Fluid Statics and Dynamics Flashcards by Tarrah Williams

The possibility of water hammer in a liquid system is minimized by…

venting systems prior to starting centrifugal pumps.

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Which one of the following methods will increase the possibility and/or severity of water hammer?

Starting a centrifugal pump with the discharge valve fully open.

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A sudden stop of fluid flow in a piping system, due to rapid closure of an isolation valve, will most
likely result in…

water hammer.

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One reason for keeping condensate out of the steam lines is to…

prevent water/steam hammer.

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The possibility of water hammer will be increased by…

condensation in a steam line just prior to initiating flow.

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To minimize the possibility of water hammer when initiating flow in a system, the operator should…

vent the system prior to initiating flow.

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Which one of the following describes why large steam lines are gradually warmed instead of suddenly
admitting full steam flow?

To minimize the potential for water hammer in the steam lines

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Which one of the following will minimize the possibility of water hammer?

Draining condensate out of steam lines before and after initiating flow.

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Which one of the following operating practices minimizes the possibility of water hammer?

Start centrifugal pumps with the discharge valve throttled.

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Refer to the drawing of two lengths of 6-inch diameter pipe, each containing an identical automatic
isolation valve. The actual pipe lengths are proportional to their symbols in the drawing
Water at 65°F is flowing at 1,000 gpm through each pipe. If isolation valves A and B instantly close,
the pressure spike experienced by valve A will be __________ the pressure spike experienced by
valve B; and the pressure spike will dissipate faster in the __________ length of pipe.

equal to; shorter

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Refer to the drawing of two lengths of 16-inch diameter pipe, each containing an identical automatic
isolation valve. The actual pipe lengths are proportional to their symbols in the drawing.
Water is flowing at 10,000 gpm through each pipe when both isolation valves instantly close.
Consider two cases:
Case 1: The water temperature upstream of both valves is 65°F.
Case 2: The water temperature is 65°F upstream of valve A, and 85°F upstream of valve B.
For which case(s), if any, will valve A experience a pressure spike that is greater than the pressure
spike at valve B?

Case 2 only

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Which one of the following will result in a higher probability and/or severity of water hammer in a
flowing water system?

Shorter valve stroke times rather than longer valve stroke times.

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An 85 gpm leak to atmosphere has developed from a cooling water system that is operating at 100
psig. Which one of the following will be the approximate leak rate when system pressure has
decreased to 50 psig?

60 gpm

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Mass flow rate equals volumetric flow rate times…

density.

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A 55 gpm leak to atmosphere has developed from a cooling water system that is operating at 100 psig.
Which one of the following will be the approximate leak rate when system pressure has decreased to
50 psig?

39 gpm

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A 75 gpm leak to atmosphere has developed from a cooling water system that is operating at 80 psig.
Which one of the following will be the approximate leak rate when system pressure has decreased to
40 psig?

53 gpm

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A 60 gpm leak to atmosphere has developed from a cooling water system that is operating at 150 psig.
Which one of the following will be the approximate leak rate when system pressure has decreased to
75 psig?

42 gpm

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A 100 gpm leak to atmosphere has developed from a cooling water system that is operating at 60 psig.
Which one of the following will be the approximate leak rate when system pressure has decreased to
20 psig?

58 gpm

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A 100 gpm leak to atmosphere has developed from a cooling water system that is operating at 45 psig.
Which one of the following will be the approximate leak rate when system pressure has decreased to
30 psig?

82 gpm

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A 47 gpm leak to atmosphere has developed from a cooling water system that is operating at 150 psig.
Which one of the following will be the approximate leak rate when system pressure has decreased to
75 psig?

33 gpm

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An 80 gpm leak to atmosphere has developed from a cooling water system that is operating at 100
psig. Which one of the following will be the approximate leak rate when system pressure has
decreased to 75 psig?

69 gpm

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49 gpm

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An 80 gpm leak to atmosphere has developed from a cooling water system that is operating at 150
psig. Which one of the following will be the approximate leak rate when system pressure has
decreased to 75 psig?

57 gpm

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65 gpm

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A 75 gpm leak to atmosphere has developed from a cooling water system that is operating at 100 psig. Which one of the following will be the approximate leak rate when system pressure has decreased to 80 psig?

67 gpm

Which one of the following describes the relationship between the main steam mass flow rate leaving a steam generator and the main feedwater mass flow rate entering the same steam generator at steady-state power operation? (Assume no other addition/removal of steam generator inventory.)

The mass flow rates will be the same only if downcomer level is constant.

``` A heat exchanger has the following initial cooling water inlet temperature and differential pressure (ΔΡ) parameters: Inlet Temperature = 70°F Heat Exchanger ΔΡ = 10 psi Six hours later, the current heat exchanger cooling water parameters are: Inlet Temperature = 85°F Heat Exchanger ΔΡ = 10 psi In comparison to the initial cooling water mass flow rate, the current mass flow rate is... ```

lower, because the density of the cooling water has decreased.

An 80 gpm leak to atmosphere has developed from a cooling water system that is operating at 150 psig. Which one of the following will be the approximate leak rate when system pressure has decreased to 100 psig?

65 gpm

Reactor coolant system (RCS) hot leg temperature is constant at 568°F while RCS pressure is decreasing due to a small reactor coolant leak. Which one of the following RCS pressure ranges includes the pressure at which two-phase flow will first occur in the hot leg?

1,200 to 1,151 psig

Reactor coolant system (RCS) hot leg temperature is constant at 538°F while RCS pressure is decreasing due to a small reactor coolant leak. Which one of the following RCS pressure ranges includes the pressure at which two-phase flow will first occur in the hot leg?

950 to 901 psig

Reactor coolant system (RCS) hot leg temperature is constant at 520°F while RCS pressure is decreasing due to a small reactor coolant leak. Which one of the following pressure ranges includes the pressure at which two-phase flow will first occur in the hot leg?

800 to 751 psig

Reactor coolant system (RCS) hot leg temperature is constant at 552°F while RCS pressure is decreasing due to a small reactor coolant leak. Which one of the following pressure ranges includes the pressure at which two-phase flow will first occur in the hot leg?

1,050 to 1,001 psig

If the quality of a flowing steam-water mixture is known, what additional information, if any, is needed to determine the percent moisture content of the steam-water mixture?

No additional information is needed.

A nuclear power plant is initially operating at steady-state 100 percent power. If an unplanned load rejection causes the main generator load to rapidly decrease to 90 percent, the voids in the two-phase flow in the steam generator tube bundle region will initially ________; which causes indicated steam generator water level (measured in the downcomer) to initially __________.

shrink; decrease

A nuclear power plant is initially operating at steady-state 80 percent power. If a control system malfunction causes main generator load to rapidly increase to 90 percent, the voids in the two-phase flow in the steam generator tube bundle region will initially ________; which causes indicated steam generator water level (measured in the downcomer) to initially __________.

expand; increase

A nuclear power plant is recovering from a loss of offsite power that caused all reactor coolant pumps (RCPs) to stop. Pressurizer level indication is off-scale high. The subcooling margin in the reactor coolant loops and reactor vessel is 100°F. Which one of the following is most likely to occur if the steam generator (SG) temperatures are 50°F higher than their associated reactor coolant system (RCS) loop temperatures when an RCP is restarted?

A large pressure spike throughout the RCS.

A centrifugal water pump was returned to service after maintenance. However, the operator failed to vent the pump. Compared to normal pump operating conditions, after the pump is started the operator will see a __________ flow rate and a __________ discharge head.

lower; lower

Refer to the drawing of a cooling water system (see figure below). Centrifugal pump A is circulating water at 100°F. Which one of the following will cause the centrifugal pump to operate closer to a condition in which gas/vapor binding can occur?

Service water flow rate is decreased by 5 percent.

If a valve closure suddenly stops fluid flow, the resulting piping system pressure transient is referred to as...

water hammer

The major concern with starting a main feedwater pump with downstream fluid in a saturated condition is...

water hammer.

Which one of the following will increase the possibility of water hammer?

Venting liquid systems only after initiating system flow.

The primary reason for slowly opening the discharge valve of a large motor-driven centrifugal cooling water pump after starting the pump is to minimize the...

potential for a water hammer.

Cavitation in an operating pump can be caused by...

throttling the pump suction valve.

Cavitation of a centrifugal pump in an open system is indicated by __________ discharge pressure and __________ flow rate.

low; low

Which one of the following is most likely to cause cavitation in an operating centrifugal pump?

Throttling the pump suction valve

While on surveillance rounds, an operator notices that a centrifugal pump is making a great deal of noise (like marbles rattling inside the pump casing) and the pump discharge pressure is fluctuating

cavitation.

Indications of pump cavitation include abnormally _________ pump discharge pressure and abnormally _________ pump flow rate.

low; low

Cavitation is the formation of vapor bubbles in the __________ of a pump; with the subsequent collapse of the vapor bubbles in the __________ of the pump

impeller; casing

Cavitation is the formation of vapor bubbles in the __________ pressure area of a pump followed by the __________ of these bubbles within the pump casing.

low; collapse

Pump cavitation occurs when vapor bubbles are formed at the eye of a pump impeller...

and enter a high pressure region of the pump where they collapse causing damaging pressure pulsations.

In an operating cooling water system with a constant water velocity, if water temperature decreases, system volumetric flow rate (gpm) will...

remain the same, because the water velocity has not changed.

Flow instruments that measure the mass flow rate of steam often have a density compensation feature because, for a steam pressure increase at a constant volumetric flow rate, steam density will __________ and the actual mass flow rate will __________.

increase; increase

A density-compensated flow instrument is being used to measure mass flow rate in a steam system. If the pressure of the steam decreases, indicated mass flow rate will: (Assume volumetric flow rate is constant.)

decrease for all steam conditions.

A steam generator transient causes main steam pressure to decrease although the actual steam mass flow rate to the main turbine remains constant. If the main steam flow instrument is not density compensated, indicated steam mass flow rate will..

increase, due to the increased velocity of the steam

A cooling water system is supplying 1.0 x 106 lbm/hour of flow at 100°F. Assuming volumetric flow rate does not change, which one of the following will be the mass flow rate in the system if cooling water temperature increases to 140°F?

9.9 x 105 lbm/hr

A reactor coolant system is supplying 1.0 x 108 lbm/hour of coolant flow at a temperature of 100°F. Assuming volumetric flow rate does not change, which one of the following is the approximate mass flow rate that will be supplied by the system if cooling water temperature increases to 400°F?

8.7 x 107 lbm/hr

A reactor coolant system is supplying 1.0 x 108 lbm/hr of coolant flow at a temperature of 100°F. Assuming volumetric flow rate does not change, which one of the following is the approximate mass flow rate that will be supplied by the system if coolant temperature increases to 500°F?

7.9 x 107 lbm/hr

A cooling water system is supplying 2,000 lbm/min coolant flow at a temperature of 100°F. Assuming volumetric flow rate does not change, which one of the following is the approximate mass flow rate that will be supplied by the system if cooling water temperature increases to 140°F?

1,980 lbm/min

A steam generator transient caused main steam pressure to increase although the actual mass flow rate of main steam remained constant. If the main steam flow instrument is not density-compensated, the greater main steam pressure will cause indicated main steam mass flow rate to...

decrease, due to a lower steam velocity

The volumetric flow rate of cooling water entering a heat exchanger is 500 gpm. Given the following: • Cooling water pressure entering and leaving the heat exchanger is 10 psig. • Cooling water inlet temperature is 90°F. • Cooling water outlet temperature is 160°F. • Heat exchanger inlet and outlet piping have the same diameter. What is the approximate volumetric flow rate of the cooling water exiting the heat exchanger?

509 gpm

A condensate pump is taking suction on a main condenser hotwell, containing water at 100°F, and discharging the water at a volumetric flow rate of 100,000 gpm to the main feedwater system. The main feedwater system heats the water to 400°F before it enters the steam generators. Assume there is no leakage, and no bypass or recirculation flow paths are in use. What is the approximate volumetric flow rate of the feedwater entering the steam generators?

115,000 gpm

Operating two pumps in parallel instead of operating a single pump will result in a...

small increase in pump head and a large increase in pump flow rate.

The major effect of starting a second centrifugal pump in parallel with an operating centrifugal pump in an open system is increased...

system flow rate.

To decrease the flow rate through an operating positive displacement pump, an operator should...

decrease the pump’s speed.

Which one of the following will decrease the head loss occurring in an operating cooling water system?

Replacing a 20 foot section of 10-inch diameter pipe with a 20 foot section of 12-inch diameter pipe.

Two centrifugal pumps and two positive displacement pumps are able to be cross-connected to provide makeup water flow to a system. Each pump will produce 100 gpm at a system pressure of 1,000 psig. If system pressure is 1,200 psig, which one of the following combinations will produce the greatest flow rate to the system?

Two positive displacement pumps in parallel

Two centrifugal pumps and two positive displacement pumps are able to be cross-connected to provide makeup water flow to a system. Each pump will produce 100 gpm at a system pressure of 1,000 psig backpressure. If system pressure is 800 psig, which one of the following combinations will produce the greatest flow rate to the system?

Two centrifugal pumps in parallel.

Two identical centrifugal pumps (CPs) and two identical positive displacement pumps (PDPs) are able to take suction on a vented water storage tank and provide makeup water flow to a cooling water system. The pumps are capable of being cross-connected to provide multiple configurations. In single pump alignment, each pump will supply 100 gpm at a system pressure of 1,000 psig. Given the following information: Centrifugal Pumps Shutoff head = 1,500 psig Maximum design pressure = 2,000 psig Flow rate with no backpressure = 180 gpm Positive Displacement Pumps Maximum design pressure = 2,000 psig Which one of the following pump configurations will supply the lowest makeup water flow rate to the system if system pressure is 1,700 psig?

Two CPs in parallel

Two identical centrifugal pumps (CPs) and two identical positive displacement pumps (PDPs) are able to take suction on a vented water storage tank and provide makeup water flow to a cooling water system. The pumps are capable of being cross-connected to provide multiple configurations. In single pump alignment, each pump will supply 100 gpm at a system pressure of 1,000 psig. Given the following information: Centrifugal Pumps Shutoff head = 1,500 psig Maximum design pressure = 2,000 psig Flow rate with no backpressure = 180 gpm Positive Displacement Pumps Maximum design pressure = 2,000 psig Which one of the following pump configurations will supply the highest makeup flow rate to the system if system pressure is 800 psig?

Two CPs in parallel

Water at 90°F and 50 psig is flowing through a 10-inch diameter pipe at 100 lbm/sec. The pipe then splits into two pipes, a 4-inch diameter pipe and an 8-inch diameter pipe. Disregarding any flow restrictions other than pipe size, which one of the following lists the approximate flow rates through the 4-inch and 8-inch diameter pipes? (Assume that water velocity is the same in each pipe.)

4-inch Pipe 8-inch Pipe (lbm/sec) (lbm/sec) 20 80

Two identical centrifugal pumps (CPs) and two identical positive displacement pumps (PDPs) are able to take suction on a vented water storage tank and provide makeup water flow to a cooling water system. The pumps are capable of being cross-connected to provide multiple configurations. In single pump alignment, each pump will supply 100 gpm at a system pressure of 1,200 psig. Given the following information: Centrifugal Pumps Shutoff head = 1,500 psig Maximum design pressure = 2,000 psig Flow rate with no backpressure = 180 gpm Positive Displacement Pumps Maximum design pressure = 2,000 psig Which one of the following pump configurations will supply the highest makeup flow rate to the system if system pressure is 500 psig?

Two CPs in parallel

Water at 90°F and 50 psig is flowing through a 10-inch diameter pipe at 100 lbm/sec. The pipe then splits into two pipes, a 3-inch diameter pipe and a 6-inch diameter pipe. Disregarding any flow restrictions other than pipe size, which one of the following lists the approximate flow rates through the 3-inch and 6-inch diameter pipes. (Assume that water velocity is the same in each pipe.)

3-inch Pipe 6-inch Pipe (lbm/sec) (lbm/sec) 20 80

Water at 90°F and 50 psig is flowing through a 10-inch diameter pipe at 100 lbm/sec. The pipe then splits into two pipes, a 6-inch diameter pipe and an 8-inch diameter pipe. Disregarding any flow restrictions other than pipe size, which one of the following lists the approximate flow rates through the 6-inch and 8-inch diameter pipes? (Assume that water velocity is the same in each pipe.)

6-inch Pipe 8-inch Pipe (lbm/sec) (lbm/sec) 36 64

Two identical centrifugal pumps (CPs) and two identical positive displacement pumps (PDPs) are able to take suction on a vented water storage tank and provide makeup water flow to a cooling water system. The pumps are capable of being cross-connected to provide multiple configurations. In single pump alignment, each pump will supply 100 gpm at a system pressure of 1,200 psig. Given the following information: Centrifugal Pumps Shutoff head = 1,500 psig Maximum design pressure = 2,000 psig Flow rate with no backpressure = 180 gpm Positive Displacement Pumps Maximum design pressure = 2,000 psig Which one of the following pump configurations will supply the highest makeup flow rate to the cooling water system if system pressure is 1,700 psig?

Two PDPs in parallel

A four-loop PWR nuclear power plant uses four identical reactor coolant pumps (RCPs) to supply reactor coolant flow through the reactor vessel. The plant is currently operating at 20 percent power with all RCPs in operation. Which one of the following describes the stable RCS flow rate through the reactor vessel following the trip of one RCP? (Assume that no operator actions are taken and the reactor does not trip.)

Greater than 75 percent of the original flow rate.

A reactor shutdown has been performed because of leakage from the reactor coolant system (RCS) to a steam generator (SG) via a tube leak. Given the following current conditions: • SG pressure is 1,000 psia. • RCS pressure is 2,200 psia. • RCS average temperature is 500°F. • Leak rate from the RCS to the SG is 100 gpm. If RCS pressure is decreased to 1,600 psia, with no other changes in plant parameters, what will be the approximate leak rate from the RCS to the SG?

71 gpm

Two identical single-speed centrifugal pumps (CPs) and two identical single-speed positive displacement pumps (PDPs) are able to take suction on a vented water storage tank and provide makeup water flow to a cooling water system. The pumps are capable of being cross-connected to provide multiple configurations. In single pump alignment, each pump will supply 100 gpm at a system pressure of 1,200 psig. Given the following information: Centrifugal Pumps Discharge pressure at shutoff head = 1,500 psig Maximum design pressure = 2,000 psig Flow rate with no backpressure = 180 gpm Positive Displacement Pumps Maximum design pressure = 2,000 psig Which one of the following pump configurations will supply the highest initial flow rate to a cooling water system that is drained and depressurized?

Two CPs in parallel

Refer to the drawing of a venturi in a main steam line (see figure below). The venturi inlet and outlet pipe diameters are equal. A main steam line break downstream of the venturi causes the main steam mass flow rate through the venturi to increase. Soon, the steam reaches sonic velocity in the throat of the venturi. How will the main steam mass flow rate through the venturi be affected as the steam pressure downstream of the venturi continues to decrease?

It will not continue to increase because the steam velocity cannot increase above sonic velocity in the throat of the venturi.

Two identical single-speed centrifugal pumps (CPs) and two identical single-speed positive displacement pumps (PDPs) are able to take suction on a vented water storage tank and provide makeup water flow to a cooling water system. The pumps are capable of being cross-connected to provide multiple configurations. In single pump alignment, each pump will supply 100 gpm at a system pressure of 1,200 psig. Given the following information: Centrifugal Pumps Discharge pressure at shutoff head = 1,500 psig Maximum design pressure = 2,000 psig Flow rate with no backpressure = 180 gpm Positive Displacement Pumps Maximum design pressure = 2,000 psig Which one of the following pump configurations will supply the lowest initial flow rate of makeup water to a cooling water system that is drained and depressurized?

One CP and one PDP in series (CP supplying PDP)

Refer to the drawing of a main water header that splits into two parallel headers (see figure below). Header A has a 2-inch diameter and header B has a 3-inch diameter. The velocity of the water in both headers is the same. If the main water header has a flow rate of 500 gpm, what is the approximate flow rate in each of the parallel headers?

Header A Header B (gpm) (gpm) 154 346

A length of pipe in a cooling water system uses a reducer fitting to decrease the pipe diameter from 6 inches to 4 inches. The flow rate in the 6-inch diameter section of pipe is 200 gpm. What is the flow rate in the 4-inch diameter section of pipe?

200 gpm

A four-loop PWR nuclear power plant uses four identical single-speed reactor coolant pumps (RCPs) to supply reactor coolant flow through the reactor vessel. The plant is currently shut down with one RCP in operation. Which one of the following describes the stable reactor coolant flow rate through the reactor vessel following the start of a second RCP?

Less than twice the original flow rate.

A vented water storage tank contains 60 feet of water at 70°F. A cracked weld at the bottom of the tank results in a leak rate of 12 gpm. If makeup water flow rate is 5 gpm, at what water level will the tank stabilize?

10.4 feet

A vented water storage tank contains 64 feet of water at 70°F. A cracked weld at the bottom of the tank results in a leak rate of 12 gpm. At what water level will the leak rate be 3 gpm?

4 feet

A plant shutdown will be performed because of leakage from the main condenser cooling water system into the main condenser via a tube leak. Given the following initial conditions: $ Main condenser pressure is 1.7 psia. $ Atmospheric pressure is 14.7 psia $ Main condenser cooling water pressure at the location of the tube leak is 18 psig. $ Cooling water leak rate into the main condenser is 80 gpm. If the main condenser is brought to atmospheric pressure, with no changes to the main condenser cooling water system parameters, what will be the approximate rate of cooling water leakage into the main condenser?

61 gpm

An ideal positive displacement pump is operating in an open system with the following initial parameters: Suction pressure = 10 psig Discharge pressure = 25 psig Flow rate = 100 gpm If the pump discharge pressure increases to 40 psig, the pump flow rate will...

remain constant

A centrifugal pump is operating at a constant speed in a closed system with the following initial parameters: Suction pressure = 10 psig Discharge pressure = 25 psig Pump flow rate = 500 gpm If the pump discharge flow control valve is throttled such that the pump discharge pressure increases to 40 psig, the change in pump flow rate will be...

impossible to determine from the provided information

Refer to the drawing of a venturi in a steam line (see figure below). The venturi inlet and outlet pipe diameters at P1 and P2 are equal. Currently, steam is flowing through the venturi, reaching sonic velocity in the throat of the venturi. If the steam inlet pressure (P1) remains constant while the downstream pressure (P2) decreases, the mass flow rate of the steam will __________; and the velocity of the steam at the venturi outlet will __________.

remain the same; increase

The following are current parameter values for an operating PWR nuclear power plant: Steam generator (SG) pressure = 1,000 psia Main feed pump (MFP) discharge pressure = 1,220 psia If SG pressure does not change, what MFP discharge pressure will increase main feedwater mass flow rate by 10 percent? (Assume MFP inlet temperature remains the same. Also, assume all valves/components that contribute to head loss downstream of the MFP remain in their current configuration.)

1,266 psia

Which one of the following will increase the head loss occurring in an operating cooling water system?

Shifting two heat exchangers from parallel to series operation.

Which one of the following changes to an operating cooling water system will decrease the head loss occurring in the system?

Positioning a flow control valve more open.

Refer to the drawing of a main water header that splits into two parallel headers (see figure below). Header A has a 2-inch diameter and header B has a 4-inch diameter. The velocity of the water in both headers is the same. If the main water header has a flow rate of 500 gpm, what is the approximate flow rate in each of the parallel headers?

Header A Header B (gpm) (gpm) 100 400

A vented water storage tank contains 30 feet of water at 70°F. A cracked weld at the bottom of the tank causes an initial leak rate of 12 gpm. If makeup water flow rate is 8 gpm, at what water level will the tank stabilize?

13.3 feet

Refer to the drawing of an operating cooling water system (see figure below). Which one of the following will increase the mass flow rate in the system with a corresponding increase in the total system head loss?

Shifting operating pump A to a higher speed.

Refer to the drawing of an operating cooling water system (see figure below). The pump is initially operating with the flow control valve (FCV) fully open. If the FCV is partially closed to decrease system flow rate, the pump differential pressure will __________; and the heat exchanger cooling water differential pressure will __________.

increase; decrease

An operating centrifugal water pump has a 26-inch diameter suction nozzle and a 24-inch diameter discharge nozzle. For this pump, the discharge water velocity is __________ the suction water velocity; and the discharge water volumetric flow rate is __________ the suction water volumetric flow rate. (Assume water is incompressible and the suction and discharge water temperatures are the same.)

greater than; equal to

Fluid Statics and Dynamics Flashcards

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