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Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019

Large Eddy Simulation of Azimuthal Instability in a Model Annular Gas Turbine Combustor

Zhi X. Chen & N. SwaminathanUniversity of Cambridge

Department of Engineering

longitudinal mode transition azimuthal mode

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �2

Outline

• Background – thermoacoustic instabilities & azimuthal mode

• LES formulation and combustion modelling

• Simulation of a model annular combustor

‣ Single sector – grid sensitivity and flame transfer function (ext. forcing)

‣ 12 burner full annular – self-excited oscillations

• Summary and future work

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �3

Outline

• Background – thermoacoustic instabilities & azimuthal mode

• LES formulation and combustion modelling

• Simulation of a model annular combustor

‣ Single sector – grid sensitivity and flame transfer function (ext. forcing)

‣ 12 burner full annular – self-excited oscillations

• Summary and future work

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �4

Thermoacoustic instabilities

• Fuel lean combustion is prone to thermoacoustic instabilities in gas turbines.

1. W. Polifke, 2nd Colloquium on Combustion Dynamics and Combustion Noise Menaggio, Sept. 20-22, 20162. Altunlu et al., J. Eng. Gas Turbines Power 136 (2014) 051510.3. N. Noiray, https://caps.ethz.ch/research/thermoacoustics.html.

Image sources:

1

1

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �4

Thermoacoustic instabilities

• Fuel lean combustion is prone to thermoacoustic instabilities in gas turbines.

1. W. Polifke, 2nd Colloquium on Combustion Dynamics and Combustion Noise Menaggio, Sept. 20-22, 20162. Altunlu et al., J. Eng. Gas Turbines Power 136 (2014) 051510.3. N. Noiray, https://caps.ethz.ch/research/thermoacoustics.html.

Image sources:

1

1

2

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �4

Thermoacoustic instabilities

• Fuel lean combustion is prone to thermoacoustic instabilities in gas turbines.

1. W. Polifke, 2nd Colloquium on Combustion Dynamics and Combustion Noise Menaggio, Sept. 20-22, 20162. Altunlu et al., J. Eng. Gas Turbines Power 136 (2014) 051510.3. N. Noiray, https://caps.ethz.ch/research/thermoacoustics.html.

Image sources:

1

1

2

3

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �5

Azimuthal mode

• Azimuthal mode instabilities are more complex, damaging and not yet well understood.

1. WSJ research; Rolls Royce2. M. Bauerheim et al., Phys. Fluids 28 (2016) 021303.

Image sources:

1

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �5

Azimuthal mode

• Azimuthal mode instabilities are more complex, damaging and not yet well understood.

1. WSJ research; Rolls Royce2. M. Bauerheim et al., Phys. Fluids 28 (2016) 021303.

Image sources:

1

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �5

Azimuthal mode

• Azimuthal mode instabilities are more complex, damaging and not yet well understood.

1. WSJ research; Rolls Royce2. M. Bauerheim et al., Phys. Fluids 28 (2016) 021303.

Image sources:

1

2

Smaller acoustic length compared to longitudinal modes

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �5

Azimuthal mode

• Azimuthal mode instabilities are more complex, damaging and not yet well understood.

1. WSJ research; Rolls Royce2. M. Bauerheim et al., Phys. Fluids 28 (2016) 021303.

Image sources:

1

2

Smaller acoustic length compared to longitudinal modes

Higher frequency and amplitude

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �5

Azimuthal mode

• Azimuthal mode instabilities are more complex, damaging and not yet well understood.

1. WSJ research; Rolls Royce2. M. Bauerheim et al., Phys. Fluids 28 (2016) 021303.

Image sources:

1

2

Smaller acoustic length compared to longitudinal modes

Higher frequency and amplitude

LES Onset of azimuthal instabilities

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �6

Outline

• Background – thermoacoustic instabilities & azimuthal mode

• LES formulation and combustion modelling

• Simulation of a model annular combustor

‣ Single sector – grid sensitivity and flame transfer function (ext. forcing)

‣ 12 burner full annular – self-excited oscillations

• Summary and future work

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �7

LES and combustion modelling

• 3D filtered N-S equations (mass, momentum and energy) are solved

• Compressibility effects are considered: pressure work heating, equation of state

1. Z.X. Chen et al., Combust. Flame 203 (2019) 279.2. Z.X. Chen et al., Proc. Combust. Inst. 37 (2019) 2325.

Refs:

Premixed

Non-premixed

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �8

Outline

• Background – thermoacoustic instabilities & azimuthal mode

• LES formulation and combustion modelling

• Simulation of a model annular combustor

‣ Single sector – grid sensitivity and flame transfer function (ext. forcing)

‣ 12 burner full annular – self-excited oscillations

• Summary and future work

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �9

Cambridge/NTNU gas turbine model annular combustor

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �9

Cambridge/NTNU gas turbine model annular combustor

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �10

Single sector – grid sensitivity and flame transfer function

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �10

Single sector – grid sensitivity and flame transfer function

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �10

Single sector – grid sensitivity and flame transfer function

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �10

Single sector – grid sensitivity and flame transfer function

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

U = A Ubsin(2πft)

Ub = 15 m /s

f = 1800 Hz(1st azim. mode)

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �10

Single sector – grid sensitivity and flame transfer function

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

U = A Ubsin(2πft)

Ub = 15 m /s

f = 1800 Hz(1st azim. mode)

FTF =·q′�/ ·q

U′�0/U0

= G(ω) eiΦω

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �10

Single sector – grid sensitivity and flame transfer function

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

U = A Ubsin(2πft)

Ub = 15 m /s

f = 1800 Hz(1st azim. mode)

FTF =·q′�/ ·q

U′�0/U0

= G(ω) eiΦω

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �10

Single sector – grid sensitivity and flame transfer function

1. Worth et al., Combust. Flame 160 (2013) 2476–24892. Mazur et al., Proc. Combust. Inst. 37 (2019) 5129–5136.

Refs:

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

U = A Ubsin(2πft)

Ub = 15 m /s

f = 1800 Hz(1st azim. mode)

FTF =·q′�/ ·q

U′�0/U0

= G(ω) eiΦω

·q = ∫VHRR(x, t) dV

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �11

Single sector – grid sensitivity for temperature and velocity fields

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

Unforced

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �11

Single sector – grid sensitivity for temperature and velocity fields

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

Unforced

x /D = 21

0.5

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �11

Single sector – grid sensitivity for temperature and velocity fields

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

Unforced

x /D = 21

0.5

-2 -1.5 -1 -0.5 0 0.5 1 1.5 2r/D

0

500

1000

1500

2000

2500

<! T>

[K]

-2 -1.5 -1 -0.5 0 0.5 1 1.5 2r/D

-10

0

10

20

30

40

<! U>

[m/s]

1M2M

-2 -1.5 -1 -0.5 0 0.5 1 1.5 2r/D

-10

0

10

20

30

40

<! U>

[m/s]

-2 -1.5 -1 -0.5 0 0.5 1 1.5 2r/D

-10

0

10

20

30

40<

! U>

[m/s]

-2 -1.5 -1 -0.5 0 0.5 1 1.5 2r/D

0

500

1000

1500

2000

2500

<! T>

[K]

-2 -1.5 -1 -0.5 0 0.5 1 1.5 2r/D

0

500

1000

1500

2000

2500

<! T>

[K]

Mean axial velocity Mean temperature

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �12

Single sector – grid sensitivity for flame transfer function

U = A Ubsin(2π ft)

·q = ∫VHRR(x, t) dV

FTF =·q′�/ ·q

U′�0 /U0

= G(ω) eiΦω

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �12

Single sector – grid sensitivity for flame transfer function

U = A Ubsin(2π ft)

·q = ∫VHRR(x, t) dV

FTF =·q′�/ ·q

U′�0 /U0

= G(ω) eiΦω

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

Two excitation amplitudes are tested:5% & 10%

p′�/p < 1 %

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �12

Single sector – grid sensitivity for flame transfer function

U = A Ubsin(2π ft)

·q = ∫VHRR(x, t) dV

FTF =·q′�/ ·q

U′�0 /U0

= G(ω) eiΦω

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

Two excitation amplitudes are tested:5% & 10%

p′�/p < 1 %

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �12

Single sector – grid sensitivity for flame transfer function

U = A Ubsin(2π ft)

·q = ∫VHRR(x, t) dV

FTF =·q′�/ ·q

U′�0 /U0

= G(ω) eiΦω

Grid G1 G2

2 1.2

No. Cells 1.4M 2.1M

Δx /δ0th

Two excitation amplitudes are tested:5% & 10%

p′�/p < 1 %

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �13

Outline

• Background – thermoacoustic instabilities & azimuthal mode

• LES formulation and combustion modelling

• Simulation of a model annular combustor

‣ Single sector – grid sensitivity and flame transfer function (ext. forcing)

‣ 12 burner full annular – self-excited oscillations

• Summary and future work

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �14

Computed pressure signals in the plenum tubes

longitudinal mode transition azimuthal mode

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �14

Computed pressure signals in the plenum tubes

longitudinal mode transition azimuthal mode

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �14

Computed pressure signals in the plenum tubes

longitudinal mode transition azimuthal mode

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �14

Computed pressure signals in the plenum tubes

longitudinal mode transition azimuthal mode

Computational cost: 48 hrs on wall-clock for 0.1s using 1248 cores, 20M cells —> 900 kAUs

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �15

Longitudinal mode

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �16

Azimuthal mode

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �17

Longitudinal -> Azimuthal mode transition in frequency domain

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �18

Heat release rate fluctuations and acoustic mode structure

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �19

Outline

• Background – thermoacoustic instabilities & azimuthal mode

• LES formulation and combustion modelling

• Simulation of a model annular combustor

‣ Single sector – grid sensitivity and flame transfer function (ext. forcing)

‣ 12 burner full annular – self-excited oscillations

• Summary and future work

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �20

• Azimuthal instability in a model annular combustor

is studied using LES

• LES are performed in two steps:

‣ Single sector – grid sensitivity and flame transfer function (external forcing)

‣ 12 burner full annular – self-excited oscillations:

transition from longitudinal to azimuthal mode

• Projected future works:

‣ Analyse the LES data to study mode switching

‣ Non-adiabatic simulations

Summary and future work

/21Zhi Chen | UKCTRF Annual Meeting, Imperial College, London | 11.09.2019 �21

Thank you for listening!

Questions?

Acknowledgements

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