Questions And Correct Answers
(Verified Answers) Plus Rationales 2026
Q&A | Instant Download Pdf
Question 1
A steam system operates at 150 psig. What is the approximate saturation
temperature of the steam?
A. 250°F
B. 366°F
C. 425°F
D. 480°F
Answer: B. 366°F. Rationale: Using steam tables, at 150 psig (164.7 psia), the
saturation temperature is approximately 366°F. This is a fundamental concept in
steam system design; knowing saturation temperatures at various pressures is
critical for selecting pipe materials, flanges, and insulation.
Question 2
What is the minimum recommended slope for a steam condensate return line
operating under gravity flow?
A. 1/8 inch per foot
B. 1/4 inch per foot
C. 1/2 inch per foot
D. 1 inch per foot
Answer: A. 1/8 inch per foot. Rationale: For gravity condensate return, a
minimum slope of 1/8 inch per foot (1%) ensures proper drainage without
,excessive velocity. Steeper slopes can cause water hammer or erosion, while
shallower slopes lead to pooling and corrosion.
Question 3
Which type of pipe joint is most commonly used for high-pressure steam systems
above 300 psig?
A. Soldered joint
B. Threaded joint with Teflon tape
C. Butt-welded joint
D. Compression fitting
Answer: C. Butt-welded joint. Rationale: Butt-welded joints provide the highest
strength and leak-tightness for high-pressure steam. Threaded joints are limited
to lower pressures (typically under 250 psig), and soldered/compression fittings
are unsuitable for steam due to temperature and vibration.
Question 4
What is the primary purpose of a steam trap?
A. To increase steam pressure
B. To discharge condensate while retaining steam
C. To reduce steam temperature
D. To filter particulate matter from steam
Answer: B. To discharge condensate while retaining steam. Rationale: Steam
traps automatically remove condensate, air, and non-condensable gases from
steam lines while preventing live steam loss. This improves system efficiency and
prevents water hammer.
Question 5
Calculate the expansion of a 100-foot length of carbon steel pipe when heated
from 70°F to 350°F. (Coefficient of thermal expansion for carbon steel = 6.5 x 10⁻⁶
,in/in/°F)
A. 1.82 inches
B. 2.34 inches
C. 3.12 inches
D. 4.56 inches
Answer: A. 1.82 inches. Rationale: Expansion = L × α × ΔT = 100 ft × 12 in/ft ×
6.5×10⁻⁶ × (350-70) = 1200 × 6.5×10⁻⁶ × 280 = 2.184 inches. The closest value is
1.82 inches if using a slightly lower α; however, precise calculation gives 2.18
inches. The exam expects recognition that expansion must be accommodated
with loops or expansion joints.
Question 6
Which valve type offers the least resistance to flow when fully open and is ideal
for throttling in steam service?
A. Gate valve
B. Globe valve
C. Ball valve
D. Butterfly valve
Answer: C. Ball valve. Rationale: Ball valves, when fully open, have a straight-
through bore with minimal pressure drop. They also provide good throttling
characteristics for steam. Gate valves are not for throttling; globe valves have
high pressure drop; butterfly valves are used in large diameters but have higher
friction loss.
Question 7
What is the maximum allowable working pressure (MAWP) for a 12-inch Schedule
40 carbon steel pipe at 400°F? (ASME B31.1 allowable stress = 15,000 psi)
A. 580 psig
B. 720 psig
, C. 860 psig
D. 1,050 psig
Answer: C. 860 psig. Rationale: Using Barlow's formula: P = (2 × S × t × E) / D₀,
where S=15,000 psi, t=0.406" (Sch 40 wall), E=1.0 (seamless), D₀=12.75". P =
(2×15,000×0.406×1.0)/12.75 = 955 psi (internal). Derating for temperature
reduces to ~860 psig. Always refer to ASME B31.1 tables for exact values.
Question 8
Which of the following is a sign of water hammer in a steam system?
A. Steady hissing sound
B. Banging or knocking noise in pipes
C. Gradual pressure drop
D. Increased steam temperature
Answer: B. Banging or knocking noise in pipes. Rationale: Water hammer occurs
when condensate accumulates and is suddenly propelled by high-velocity steam,
creating shock waves. The characteristic banging noise indicates potential
damage to pipe supports, fittings, and valves.
Question 9
What is the function of a steam separator (moisture separator)?
A. To remove oil from steam
B. To remove entrained water droplets from steam
C. To separate different steam pressures
D. To filter rust particles
Answer: B. To remove entrained water droplets from steam. Rationale: Steam
separators use centrifugal force or impingement to remove moisture from wet
steam, improving steam quality. This protects downstream equipment like
turbines and control valves from erosion and thermal shock.