Wind speed profiles over Greater London, UKbl_met/actual/non_protect... · Wind speed profile...

Wind speed profiles over Greater London, UK Daniel Drew, Janet Barlow and Siân Lane

Introduction

• Vertical wind speed profiles are required to address a

number of wind engineering problems:

• Dispersion of pollution

• Designing tall buildings

• Several theoretical and empirical models:

• Power law

• Log law

• Deaves and Harris model

Wind speed profile models

• Log law (Eurocode)

𝑈 𝑧 =𝑢∗

𝜅ln

𝑧0 z0=0.8 m for an urban surface (Cook, 1985).

• Deaves and Harris Model (UK, Australia)

𝑈 𝑧 =𝑢∗𝑘

𝑙𝑛𝑧

𝑧0+ 5.75

ℎ− 1.88

− 1.33𝑧

+ 0.25𝑧

h, the height of the boundary layer is assumed to equal 3250 m.

Introduction

• Vertical wind speed profiles are required to address a

number of wind engineering problems:

• Dispersion of pollution

• Designing tall buildings

• Several theoretical and empirical models:

• Power law

• Log law

• Deaves and Harris model

• Little validation of models, particularly in urban areas.

• Assessed wind speed profile over Greater London.

The surrounding surface is very heterogeneous (parks, urban, river)

Gill instruments R3-50 ultrasonic anemometer

•Measures horizontal and vertical components of wind.

•Sampling frequency = 20 Hz

Instruments at BT Tower (190 m)

Observations analysed to estimate:

𝑈∗2 = 𝑢′𝑤′2 + 𝑣′𝑤′2

𝐿 =−𝑢∗

𝜅𝑔 𝑤′𝑇′

Halo Photonics Streamline pulsed Doppler lidar

•Fully programmable scanner

•Doppler Beam Swinging Method

•Gate length = 30 m

•80 measurement gates

•Instrument location = 20 m above ground level

•Min. measurement height = 90 m above lidar (110 m above ground)

•Profile every 2 minutes

•21st May 2011 – 6th Jan 2012

Doppler beam swinging method

• Three-beam wind-profiling method

• Derives wind speeds from one vertical and two tilted beams

• 2 s of data taken consecutively in each direction (40,000 pulses)

• Short scan time means flow will not change much over scan period.

• Interval between scans = 120 s

• See Pearson et al. (2009) for comparison with other methods in a rural setting.

θ = 15°

Halo Photonics Streamline pulsed Doppler lidar

•Fully programmable scanner

•Doppler Beam Swinging Method

•Gate length = 30 m

•80 measurement gates

•Instrument location = 20 m above ground level

•Min. measurement height = 90 m above lidar (110 m above ground)

•Profile every 2 minutes

•21st May 2011 – 6th Jan 2012

30th September 2011

Mean wind speed profile

• Derived from 5500 hours of observations

• Compared with the 3 models

Surface dependent

parameters (Cook, 1997)

z0=0.8 m

h=3250 m

α=0.32

Stability

• Data filtered by stability derived from BT tower observations.

13 UQ25 UQ50 UQ75

High wind speeds

U<UQ25

MEDIUM:

UQ25<U<UQ50

UQ50<U<UQ75

VERY HIGH:

U>UQ75

Terrain dependent parameters

Roughness length, z0

• Derived from log law using

u* observed at BT tower.

• Morphological values determined in Wood et al. (2010).

z0mean= 0.6 m

z0mean= 0.9 m

Power law exponent, α

• Derived from wind profile

observations.

• Good agreement for

westerly winds.

𝛼 =1

ln(𝑧1𝑧2)

αmean= 0.23

Boundary layer height, h

ℎ =𝑈∗

hmean= 1050 m

Model comparison

Conclusions

Future Work

• Presented wind speed profiles derived from lidar observations.

• High wind speeds occur during neutral conditions. • High wind speed profile shows reasonable fit with

model profiles (log law and Deaves and Harris).

• Lack of Doppler lidar observations below 90 m restricts potential to assess wind loading models- potential for Sodar.

Extra slides

Doppler beam swinging method

• Three-beam wind-profiling method

• Derives wind speeds from one vertical and two tilted beams

• 2 s of data taken consecutively in each direction (40,000 pulses)

• Short scan time means flow will not change much over scan period.

• Interval between scans = 120 s

• See Pearson et al. (2009) for comparison with other methods in a rural setting.

θ = 15°

. of d

Wind speed (60 minute average)

•60 minute average used to include sufficient data from lidar.

•Some of RMSE can be explained by standard error (average SE = 0.4 ms-1).

•Some difference likely due to large separation between instruments.

Y=0.98x+0.56

RMSE=1.4

Weighted best fit

Wind speed profiles over Greater London, UKbl_met/actual/non_protect... · Wind speed profile...

Documents

Transcript of Wind speed profiles over Greater London, UKbl_met/actual/non_protect... · Wind speed profile...

Visibility in smoke - FSMF.UKVisibility in CFD –how do we calculate it? C factor for light emmiting: 0−initial contrast 𝑧−coef. characterizing illumination of the dispersion

Multi-dimensional Parallel Discontinuous Galerkin …...Sample 2D Mesh −Δ = 𝑖 Ω = Γ 𝜕𝑢 𝜕𝑛 = 𝑛 Γ𝑁 • We want to solve through numerical method ... Dr. Ohannes

A Practical Review of Earth Pressure Theory and the ... › documents › webinar_resources › Earth-P… · Fellenius (1927) H c 𝑧= 𝑺𝒖 Tension Crack 𝜸 intersecting a

An Anisotropic Shear Strength Model for Cyclic Accumulated ... · Phenomenological laws are put forward for the cyclic translation 𝜂 and the cyclic hardening 𝜅 respectively.

12. Thermal and scalar field analysiswood, the governing equation again takes on a more complicated form 𝜅 ( , ) 𝜕 2 𝜕 2 +𝜅 ( , ) 𝜕 𝜕 2 = ( , ) The most general form

The evolution of radio luminosity function of star forming ... · The evolution of radio luminosity function of star forming galaxies and AGNs up to 𝑧∼5.5 Kai Kono, Tsutomu T.

Estadística Inferencial - moodle2.unid.edu.mxmoodle2.unid.edu.mx/dts_cursos_mdl/ejec/ME/EI/S05/EI05_Lectura.pdf · La probabilidad de que la variable aleatoria normal 𝑧 estándar

Signals and Systems - commsp.ee.ic.ac.uktania/teaching/SAS 2017/Lecture 15.pdf · Discrete time signals. 𝑧− ... Solution 𝑋[𝑧] ... causal continuous-time systems and the

State-of-the-Art in Chemical Reaction Characteristics ...bigchem.eu/sites/default/files/Timur_Madzhidov.pdf · Activation Free Energy ΔG Free Energy of Reaction 𝑘=𝜅 𝑘𝐵𝑇

An energy efficiency evaluation method based on least squares …ifk2018.com/frontend/converia/media/FPCA18/Presentations/... · 2018. 7. 20. · ⋯ 𝑢1 ⋯ 𝑢2 ⋮ ⋮ 𝑢

Greater London - met.reading.ac.ukbl_met/actual/non_protect... · Wind speed profile models • Power Law (Japan, Canada) 𝑈𝑧=𝑈𝑟 𝑧 𝑧𝑟 ∝ α =0.32 for an urban

1 >1 dan 𝑛+1 =2− untuk 𝑛∈𝑁. Tunjukan (bahwa 𝑛 𝑥𝑛 · 2020. 6. 21. · Diberikan 𝐴⊂𝑅 tak berhingga yang terbatas ke atas dan misalkan 𝑢≔sup𝐴. Tunjukan

Unsupervised Learning: Generation - 國立臺灣大學speech.ee.ntu.edu.tw/~tlkagk/courses/ML_2017/Lecture/GAN (v3).pdf · 𝑔𝑃 =න 𝑧 𝑧| 𝑔𝑃 𝑧q(z|x) can be any

SIMULASI Kendalan Reliability Simulation)*zacoeb.lecture.ub.ac.id/files/2015/12/XIII-Simulasi.pdf · Φ𝑧=1−Φ−𝑧 ... x adalah mean dan standar deviasi. 7 Bilangan Acak dengan

The Analytical Form of the Dispersion Equation of …downloads.hindawi.com/journals/amp/2017/5236898.pdfAdvancesinMathematicalPhysics 5 See(3). W =(𝑢 𝑧,𝜎𝑧𝑧,𝑢𝑥,𝜎𝑥𝑧,𝑢𝑦,𝜎𝑦𝑧)

Thermodynamik I – Übung 1 - ETH Zürichsemmarco/download/2020 HS...;nur ein Wärmestrom → = 𝐺 2− 1− 𝑧 Da der Exergieanteil durch Wärme als reversibel betrachtet wird,

INTRODUCTION TO CHEMICAL PROCESS …cacheme.org/wp-content/uploads/2016/09/INTRODUCTION-TO...The reaction follows the next kinetic law: =𝑘𝐹 𝑀 »𝑢 𝐻−𝑘𝑅 𝑀 𝐻

Matematiikan kotitehtävä 1, MAA 12 Algoritmit matematiikassa … · eri arvot, kun J saa arvot nollasta sataan. Lista 2 laskee summat ∑ 𝑧 𝑛 =02𝑛 kun J saa arvot nollasta

Beam Modeling New Developments - BETA CAE Systems · RSECTBT - A new R-type element RSECTBT RBE2 (Rigid Body Modes) m i 𝑢 𝑖=𝑢 𝑚+𝑎 1𝜃 𝑚+𝑎 2𝜃 𝑚+𝑎 3𝑠

Geroliminis, N., Daganzo, C.F., Existence of urban …bin.t.u-tokyo.ac.jp/rzemi11/test/瀧口１.pdf•平日（濃線）休日（薄線）の 𝑢， 𝑢の時間変化 – 𝑢を平均交通量，