Amber Book - PDD Flashcards
Why would you fill a hollow CMU?
Grout: easy-flowing cementitious material poured into a CMU wall from the cavity openings in the top every four feet as the wall goes up. Used for compressive strength, horizontal rebar and vertical rebar added for tensile strength. Used for load-bearing walls (including those that resist seismic). See here to learn more.
Hollow: CMU cells with air are better insulators than grout-filled, but obviously weaker than grout-filled reinforced block.
Vermiculite-filled: loose granular mineral stuff poured into the cavities for increased thermal resistance, increased sound transmission loss, and improved fire rating (performs better than air in all three). In older construction, vermiculite may contain asbestos.
Perlite- filled: loose granular stuff poured into the cavities; looks like small packing peanuts, if small packing peanuts were made from stone. The process for making perlite: volcanic glass is mined, then heated until it pops like popcorn, so it has tiny air pockets each of which is a good insulator. Used for increased thermal resistance (slightly better than vermiculite and meaningfully better than air).
Polystyrene bead insulation: Styrofoam beads poured into the top of a CMU wall. Used as insulation.
Injection-foam-filled: increased thermal resistance (insulation). Can be injected from either the inside or the outside and doesn’t need to be poured in from the top so it can be used in renovations where the top of the wall is not accessible. Vermiculite, perlite, and polystyrene beads pour out of the wall like sand if you need to cut into the blocks for any reason after they’ve been filled. Injection-foam-filled CMU doesn’t have this problem. Plus with vermiculite, perlite and polystyrene beads, you don’t really know if the granules have made it down to all the cavities below (what if there was a clump or obstruction and some of the cells went unfilled?). Here, foam is injected into multiple holes in the wall, so you know each cavity is filled. These closed-cell foams also serve as an air barrier.
In an earthquake, overhead ducts and pipes are subject to unpredictable swaying that may lead to failure, especially when the rod that supports them is long and slender. Ducts and pipes therefore must be braced in both the transverse and longitudinal dimensions. In seismic zones, transverse bracing perpendicular to the direction of the flow, is required on each end of a run.
See Image
Longitudinal bracing parallel to the flow is required once per run (each section of straight duct or pipe, between elbows, is considered a run). Especially long runs may require additional lateral bracing.
image
Duct and pipe bracing detailing
To prevent sway in an earthquake
Materials with high embodied energy
Manufactured with high heat:
Ceramics
Glass
Stainless or galvanized steel
Concrete (but, because of its weight, can look on tables like it has low embodied energy when measured on a per-kilogram basis)
Manufactured with intense chemical processes and petrochemical use:
Epoxies/Resins/Formaldehyde/many adhesives
Paints and stains
Foam insulation (polystyrene, spray-foams, polyisocyanurate)
Plastics/Vinyl/PVC/melamine/polycarbonate
Engineered wood products (MDF, Glue-lam)
Manufactured with intense mining processes:
Copper
Aluminum
Stone
Materials with low embodied energy
Cellulose and glass fiber insulation
Wood (depends on what powers the kiln and whether you include the loss of the carbon-removal capabilities of the tree that was cut down)
Gypsum board and plaster
Rammed earth
*note that a given manufacturer can easily greenwash here by measuring embodied energy per weight (concrete looks better because it is heavy), per square foot (vinyl looks better because it is thin), or per volume (foam insulations look better because they’re big). The most legit data I’ve found is from the University of Bath and can be accessed at https://drive.google.com/file/d/1_R9HEBppxEy5tJOUN3nFCSstM2p9NR8c/view.
What type of rubber should your gasket be made of?
Natural Rubber: Strong but breaks down quickly in sunlight
Styrene-Butadiene rubber (SBR): less expensive but not as strong nor resilient over prolonged pressure
EPDM: most water resistant (also used as roofing membranes), resistant to abrasions and tears, stands up to weathering and breakdown from sunlight exposure, and maintains resilience over prolonged pressure.
Silicone: Also resists breakdown from sunlight exposure and maintains resilience over prolonged pressure. Has a longer lifespan than EPDM, more stretchy, and much better in locations where it might get hot (EPDM can fail at 130 degrees).
Each rubber breaks down when it gets too hot and each becomes brittle when it gets too cold.
What is the difference between a curtain wall and storefront?
Curtain wall: glazing system hangs like a curtain to create the exterior skin of a building, outboard of the floor slabs. Often multiple stories tall (multi-span); higher design wind pressures. More expensive
Storefront: aluminum and glass framing system that sits inboard of floor slabs. One story (single span) max, often for the first floor only in commercial construction. Less expensive.
Crews erect and glaze both on site; curtain wall can be unitized in the shop and field-erected. Either one can be reinforced with steel In the framing cavity if loads are excessive.
Mullion detail
Gaskets provide the thermal break; glass-to-aluminum clearance provides the spacing needed for seismic shifting.
How do we reinforce storefront window frames?
With steel enclosed in the aluminum, when structurally necessary.
Draw a window section detail for a masonry wall
For masonry wall
Draw a window section detail for a stick-built wall
For stick-built wall
Draw a vertical shaft wall detail in stick-built wall construction
Vertical shafts are required for ducts, pipes, conduits, etc. traveling from floor-to-floor; and for elevators and stairwells. Because if compromised they could easily spread fire and smoke from one floor to the floors above, they require a significant fire rating, necessitating construction of concrete, concrete block, or as many as five layers of especially-fire-resistant gypsum board in plan (“type X” gypsum board or “type C” gypsum board”). Penetrations, are minimized, and detailed to maintain the required fire rating (often two- three- our four-hour rated). Mechanical shafts are often non-load-bearing. The plan detail is below.
Because the fire protection must be maintained continually up the shaft, and builders may have difficulty screwing gypsum board to the inside face of the shaft wall when building from the room outside the cavity, we’ve developed techniques to affix fire-rated “gypsum liner” panels on the inside of the cavity wall from outside of the shaft. See this video.
See this video too if you’re still not sure how this works.
Expansion joint detail vs a control joint detail
A control joint is a shallow groove in concrete to control cracks from shrinkage.
Cutting a control joint with a saw (scoring one, really):
Relish the drawing of necessary control joints, because if you don’t lay them out, someone else will do that task poorly. Note that this curb cut control joint almost–but not quite–aligns with the 16-square brick pattern.
Expansion joint detail vs a control joint detail
An expansion joint extends the full depth of the building assembly, creating two independent structural elements. When part of the building expands, it won’t push on the other. The gaps between the elements are filled by a squishy material (bitumen, fiberboard).
*Important for CE exam as well.
ADA-compliant room name signs: what height above the floor?
An ADA sign might denote that there is an exam room just on the other side of a door. Installation height: Max 60” to top line of tactile text; Min 48” to bottom line of tactile text; anywhere in between is okay.
ADA-compliant room name signs: location
Location: Latch side of single door; inactive leaf of a double door with an inactive leaf; to the right of the right-hand door of a double door with two active leaves; if there is not enough room next to the door, you may place the sign on the nearest adjacent wall.
See this video.
What is a “collector” in seismic design?
The floors and roof of a building form diaphragms, horizontal-resistance membranes important in seismic design that transfer lateral earthquake forces. Collectors (also called drag struts or ties) “drag” diaphragm shear forces from diaphragms to vertical resisting elements. In practice the collectors themselves look like sheet metal brackets or pneumatic shock absorbers that attach the floor of one part of a building to the wall of another.
The component parts of irregularly-shaped buildings (i.e. both wings of an L-shaped building) sway in an earthquake out of phase with one another. Detailing each building part as its own structure, and connecting the parts with ductile metal, employs a “bend but don’t break” strategy, making the joint between the parts less brittle.
What is a “collector” in seismic design look like?
The floors and roof of a building form diaphragms, horizontal-resistance membranes important in seismic design that transfer lateral earthquake forces. Collectors (also called drag struts or ties) “drag” diaphragm shear forces from diaphragms to vertical resisting elements. In practice the collectors themselves look like sheet metal brackets or pneumatic shock absorbers that attach the floor of one part of a building to the wall of another.
***These are also called “drag struts” or “drag trusses” (remember that)
How do you separate floors with different occupancies in mixed use buildings?
IBC Section 508 addresses mixed uses and occupancies. Sometimes different occupancies within a building are considered by the code to be “separated” and sometimes they are considered to be “non-separated.” We achieve separation with a fire-rated wall or floor-ceiling assembly. See the table. The “S” column is used for sprinklered buildings and the “NS” column is for buildings without a sprinkler.
Sometimes there is no fire-rated barrier required by the code to separate different occupancies. This is indicated by an “N” in the cell that aligns with the two different occupancies under consideration. For instance, looking across the first row of the table, there surprisingly appears to be no fire rated separation requirement for a theater (group A-1 “assembly” occupancy) that shares a wall with foundry (group F-2 “factory industrial low-hazard” occupancy), provided that the building is sprinklered. If the building is not sprinklered, there would be a requirement for a one-hour-rated wall. There are of course other, acoustic, reasons why these two spaces shouldn’t share a wall.
Some adjacencies are not permitted no matter how fire-resistant the wall or floor-ceiling assembly is constructed. These have an “NP” in the cell. This is the case with a parking garage (group S-2 occupancy) below a drug detox medical facility (group I-2 occupancy) in a building without a sprinkler system.
What is the difference between internal and external metal roof flashing?
External roof flashing is laid on top of shingles in valleys and along peaks. Internal flashing is installed under the roof shingles. Counterflashing (or cap flashing) is the first line of defense when shedding water off a parapet. It attaches to parapet wall with sealant (to prevent water from penetrating behind the flashing) and laps the step flashing. In high wind applications, use flashing with clips so it doesn’t rip off the wall.
Flashing and sealing where the parapet meets the roof
Flashing and sealing where the parapet meets the roof. The counterflashing allows the roof membrane to be replaced more easily.
Delayed egress locking systems
In retail, these delayed door panic hardware systems prevent shoplifters from running out of the emergency exit because an alarm sounds and the door doesn’t let the perp out of the building for 15 seconds after they lean on the hardware bar (30 seconds when an exception is granted). Delayed egress locking systems can also be used for other security-sensitive applications such as airports, warehouses wary of employee theft, and nursing homes fearful of wandering dementia patients. They are only permitted in buildings outfitted with sprinkler systems or automatic smoke or heat detection. That way, when the automatic sprinkler system, smoke detection system, or heat detection system is activated, the delay in the system that prevents fleeing occupants from immediately exiting is deactivated automatically and occupants can easily leave without waiting in a real emergency. The delay also can be deactivated by a loss of building power or manually by the fire command center. Delayed egress systems are not permitted in occupancy groups
A (assembly): we don’t want the first occupants out of a burning theater to be crushed against a door that won’t open by the panicked pushing of those fleeing behind them.
E (K-12 education): I don’t know if this is school-shooting-related, or, like the assembly exception, related to the potential for crushing and trampling.
H (high hazard): You need to be able to get out of the gunpowder factory without ever waiting 15 seconds.
In each exception, the possible security benefit of the delay is outweighed by the life-safety benefit of easy exit.
In I-2 (detox facilities, psych hospitals) and I-3 (prisons) a second (but not a third) delayed egress door is permitted as part of the egress path.
To see an demonstration video, go here.
Unit cost vs unit-in-place cost
Both these terms, unit cost and unit-in-place cost, mean (just about) the same thing. The “unit cost” usually refers to construction cost estimating during design and bidding and “unit-in-place” is a term usually reserved for appraisers estimating the worth of a building someone is looking to purchase, refinance, insure, or account for in an audit.
The unit cost method estimates building budgets or construction costs by breaking down the project into smaller parts, estimating the cost of each of those parts, then multiplying that unit cost by the number of parts (units) in the project. In early design, the “units” may be square feet of finished space. One might make an estimate by taking a $600 per square foot guess (unit cost) and multiplying that by the 10,000 square feet in the project to reach a budget of $6,000,000. Later in the design process (PDD world) the estimate is based on more detailed information: the linear feet of pipe multiplied by the approximate installed cost per linear feet of pipe, plus the number of faucets times the average price of an installed faucet, plus. . . . and so forth for the rest of the project. These spreadsheets may swell in length.
Unit-in-place cost method does the same thing–separate all the components of a building, estimate the cost of each unit (in cubic feet of concrete, square feet of paint, linear feet of foundation, number of theaters in the multiplex, number of roofs on the campus, or number of exterior doors on the warehouse) and multiply that unit cost by the number of units on the property. . . , then add everything up to reach a total value for a property appraisal.
Name the lock type: door that never locks, like when you need to maintain egress
Passage Latch: The latchbolt is retracted by the lever or knob from either side, always (lever meets accessibility and knob doesn’t, but the knob is drawn here for clarity)
Name the lock type:
- Outside is locked by an inside thumbturn
- Turning the inside lever or closing the door automatically unlocks the outside lever
- If you are locked out, an emergency specialized key can get you back in.
Bath/Bedroom Privacy Lock
Name the lock type:
- A key outside, or inside thumbturn locks/unlocks the outside lever
- The inside lever automatically retracts the latchbolt for egress.
Office and Inner Entry Lock
Name the lock type:
- A key locks/unlocks the room from the outside
- The inside lever automatically retracts the latchbolt for egress.
Classroom Lock
Name the lock type:
- A key locks/unlocks the room from the outside and the key also locks/unlocks the room from the inside
- The inside lever automatically retracts the latchbolt for egress.
Classroom Security Lock
Name the lock type:
- The door is unlocked by a key outside
- The outside lever is continuously locked by 24 volt AC or DC current
- An electrical switch or power failure unlocks the door remotely
- The inside lever automatically retracts the latchbolt for egress.
Electrically Locked (Fail Safe)
Name the lock type:
- The door is unlocked by a key outside
- The outside lever is continuously locked but can also be unlocked by a 24 volt AC or DC current
- An electrical switch unlocks the door remotely, but in a power failure, the remains locked
- The inside lever automatically retracts the latchbolt for egress.
Electrically Unlocked (Fail Secure)
Name the lock type:
- The door is unlocked by a key outside
- The outside lever is inoperative
- The inside lever automatically retracts the latchbolt for egress.
Storeroom Lock
Which type of pipe expands more when hot water flows through it: Metal or Plastic?
Answer: Plastic
Name these valvles
What does this very-heavy dashed line inside the wall mean?
That wall is fire-rated and is part of a life safety strategy of separation to keep the fire contained, for a while, in just one part of a building.
When a duct passes through that rated wall, a smoke damper, electronically tied to the smoke detectors, is required that will choke off the air (and smoke) passing from one side of the rated wall to the other. Gaps in the wall that arise as part of the expediency present in any construction project will need to be filled with appropriate firestop (a putty often red in color) as will penetrations in the wall for conduit, pipe, and ductwork. And the wall itself will either be constructed of a fire-resistant material such as concrete or CMU, or is likely to have multiple layers of gypsum board on each side to achieve a required one-, two-, three-, or four-hour rating.
This example, which is also red in the digitally-submitted CD drawing set, depicts a one-hour rated wall because the number “1” sits between the dashes in the long-dashed line. Were it a three-hour rated wall, the pattern would be dash-3-dash-3-dash. . . This particular wall requires a fire rating (as does the ceiling) because the restaurant is classified as an assembly space and apartments populate the rest of the building, both adjacent in plan and above in section. The short-dashed portion of the red line on the top of the plan denotes a “water curtain,” which is just what it sounds like: close together special sprinkler heads that make a wall of water to maintain the fire separation. Available but atypical, it was required here because, to earn the historic tax credit, an existing portion of the glass vestibule had to remain intact, and because the ramp just plan-north of the water curtain is part of the apartment egress, this ramp has to be fire-separated from the restaurant.
Describe the difference between the following types of specifications:
Performance
Prescriptive
Proprietary (closed)
Proprietary (open)
Reference
Descriptive
Specs may be written in different formats, but are typically written as a combination of the following:
Performance-based specs describe the way the product will perform without calling out a specific manufacturer, for example, “fasteners must be able to withstand a wind load of 110 mph.”
Prescriptive specs describe the construction means and methods, for example, the composition of the concrete mix.
Closed Proprietary specs name the specific manufacturer, and don’t allow substitutions, for example, “CR Laurence Co Double Seal Spacers, in dark bronze and with a dual seal, catalog number 3455590 shall be used at stairwell windows”
Open Proprietary specs also name one product from one manufacturer as the basis for design, but they allow other products as acceptable substitutions. Substitutions are processed through the General Requirements substitutions procedures in Division 01 of the spec set.
Reference specs demand the product or installation meet the requirements laid out by a trade association, government agency, or other industry reference standard, for instance, “Scaffolding must meet requirements as laid out in ANSI ASC A14.2,” or, “Clay brick conservation treatment must meet requirements as established in the National Research Council Canada National Master Specification, section 04 04 21.19.”
Descriptive specs are a hybrid of performance and prescriptive specs. They describe the way the product will perform without calling out a specific manufacturer, but are likely to also include clauses detailing specific means and methods of construction. For instance, a descriptive specification might both establish the strength of the mortar, and establish the water ratio in a mortar mix to be used.
*Often specs fall into more than one of these categories. For instance calling out a specific products and accepting substitutes that meet a standard and prescribing the mean and methods of installation.
What is CSI Masterformat?
Masterformat is a system for organizing construction documents, specs, contracts, and operational manuals. Published by the Construction Specification Institute (CSI), it allows, for instance, a fire sprinkler subcontractor to easily find the relevant sections of a building’s documents so a requirement is less likely to be overlooked when bidding, purchasing a product, or during construction. There are 50 numbered divisions, ranging from Instructions for Procurement (found in Division 01) to Fire Suppression Sprinkler Systems (found in Division 21). Masterformat is especially useful for systematizing spec writing, as specifications may easily reach thousands of pages in length in a medium-sized building project. When using Masterformat—which is typically, though not always, utilized on a medium-sized or large project—know that the table of contents alone is nearly 200 pages! If the drawings are the broad intention of a building, specs act as the fine-print, establishing the scope of the work, the materials and methods of construction to be used, and the quality of the workmanship expected. Spec-writing is important to the project, though tedious. Some firms write their own specs in-house, and others hire a professional architectural spec writer. Once a thriving category of consultancy, human spec writing is now waning, gradually being replaced by digital tools: Google searches or links to product information within a BIM file.
What percentage of light that comes out of the fixtures, actually makes it to the desk height in a classroom?
Given:
2 lamps per fixture
2500 lumens per lamp
Light loss factor (LLF)= 0.60
Coefficient of utilization (CU) = 0.65
24 fixtures in the room
Room dimensions: 20’ x 30’
Foot-candles=(lamp lumens) x (lamps per fixture) x (number of fixtures) x (CU) x (LLF)/(area in sq ft)
A: 39%
Note that I’m not looking for the illuminance in foot-candles, and know that there is more information given than you need to calculate the answer.
Coefficient of utilization (CU), which ranges from 0 to 1, is the fraction of light that reaches the desk plane because of losses as the light reflects off surfaces. So a black room with lots of surfaces will have a lower CU value and a space with minimal white surfaces will measure a higher CU value.
Light loss factor (LLF), which also ranges from 0 to 1, is the fraction of light that reaches the desk plane because of losses from dirt inside the fixture and from the lamp dimming over time through lamp “depreciation.” So a room with a regular lamp wiping regimen and lamps that lose very little light over time will have a high LLF value and a dusty room with lamps that depreciate rapidly will have a lower LLF value.
In this case because the CU=0.65 we are only left with 65% of our light after we account for the reflection off the room surfaces on the way down to the desk. . . And because our LLF is 0.60, we then have only 60% of what is left after adjusting for CU when we account for the light lost in the old lamp and the dirty fixture. So we are looking for 60% of 65% of the light reaching the desk . . . 0.60 * 0.65 = 0.39. That’s our answer: only 39% of the light at the top of the room makes it down to the desk! 61% is lost! It is not uncommon for that much of the light energy to be lost before it reaches the desk.
Wall A has a sound transmission loss (TL) of 60 in the opaque portion and five percent of the surface of the wall is covered by window (TL of 25).
Wall B has a sound transmission loss of 40 for the whole assembly (there is no window in Wall B)
Which will do a better job keeping passing bus noise out of the apartment, Wall A or Wall B?
Wall A has a sound transmission loss (TL) of 60 in the opaque portion and five percent of the surface of the wall is covered by window (TL of 25).
Wall B has a sound transmission loss of 40 for the whole assembly (there is no window in Wall B)
Which will do a better job keeping passing bus noise out of the apartment, Wall A or Wall B?
Answer: Wall B
To calculate Wall A TL
TL1-TL2 = 60-25 = 35, which is the difference between the acoustical performance of the opaque portion of Wall A and the performance of the window portion, given that only five percent of the wall is window.
From nomograph here in red. . .
TL1-TLc = 22, which means that the window knocked 22 points off the TL rating of the composite wall. 60-22=38 so the composite wall is 38, which is FAR lower than the 60 we started with on that wall, even though only 5% of the wall surface is window! It’s almost always about the window, not the wall!
The composite TL of Wall A, then, is calculated at 38.
The TL of Wall B is given at 40, and there is no window.
So Wall B, the one without the window, performs (moderately) better than Wall A, even though 95% of Wall A is so much more robust.
Circuit A is 240 volts and 4000 watts
Circuit B is 120 volts and 500 watts
Which circuit needs a thicker wire? Given:
W=I*V
Answer: Circuit A
W=I*V
Circuit A
4000w = I * 240V
4000w/240V = I
I=17amps
Circuit B
500w = I * 120V
500w/120V = I
I=4 amps
More current (measured in amps and denoted by “I”) needs thicker “pipes” (thicker wire). If the wire isn’t thick enough, it becomes hot and can start a fire. So Circuit A, because it runs with more current, needs a thicker wire.
As an aside, wire thickness—like many metals used in building– is measured in gauge number. . . And counter-intuitively, a lower gauge number translates to a thicker wire.
The pressure in a city water main is 50 psi. The pressure loss through piping, fittings, and the water meter can be ignored for this exercise. What is the height above the water main, above which the water will not flow? Given:
h=2.3 psi
Answer: 115’
h=2.3 P
h=2.3 * 50psi
h=115’
So if you extend a pipe to 116 feet higher than the water main, there will be no water pressure at that altitude in that pipe. You could look down inside that 116-foot-high pipe and see the top of the water column one foot down into the pipe, but the pipe could be uncapped and water wouldn’t flow out of it.
*A similar formula 1 psi = 2.31 feet of water can be found in the exam by clicking on “References” on the top bar and then clicking on the “Plumbing” tab. You can practice on the NCARB demonstration exam, which is found on the right side of your my NCARB page. In 2021, NCARB began minimizing the importance of the reference tabs in the exam and prioritized including relevant reference material and formulas INSIDE the relevant test item question instead.
To watch an Amber Book 40 Minutes of Competence video solving this problem, click here.
Non-load-bearing exterior walls may require a fire rating. The type of fire rating (one hour, two hours, etc.) is based on the _______.
Distance between your building and the property line
or
Height of your building
Answer: Distance between your building and the property line
The fire rating of exterior walls is based upon fear that your fire will spread to the adjacent buildings. It is determined on Table 602 “Fire Resistance Rating Requirements for Exterior Walls Based on Fire Separation Distance.” Besides the distance to the property line, the fire rating of the exterior wall is governed by the construction type (non-combustible concrete buildings can sometimes have a lower fire rating in the exterior wall); and further controlled by occupancy type (high- and medium-hazard buildings, factories, and retail (with lots of content to burn) may require more fire-resistant exterior walls). See here (and scroll down to Table 602).
Load-bearing exterior walls must also comply with the fire ratings set forth in Table 601. Those parameters serve a different purpose: not so much to prevent fire from spreading to the neighbors, but rather to make it less likely that your building will collapse once on fire.
A bank shares a wall with a courtroom in an unsprinklered building. That wall must be rated to _______ hours. (You may use the internet or the Amber Book Case Study material to answer this question.)
No rating required (0 hours)
A 1-hour fire rating
A 2-hour fire rating
A 4-hour fire rating
Answer: A 2-hour fire rating
You’ll search the case study (seehere for a substitute) for “bank” and “courtroom” and see that the bank has an occupancy classification of Business (B) and a courtroom has an occupancy classification of Assembly (A-3). Then you’ll search for the adjacency table called Required Separation of Occupancies (Hours): Table 508.4. You can gohere for that now, but if you don’t remember a good search word like “separation” while in the testing center, scroll down through the case study until you find it. Confusingly, that table has four classifications, three of which begin with N:
N= No separation requirement
NP=Not permitted (meaning the two adjacencies may not be adjacent!)
NS=No sprinkler system
S=Sprinkler system
1=One-hour fire separation required
2—Two-hour fire separation required, etc.
To watch me solve this problem in an Amber Book : 40 Minutes of Competence video, click here.
Which pipes create less friction?
Copper
Plastic
Steel
A: Plastic
So much information! I’m having trouble memorizing all of this. What should I do?
As with any test, memorize what you think you need to, but recognize that you will not be able to recall everything, and be okay with that. This is why it is most important to own the concepts: so that you can answer even the content you didn’t study (or forgot). If you are having trouble remembering, practice putting the content into your own words. Taking notes using my words is not effective for long term recall: it is just glorified highlighting.
And know that this is a long course because it is comprehensive. If you generally understand the content in Amber Book, I don’t think that you need other material to get to a place where you are likely to pass these exams. You don’t need practice tests (beyond NCARB’s Demonstration Exam). If you’ve already taken an exam division, ask yourself: Did I answer a test item incorrectly because I didn’t understand the exam format? Or did I answer a test item incorrectly because I didn’t understand the exam content?
A horizontal wind force of 3,840 pounds is acting on a wood shear wall with a uniform gravity load of 1,000 pounds per linear foot on top of the wall. The wall height is 35’ . Calculate the minimum length of the wall so that it will still behave as a shear wall and resist the lateral loads.
Answer: Minimum length of 10’
As shear walls shrink in length and get taller, they behave more like columns and less like shear walls–and are unable to resist lateral loads from wind or seismic forces. We need to establish a maximum aspect ratio for tall, thin, shear walls, beyond which the panel action of the wall in resisting horizontal loads can no longer be trusted to stabilize the building.
The gravity load on the top presented in this problem isn’t relevant to this calculation. Prescriptive code requires a maximum shear wall aspect ratio (height:length) of 3.5:1, provided the shear wall is made of something stiff (like structural fiberboard). This maximum drops to 2:1 for a less-stiff wall (like blocked particle board), so if the shear wall were less-stiff, our minimum wall length would be one-half of the 35’ height, or 17.5’. With a stronger wall assembly, we can get the wall thinner: 3.5:1 or 10’ long, which is our answer. When using the prescriptive code, the horizontal force is also redundant.
The above are based on rules-of-thumb. There are at least three different math-based alternatives to calculate the minimum length if the wall has openings for windows/doors, but for a basic un-perforated wood wall, we can simply divide the horizontal wind force of 3840 pounds by 320 pounds/foot to derive a minimum wall length of 12 feet. Where did the 320 number come from? You’d need to look it up in a table (not given in this problem) defining allowable shear forces for different constructions. This is likely beyond what the ARE would ask of you, but I include it here for those who are curious.
In practice, a shear wall in wood construction is almost always built as follows. OSB on one side of the exterior stud wall (that doubles as enclosure sheathing) with horizontal blocking framed so the OSB edges have something to nail into: that way when the wall is pushed horizontally, the free edges of the OSB panels won’t buckle. Framers nail the perimeter of the OSB six inches on-center and the middle of the OSB at 12” O.C.; and they affix hold-down anchors at the ends of each segment so that the wall doesn’t peel off the foundation when exposed to the lateral loads that the wall intends to resist.
Code limits masonry shear wall aspect ratios (height:length) to 2:1, and concrete and CLT have aspect ratios defined by other tables and calculations.
As you may imagine, this is a complex subject– see here if you are curious to learn more (not necessary for your ARE studying).
Are fire-rated barriers (walls or floor-ceiling assemblies) required between “nonseparated” occupancies?
Answer: No (not usually).
If two occupancies are considered nonseparated, the barriers between them needn’t be rated unless they are dwelling units (apartments), sleeping units (hotels) or similar residential (R) classifications–which do require fire-rated barriers. And as is often the case, prisons (I) and fireworks storage facilities (H) are also exceptions–and also require fire-rated separation.
Incidental use vs. accessory use in the code
Incidental use example: An accountant’s office (occupancy class B) includes a boiler room or other space that poses a greater life-safety risk than posed by the office. Provided that the boiler room does not exceed 10% of the story’s floor area, the boiler room can be counted with the office in the less-stringent B-classification. . .but the more dangerous boiler room requires fire separation in the form of fire-rated walls and floor-ceiling assemblies (and/or sprinklers). It is not up to the architect to decide what can be considered incidental use (though it used to be in older code versions). Rather, the code maintains a list of such high-risk-but-small-area rooms it considers “incidental,” such as refrigeration equipment rooms, laboratories, paint shops, and large laundry rooms.
Accessory use example: An accountant’s office (B) includes some storage (usually S, but not considered separate here). If the storage is for the accountant, and not on the list of small-but-risky incidental use spaces, and less than 10% of the floor area of that story, it doesn’t have to be counted as a different occupancy classification. . . and therefore doesn’t require a fire rated wall separating the storage area from the office around it.
Define nonseparated occupancy vs separated occupancy in the code
Nonseparated occupancies example: We’ll use the same accountant’s office (occupancy class B), but this time the storage area (S) exceeds 10% of the story’s floor area or the storage area is used not by the accounting office, but rather by the landlord, who has an eBay business and likes to keep his merchandise in the storage room. For either of these reasons, we can’t classify the storage area as an accessory space. We have two options instead. We can deem them “nonseparated” B and S occupancies, or we can deem them “separated” B and S occupancies. The nonseparated flavor often, but not always, allows for a less expensive alternative. You typically wouldn’t have to design fire separation between the B and S areas in nonseparated construction, however when you determine area limits, height limits, and construction type, you would have to treat the whole building as if it were the more restrictive of the two occupancy types. In this case, the whole building’s construction type might have to be designed to a higher S standard, instead of a lower B standard.
Separated occupancies example: Here, again, the storage area exceeds 10% of the floor’s area or someone other than the accountant uses the storage area. We have the option of declaring the B and the S as “separated” occupancies and, as such, we may have to build fire-rated walls and floor-ceilings between them. The B and S areas each comply with the code based on their respective occupancy classification. Construction type here (and area limitations) would be based on the proportions of the building that fall under each type of classification. You can see how this may, or may not, work out to your advantage. In some cases the cost of building fire separation within the building’s different occupancies exceeds the cost of the limitations on whole-building construction type (and you’ll choose to pursue nonseparated occupancy status); in other cases the cost penalty of within-building fire separation pales relative to limitations of whole-building construction type (and you’ll go with separated occupancies instead). In short, either don’t separate the rooms and build the whole building to the more strict standard, or separate the rooms and build each part of the building to its own standard.
If you are still unclear, see this video I made.
The top of the municipal water tank sits 115 feet above a fixture. The pressure loss through piping, fittings, and the water meter can be ignored for this exercise. What is the water pressure at the fixture?
Given: 1psi = 2.31 ft of water
Answer: 50psi
http://flashcards.amber-book.com/wp-content/uploads/2020/06/Plumbing-Pressure-Video.mp4
What is the cost of heating a building with a natural gas boiler, given . . .
Peak heat loss = 500,000 BTU/hr
2,000 Full-load hours/yr
Fuel heat value of natural gas = 1,000 BTU/cu ft
Fuel cost = $11 per thousand cubic feet of natural gas
Boiler efficiency = 90%
A: $12,222
given . . .
Peak heat loss = 500,000 BTU/hr
2,000 Full-load hours/yr
Fuel heat value of natural gas = 1,000 BTU/cu ft
Fuel cost = $11 per thousand cubic feet of natural gas
Boiler efficiency = 90%
Now to solve. . . .
Where is an outdoor transformer located when the power is buried underground? Where is the switchgear located for that same building?
Underground power lines are typically buried in a line 4’ inboard from the street property line. Outdoor transformers for underground power lines are often on the property line that separates your building from your neighbor’s building, 4’ in from the street.
Switchgear is located right at the point where the power enters the building, so inside the wall closest to the transformer.