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Extreme Winds in Kuwait Including the Effect of Climate Change 109 Fig. 20. The predicted extreme gust speed for different return periods from the three different data groups for the year range 1957-1974, 1975-1992 and 1993-2009. Fundamental and Advanced Topics in Wind Power 110 5. Conclusions Extreme wind speed from different directions and for return periods of 10, 25, 50, 100 and 200 years were predicted for five different locations in Kuwait Viz. Kuwait International Airport (KIA), Kuwait Institute for Scientific Research (KISR), Ras Al-Ardh, Failaka Island and Al-Wafra. Measured wind speed by the Meteorological office of KIA is used for this analysis. The wind speeds are measured at 10 m elevation from the ground and the data value is the average of 10 minutes duration. For KIA location, data is available for 45 years (From 1962 to 2006). For other locations, measured data is available for about 12 years. The annual maximum measured wind speed data at KIA location is used as input for the extreme value analysis for KIA location, whereas the monthly maximum measured wind speed data is used for other locations. The extreme 10 minute average wind speeds are predicted based on Gumbel distribution. The wind speed on the earth is dictated by the spatial gradient of the atmospheric pressure which in turn is governed by the temperature gradient. The long term climate change affects the temperature gradients and hence the wind speed. Extreme wind and Gust speed for different return periods is an important input for safe and economic design of tall structures, power transmission towers, extreme sand movement in desert and its effects on farm land and related infrastructures. The updated wind and Gust speed data from Kuwait International Airport (measured data for 54 years from 1957 to 2009) is divided into 3 equal periods, i.e. 1957-1974, 1975-1992, 1993- 2009, each of 18 years duration. Extreme value analysis is also carried out on these three sets of data to understand the climate change effect on the extreme wind speed. The following important conclusions are obtained based on the study:- a. Among the five locations selected for the study, KIA area is expected to experience the highest wind speed from ENE, ESE, SSE, S, SSW, SW, WSW, W, and WNW directions. KISR area is expected to experience the highest wind speed from NW and NNW. Ras Al-Ardh area is expected to experience the highest wind speed from SE. Failaka Island is expected to experience the highest wind speed from N, NE and E. Al-Wafra Island is expected to experience the highest wind speed from NNE. b. Even though the total land area of Kuwait is about 17,818 km 2 , the variation of space has very significant effect on the predicted extreme wind speeds in Kuwait. For example, the 100 year return period wind speed from NW direction varies from 21 m/s to 27 m/s, when the location is changed from Ras Al-Ardh to KISR. Similarly, the 100 year return period wind speed from SW direction varies from 18 m/s to 31 m/s, when the location is changed from Al-Wafra to KIA. Similarly, the 100 year return period wind speed from SE direction varies from 16 m/s to 23 m/s, when the location is changed from KISR to Ras Al-Ardh. c. Hence it is strongly recommended that both the effect of wind direction as well as the location need to be considered, while selecting the probable extreme wind speed for different return periods for any engineering or scientific applications. The results of the present study can be useful for the design of tall structures, wind power farms, the extreme sand transport etc in Kuwait. d. It is found that the extreme 10 minute average wind speed for 100 year return period is 31.4, 26.5 and 21.8 m/s based on the data set for 1957-1974, 1975-1992, 1993-2009. e. The extreme gust speed for 100 year return period is 43.1, 38.4 and 33.0 m/s for the same data sets. Extreme Winds in Kuwait Including the Effect of Climate Change 111 f. It is clear from the study that long term climate change has reduced the extreme wind speeds in Kuwait. g. This information will be useful for various engineering works in Kuwait. Further investigation is needed to understand why the extreme wind speed for any return period is reducing when the latest data set is used compared to the oldest data set. 6. Acknowledgements The authors wish to acknowledge the Kuwait International Airport authorities for providing the data for the present research work. We are grateful to Warba Insurance Company (K.S.C.) and Kuwait Foundation for the Advancement of Sciences (KFAS) for the financial support for the project. We thank Kuwait Institute for Scientific Research, Kuwait for providing all the facilities for carrying out the research work. 7. References Abdal,Y., Al-Ajmi, D., Al-Thabia, R., and Abuseil, M., 1986. Recent trends in Wind direction and Speed in Kuwait. Kuwait Institute for Scientific Research, Report No. 2186, Kuwait. Al-Madani, N., Lo, J. M., and Tayfun, M. A., 1989. Estimation of Winds over the Sea from Land Measurements in Kuwait. Kuwait Institute for Scientific Research, Report No. 3224, Kuwait. Al-Nassar, W., Al-Hajraf, S., Al-Enizi, A., and Al-Awadhi, L., 2005. Potential Wind Power Generation in the State of Kuwait, Renewable Energy, Vol. 30, 2149-2161. Ayyash, S., and Al-Tukhaim, K., 1986. Survey of Wind speed in Kuwait. Kuwait Institute for Scientific Research, Report No. 2037, Kuwait. Ayyash, S., and Al-Ammar, J., 1984. Height variation of wind speed in Kuwait. Kuwait Institute for Scientific Research, Report No. 1402, Kuwait. Ayyash, S., Al-Tukhaim, K., Al-Jazzaf, M., 1984. Statistical aspects of Wind speed in Kuwait. Kuwait Institute for Scientific Research, Report No. 1378, Kuwait. Ayyash, S., Al-Tukhaim, K., Al-Ammar, J., 1985. Assessment of Wind Energy for Kuwait. Kuwait Institute for Scientific Research, Report No. 1661, Kuwait. Ayyash, S., Al-Tukhaim, K., Al-Ammar, J., 1984. Characteristics of Wind Energy in Kuwait. Kuwait Institute for Scientific Research, Report No. 1298, Kuwait. Climatological Summaries, Kuwait International Airport 1962-1982., 1983. State of Kuwait, Directorate General of Civil Aviation, Meteorological Department, Climatological Division. EPA, 1987. On-Site Meteorological Program Guidance for Regulatory Modeling Applications, EPA-450/4-87-013, Office of Air Quality Planning and Standards, Research Triangle Park, NC, 27711 EPA, 1989. Quality Assurance Handbook for Air Pollution Measurement System, Office of Research and Development, Research Triangle Park, NC, 27711. Gopalakrishnan, T.C., 1988. Analysis of wind effect in the numerical modeling of flow field. Kuwait Institute for Scientific Research. Report No.2835-B, Kuwait. Gomes, L. and Vickery, B.J. (1977). “On the prediction of extreme wind speeds from the parent distribution”, Journal of Wind Engineering and Industrial Aerodynamics, Vol. 2 No. 1, pp.21-36. Fundamental and Advanced Topics in Wind Power 112 Gumbel, E.J., 1958. Statistics of Extremes. Columbia University Press, New York. Kristensen, L., Rathmann, O., and Hansen, S.O. (2000). “Extreme winds in Denmark”, Journal of Wind Engineering and Industrial Aerodynamics, Vol. 87, No. 2-3, pp.147-166. IPCC (2007). “Summary for Policymakers, in Climate Change 2007: Impacts, Adaptation and Vulnerability”. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, Cambridge University Press, Cambridge, UK, p. 17. Milne, R. (1992). “Extreme wind speeds over a Sitka spruce plantation in Scotland”, Agricultural and Forest Meteorology, Vol. 61, Issues 1-2, pp. 39-53. Neelamani, S. and Al-Awadi, L., 2004. Extreme wind speed for Kuwait. International Mechanical Engineering Conference, Dec. 5-8, 2004, Kuwait. Neelamani, S., Al-Salem, K., and Rakha, K., 2007. Extreme waves for Kuwaiti territorial waters. Ocean Engineering, Pergaman Press, UK, Vol. 34, Issue 10, July 2007, 1496- 1504. Neelamani, S., Al-Awadi, L., Al-Ragum, A., Al-Salem, K., Al-Othman, A., Hussein, M. and Zhao, Y., 2007. Long Term Prediction of Winds for Kuwait, Final report, Kuwait Institute for Scientific Research, 8731, May 2007. Simiu, E., Bietry, J., and Filliben, J.J., 1978. Sampling errors in estimation of extreme winds. Journal of the Structural Division, ASCE, Volume 104, 491-501. The State Climatologist, 1985. Publication of the American Association of State Standards for Sensors on Automated Weather Stations, Vol. 9, No.4. WMO, 1983. Guide to Meteorological Instruments and Methods of Observation, World Meteorological Organization, No.8, 5 th Edition, Geneva, Switzerland. Part 2 Structural and Electromechanical Elements of Wind Power Conversion 0 Efficient Modelling of Wind Turbine Foundations Lars Andersen and Johan Clausen Aalborg University, Department of Civil Engineering Denmark 1. Introduction Recently, wind turbines have increased significantly in size, and optimization has led to very slender and flexible structures. Hence, the Eigenfrequencies of the structure are close to the excitation frequencies related to e nvironmental loads from wind and waves. To obtain a reliable estimate of the fatigue life of a wind turbine, the dynamic response of the structure must be analysed. For this purpose, aeroelastic codes have been developed. Existing codes, e.g. FLEX by Øye (1996), HAWC by Larsen & Hansen (2004) and FAST by Jonkman & Buhl (2005), have about 30 degrees of freedom for the structure including tower, nacelle, hub and rotor; but they do not account for dynamic soil–structure interaction. Thus, the forces on the structure may be over or underestimated, and the natural frequencies may be determined inaccurately. q(t)q(t) Q( f ) ttf h t d M f , J f M n , J n E t I t , m t Rigid Rigid Flexible cylinder LPM Layer 1 Layer 2 Half-space Fig. 1. From prototype to computational model: Wind turbine on a footing over a soil stratum (left); rigorous model of the layered half-space (centre); lumped-parameter model of the soil and foundation coupled with finite-element model of the structure (right). 6 2 Will-be-set-by-IN-TECH Andersen & Clausen (2008) concluded that soil stratification has a significant impact on the dynamic stiffness, or impedance, of surface footings—even at the very low frequencies relevant to the first few modes of vibration of a wind turbine. Liingaard et al. (2007) employed a coupled finite-element/boundary-element model for the analysis of a flexible bucket foundation, finding a similar variation of the dynamic stiffness in the frequency range relevant for wind turbines. This illustrated the necessity of implementing a model of the turbine foundation into the aeroelasic codes that are utilized for design and analysis of the structure. However, since co mputation speed is of paramount importance, the model of the foundation should only add few degrees of freedom to the model of the structure. As proposed by Andersen (2010) and illustr ated in Fig. 1, this may be achieved by fitting a lumped-parameter model (LPM) to the results of a rigorous analysis, following the concepts outline by Wolf (1994). This chapter outlines the methodology for calibration and implementation o f an LPM o f a wind turbine foundation. Firstly, the f ormulation of rigorous computational models of foundations is discussed with emphasis on rigid footings, i.e. monolithic gravity-based foundations. A brief introduction to other types of foundations is given with focus on their dynamic stiffness properties. Secondly, Sections 2 and 3 provide an in-depth description of an efficient method for the evaluation of the dynamics stiffness of surface footings of arbitrary shapes. Thirdly, in Section 4 the concept of consistent lumped-parameter models is presented and the formulation of a fitting algorithm is discussed. Finally, Section 5 includes a numbe r o f example results that illustrate the performance of lumped-parameter models. 1.1 Types of foundations and their properties The gravity footing is the only logical choice of foundation for land-based wind turbines on residual soils, whereas a direct anchoring may be applied on intact rock. However, for offshore wind turbines a greater variety of possibilities exist. As illustrated in Fig. 2, when the turbines are taken to greater water depths, the gravity footing may be replaced by a mo nopile, a bucket foundation or a jacket structure. Another alternative is the tripod which, like the jacket structure, can be placed o n piles, gravity footings or s pud cans (suction anchors). T he latter case was studied by Senders (2005). In any case, the choice of foundation type is site dependent and strongly influenced by the soil properties and the environmental conditions, i.e. wind, waves, current and ice. Especially, current may involve sediment transport and scour on sandy and silty seabeds, which m ay lead to the necessity of scour protection around foundations with a large diameter or width. Regarding the design of a wind turbine foundation, three limit states must be analysed in accordance with most codes of practice, e.g. the Eurocodes. For offshore foundations, design is usually based on the design guidelines provided by the API (2000) o r DNV (2001). Firstly, the strength and stability of the foundation and subsoil must be high enough to support the structure in the ultimate limit state (ULS). Secondly, the stiffness of t he foundation should ensure that the displacements of the structure are below a threshold value in the serviceability limit state (SLS). Finally, the wind turbine must be analysed regarding failure in the fatigue limit state (FLS), and this turns out to be critical for large modern o ffshore wind turbines. The ULS is typically design giving for the foundations of smaller, land-based wind turbines. In the SLS and FLS the turbine m ay be regarded as fully fixed at the base, leading to a great simplification of the dynamic system to be analysed. However, as the size of the turbine increases, soil–structure interaction becomes stronger and due to the high flexibility of the structure, the first Eigenfrequencies are typically below 0.3 Hz. 116 Fundamental and Advanced Topics in Wind Power Efficient Modelling of Wind Turbine Foundations 3 (a) (b) (c) (d) Fig. 2. Different types of wind turbine foundations used offshore a various water depths: (a) gravity foundation; (b) monopile foundation; (c) monopod bucket foundation and (d) jacket foundaiton. An i mproper design may cause resonance d ue to the excitation from wind and waves, leading to immature failure in the FLS. An accurate prediction of the f atigue life span of a wind turbine requires a precise estimate of the Eigenfrequencies. This in turn necessitates an adequate model for the dynamic stiffness of the foundation and subsoil. The formulation of such models is the focus of such models. The reader is referred to standard text b ooks on geotechnical engineering for further reading about static behaviour of foundations. 1.2 Computational models of foundations for wind turbines Several methods can be used to evaluate the dynamic stiffness of footings resting on the surface of the ground or embedded within the soil. Examples include analytic, semi-analytic or semi-empirical methods as proposed by Luco & Westmann (1971), Luco (1976), Krenk & Schmidt (1981), Wong & Luco (1985), Mita & Luco (1989), Wolf (1994) and Vrettos (1999) as well as Andersen & Clausen (2008). Especially, torsional motion of footings was studied by Novak & Sachs (1973) and Veletsos & Damodaran Nair (1974) as well as Avilés & Pérez-Rocha (1996). Rocking and horizontal sliding motion of footings was analysed by Veletsos & Wei (1971) and Ahmad & Rupani (1999) as well as Bu & Lin (1999). Alternatively, numerical analysis may be conducted using the finite-element method and the boundary-element method. See, for example, the work by Emperador & Domínguez (1989) and Liingaard et al. (2007). For monopiles, analyses are usually performed by means of the Winkler approach in which the pile is continuously supported by springs. The nonlinear soil stiffness in the axial direction along the shaft is described by t–z curves, whereas the horizontal soil resistance along the shaft is provided by p–y curves. Here, t and p is the resulting force per unit length in the vertical and horizontal directions, respectively, whereas z and y are the corresponding displacements. For a pile loaded vertically in compression, a similar model can be formulated for the tip 117 Efficient Modelling of Wind Turbine Foundations 4 Will-be-set-by-IN-TECH resistance. More information about these methods can be found in the design guidelines by API (2000) and D NV (2001). Following this approach, El Naggar & Novak (1994a;b) formulated a model for vertical dynamic loading of pile foundations. Further studies regarding the axial response were conducted by Asgarian et al. (2008), who studied pile–soil interaction for an offshore jacket, and Manna & Baidya ( 2010), who compared computational and experimental re sults. In a similar manner, El Naggar & Novak (1995; 1996) studied monopiles subject to horizontal dynamic excitation. More work along this line is attributed to El Naggar & Bentley (2000), who formulated p–y curves for dynamic pile–soil interaction, and Kong et al. (2006), who presented a simplified method including the effect of separation between the pile and the soil. A further development of Winkler models for nonlinear dynamic soil behaviour was conducted by Allotey & El Naggar (2008). Alternatively, the performance of mononpiles under cyclic lateral loading was studied by Achmus et al. (2009) using a finite-element model. Gerolymos & Gaze tas (2006a;b;c) developed a Winkler model for static and dynamic analysis of caisson foundations fully embedded in linear or nonlinear soil. Further research regarding the formulation of simple models for dynamic response of bucket foundations was carried out by Varun et al. (2009). The concept of the monopod bucket foundation has been d escribed by Houlsby et al. (2005; 2006) as well as Ibsen (2008). Dynamic analysis of such foundations were performed by Liingaard et al. (2007; 2005) and Liingaard (2006) as well as Andersen et al. (2009). The latter work will be further described by the end of this chapter. 2. Semi-analytic model of a layered ground This section provides a thorough explanation o f a semi-analytical model that may be a pplied to evaluate the response of a layered, or stratified, ground. The derivation follows the original work by Andersen & Clausen (2008). The fundamental assumption is that the ground may be analysed as a horizontally layered half-space with each soil layer consisting of a homogeneous linear viscoelastic material. In Section 3 the model of t he ground will be used as a b asis for the development of a numerical method providing the dynamic stiffness of a foundation over a stratum. Finally, in Section 5 this method will be applied to the analysis of gravity-based foundations for offshore wind turbines. 2.1 Response of a layered half-space The surface displacement in time domain and in Cartesian space is denoted u 10 i (x 1 , x 2 , t)= u i (x 1 , x 2 ,0,t). Likewise the surface traction, or the load on the free surface, will be denoted p 10 i (x 1 , x 2 , t)=p i (x 1 , x 2 ,0,t). An explanation of the double superscript 10 is given in the next subsection. Here it is just noted that superscript 10 refers to the top of the half-space. Further, let g ij (x 1 − y 1 , x 2 − y 2 , t − τ) be the Green’s function relating the displacement at the observation point (x 1 , x 2 ,0) to the traction applied at the source point (y 1 , y 2 ,0).Both points are situated on the surface of a stratified half-space with horizontal interfaces. The total displacement at the point (x 1 , x 2 ,0) on the surface of the half-space is then found as u 10 i (x 1 , x 2 , t)=  t −∞  ∞ −∞  ∞ −∞ g ij (x 1 −y 1 , x 2 −y 2 , t −τ)p 10 j (y 1 , y 2 , τ) dy 1 dy 2 dτ.(1) The displacement at any point on the surface of the half-space and at any instant of time may be evaluated by means of Eq. (1). However, this requires the existence of the Green’s function g ij (x 1 −y 1 , x 2 −y 2 , t −τ), which may be interpreted as the dynamic flexibility. Unfortunately, 118 Fundamental and Advanced Topics in Wind Power [...]... and local coordinates for layer j with the depth h j The ( x1 , x2 , x3 )-coordinate j system has the origin O, whereas the local ( x1 , x2 , x3 )-coordinate system has the origin O j 121 7 Efficient Modelling ofFoundations Efficient Modelling of Wind Turbine Wind Turbine Foundations 2.2.2 Governing equations for wave propagation in a soil layer In the time domain, and in terms of Cartesian coordinates,... footing in the frequency domain: (a) displacements and rotations, and (b) forces and moments M1 1 35 21 Efficient Modelling ofFoundations Efficient Modelling of Wind Turbine Wind Turbine Foundations centre of the soil–foundation interface, the torsional and vertical displacements are completely decoupled from the remaining degrees of freedom Thus, the impedance matrix simplifies to ⎡ ⎤ Z11 Z12 0 Z14 Z 15. .. )-coordinates into the rotated wavenumbers (γ, α) Likewise, a transformation of the Cartesian coordinates ( x1 , x2 ) into the rotated (q, r )-coordinate frame is provided by the angle θ However, in order to simplify the analysis in cylindrical coordinates, it is convenient to introduce the angle ϑ = π/2 + ϕ − θ (60) 131 17 Efficient Modelling ofFoundations Efficient Modelling of Wind Turbine Wind Turbine... D33 = e( α S −α P ) h , D44 = e−2α P h , D 55 = D66 = e−( α P +α S ) h , j j j j j j j j j ( 35) 1 25 11 Efficient Modelling ofFoundations Efficient Modelling of Wind Turbine Wind Turbine Foundations j j j found by evaluation of the matrix e−α P x3 E j at x3 = h j Equations (34a) and (34b) may be combined in order to eliminate vector b j which contains unknown integration constants This provides a transfer... argument of the Bessel function of the first kind and order 1 The decay rate increases if the load is distributed over a large area in spatial domain, i.e if r0 is large However, at α = 0, the spectrum has a strong singularity 134 Fundamental and Advanced Topics Will-be-set-by -IN- TECH in Wind Power 20 2.6.3 A vertical “bell-shaped” surface load 10 Finally, applying a Gaussian distribution of P3 (r, ω )... μ j {k S }2 Δ = 0 ⇒ ⇒ (23) 123 9 Efficient Modelling ofFoundations Efficient Modelling of Wind Turbine Wind Turbine Foundations The last derivation follows from Eq (21) Further, Eqs (19) and (20) involve that j j μ j {k S }2 = λ j + 2μ j {k P }2 (24) Inserting this result into Eq (23), and once again making use of Eq (21), we finally arrive at the ordinary homogenous differential equation j d2 Δ j j... point ( x1 , x2 , 0) on the surface of the stratified or homogeneous ground due to a load applied in x2 , k 2 γ r, k r q, k q ϑ α ϕ θ x1 , k 1 x3 Fig 5 Definition of the three angles ϕ, θ and ϑ 132 Fundamental and Advanced Topics Will-be-set-by -IN- TECH in Wind Power 18 direction j over an area of rotational symmetry and centred around (0, 0, 0) In the general 10 case, P depends on both the angle ϑ and. .. (k1 , k2 , ω ) = Ril ( ϕ) Glm Rkm ( ϕ) (52 ) 128 Fundamental and Advanced Topics Will-be-set-by -IN- TECH in Wind Power 14 α k2 k1 ϕ γ x3 Fig 4 Definition of the (k1 , k2 , x3 )- and (γ, α, x3 )-coordinate systems J +1 Here G = G(α, ω ) = G(0, α, ω ) Secondly, the matrices A j0 and A j1 and therefore also A12 J +1 and A22 —simplify significantly k1 = γ = 0, k2 = α and ω = 0, when one of the wavenumbers...119 5 Efficient Modelling ofFoundations Efficient Modelling of Wind Turbine Wind Turbine Foundations a closed-form solution cannot be established for a layered half-space, and in practice the temporal–spatial solution expressed by Eq (1) is inapplicable Assuming that the response of the stratum is linear, the analysis may be carried out in the frequency domain The Fourier transformation... Z 25 0 ⎥ ⎢ ⎥ ⎢ 0 0 0 ⎥ 0 Z33 0 ⎥ (73) Z(ω ) = ⎢ ⎢ Z14 Z24 0 Z44 Z 45 0 ⎥ ⎢ ⎥ ⎣ Z 15 Z 55 0 Z 45 Z 55 0 ⎦ 0 0 0 0 0 Z66 A further simplification of Z(ω ) is obtained if the moment of inertia around a given horizontal axis is invariant to a rotation of the footing around the z-axis This is the case for the gravitation foundations that are typically utilised for wind turbines, i.e circular, square, hexagonal and . O j . 120 Fundamental and Advanced Topics in Wind Power Efficient Modelling of Wind Turbine Foundations 7 2.2.2 Governing equations for wave propagation in a soil layer In the time domain, and in terms. 1 957 -1974, 19 75- 1992 and 1993-2009. Fundamental and Advanced Topics in Wind Power 110 5. Conclusions Extreme wind speed from different directions and for return periods of 10, 25, 50 ,. distribution”, Journal of Wind Engineering and Industrial Aerodynamics, Vol. 2 No. 1, pp.21-36. Fundamental and Advanced Topics in Wind Power 112 Gumbel, E.J., 1 958 . Statistics of Extremes.

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