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Exploring Load-Bearing Walls: Identifying Signs and When to Consult a Licensed Engineer

In this section, we delve into the world of load-bearing walls. Discover key indicators to determine whether a wall is load-bearing or not, and learn when it's wise to seek the expertise of a licensed engineer.

Load-Bearing or Non-Load-Bearing Walls: A Vital Decision

Many houses were constructed with an abundance of walls, which may not align with modern preferences. These walls often restrict and segment living spaces, and in today's world, larger kitchens with islands are becoming the norm. One solution to these challenges is removing walls to create open-concept layouts.

However, determining whether a wall is load-bearing or not can pose a significant challenge. If a wall is load-bearing, the next steps become crucial.

Here are some insights for our readers:

Load-Bearing Wall Identification: Identifying whether a wall is load-bearing is essential. Even though people might assume it's easy by following the joist orientation, it's worth noting that a wall can still be load-bearing if it supports the floor from two floors above, especially when there are changes in joist direction, like in a third-floor "attic space."

Installing a Load-Bearing Beam: If a wall is confirmed to be load-bearing, the recommended course of action is to replace it with a load-bearing beam. This beam should be meticulously designed to support a continuous span, ensuring both strength and minimal deflection. It must effectively carry the load from upper levels, then transfer it to the lower support system while maintaining the proper load path. Furthermore, it's crucial to determine if any reinforcements are necessary on the lower levels.

Involving a Structural Engineer: Typically, this process requires hiring a structural engineer to evaluate, calculate, and provide stamped drawings for permit application. Such changes are considered structural modifications, and most jurisdictions mandate permits, stamped drawings, and the involvement of a licensed and qualified contractor to perform the work.

Making the distinction between a load-bearing and non-load-bearing wall may seem straightforward when following joist orientation, but it can be more complex in practice. Walls parallel to joist layouts can still be load-bearing, especially when supporting floors from multiple stories above, especially in cases where the joist direction changes, as in third-floor "attic spaces."

If you're facing such decisions or need assistance with structural modifications, don't hesitate to reach out to professionals who can guide you through the process.

Important Considerations During the Process:

1. Adding Heavier Loads: It's crucial to remember that when incorporating a heavier load, like an island in the kitchen, you must ensure that the floor below can adequately support the additional weight. In many older homes, the joists often span beyond the current standard by 1 or 2 feet. This can lead to a significant sag, which may not become apparent until several months or even up to a year after construction is completed.

2. Load-Bearing Beams: When installing a load-bearing beam, it's essential to verify that your support posts are designed correctly. Properly engineered posts are equally important in transferring the load. Depending on the design load or weight of your beam, using two 2x4s may not be equivalent to using a single 4x4.

3. Inspecting Old Wood Beams: Lastly, it's crucial to inspect older, potentially fatigued wood beams in your basement. Ensure that the point load added from a single post above does not exceed their capacity. This becomes especially critical if your basement is damp and lacks humidity control. While you may not be changing the overall load, you are redistributing it to specific parts of the beam's span.

For further assistance or inquiries, please don't hesitate to call us at 724-949-0004.

Visit our website at www.pittdes.com.

Written by Firas Abdelahad, P.E.

Firas Abdelahad has been a practicing structural engineer since 2005, collaborating with a diverse range of professionals, including consultants, architects, investors, homeowners, contractors, and subcontractors. Together, they tackle the various challenges that can arise during the design and construction phases of projects.

The information and statements in this document are for information purposes only and do not comprise the professional advice of the author or create a professional relationship between reader and author.

With winter storm warning into effect for our region, it is important to bring to your attention the potential snow loads impact on roof structures.

Snow loads on roofs can vary by state, location (depends on topographic factors), elevations, ground snow load, insulation, roofing materials, pitch and many other directly or indirectly related factors like drifting, wind, etc.

Pictures below from FEMA document “snow load Safety Guide”

https://www.fema.gov/media-library-data/7d8c55d1c4f815edf3d7e7d1c120383f/FEMA957_Snowload_508.pdf

It is important for homeowners and/or property managers to develop a routine maintenance plan to inspect their roof structure after a heavy snow fall especially for older structures or If your structure was renovated or you know that it had structural elements upgraded, replaced and or changed with no permits or stamped drawings to document that the modification was reviewed by a licensed engineer.

Potential issue:

We have seen a fair share of modification to roof structure to convert a conventional roof structure (rafters and joists) to a cathedral ceiling style with no proper reinforcement to reduce the thrust on side walls. Heavy snow fall will put these kinds of modification to test when roof will experience heavier load, hence some cracks may start developing as a result of the improper modification to the roof structure.

Local Snow Requirement for City of Pittsburgh:

City of Pittsburgh modified/amended code requirement for ground snow load to be 30 pound per square foot.

When calculating flat roof snow load following ASCE7-10 formulas, tables to select exposure factor Ce, thermal factor Ct, importance factor Is:

Pf=0.7*Ce*Ct*Is*Pg= 0.7*1*1*1*30=21 psf (pound per square foot)

Snow load on sloped roof, Ps, will be a factor of the flat roof snow: Ps=Cs*Pf

Roof slope factor, Cs, values can be determined from Sections 7.4.1-7.4.4 (ASCE7-10) for warm, cold, curved and multiple roofs.

It is important to bring to your attention Partial Loading, unbalanced roof snow loads, drifts on lower roofs, roof projections and parapets, rain on snow surcharge as other effects as explained in ASCE7-10

Please consult with your structural engineer for more information and clarification. This document is not intended to summarize the section of the code/standard (IBC2015/ASCE7-10) nor it is sufficient to use to complete your own snow load calculations without referring to the referenced documents and having it reviewed a licensed engineer.

Pittsburgh Design & Engineering Services LLC can assist you with your snow load calculations or any other structural engineering needs at your request.

#structuralengineer #snowload #roofstructure #realestate #pittsburgh

Written by Firas Abdelahad, P.E.

Firas Abdelahad has been a practicing structural engineer since 2005, collaborating with a diverse range of professionals, including consultants, architects, investors, homeowners, contractors, and subcontractors. Together, they tackle the various challenges that can arise during the design and construction phases of projects.

The information and statements in this document are for information purposes only and do not comprise the professional advice of the author or create a professional relationship between reader and author.

Please note that as code changes some information may not be current on this post.