Kinetics With Delayed Neutrons - PowerPoint PPT Presentation

1 / 38
About This Presentation
Title:

Kinetics With Delayed Neutrons

Description:

Title: 15_kinetics_with_delayed_neutrons Author: B. Rouben Created Date: 10/13/2003 8:30:02 PM Document presentation format: On-screen Show Company – PowerPoint PPT presentation

Number of Views:531
Avg rating:3.0/5.0
Slides: 39
Provided by: B277
Category:

less

Transcript and Presenter's Notes

Title: Kinetics With Delayed Neutrons


1
Kinetics With Delayed Neutrons
  • B. Rouben
  • McMaster University
  • EP 4D03/6D03
  • Nuclear Reactor Analysis
  • 2008 Sept-Dec

2
Prompt and Delayed Fractions
  • We now have to distinguish between the prompt and
    delayed neutrons. Lets write





3
Prompt and Delayed Sources
  • Without delayed neutrons, we had gotten to the
    following evolution equation for the neutron
    density
  • Now, we will need to separate the neutron source
    into a prompt part,
  • and a delayed part.

4
Prompt and Delayed Sources
  • The delayed source comes from the decay of
    delayed-neutron precursors. We saw last time
    that there are many delayed-neutron precursors.
    However, we will for now assume only 1
    delayed-neutron precursor group. We will write
    its concentration as C.
  • By the radioactive-decay law, the decay rate of
    the precursor is ?C, where ? is the decay
    constant of the precursor.
  • There is 1 delayed neutron born from the decay of
    1 precursor nuclide. Therefore the production
    rate of the precursor must be equal to the
    fission rate times ?d

5
Prompt and Delayed Sources
  • Therefore the equation for the evolution of the
    precursor concentration is (production rate
    decay rate)
  • and the new equation for the evolution of the
    neutron density is
  • The above coupled equations are the
    point-kinetics equations in 1 energy group, with
    1 delayed-neutron-precursor group.

6
Point-Kinetics Equations with 1 Precursor
  • At the end of the previous presentation, we had
    just reached the point-kinetics equations with 1
    delayed-neutron-precursor group in the following
    form
  • Equation for the evolution of the precursor
  • (we hadnt previously shown explicitly the
    dependence of C and ? on space and time - we now
    added this for completeness)
  • Equation for the evolution of the neutron
    density

7
Point-Kinetics Equations with 1 Precursor (cont.)
  • Simplify Eq. (2) by factorizing from
    first 3 terms

8
Point-Kinetics Equations with 1 Precursor (cont.)
  • So lets rewrite the final point-kinetics
    equations for the neutron density and precursor
    concentration in terms of time only (write
    equation for n first, as per convention)
  • We can also rewrite the equations in terms of ?,
    using
  • , but this will involve

9
Solution of Point-Kinetics Equation
  • Lets try to solve the point-kinetics equations,
    (6) (7).
  • Note that there are 2 time constants ( ? and 1/?)
    which enter into the equations, so we may expect
    that the time evolution will somehow involve
    these 2 time constants.
  • We have a system of two differential equations in
    1st-order in 2 variables, n and C. The usual
    form of solution tried for linear differential
    equations is the exponential form, so lets try
  • Substituting this form into Eqs. (6) (7)
    yields, after division of both sides by the
    common factor e?t, found in every term

10
Solution of Point-Kinetics Equation
  • These are in fact 2 homogeneous equations in 2
    unknowns
  • We know that there will be a non-trivial solution
    only if the determinant is zero, i.e.,
  • There are 2 ways to attack this equation
  • One is to realize that this is a quadratic
    equation, whose roots can be found. Well come
    back to this method later.
  • The other method is graphical. In this approach,
    the form of the equation usually seen is obtained
    by writing ? in terms of l. Remember from Eq.
    (19) in the previous presentation

11
Inhour Equation
  • Eq. (15) then becomes
  • This form of the equation is called the Inhour
    equation (for 1 delayed-neutron-precursor group).
  • The Inhour equation is not easy to solve, as the
    left-hand side is a discontinuous function which
    goes to ?? at 2 values of ? (at G1 values of ?
    if we had done the analysis with many
    delayed-neutron-precursor groups).
  • The way to visualise the solutions is to plot the
    left-hand side in terms of ?, and see where it
    crosses a horizontal line at height ?.

12
Inhour Equation
  • To plot Eq. (16), we need to note the following
    features

13
Inhour Equation (cont.)
  • The plots of the l.h.s. and r.h.s. of Eq. (16)
    are then as follows From Lamarsh
  • There are always 2
  • solutions for ?
  • When ? lt 0, both
  • ? values are negative
  • When ? gt 0, one
  • ? value is positive, and
  • the other is negative.
  • When ? 0, one
  • ? value is 0, the other is
  • is negative.

14
General Solution for 1 Precursor Group
  • Thus there are always 2 values of ? as solutions,
    and consequently the general solution for the
    neutron density and the precursor concentration
    is a sum of 2 exponentials
  • By convention, lets agree that ?1 is the
    algebraically larger solution, i.e., the
    rightmost one.
  • Note that l is very small (1 ms), therefore the
    vertical line at 1/l is very much to the left of
    the line at ? (i.e., the figure is far from being
    to scale).
  • Thus, although ?2 is algebraically smaller (i.e.,
    it is the one on the left), in absolute magnitude
    it is much larger than ?1

15
General Solution for 1 Precursor Group
  • Physically, l is the time constant at which the
    neutron density (or power) would evolve without
    delayed neutrons (as we showed before), whereas
    1/? is the time constant corresponding to the
    delayed neutrons.
  • Because of the coupled nature of the kinetics
    equations, the time constants for the evolution
    of the neutron density (and power) are not equal
    to l or 1/?, but at least one of the time
    constants is intermediate between these values.

16
General Solution for 1 Precursor Group (cont.)
  • Summarizing, therefore
  • In the general solution, then, the exponential
    term in ?2 will first die away (quite quickly),
    and the term in ?1 will remain as the asymptotic
    time evolution of the neutron density
  • increasing exponentially if ? gt 0, decreasing
    exponentially if
  • ? lt 0, and tending to a constant value if ?
    0.

17
Stable Period
  • Since the asymptotic evolution of the neutron
    density (or the flux, or power) will be
    proportional to the exponential , then we
    can write
  • which will be a positive period (increasing
    flux) if ?1gt0, and a negative period if ?1lt0.

18
Kinetics with 6 Delayed-Neutron-Precursor Groups
  • If we retain 6 delayed-neutron precursor groups,
    the analysis will be similar, but the Inhour
    equation will have 7 roots instead of just 2.
    The graphic representation of the Inhour is
    from Duderstadt Hamilton

19
Kinetics with G Delayed-Neutron-Precursor Groups
  • Generalizing to any number (G) of delayed-neutron
    precursors, the point-kinetics equations will be
  • and in this case the inhour equation will be
  • which will have (G2) branches and (G1)
    roots.
  • If ?lt0 all roots will be negative, but
  • If ?gt0 one root will be positive (?1), and all
    other roots will be negative

20
Kinetics with G Delayed-Neutron-Precursor Groups
  • With G delayed-neutron-precursor groups, then,
    the general solution will be a sum of (G1)
    exponentials,

21
General Solution
  • By convention, we denote ?1 the algebraically
    largest root (i.e., the rightmost one on the
    graph)
  • ?1 has the sign of ?.
  • Since all other ? values are negative (and more
    negative than ?1 if ?1 lt0), the exponential in ?1
    will survive longer than all the others.
  • Therefore, the eventual (asymptotic) form for n
    and Cg is exp(?1t), i.e., the power will
    eventually grow or drop with a stable (or
    asymptotic) period .

22
General Solution (cont.)
  • In summary, for the asymptotic time dependence
  • For ? not too large and positive (i.e., except
    for positive reactivity insertions at prompt
    criticality or above)
  • , i.e., things evolve much more
    slowly than without delayed neutrons

23
Situation at Steady State
  • The point-kinetics equations apply even in steady
    state, with ?0.
  • The relationship between the precursor
    concentrations and the neutron density can be
    obtained by setting the time derivatives to 0 in
    the point-kinetics equations. For G precursor
    groups at steady state (subscript ss)
  • From Eq. (26) we get
  • Summing Eq. (27) over all g yields back Eq. (25),
    since

24
Prompt-Jump (or Drop) Approximation
  • We have seen that the time evolution of the
    flux/power is a sum of exponentials, all with
    negative exponent, except for a single one if ? gt
    0.
  • In either case, whether ? gt 0 or lt0. the
    exponential with the (algebraically) largest
    exponent, ?1, will quickly be the surviving one,
    the other exponentials dying away more quickly.
  • In a sudden insertion of reactivity (whether gt 0
    or lt 0) in a reactor running steadily, there will
    therefore be a prompt jump or prompt drop, during
    which these dying exponentials die away, after
    which the flux/power will be on an exponential
    behaviour with a stable period 1/?1 (see figure).

25
Prompt Jump
  • Illustration of prompt jump prompt drop is
    similar

26
Estimating the Prompt Jump/Drop
  • An estimate of the size of the prompt jump (or
    drop) can be obtained most easily by making the
    following approximations
  • 1) The delayed-neutron-precursor concentrations
    cannot change substantially during the prompt
    jump, therefore the precursor concentration at
    the start of the stable period can be taken equal
    to the steady-state value.
  • 2) The derivative of the time evolution at the
    start of the stable period is much smaller than
    the derivative during the prompt jump, therefore
    the derivative at the start of the stable period
    can be approximated by zero.
    contd

27
Estimating the Prompt Jump/Drop (cont.)
  • Lets do this estimate with one precursor group,
    for simplicity

28
Prompt-Jump Invalidity
  • What happens if ? gt ? ? We can see from Eq. (30)
    that the r.h.s. would be negative, i.e. n would
    be lt 0!
  • This is a symptom that the prompt-jump
    approximation breaks down when the value of
    (positive) ? comes close to the value of ?.
  • The reason that it breaks down is that as ?
    increases and crosses the value of ?, the value
    of ?1 becomes very large (the exponential
    increases extremely rapidly), and the
    approximation of setting the derivative of n to
    zero simply breaks down.
  • Note that this is not the case for any negative
    value of ? The prompt-drop approximation does
    not break down.

29
Prompt Criticality
  • The condition ? ? corresponds to
  • This means that keff or gt1 even if we ignore
    the delayed neutrons (? ), i.e., the reactor is
    critical on prompt neutrons alone. This
    condition is called prompt criticality.
  • The delayed neutrons then no longer play a
    crucial role, and when ? increases beyond ?
    (prompt supercriticality), very very short
    reactor periods (lt 1 s, or even much smaller,
    depending on the magnitude of ?) develop.
  • Thus, it is advisable to avoid prompt
    criticality.
  • The next slide shows how the period changes above
    prompt criticality for various prompt-neutron
    lifetimes.

30
Reactor Period vs. Reactivity for Various
Prompt-Neutron Lifetimes
31
Alternate Treatment for 1 Precursor Group
  • Now that we have analyzed the kinetics by means
    of the Inhour equation, we will return to
    investigate the alternate solution for the ?
    values, for 1 precursor group. We return to Eq.
    (15)
  • This is in fact a quadratic equation in ?
  • We can write the exact two solutions for ?

32
Alternate Treatment for 1 Precursor Group (cont.)
  • We can see that ?1 and ?2 are respectively the
    solutions with the plus sign and the minus sign
    in front of the square root.
  • Under these conditions, then, we can see that

33
Alternate Treatment for 1 Precursor Group (cont.)
  • As for ?1
  • The general solution is

34
Alternate Treatment for 1 Precursor Group (cont.)
  • Each C is related to its corresponding n as per
    Eq. (12)
  • Therefore Eqs. (35) (36) become

35
Alternate Treatment for 1 Precursor Group (cont.)
  • So Eqs. (35) (36) become, at t 0

36
Alternate Treatment for 1 Precursor Group (cont.)
  • Using the value of ?1 from Eq. (34),

37
Summary
  • This presentation has focused on presenting the
    principles and concepts of delayed-neutron
    influence on the kinetics of a reactor core.
  • Most of the analysis was based on a
    1-delayed-neutron-precursor-group model. Some of
    the analysis was generalized to 6 or G precursor
    groups.
  • However, remember that all the analysis was based
    on point kinetics, in which the flux shape did
    not change.
  • In reality, for a more accurate analysis of what
    happens in neutronic transients, spatial kinetics
    is required. We will not cover this here.

38
  • END
Write a Comment
User Comments (0)
About PowerShow.com