intermediate floors are supported by ribbon boards—narrow horizontal ledgers, such as 1x4-inch pieces, notched into the studs—or ledger boards nailed to the sides of the studs, allowing joists to hang without breaking the vertical continuity of the framing. This system relies on nails rather than complex , enabling rapid assembly with lighter materials compared to traditional heavy . Originating in the 1830s in during the city's rapid expansion, balloon framing became predominant in the United States, particularly in the Midwest, where abundant lumber and the need for quick, fueled its adoption amid westward migration. By 1900, it had supplanted heavier braced-frame methods as the standard for residential and light commercial wood-frame across the country, remaining common until the 1940s when it was largely replaced by platform framing due to evolving building codes and practices. Today, balloon framing is rarely used in new but persists in historic restorations and heritage projects to preserve original structural integrity. The technique offers advantages in material efficiency and construction speed, as it uses smaller, machine-sawn pieces and simple nailing, reducing the need for skilled labor and heavy timbers while minimizing differential settlement between floors due to the continuous vertical members. However, it presents significant disadvantages, including a heightened spread risk from uninterrupted vertical cavities that allow flames and heat to travel unchecked between stories unless firestops are installed at floor levels and other intervals. Additionally, sourcing long studs for multi-story buildings increases costs and logistical challenges, and the method demands more temporary bracing or during erection, making it less practical for modern multi-story applications compared to safer, story-by-story platform framing. Assembly begins with securing a to the foundation, followed by erecting the continuous studs vertically at specified centers, ensuring precise alignment with temporary diagonal bracing for stability. or boards are then installed at heights by notching or nailing them into the studs, onto which floor joists are attached and sheathed. The process concludes with capping the studs with double top plates, framing the structure, and adding fire blocking in cavities as required by to mitigate hazards.

Platform framing

Platform framing, also known as western framing, is a light-frame technique where each building story is constructed independently on a horizontal platform formed by the floor joists and sheathing of the level below, with vertical studs typically starting from the of each floor rather than running continuously through multiple stories. This method utilizes shorter pieces, such as 8- or 9-foot studs, which are assembled into wall frames that are raised onto the platform, creating a segmented structure that contrasts with continuous-stud systems. The platform itself consists of dimensional joists spaced at standard intervals, covered with or (OSB) sheathing to provide a stable base for the next level's framing. Key advantages of platform framing include enhanced fire resistance due to the natural firebreaks created by the double top plates and subfloor at each level, which interrupt vertical fire paths and limit spread between stories compared to continuous framing methods. It facilitates easier and faster construction by allowing workers to assemble components on the ground or a secure platform, reducing the need for and improving overall worker safety through the provision of a solid working surface at each elevation. Standard stud and spacing of 16 or 24 inches on center optimizes material efficiency while maintaining structural integrity, aligning with common building practices for load distribution. The assembly process begins with laying out the subfloor on the foundation, securing sill plates to the , and installing floor joists followed by sheathing to form the initial platform. Wall frames are prefabricated flat on the platform or ground, then tilted up, plumbed, and nailed or screwed into place along the sill and top plates, with subsequent platforms added iteratively for multi-story builds. In seismic-prone areas, adaptations such as hold-down devices at wall ends or openings are incorporated to resist uplift forces, integrating with overall bracing systems for lateral stability. Since the mid-20th century, platform framing has dominated U.S. residential construction, accounting for over 90% of new wood-framed homes by the , due to its adaptability, cost-effectiveness, and alignment with standardized building codes. This prevalence reflects its evolution as the preferred method for single-family and low-rise structures, emphasizing modular assembly and safety enhancements over earlier techniques.

Braced framing

Braced framing is a traditional technique that employs diagonal timbers or metal straps to resist shear forces and provide lateral stability to building walls and roofs. Originating in colonial America and influenced by English half-timber methods, it features heavy timbers—typically 4x4 inches or larger—joined primarily with mortise-and-tenon connections and reinforced by diagonal braces to form a rigid, truss-like structure. This system was prevalent in pre-20th century building practices, where abundant timber resources allowed for such robust assemblies without reliance on . Common configurations include single diagonal braces let into studs and plates at angles of about 45 to 60 degrees, knee braces at corners for added rigidity, double diagonals forming an X-pattern, or chevron arrangements in framing to counter . These elements integrate with vertical posts, horizontal sills, girts, and top plates, creating a framework that distributes loads effectively while allowing for infill materials like or boards. In lighter applications, 1x4-inch let-in braces may be used, but traditional heavy braced frames employ thicker members for greater strength. Historically, braced framing found widespread application in colonial homes, barns, and agricultural structures, particularly in regions like where it provided durability against wind and settlement in small dwellings. Its use persisted into the for buildings requiring permanence, such as farm outbuildings, due to the method's ability to create stable enclosures with minimal materials. In modern contexts, it appears in seismic retrofits of historic wood-frame buildings, where diagonal braces are added to cripple walls or infill panels to enhance resistance to earthquakes without altering facades; this approach contrasts with continuous shear walls by employing discrete elements that preserve architectural character while using less sheathing. Despite its strengths, braced framing has notable limitations, including high labor demands for precise and timber preparation, which made it costly and skill-intensive even in eras of cheap wood. It offers lower efficiency under extreme lateral loads compared to sheathed systems, leading to its decline after the 1900s in favor of lighter and platform methods. Following 1970s updates to building codes emphasizing seismic performance, pure braced systems have evolved into hybrids incorporating or OSB sheathing to meet contemporary standards for and energy dissipation.

Post-frame construction

Post-frame construction, also known as pole barn construction, is a building that utilizes large vertical posts embedded directly into the ground or attached to minimal to support the primary , eliminating the need for a full continuous foundation. These posts, typically pressure-treated wood or columns, serve as the main load-bearing elements, resisting axial, bending, and lateral forces while supporting horizontal girts on walls and purlins on the roof, which in turn carry roof trusses or rafters and exterior cladding. This method provides efficient load paths through the embedded posts, which offer partial fixity in the , supplemented by diaphragms and shear walls for and seismic resistance. The assembly process begins with setting posts at spacings of 8 to 12 feet on center, using materials such as solid-sawn or laminated (e.g., Southern Pine or glulam) treated for ground contact per AWPA U1 standards, or columns for greater durability. Posts are embedded 3.5 to 4 feet deep, often with small footings or collars for stability, followed by the erection of prefabricated trusses spaced 4 to 12 feet apart. Girts (typically 2x4 or 2x6 ) are then attached horizontally to the posts to form wall frameworks, and purlins are installed on the trusses to support the ; finally, metal siding and roofing panels are fastened to these secondary members for enclosure. This streamlined process allows for rapid erection, often completing a in days or weeks, and supports clear spans up to 100 feet without intermediate supports, making it cost-effective compared to traditional framing due to reduced material and labor needs. It gained prominence in 20th-century U.S. farms during the 1930s and , evolving from early pole buildings to meet the demand for spacious, economical agricultural storage as mechanized farming increased. In modern applications, post-frame construction extends beyond to commercial storage facilities and equestrian arenas, where its open interiors and design flexibility accommodate diverse uses like warehousing and housing. Building codes, such as the International Building Code (IBC) and ASCE/SEI 7-22, mandate uplift anchors or brackets at post bases to resist wind uplift forces, ensuring structural integrity through specified connections like wet-set embeds or treated cleats that transfer loads effectively. These requirements, along with standards from the National Frame Builders Association (NFBA), emphasize engineered designs for durability and code compliance in non-residential settings.

Materials

Wood and dimensional lumber

Wood and dimensional lumber form the backbone of traditional framing in residential and light commercial construction, primarily consisting of sawn softwood members derived from coniferous trees. Common species include (SPF) for studs due to its availability and workability, and for beams owing to its superior strength and . Hem-fir and are also widely used, with particularly favored for its and treatability in structural applications. These species are selected based on regional and performance requirements, ensuring economical framing while meeting load-bearing needs. Grading of dimensional lumber follows the American Softwood Lumber Standard (PS 20), overseen by the American Lumber Standard Committee, which categorizes pieces by for defects like knots, checks, and splits that affect strength. Grades such as No. 1 (few defects, suitable for high-stress uses) and No. 2 (more allowable imperfections but adequate for general framing) determine allowable spans and loads, with No. 2 being the most common for studs and joists in platform framing. Standard dimensions are nominal, referring to rough-sawn sizes before and surfacing; for example, a nominal 2x4 measures 1.5 by 3.5 inches actual, a 2x6 is 1.5 by 5.5 inches, and a 2x12 is 1.5 by 11.25 inches, with lengths typically in 2-foot increments from 8 to 20 feet. Moisture content is limited to 19% or less for framing lumber to minimize shrinkage and warping after installation, as specified in building codes. The properties of and dimensional , including a high strength-to-weight , make it ideal for framing, outperforming materials like in tension and per unit weight for many applications. For exterior use, such as in exposed sills or rim joists, is often pressure-treated with waterborne preservatives like (ACQ) or copper azole (CA) to resist decay and , with southern exhibiting excellent treatability due to its permeable sapwood. Sourcing emphasizes , with increasing use of from forests certified by the (FSC), which verifies responsible management practices to prevent and maintain . Historically, the early marked a shift from old-growth forests—characterized by large, slow-growing trees yielding dense, —to second-growth sources as virgin stands were depleted by 1900, prompting national efforts. This transition, accelerated post-1924 with the adoption of Simplified Practice Recommendation No. 16, influenced sizing by accounting for greater shrinkage in younger, faster-growing trees, resulting in refined actual dimensions and the widespread use of kiln-drying to achieve consistent . For longer spans beyond the limits of dimensional lumber, products offer enhanced performance.

Engineered wood products

Engineered wood products are manufactured wood items engineered for enhanced structural performance in construction framing, utilizing wood fibers, veneers, or laminations bonded with adhesives to create materials with superior strength, uniformity, and dimensional stability compared to solid sawn lumber. These products address limitations of natural wood variability, such as knots and warping, by combining smaller or lower-grade wood pieces into large, consistent structural members suitable for load-bearing applications like beams and headers. Key types include (LVL), (PSL), and (glulam). LVL consists of thin wood veneers oriented with the grain parallel and bonded together using adhesives, then sawn into desired dimensions for use as headers, beams, and rafters. PSL is produced by bonding long, thin wood strands aligned parallel to the grain with adhesives to form dense billets that are sawn into beams, headers, and load-bearing columns. Glulam is made by gluing multiple layers of dimensional laminations, typically 1-3/8 to 1-1/2 inches thick, with all grains parallel, resulting in curved or straight beams and girders. These manufacturing processes involve pressing the assemblies under and to achieve uniform density and strength, enabling production in sizes larger than traditional sawn , such as glulam beams up to 60 feet in length. In framing applications, these products replace solid sawn lumber for long spans where consistency and reduced defects are critical, such as LVL headers spanning over 10 feet in residential framing or glulam beams supporting loads in commercial structures. Their advantages include higher predictable strength-to-weight ratios, minimal shrinkage or splitting, and the ability to span greater distances without intermediate supports, which optimizes material use and enhances framing efficiency. For instance, PSL's strand configuration provides exceptional uniformity, making it ideal for high-load columns in multi-story buildings. Standards for engineered wood products are governed by the APA - The Engineered Wood Association, which certifies compliance through trademarks indicating adherence to rigorous testing and quality controls, such as ANSI A190.1 for glulam and ASTM D5456 for structural composite lumber like LVL and PSL. Environmentally, these products promote by utilizing smaller trees from managed forests and wood by-products, with manufacturing processes powered by over 50% renewable from bark and , reducing reliance on fossil fuels and supporting renewable resource cycles.

Metal framing materials

Metal framing in construction primarily utilizes , which involves shaping thin steel sheets at to create structural members such as studs, tracks, and joists for light-gauge framing systems. These systems are widely employed in non-combustible structures like commercial buildings and multi-family housing. The primary material consists of studs, typically available in gauges ranging from 25 to 18 (corresponding to thicknesses of about 0.0187 to 0.0474 inches), with common widths such as 3-5/8 inches for standard framing. To enhance durability, these studs are often coated with galvanized , providing a minimum G40 coating weight for corrosion resistance in interior applications. Key properties of include high tensile and yield strengths, often reaching up to 50 for structural grades, enabling efficient load-bearing capacity in slender profiles. Steel's recyclability is a significant environmental advantage, with over 90% of steel being recycled, supporting sustainable building practices. However, designers must account for , as steel's coefficient (approximately 6.5 × 10^{-6}/°F) is higher than that of , potentially requiring accommodations in joints and connections to prevent or distortion under temperature fluctuations. Sizing and quality of metal framing members are governed by established standards to ensure performance. For non-structural applications, such as interior partitions, ASTM C645 specifies requirements for framing members, including minimum thickness, coating, and dimensional tolerances. Load-bearing systems adhere to AISI S100, the North American Specification for the Design of Structural Members, which outlines design provisions for strength, stability, and connections. framing gained prominence in commercial and multi-family construction starting in the , driven by the need for fire-resistant, durable alternatives in taller buildings. Compared to wood framing, which is more common in residential single-family homes, metal framing offers advantages like complete resistance to and pests, as well as consistent dimensions that eliminate issues like warping or shrinking. However, it typically incurs higher material and installation costs—often 15-20% more than wood—and requires specialized tools for cutting due to steel's hardness, which can complicate on-site modifications.

Concrete

Reinforced concrete serves as a key framing material for heavy-duty applications in commercial, industrial, and high-rise construction, where it forms structural skeletons using columns, beams, and slabs. It combines , aggregates (sand and gravel), water, and admixtures with embedded steel reinforcement bars () or prestressing steel to leverage concrete's high (typically 3,000–5,000 psi for structural grades) and steel's tensile strength (Grade 60 at 60 yield). This is cast in place or precast, providing monolithic frames that transfer loads efficiently to foundations. Design and construction of frames follow ACI 318, Requirements for Structural Concrete, which specifies provisions for strength, , serviceability, and fire resistance, including minimum over (1.5–3 inches depending on exposure) and development lengths for anchorage. Advantages include superior fire resistance (up to 4-hour ratings), seismic performance through , and longevity with minimal maintenance, though it has higher self-weight (about 150 lb/ft³) requiring robust foundations. Compared to steel framing, offers better for energy efficiency but longer on-site curing times (7–28 days for removal). Sustainability improvements involve supplementary cementitious materials like fly ash to reduce the of production, with recycled aggregates increasingly used as of 2025.

Components and Assembly

Wall framing

Wall framing forms the vertical structural skeleton of buildings, enclosing spaces and providing support for loads from floors, roofs, and lateral forces. In wood-frame construction, walls consist of horizontal plates and vertical studs assembled to create load-bearing or non-load-bearing partitions. These elements are typically dimensioned , such as 2x4 or 2x6 members, fastened together to achieve rigidity and alignment before erection. For metal or framing variants, see the Materials section. Key components include the bottom plate, also known as the sole plate, which is a horizontal member at the base of the wall, providing a nailing surface for the studs and anchoring the assembly to the floor framing; it must be at least 2 inches nominal thickness and match the stud width for full bearing (as of 2024 IRC). The top plate, usually doubled for load-bearing walls, sits at the upper end, overlapping at corners and intersections with joints offset by at least 24 inches to ensure continuity and load transfer. Vertical studs, the primary load-carrying members, run continuously from the bottom plate to the top plate and are spaced at 16 or 24 inches on center depending on design requirements. Specialized studs include king studs, which are full-height members adjacent to or openings to support headers; jack studs (or trimmer studs), shorter members beneath the header that transfer loads to the bottom plate; and studs, which are partial-height studs above or below openings to maintain framing integrity. Corners are reinforced with three- or four-stud configurations to provide nailing surfaces for adjoining walls and sheathing while minimizing material use. Headers, or lintels, span openings and are often constructed from doubled 2x10s or similar with a spacer, nailed at 16 inches on center along each edge to distribute loads around s and s. Exterior walls differ from interior partitions primarily in dimension and spacing to accommodate insulation and structural demands. Exterior load-bearing walls commonly use 2x6 studs at 24 inches on center to create deeper cavities for enhanced , reducing thermal bridging compared to traditional 2x4 framing at 16 inches on center. Interior non-load-bearing partitions, by contrast, often employ 2x4 studs at 24 inches on center or even 2x3 for lighter applications, as they do not support vertical loads beyond their own weight and finishes. These partitions provide spatial division without contributing to the building's primary structure. Assembly begins with laying out the top and bottom plates parallel on a flat surface, marking stud locations with a tape measure and framing square for accuracy, then end-nailing or toe-nailing studs to the plates using 2-16d common nails (3½ inches x 0.135 inches) for end nailing or 3-8d nails (2½ inches x 0.113 inches) for toe nailing to secure the frame. The wall is squared by checking that the diagonals measure equal and using a framing square at corners to ensure 90-degree angles before sheathing or additional bracing. For openings, king and jack studs are installed first, followed by the header, with cripple studs added to fill spaces; integration of windows and doors involves aligning rough openings to manufacturer specifications and securing frames within the stud assembly. Once assembled flat, walls are tilted up, plumbed, and braced temporarily until permanent connections are made. Variations in wall framing include adaptations for non-standard geometries, such as curved walls achieved by kerfing straight —cutting shallow grooves along one face to allow —while maintaining structural integrity through additional blocking. Balloon-style framing features continuous full-length studs spanning multiple stories for continuity, though it is less common today due to fire-stopping challenges. Bracing, such as wood structural panels, may be incorporated in walls to resist shear forces, as detailed in specific bracing provisions.

Floor framing

Floor framing forms the horizontal structural system that supports the weight of building floors, distributes loads to the walls or beams below, and provides a stable base for interior finishes and subflooring. In residential , this system typically consists of parallel floor joists spanning between load-bearing walls or girders, connected at their ends by rim joists to create a perimeter frame. For metal or alternatives, refer to the Materials section. The joists are commonly spaced at 16 inches on center to balance strength, material efficiency, and ease of installation, though spacings of 12, 19.2, or 24 inches may be used depending on joist size and load requirements (as of 2024 IRC). Traditional sawn joists, such as 2x10 or southern pine graded for structural use, have been standard for decades, offering spans up to about 16 feet under typical residential loads. Over time, the industry has evolved toward products like , which consist of webs and flanges, enabling longer clear spans of up to 24 feet or more while reducing weight and deflection. This shift, driven by demand for open floor plans and efficient material use, began in the late with the development of prefabricated systems that provide consistent performance and easier handling on job sites. Rim joists, often matching the depth of the floor joists, enclose the ends to transfer loads laterally and prevent twisting, while subfloor sheathing—typically 3/4-inch tongue-and-groove or —nails or screws directly to the tops of the joists for a continuous diaphragm that resists shear forces. Assembly techniques emphasize stability and load distribution, with solid blocking installed at joist ends and supports to provide lateral restraint and prevent rotation, as required by building codes. For longer spans, diagonal bridging or cross-blocking between joists at mid-span or third-points enhances torsional stiffness and controls , particularly in engineered systems where thin webs can amplify bounce under foot traffic. Residential floors must support a minimum live load of 40 pounds per (psf) in living areas, plus dead loads from finishes and occupants, with deflection limited to L/360 (span length divided by 360) to ensure serviceability (as of 2024 IRC). Cantilevered portions of floor joists, used to extend beyond supports for bay windows or decks, are permitted up to 2 feet in many applications per prescriptive code tables, provided the adjacent backspan is at least three times the length for balance. In platform framing systems, the floor assembly integrates seamlessly atop wall plates, creating a continuous load path to the foundation.

Roof framing

Roof framing forms the structural skeleton of a building's overhead enclosure, supporting loads from weather, snow, and wind while providing weather protection and defining the roof's shape. In residential , it typically involves sloped systems to facilitate drainage, with common configurations including , , and roofs. These frames transfer vertical and lateral forces downward through walls to the foundation, ensuring overall stability. is the predominant , though engineered components enhance efficiency for wider spans; metal or options are detailed in the Materials section. Stick framing, also known as framing, constructs roofs using individual pieces cut on-site to form the desired shape. Common rafters span from the exterior walls to a central board, creating ends with triangular profiles for ventilation and . Hip roofs employ sloped rafters on all sides, converging at hips without vertical ends, which provides better wind resistance in exposed areas. Prefabricated trusses, assembled off-site from triangular web configurations, allow spans up to 60 feet without intermediate supports, reducing labor and material waste compared to stick methods. Key components include the ridge board, a horizontal member at the roof peak that aligns opposing rafters without bearing load, sized to at least 1 inch nominal thickness and matching the depth of the rafter's cut end. Collar ties, horizontal braces connecting rafter pairs near the top third of the attic space, prevent outward on walls and maintain structural integrity. Rafters feature birdsmouth cuts—a notched at the lower end—to seat securely on the top , with the notch depth limited to one-third of the rafter's depth to preserve strength. Roof sheathing, typically 1/2-inch or , covers the rafters to provide a nailable surface for roofing materials and lateral bracing (as of 2024 IRC). Roof pitch, expressed as the rise over run (e.g., vertical units per 12 horizontal inches), must be at least 2:12 for , with double underlayment required for slopes between 2:12 and 4:12 to ensure adequate drainage and prevent water ponding. Overhangs extend beyond walls for eave protection, typically 12 to 24 inches, influencing total length. length is calculated using the , where the sloped distance () equals the of the sum of the squared run (half the building span) and squared rise (vertical height to ), adjusted for overhangs and cuts. During assembly, or are erected sequentially from walls upward, secured with metal fasteners, and stabilized using temporary diagonal bracing to counter wind or imbalance until sheathing is applied. Integration with walls occurs via hurricane ties or straps at each rafter or truss heel, anchoring the to resist uplift forces in high-wind regions and ensuring load transfer without relying solely on toenails.

Modern Practices

Prefabrication and modular construction

Prefabrication and modular construction involve the off-site fabrication of framing components, such as panelized walls, cassettes, and full volumetric modules, which are then transported to the site for assembly using cranes. Panelized walls consist of flat-pack structural framing and sheathing produced in , while cassettes include prefabricated framing elements that serve as diaphragms spanning modules. Full volumetric modules are three-dimensional units pre-assembled with , walls, ceilings, and sometimes integrations, allowing up to 70% of the building to be completed off-site. These methods enable simultaneous on-site preparation, such as foundation work, and rely on controlled environments for precision cutting and assembly, typically resulting in waste as low as 5%. On-site erection involves crane-lifting modules into position, followed by stitching connections between adjacent units to ensure structural integrity. The adoption of prefabrication and modular construction has surged since 2020, driven by persistent labor shortages in the construction industry, with 51% of general contractors citing workforce challenges as a primary motivator for off-site methods. This growth addresses broader housing shortages, particularly in urban infill projects where space constraints favor rapid assembly; for instance, developments like Union Flats in , utilized modular framing to expedite multifamily housing in dense areas. Market projections indicate the sector expanding from USD 173.5 billion in 2025 to USD 302.0 billion by 2035, fueled by over 200 new companies entering the field in the past two decades and increasing research output peaking in 2021-2022. These techniques integrate with traditional framing components, such as and assemblies, through bolted or welded connectors designed for load transfer. Key benefits include significant time savings of 25-50% in project timelines, as seen in recent 2023-2025 initiatives where modular framing reduced overall schedules by up to 25% through parallel factory and site activities. is enhanced in factory settings, minimizing errors and enabling precise material estimation with up to 20% savings in resources. Waste reduction reaches up to 90% compared to traditional on-site framing, due to optimized cutting and processes that limit off-cuts of materials like timber and . These efficiencies stem from standardized production lines, which also mitigate on-site disruptions from weather or labor variability. Standards such as ICC/MBI 1200-2021 govern the entire off-site process, including planning, design, fabrication, transportation, and on-site assembly of prefabricated framing components, ensuring compliance for both residential and commercial applications. under these guidelines addresses transport requirements, such as securing modules for movement and seismic considerations, while ICC/MBI 1205-2021 focuses on inspections and regulatory approval to verify structural performance. Integration with traditional framing occurs via specified connectors at module interfaces, which are inspected for load-bearing capacity and alignment during erection. These standards, developed in collaboration with the Modular Building Institute, promote uniformity and safety equivalent to site-built methods.

Sustainable and advanced framing techniques

(CLT) consists of layered panels made from dimensionally stable lumber glued in alternating directions, enabling its use in mid-rise buildings up to 18 stories under updated building codes. These panels provide structural integrity while sequestering carbon, making CLT a key material for reducing the environmental footprint of construction. In fire scenarios, CLT demonstrates enhanced resistance due to its charring behavior, with a nominal char rate of approximately 1.5 inches per hour that protects the underlying mass from heat exposure. The global CLT market has experienced significant growth, valued at USD 1.10 billion in 2024 and projected to reach USD 1.28 billion in 2025, driven in part by its adoption in net-zero energy homes that leverage wood's renewability to meet decarbonization targets. Hybrid framing systems combining and CLT offer optimized performance by integrating the strength of with the sustainability of timber, resulting in structures that balance load-bearing capacity and reduced material use. Recent 2025 research highlights how these steel-CLT hybrids can achieve embodied carbon reductions of 30-50% compared to traditional or alternatives through strategic material substitution and efficient design. Incorporating recycled into such framing further enhances , as structural typically contains 92% recycled content and is fully recyclable, minimizing extraction impacts and supporting principles in . Sustainable framing emphasizes low-carbon designs that prioritize renewable or rapidly regenerating materials, such as as an alternative to traditional timber, which can sequester more carbon per unit volume while offering comparable strength for lightweight framing applications. Techniques like exterior insulation create tighter building envelopes, reducing thermal bridging and air leakage to improve energy efficiency by up to 20-30% in residential structures. These approaches align with certification standards like , which reward low embodied carbon materials, and broader 2030 goals for net-zero emissions in the building sector, including a 45% reduction in global construction-related carbon from 2010 levels. Advancements in framing include 3D-printed connectors that enable precise, customizable joints for timber assemblies, reducing labor and waste while allowing complex geometries in modular wood systems. Mass timber, particularly CLT, has enabled taller buildings, with post-2020 projects like the 25-story Ascent in featuring 18 stories of mass timber over a concrete base, demonstrating scalability for urban high-rises while maintaining and seismic performance. In June 2025, groundbreaking occurred for a 31-story mass timber tower in , further advancing the height potential of these systems. The 2021 International formalized Type IV-A , permitting mass timber up to 18 stories and accelerating adoption in sustainable high-density developments.

References

  1. https://www.huduser.gov/publications/pdf/res2000_3.pdf
  2. https://www.beaverconstructionut.com/blog/what-is-framing-construction-methods-and-materials-explained
  3. https://www.troyhistoricvillage.org/pathway-to-preservation/installment-4-framing-history/
  4. https://www.chipublib.org/blogs/post/technology-that-changed-chicago-balloon-framing/
  5. https://www.bayandbent.com/balloon-framing
  6. https://www.energy.gov/energysaver/advanced-house-framing
  7. https://www.tfguild.org/historical-perspectives
  8. https://engineering.rowan.edu/_docs/civilenvironmental/cee-materials-reading-assignment.pdf
  9. https://www.academia.edu/1160526/A_Neolithic_treasure_chest_The_well_of_Altscherbitz
  10. https://www.britannica.com/technology/architecture/Non-Western-architecture-after-1000-bce
  11. https://www.academia.edu/28526308/The_Roman_timber_framework_a_neglected_construction_method
  12. https://thefriendsofcressingtemple.org/the-barns-and-medieval-carpentry-new/
  13. http://projects.mcah.columbia.edu/medieval-architecture/htm/cl/ma_cl_discuss.htm
  14. https://www.fpl.fs.usda.gov/documnts/pdf1991/moody91a.pdf
  15. https://www.buildingarchaeology.org/wp-content/uploads/2015/03/Structural-Carpentry-Hewett.pdf
  16. https://historicmassachusetts.org/wp-content/uploads/2021/02/how-to-date-a-house.pdf
  17. https://www.jstor.org/stable/989648
  18. https://www.sbcmag.info/sites/default/files/0901_balloon.pdf
  19. https://www.arrowtimber.com/post/a-brief-history-and-evolution-of-timber-framing
  20. https://ncpe.us/wp-content/uploads/2012/07/Obrien.pdf
  21. https://mtcopeland.com/blog/dimensional-lumber-types-sizes-history/
  22. https://www.finehomebuilding.com/2023/07/19/a-history-of-u-s-building-codes
  23. https://www.huduser.gov/portal/Publications/PDF/review.pdf
  24. https://www.facebook.com/groups/1706748102970911/posts/3786044568374577/
  25. https://www.huduser.gov/publications/pdf/res2000_2.pdf
  26. https://awc.org/publications/tutorial-for-understanding-loads-and-using-span-tables/
  27. https://www.fema.gov/sites/default/files/documents/fema_p-749-earthquake-resistant-design-concepts_112022.pdf
  28. https://awc.org/wp-content/uploads/2022/02/AWC-DCA62012-DeckGuide-1405.pdf
  29. https://awc.org/span_tables/2024-span-tables-for-joists-and-rafters/
  30. https://awc.org/publications/2024-design-values-for-joists-and-rafters/
  31. http://www.ce.memphis.edu/7119/pdfs/fema356/ps-ch08.pdf
  32. https://www.fpl.fs.usda.gov/documnts/fplgtr/fplgtr59.pdf
  33. https://codes.iccsafe.org/s/IBC2021P1/chapter-23-wood/IBC2021P1-Ch23-Sec2306.3
  34. https://codes.iccsafe.org/s/IBC2024P2/chapter-23-wood/IBC2024P2-Ch23
  35. https://www.fpl.fs.usda.gov/documnts/pdf1992/wolfe92a.pdf
  36. https://ascelibrary.org/doi/10.1061/%2528ASCE%25291084-0680%25282004%25299%253A1%252844%2529
  37. https://www.aisc.org/architecture-center/engineering-basics/lateral-systems/
  38. https://www.huduser.gov/PORTAL//Publications/PDF/earthqk.pdf
  39. https://scholarsmine.mst.edu/cgi/viewcontent.cgi?article=1016&context=ccfss-aisi-spec
  40. https://www.fpl.fs.usda.gov/documnts/fplgtr/fplgtr190/chapter_17.pdf
  41. https://web-media.awc.org/wp-content/uploads/2021/11/17210927/lumber.pdf
  42. https://web-media.awc.org/wp-content/uploads/2021/12/17210650/WDF-2003-CodePrescribedLimits-0501.pdf
  43. https://mtcopeland.com/blog/house-framing-basics-types-terms-and-components/
  44. https://www.thisoldhouse.com/foundations/21015557/from-the-ground-up-framing
  45. https://publications.gc.ca/collections/collection_2008/nrc-cnrc/NR25-2-45E.pdf
  46. https://eyeonhousing.org/2023/08/wood-framed-home-share-increased-for-three-straight-years/
  47. https://buildingscience.com/documents/insights/bsi-033-evolution
  48. https://www.gutenberg.org/files/61880/61880-h/61880-h.htm
  49. https://www.constructionknowledge.net/public_domain_documents/Div_6_Woods_Plastics/Partial%20Carpentry%20pdfs/Rough_Framing_Army_FM5-426.pdf
  50. https://up.codes/s/bracing
  51. https://www.nps.gov/orgs/1739/upload/preservation-brief-41-seismic-rehabilitation.pdf
  52. http://watsonmetals.com/wp-content/uploads/2023/08/Post-Frame-Building-Handbook.pdf
  53. https://web-media.awc.org/wp-content/uploads/2021/12/17210720/AWC-DCA5-PostFrameBuildings-1012.pdf
  54. https://clearybuilding.com/news/history-of-the-pole-barn/
  55. https://www.asce.org/publications-and-news/codes-and-standards/asce-sei-7-22
  56. https://www.fpl.fs.usda.gov/documnts/fplgtr/fplgtr113/ch05.pdf
  57. https://codes.iccsafe.org/s/IBC2018P6/chapter-23-wood/IBC2018P6-Ch23-Sec2303.1.9.2
  58. https://www.fpl.fs.usda.gov/documnts/fplgtr/fplgtr190/chapter_05.pdf
  59. https://www.fpl.fs.usda.gov/documnts/fpl_gtr275.pdf
  60. https://fsc.org/en/businesses/construction
  61. http://www.synthmind.com/miscpub_6409.pdf
  62. https://swansongroup.biz/wp-content/uploads/2024/09/APA-Engineered-Wood-Construction-Guide-E30.pdf
  63. https://www.bc.com/ewp/boise-glulam/
  64. https://www.weyerhaeuser.com/woodproducts/engineered-lumber/resources/sizing-table-lookup/
  65. https://www.apawood.org/
  66. https://www.astm.org/c0645-18.html
  67. https://leff.ca/archive/cold-formed-metal-framing-sizes-steel-stud-framing-sizes/
  68. https://www.buildusingsteel.org/build-using-steel/cold-formed-steel-framing/
  69. https://scholarsmine.mst.edu/cgi/viewcontent.cgi?article=1160&context=ccfss-aisi-spec
  70. https://sfia.memberclicks.net/history
  71. https://www.foxblocks.com/blog/metal-studs-vs-wood-studs
  72. https://www.concrete.org/publications/aci318
  73. https://jonochshorn.com/structuralelements/book/5.01-material-properties.html
  74. https://www.cement.org/cement-concrete/applications-of-cement
  75. https://codes.iccsafe.org/content/IRC2024P2/chapter-6-wall-construction
  76. https://www.finehomebuilding.com/project-guides/framing/anatomy-of-a-load-bearing-wood-framed-wall
  77. https://www.nachi.org/gallery/framing-2/door-and-window-framing
  78. https://www.apawood.org/advanced-framing
  79. https://www.finehomebuilding.com/2002/07/01/framing-curved-walls
  80. https://www.energy.gov/eere/buildings/articles/advanced-framing-systems-and-packages-building-america-top-innovation
  81. https://codes.iccsafe.org/content/IRC2024P2/chapter-5-floors
  82. https://www.homedepot.com/c/ah/floor-joist-spacing/9ba683603be9fa5395fab901b3da028f
  83. https://www.umass.edu/bct/publications/articles/the-evolution-of-engineered-wood-i-joists/
  84. https://www.woodworks.org/wp-content/uploads/seaoo_2012_conference_design_of_wood_floors_to_mitigate_floor_vibration_problems.pdf
  85. https://www.finehomebuilding.com/2024/09/05/how-far-can-deck-joists-cantilever
  86. https://codes.iccsafe.org/content/IRC2024P2/chapter-8-roof-ceiling-construction
  87. https://www.structuremag.org/article/code-requirements-for-residential-roof-trusses/
  88. https://codes.iccsafe.org/content/IRC2024P2/section-r802-wood-roof-framing
  89. https://books.byui.edu/construction_estimat/chapter_09_framing_p
  90. https://codes.iccsafe.org/content/IRC2024P2/chapter-9-roof-assemblies
  91. https://www.fema.gov/sites/default/files/documents/fema_p-2181-fact-sheet-3-3-1-roof-systems-sloped-roofs.pdf
  92. https://www.projectmercybaja.org/wp-content/uploads/2020/09/project-mercy-baja-e-rafters-and-roof-structure-for-reference-only.pdf
  93. https://www.woodworks.org/learn/off-site-panelized-construction/modular-construction/
  94. https://www.mdpi.com/2075-5309/15/12/2020
  95. https://www.futuremarketinsights.com/reports/modular-prefabricated-construction-market
  96. https://proddrupalcontent.construction.com/s3fs-public/SMR1219_Prefab_2020_rev_9-29.pdf
  97. https://www.mckinsey.com/industries/engineering-construction-and-building-materials/our-insights/putting-the-pieces-together-unlocking-success-in-modular-construction
  98. https://www.modular.org/2023/12/26/how-modular-construction-leads-to-zero-waste-and-eco-fficiency/
  99. https://www.iccsafe.org/products-and-services/standards/is-osmc/
  100. https://www.woodworks.org/resources/tall-wood-buildings-in-the-2021-ibc-up-to-18-stories-of-mass-timber/
  101. https://www.fpl.fs.usda.gov/documnts/pdf2012/fpl_2012_dagenais001.pdf
  102. https://www.marketdataforecast.com/market-reports/cross-laminated-timber-clt-market
  103. https://www.researchgate.net/publication/393191289_Carbon_reduction_strategies_with_steel-CLT_hybrid_structures
  104. https://parallax.aisc.org/sustainability.aspx
  105. https://arpa-e.energy.gov/programs-and-initiatives/search-all-projects/maximizing-carbon-negativity-next-generation-bamboo-framing-materials
  106. https://www.archdaily.com/993348/low-carbon-strategies-insulated-panels-for-energy-efficient-envelopes
  107. https://www.archpaper.com/2025/06/31-story-mass-timber-tower-in-milwaukee/
  108. https://www.mdpi.com/1996-1944/18/1/201
  109. https://skyscraper.org/tall-timber/
  110. https://www.structuremag.org/article/groundbreaking-tall-mass-timber-construction-types-included-in-2021-ibc/
Add your contribution
Related Hubs
User Avatar
No comments yet.