Control Rods

Question 1

A reactor is initially critical well below the point of adding heat (POAH) during a reactor startup.
Control rods are withdrawn for 20 seconds to establish a 0.5 DPM startup rate.
In response to the control rod withdrawal, reactor power will initially increase, and then…

Answer 1

stabilize at a value slightly above the POAH.

Question 2

A reactor is initially critical below the point of adding heat during a reactor startup. If control
rods are manually inserted for 5 seconds, reactor power will decrease…

Answer 2

to a lower power level determined by subcritical multiplication.

Question 3

A reactor is initially critical below the point of adding heat (POAH) during a reactor startup. If
control rods are manually withdrawn for 5 seconds, reactor power will…

Answer 3

increase to a stable critical power level at the POAH

Question 4

A reactor is operating at steady-state 50 percent power near the end of a fuel cycle when the
operator withdraws a group of control rods for 5 seconds. (Assume main turbine load remains
constant and the reactor does not trip.)
In response to the control rod withdrawal, actual reactor power will stabilize __________ the
initial power level and reactor coolant temperature will stabilize __________ the initial
temperature.

Answer 4

at; above

Question 5

A reactor is operating at steady-state 50 percent power when control rods are inserted a short
distance. Assume that main turbine-generator load remains constant and the reactor does not trip.
In response to the control rod insertion, reactor power will initially decrease, and then…

Answer 5

increase and stabilize at the original value.

Question 6

A reactor is operating at steady-state 50 percent power near the end of a fuel cycle when the
operator inserts a group of control rods for 5 seconds. Assume that turbine load remains constant
and the reactor does not trip.
In response to the control rod insertion, reactor power will stabilize __________ the initial power
level and reactor coolant temperature will stabilize __________ the initial temperature.

Answer 6

at; below

Question 7

A reactor has been shut down for three weeks with all control rods fully inserted. If a single
control rod is fully withdrawn from the core, neutron flux level will… (Assume the reactor
remains subcritical.)

Answer 7

increase and stabilize above the original level.

Question 8

A reactor has been shut down for three weeks with all control rods fully inserted. If a center
control rod is fully withdrawn from the core, neutron flux level will… (Assume the reactor
remains subcritical.)

Answer 8

increase and stabilize at a new higher level.

Question 9

Criticality has been achieved during a xenon-free reactor startup. The core neutron flux level is
low in the intermediate range with a stable 0.5 DPM startup rate (SUR). The operator begins
inserting control rods in an effort to stabilize the core neutron flux level near its current value.
The operator stops inserting control rods when the SUR indicates exactly 0.0 DPM.
Immediately after the operator stops inserting the control rods, the SUR will become __________;
and the core neutron flux level will __________.

Answer 9

positive; increase exponentially

Question 10

The total amount of reactivity added by a control rod position change from a reference height to
any other rod height is called…

Answer 10

integral rod worth.

Question 11

Integral control rod worth can be described as the change in __________ for a __________ change
in rod position.

Answer 11

reactivity; total

Question 12

A control rod is positioned in a reactor with the following neutron flux parameters:
Core average thermal neutron flux = 1 x 1012 neutrons/cm2
-sec
Control rod tip thermal neutron flux = 5 x 1012 neutrons/cm2
-sec
If the control rod is slightly withdrawn such that the tip of the control rod is located in a thermal
neutron flux of 1 x 1013 neutrons/cm2
-sec, the differential control rod worth will increase by a
factor of __________. (Assume the core average thermal neutron flux is constant.)

Answer 12

4.0

Question 13

Integral rod worth is the…

Answer 13

reactivity added by moving a control rod from one position to another position.

Question 14

Reactor power was ramped from 80 percent power to 100 percent power over 4 hours. The 80
percent conditions were as follows:
Reactor coolant system (RCS) boron concentration = 600 ppm
Control rod position = 110 inches
RCS average temperature = 575°F
The 100 percent conditions are as follows:
RCS boron concentration = 580 ppm
Control rod position = 130 inches
RCS average temperature = 580°F
Given the following reactivity coefficient/worth values, and ignoring fission product poison
reactivity changes, what was the average differential control rod worth during the power change?
Power coefficient = -0.03 %ΔK/K/percent
Moderator temperature coefficient = -0.02 %ΔK/K/°F
Differential boron worth = -0.01 %ΔK/K/ppm

Answer 14

-0.02 %ΔK/K/inch

Question 15

A control rod is positioned in a reactor with the following neutron flux parameters:
Core average thermal neutron flux = 1.0 x 1012 n/cm2
-sec
Control rod tip thermal neutron flux = 5.0 x 1012 n/cm2
-sec
If the control rod is slightly inserted such that the control rod tip is located in a thermal neutron
flux of 1.0 x 1013 n/cm2
-sec, the differential control rod worth will increase by a factor of
__________. (Assume the core average thermal neutron flux is constant.)

Answer 15

4

Question 16

A control rod is positioned in a reactor with the following neutron flux parameters:
Core average thermal neutron flux = 1.0 x 1012 n/cm2
-sec
Control rod tip thermal neutron flux = 4.0 x 1012 n/cm2
-sec
If the control rod is slightly inserted such that the control rod tip is located in a thermal neutron flux
of 1.2 x 1013 n/cm2
-sec, the differential control rod worth will increase by a factor of __________.
(Assume the core average thermal neutron flux is constant.)

Answer 16

9

Question 17

A reactor is initially operating at steady state 70 percent power with the following conditions:
Reactor coolant system (RCS) boron concentration = 600 ppm
Control rod position = 110 inches
RCS average temperature = 575°F
Reactor power is increased to 100 percent. The 100 percent reactor power conditions are as
follows:
RCS boron concentration = 590 ppm
Control rod position = 130 inches
RCS average temperature = 580°F
Given the following reactivity coefficient/worth values, and ignoring fission product poison
reactivity changes, what was the average differential control rod worth during the power change?
Power coefficient = -0.03 %ΔK/K/percent
Moderator temperature coefficient = -0.02 %ΔK/K/°F
Differential boron worth = -0.01 %ΔK/K/ppm

Answer 17

-0.04 %ΔK/K/inch

Question 18

A control rod is positioned in a reactor with the following neutron flux parameters:
Core average thermal neutron flux = 1.0 x 1012 n/cm2
-sec
Control rod tip thermal neutron flux = 4.0 x 1012 n/cm2
-sec
If the control rod is slightly inserted such that the control rod tip is located in a thermal neutron flux
of 1.6 x 1013 n/cm2
-sec, the differential control rod worth will increase by a factor of __________.
(Assume the core average thermal neutron flux is constant.)

Answer 18

16

Question 19

Which one of the following expresses the relationship between differential rod worth (DRW) and
integral rod worth (IRW)?

Answer 19

DRW is the slope of the IRW curve at a given rod position.

Question 20

Which one of the following parameters typically has the greatest influence on the shape of a
differential rod worth curve?

Answer 20

Core axial neutron flux distribution

Question 21

During normal full power operation, the differential control rod worth is less negative at the top
and bottom of the core compared to the center regions due to the effects of…

Answer 21

neutron flux distribution.

Question 22

Which one of the following expresses the relationship between differential rod worth (DRW) and
integral rod worth (IRW)?

Answer 22

IRW is the sum of the DRWs between the initial and final control rod positions

Question 23

As moderator temperature increases, the differential rod worth becomes more negative because…

Answer 23

moderator density decreases, which increases the neutron migration length.

Question 24

Differential rod worth will become most negative if reactor coolant temperature is __________
and reactor coolant boron concentration is __________.

Answer 24

increased; decreased

Question 25

With a nuclear power plant operating normally at full power, a 5°F decrease in moderator
temperature will cause the differential control rod worth to become…

Answer 25

less negative due to shorter neutron migration length.

Question 26

As moderator temperature increases, the differential rod worth becomes…

Answer 26

more negative due to longer neutron diffusion lengths

Question 27

A reactor is operating at 60 percent power near the end of a fuel cycle with the controlling group of
control rods inserted 5 percent into the core. Which one of the following will cause the group
differential rod worth to become less negative? (Consider only the direct effect of the indicated
change.)

Answer 27

Reactor coolant temperature is allowed to decrease from 575°F to 570°F.

Question 28

A reactor startup is in progress from a cold shutdown condition. During the reactor coolant
heatup phase of the startup, the differential control rod worth will become __________ negative;
and during the complete withdrawal of the initial bank of control rods, the differential control rod
worth will become __________.

Answer 28

more; more negative initially and then less negative

Question 29

Which one of the following will cause the differential rod worth for a group of control rods to
become less negative? (Consider only the direct effect of the initiated change.)

Answer 29

The reactor coolant system is cooled from 170°F to 120°F in preparation for refueling.

Question 30

The main reason for designing and operating a reactor with a flattened neutron flux distribution is
to…

Answer 30

achieve a higher average power density

Question 31

Which one of the following is a reason for neutron flux shaping in a reactor core?

Answer 31

To minimize local power peaking by more evenly distributing the core thermal neutron flux.

Question 32

Which one of the following includes two reasons for control rod bank/group overlap?

Answer 32

Provides a more uniform differential rod worth, and minimizes axial neutron flux peaking.

Question 33

Which one of the following includes two reasons for control rod bank/group overlap?

Answer 33

Provide a more uniform axial power distribution and provide a more uniform differential rod
worth.

Question 34

One purpose of using control rod bank/group overlap is to…

Answer 34

provide a more uniform differential rod worth.

Question 35

A reactor has been operating at 100 percent power for several weeks near the middle of a fuel cycle
with all control rods fully withdrawn. Which one of the following describes why most of the
power is being produced in the lower half of the reactor core?

Answer 35

The moderator temperature coefficient of reactivity is adding less negative reactivity in the
lower half of the core.

Question 36

A reactor is operating at steady-state 75 percent power in the middle of a fuel cycle. Which one of
the following actions will cause the greatest shift in reactor power distribution toward the top of
the core? (Assume control rods remain fully withdrawn.)

Answer 36

Decrease reactor power by 25 percent

Question 37

A reactor has been operating at 100 percent power for three weeks shortly after a refueling outage.
All control rods are fully withdrawn. Which one of the following describes why most of the
power is being produced in the lower half of the core?

Answer 37

The moderator temperature coefficient of reactivity is adding more negative reactivity in the
upper half of the core.

Question 38

If core quadrant power distribution (sometimes called quadrant power tilt or azimuthal tilt) is
maintained within design limits, which one of the following conditions is most likely?

Answer 38

Radial power distribution is within design limits.

Question 39

A reactor was restarted following a refueling outage and is currently at the point of adding heat.
Which one of the following describes the change in axial power distribution as reactor power is
increased to 5 percent by control rod withdrawal?

Answer 39

Shifts toward the top of the core.

Question 40

By maintaining the radial and axial core power distributions within their prescribed limits, the
operator is assured that __________ will remain within acceptable limits.

Answer 40

power density (kW/foot) and departure from nucleate boiling ratio (DNBR)

Question 41

Consider a reactor core with four quadrants: A, B, C, and D. The reactor is operating at
steady-state 90 percent power when a fully withdrawn control rod in quadrant C drops to the
bottom of the core. Assume that no operator actions are taken and reactor power stabilizes at 88
percent.
How are the maximum upper and lower core power tilt values (sometimes called quadrant power
tilt ratio or azimuthal power tilt) affected by the dropped rod?

Answer 41

Both upper and lower core values increase.

Question 42

A reactor is operating at steady-state 100 percent power when a single control rod fully inserts
from the fully withdrawn position. After the initial transient, the operator returns the reactor to
100 percent power with the control rod still fully inserted.
Compared to the initial core axial neutron flux shape, the current core axial neutron flux shape will
have a…

Answer 42

minor distortion, because the fully inserted control rod is an axially uniform poison.

Question 43

After a control rod is fully inserted (from the fully withdrawn position), the effect on the axial flux
shape is minimal. This is because…

Answer 43

the fully inserted control rod is an axially uniform poison.

Question 44

The control rod insertion limits generally rise as reactor power increases because…

Answer 44

the power defect becomes more negative as power increases

Question 45

Control rod insertion limits are established for power operation because excessive rod insertion
will…

Answer 45

adversely affect core power distribution.

Question 46

Control rod insertion limits ensure that control rods will be more withdrawn as reactor power
__________ to compensate for the change in __________.

Answer 46

increases; power defect

Question 47

Why are control rod insertion limits established for power operation?

Answer 47

To provide adequate shutdown margin after a reactor trip

Question 48

A reactor has been operating at 80 percent power for four weeks with the controlling rod
bank/group inserted 10 percent from the fully withdrawn position.
Which one of the following will be most affected by inserting the controlling bank/group an
additional 5 percent? (Assume steady-state reactor power does not change.)

Answer 48

Axial power distribution

Question 49

A reactor is operating at steady-state 75 percent power with all control rods fully withdrawn.
Assuming the reactor does not trip, which one of the following compares the effects of dropping
(full insertion) a center control rod to the effects of partially inserting (50 percent) the same control
rod?

Answer 49

A dropped rod causes a greater change in radial power distribution.

Question 50

A reactor is operating at steady-state 75 percent power with all control rods fully withdrawn.
Assuming the reactor does not trip, which one of the following compares the effects of dropping
(full insertion) a center control rod to the effects of partially inserting (50 percent) the same control
rod?

Answer 50

A partially inserted rod causes a greater change in axial power distribution

Question 51

A reactor is operating at steady-state 75 percent power with all control rods fully withdrawn.
Assuming the reactor power does not trip, which one of the following compares the effects of
dropping (full insertion) a center control rod to the effects of partially inserting (50 percent) the
same control rod?

Answer 51

A dropped rod causes a smaller change in axial power distribution.

Question 52

A reactor is operating at steady-state 85 percent power with all control rods fully withdrawn.
Assuming the reactor does not trip, which one of the following compares the effects of partially
inserting (50 percent) a center control rod to the effects of dropping (full insertion) the same
control rod?

Answer 52

A partially inserted rod causes a smaller change in radial power distribution.

Question 53

A reactor is operating at steady-state 100 percent power at the beginning of a fuel cycle with all
control rods fully withdrawn. Assuming the reactor does not trip, which one of the following
compares the effects of dropping a control rod in the center of the core to dropping an identical
control rod at the periphery of the core?

Answer 53

Dropping a center control rod causes a greater change in radial power distribution.

Question 54

A reactor has been operating at 80 percent power for four weeks with the controlling rod group
inserted 15 percent from the fully withdrawn position.
Which one of the following will be significantly affected by withdrawing the controlling rod group
an additional 5 percent? (Assume steady-state reactor power does not change.)

Answer 54

Axial power distribution

Question 55

A reactor is operating at steady-state 100 percent power with all control rods fully withdrawn when
one control rod at the core periphery falls completely into the core. Assuming no reactor trip and
no operator action, which one of the following will change significantly as a result of the dropped
rod?

Answer 55

Radial power distribution only