12 Examples Applications of Post Frame

Post frame works great for retailers needing large glass facades.

Windows and doors in a post-frame building that are narrower than the post spacing typically do not require structural headers, since roof trusses/rafters in most post-frame buildings bear directly on the posts. Elimination of structural headers enables elimination of trimmer studs (a.k.a. jack studs, shoulder studs) and other special structural members required to support the headers.

Removing headers and their supports not only saves money, but results in an enhanced thermal envelope when framing members are replaced with thermal insulation. Additionally, fewer framing members mean fewer cracks for air infiltration.

Mini-warehouses (figure 1) and service garages typically have several equally-spaced and equally-sized overhead doors making them ideal candidates for post frame. In these buildings, posts are often used to frame both sides of the doors.

Replace the doors in a mini-warehouse with large glass panels, and you can understand why post frame is also ideal for retail stores with large glass facades like that shown in figure 2. In general, any building with large, regularly-spaced door and window openings is an ideal candidate for post frame (figure 3).

Figure 1: The numerous, equally-spaced overhead doors of mini-warehouses are ideal for post frame.

Figure 2: Large, equally spaced windows are well-suited for post frame.

Figure 3: Post frame easily accommodates the size and relative location of door and window openings in this building.

Mechanically- and glue-laminated posts (figures 4 and 5, respectively) are used in the vast majority of today’s post-frame buildings. These posts enable the construction of buildings with relative large floor-to-ceiling heights at prices much less than they could be fabricated with a comparable wood stud wall.

Laminated posts can be fabricated to any length by splicing shorter pieces of wood together. Laminated posts are also straight and inherently more stable because of the laminating process. The only way to get a tall, relatively straight wall with wood studs is to use more expensive, engineered lumber products (e.g., laminated strand lumber, parallel strand lumber).

As wall height increases, bending moments in the wall’s vertical framing elements increase. This increase is not minor. Bending moments induced by uniformly-applied loads increase with the square of the unsupported length of a member. This means that a 20-foot wall stud is subjected to a bending  moment that is four times greater than that for a 10-foot wall stud with the same on-center spacing.

Laminated posts are able to deal with increases in bending moment more effectively than solid-sawn posts. This is because weak areas in one layer of a laminated assembly are supported by adjacent layers — layers with a low probability of having a weakness at the same location. This support of  weak areas in one layer by the adjacent layers gives rise to the phenomena of load sharing. Load sharing is very important in any area of a laminated assembly in which there is a butt joint between two members. Because of load sharing, the design strength of a laminated assembly is greater than the summed total of its individual layers prior to lamination.

The increased bending moments associated with taller walls may be handled by using higher grade lumber or with larger vertical wall framing elements. Another option is to reduce the spacing of the framing elements so that each element is subjected to less load. These options are easy to  accommodate into post-frame building design. It’s one more reason why they get the nod over other framing systems in tall wall applications.

The cost advantage that post-frame buildings hold over low-rise steel frame buildings generally starts to disappear once minimum floor-to-ceiling heights move beyond 20 feet. Below these heights, post-frame holds thermal insulation advantages, if not cost advantages, over steel frame structures. This has made post-frame very popular for storage facilities such as the airplane hangar in figure 6.

It is not uncommon for the required length of vertical wall framing elements to be significantly different in  various locations within a building. Where such length variations occur, structural requirements for the longer elements generally control framing/support system selection. Significant wall framing length variations most commonly occur in the endwall framing of wide buildings with sloped ceilings (the dairy freestall barn in figure 7 is one such example). Not surprisingly, the endwalls in many of these buildings are post-frame.

Buildings whose only purpose is to provide protection from precipitation and/or solar radiation are generally fabricated with one or more open sides. This would include many commodity (e.g. fertilizer, lumber, feed) storage buildings, animal shelters, and park and other recreational shelters. Open sides facilitate quick building access, which can translate into significant cost savings when handling stored materials.

Unless a unique structural support system has been employed, expect the roof above an open wall to be supported by posts with an on-center spacing of 8 or more feet. Since these posts are seldom laterally  supported between their base and crown, they must be designed to resist buckling equally in all horizontal
directions. For this reason they tend to be round poles, square solid-sawn timbers, or square glulam or parallel-strand lumber members. Nail-laminated posts will typically require the addition of face plates to obtain relatively equal bending strength in all horizontal directions.

Wood posts in open-front buildings are often preservative-treated because of their direct exposure to “the elements.” However, in situations where wood posts are supported on concrete piers or walls and fairly well  protected from precipitation with a roof overhang, preservative treatment may be unnecessary.

Component connections are critical to the structural integrity of a framing system. In buildings with large, clearspan wood trusses, the most critical connections are those between the truss and its supports. In addition to gravity-induced forces (a.k.a. bearing loads), these connections must resist shear forces acting perpendicular to the plane of the truss and uplift forces due to wind. Depending upon overall building design,  connections may also be required to transfer bending moment.

Wood posts enable the fabrication of strong, direct, yet inexpensive connections between large trusses and walls. Exact details for post-to-truss connections vary from designer to designer, and may be influenced by post type. Solid-sawn timber and glulam posts are generally notched to form a truss bearing surface. The truss is rested on notches and bolted into place. A special plate/bracket like that shown in figure 12 may be added to increase connection load transfer capabilities. With mechanically-laminated posts, the truss may rest on a shortened outer-ply or on a shortened inner-ply. The later scenario, which is shown in figure 13, places the
bolts in double shear and is a very effective connection.

Stilt buildings are among the least expensive options when building in floodplains, over very poor soils or water, on very steep terrain, and in regions of high snowfall..

Stilt buildings fall into two categories: those with stilts that only support sill plates and floor headers, and those with stilts that connect to both roof and floor framing. The latter are essentially post-frame buildings with wood-framed floors. Exactly how a post-frame stilt building would be detailed depends largely on desired floor, wall and ceiling finishes as they control the spacing of structural frame components.

Spacing of posts used to support a building’s porch, roof overhang and/or arcade (an arcade is a walkway at the edge of a building that has a cover supported by posts) is generally in the 6 to 10 foot range regardless of the building’s structural framing/support system. Given that this spacing is typical of the post spacing in most post-frame buildings, there are benefits to using a post-frame building system anytime a building features a relatively long post-supported porch, roof overhang or arcade.

First, it increases the likelihood that all building support elements will be on similar footings. This speeds construction and minimizes the likelihood of differential settlement. Second, posts used to support a porch, roof overhang or arcade may be aligned with — and then connected via — rafters to posts in the exterior wall to form a more efficient structural frame.