A fair amount of construction projects require components to be “Seismic Certified.” A Seismic Certification ensures the component will withstand and operate after an event such as an earthquake. In addition to requiring structural components to meet specific seismic regulations, most jurisdictions also require non-structural components – including electrical systems – to be “Seismic Certified.”
Seismic requirements are defined by the International Building Code 2018 and the California Building Code (2019). ASCE 7-16 is the base standard for many building codes, and is referenced by both IBC and the CBC.Seismic requirements are defined by the International Building Code 2018 and the California Building Code (2019). ASCE 7-16 is the base standard for many building codes, and is referenced by both IBC and the CBC.
OSHPD, the Office of State-wide Health Planning and Development, requires actual “shake-testing” of products prior to allowing products to be specified for construction or retrofit projects anywhere in the state of California. This testing must be reviewed by a California state certified structural engineer. Without a widespread nationwide approval process, many other jurisdictions require the OSHPD Special Seismic Certification Preapproval (OSP) for projects.
In earthquake-prone areas, proper design and engineering make sure buildings stay structurally sound during a seismic event. But earthquakes damage more than just piers and beams, so it’s important to protect a building’s nonstructural components, including the mechanical, electrical, plumbing, and fire protection systems (sometimes abbreviated MEP-F). Seismic protection for ductwork, plumbing, and other infrastructure is essential for both financial and life safety reasons.
QRFS explained the code requirements and technologies involved in seismic protection of fire sprinkler systems in our recent series. In this article, we dig into seismic protection issues, technologies, and some code requirements for MEP-F elements, including:
Damaged infrastructure has financial costs in three ways: the expenses of repairing the equipment, cleaning up the damage, and the lost function of the building. Especially in an industrial building, the cost of replacing HVAC, plumbing and other piping, electrical systems, and fire sprinkler systems can exceed the cost of the entire structure.
The secondary damage alone—water damage from broken pipes, chemical spills, a fire caused by exposed wires and ruptured natural gas lines, etc.—can create an enormous financial impact. And broken nonstructural elements can render the building completely useless. Without plumbing, ventilation, electricity, and fire protection, it’s difficult to do any work. And the authority having jurisdiction (AHJ) may shut the building down when enforcing building and life safety codes.
Earthquake damage to MEP-F components also threatens safety. The increased risk of fire (caused by broken electrical equipment or ruptured gas lines) combined with nonfunctional fire suppression systems is one example of this. Unsecured heavy equipment—for instance, a fan in the ductwork—can fall, creating another major hazard. Even HVAC can be essential to life safety, such as when it is needed to clear away smoke or provide hospital ventilation. Piping systems may transport hazardous materials, and containment failure is especially dangerous.
On the topic of seismic protection, building codes and emergency management organizations—most notably, the Federal Emergency Management Agency (FEMA) and the International Building Code (IBC) defer to one authority—the American Society of Civil Engineers (ASCE). ASCE’s standard, Minimum Design Loads for Buildings and Other Structures (ASCE 7, 2010 edition), gives instructions for the seismic protection of nonstructural elements.
One area where ASCE 7 sets the standard is determining when a structure and its infrastructure need seismic protections. Obviously, not all buildings need to be protected from earthquakes.
ASCE 7 groups buildings (and their nonstructural elements) into seismic design categories (SDC). These categories range from A to F (A having the least concern and F the most) and take into account anticipated ground acceleration (obtained from US Geological Survey maps) and occupancy category. The occupancy category ranges from I to IV and describes, in ascending order, the risk to human life in the event of a structure’s failure. Category IV buildings offer emergency services (police, fire, and medical) and require the greatest protection because they must remain operational after an earthquake.
You shouldn’t need to hunt for the anticipated ground acceleration, occupancy category, or seismic design category of your building. These values will likely be available in your engineering plans or from the authority having jurisdiction (AHJ; often, the local building department).
Determining when seismic protections are needed is ultimately up to the AHJ. FEMA’s Recommended Seismic Provisions for New Buildings and Other Structures (FEMA P-749) offers some guidance, however: “Critical nonstructural components must be provided with seismic restraint” for buildings in seismic design category C. For categories D through F, stricter recommendations are made, including that essential life safety components be able to function after an earthquake.
ASCE also assigns importance factors (Ip) to different equipment. Simply put, the importance factor reflects how serious the failure of that equipment would be. HVAC equipment designed to clear away smoke, backup generators in a hospital, and pipes carrying hazardous materials would all have higher importance factors. Normal plumbing pipe in a Category IV building would also have a high importance factor since the structure will need a water supply to remain operational.
In load calculations, the importance factor acts as a multiplier, requiring stronger protection as the value increases. Importance factor also influences whether specific equipment needs seismic protection.
The core purpose of seismic bracing is to restrict horizontal shaking from an earthquake. All seismic braces firmly attach equipment to structural members of a building so that they move with the structure during an earthquake. This prevents the equipment from tipping over, falling from where it is suspended, or colliding with other objects.
Seismic braces must be able to withstand and resist the expected seismic forces in their area. The magnitude of the seismic forces (in other words, how much the equipment will shake) depends on two things. Remember the formula F=ma; force equals mass times acceleration?
Equipment experiences a bigger force the more it weighs, and the greater the ground acceleration. Determining the functional weight and the ground acceleration, though, is easier said than done. ASCE 7 gives detailed instructions and coefficients for the calculations. All components—brace material, hardware, the structure, and the equipment itself—must be able to withstand these seismic forces.
Where the seismic bracing strategy is concerned, MEP-F equipment fits into two general categories: heavy equipment and conduits. The strategy for bracing equipment in either of these categories is principally the same, whether it’s electrical, piping, or HVAC components.
Industrial HVAC and electrical systems are expansive, and they involve some large and heavy pieces of equipment. Examples include:
ASCE 7 requires “mechanical components” (which includes most HVAC equipment) with an Ip greater than 1.0 to be secured against seismic forces (section 13.6.3). It makes the same requirements for electrical equipment (section 13.6.4).
In practice, this means securing them to structural members so they can’t move. As FEMA’S Installing Seismic Restraints for Mechanical Equipment (FEMA 412) and Installing Seismic Restraints for Electrical Equipment (FEMA 413) outline, heavy equipment like this can be installed in several ways, including:
In an earthquake, equipment sitting on a surface (no matter how heavy) can shake, wobble, and tip over. The hangers for suspended equipment can experience significant stress during an earthquake because of shaking, and the equipment itself may deform, collide with other objects, or fall from its mounting point. To prevent damage—by ensuring that the equipment moves with the building during an earthquake and can’t shift or tip over—seismic bracing is necessary. As FEMA 412 and FEMA 413 explain, this can involve:
Vibration isolation systems may also be used to dampen the effects of shaking on equipment. These commonly take the form of heavy-duty springs.
Conduits, including HVAC ductwork, piping, and electrical conduits and raceways, may also require seismic bracing. ASCE 7 says that:
Any system, whether it meets these specific requirements or not, needs seismic bracing in Occupancy Category IV buildings, where the failure of a system renders the building unusable.
When ductwork, electrical conduits, and piping are hung from the ceiling (whether by rods or trapeze supports), seismic bracing is used to resist horizontal forces. The bracing protects the equipment and its hangers (often threaded rods or trapeze supports) from lateral (perpendicular to the run of the conduit) and longitudinal (parallel to the run of the conduit) shaking.
Seismic bracing in these cases consists of tension-based cable braces or rigid steel braces.
Cable seismic braces link part of the conduit system to a structural member. To resist motion in two directions, opposing cable braces are needed.
Rigid steel braces perform the same job as cable braces, but only one length of steel is needed. Rigid braces are, however, limited in length, and they won’t fit in certain areas and set-ups. Thus, cable braces are a far more flexible option, as they can be used just about anywhere. FEMA 412 also shows cable and rigid bracing used in conjunction with rod stiffeners and vibration isolation systems.
You can learn about the principles and technologies of seismic bracing in our article on bracing for fire sprinkler systems. For more information on specific design considerations (including load calculations) for seismic bracing, check out our other blog on the subject. Keep in mind, though, that the specific requirements and calculations for fire sprinkler systems are dictated by the National Fire Protection Association (NFPA); other systems have different requirements and standards.
Seismic bracing is not the only element of seismic design. When different floors or wings of a building (or two independent buildings with shared utilities) move differentially (relative to one another), it can cause damage to conduit materials passing through the joints. The same problem can arise when a piece of equipment—e.g., a boiler or fan—is braced to the structure. Conduit materials—piping, ducting, etc.—connected to that equipment can experience stress from this differential movement.
In any of these cases, flexible design may be necessary. The techniques of flexible design for all kinds of MEP-F equipment are outside the scope of this article, but you can read more about the principles in our piece on flexible protections for fire sprinkler pipe.
HVAC, electrical systems, and piping each have some unique challenges that must be taken into account when designing seismic protections.
For the most part, heavy HVAC equipment and ducting are distinct, though linked, equipment. However, ducting may be connected to in-line heavy equipment (fans, humidifiers, etc.). ASCE 7 (section 13.6.7) requires equipment weighing 75 pounds or more that is installed in-line with ducts to be laterally braced independently of the ducts. In other words, such equipment needs dedicated bracing—duct bracing cannot do double-duty.
Electrical components with an Ip factor greater than 1.0 must be protected against seismic forces, according to ASCE 7 (section 13.6.4). Heavy electrical equipment, as FEMA 412 shows, can be secured against movement in much the same way that HVAC equipment can. However, ASCE 7 (section 13.6.4) mentions some special protections needed for electrical equipment, including the following:
Pipe networks may require seismic protection. Besides water, pipes transport many substances throughout buildings, especially in industrial and healthcare settings. These substances can be under high pressure (15 pounds per square inch or more) or not under high pressure (less than 15 psi). They also may or may not convey hazardous materials (toxic, flammable, explosive, etc.) that require containment.
As explained by Reducing the Risks of Nonstructural Earthquake Damage – A Practical Guide (FEMA E-74), HAZMAT piping has Ip=1.5 and requires seismic protection. Pressure piping requires bracing.
The failure of non-HAZMAT, non-pressure piping mainly threatens property, so it may be exempt from seismic protection requirements—but not necessarily. One case where non-pressure pipe needs protection is piping in Occupancy Category IV buildings, where the failure of water lines, for instance, renders the building unusable.
The main complications in applying braces to pipe are in-line pumps and valves (such as large cast-iron valves) in high-pressure systems. These components can be very heavy, and FEMA E-74 gives a few special requirements for their protection:
HVAC, electrical, and piping systems may need seismic protection if a building is in a specific seismic design category, and ASCE assigns the equipment a high importance factor (Ip). The failure of these systems in an earthquake can mean huge financial costs, not to mention the loss of life. The basics of seismic protection are simple:
The specifics, though, are very complicated. You need to calculate the seismic loads, expected displacement, the strength of your braces cable or members, the number and placement of the braces, the limits of the hardware, the strength of the structure, and more.
Many industry standards and codes govern seismic protection for nonstructural components. ASCE 7, the International Building Code (IBC), and various FEMA publications have already been named. Beyond these, you may need to refer to:
Other standards and documents may apply. Local building codes and authorities having jurisdiction will have the final say on which standards, listing requirements, and other mandates may apply.
Make sure to consult with your AHJ—often, the local building department—to verify how much protection is required in a structure.
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