This document describes a procedure for optimizing the design of horizontal-axis wind turbine blades to maximize annual energy production and minimize blade mass. The procedure uses three modules: an aerodynamic analysis module using blade element momentum theory, a structural analysis module using finite element modeling, and a multi-objective optimization module using a genetic algorithm. As a case study, the procedure is applied to optimize the design of a 1.5 megawatt wind turbine blade, with the goal of improving its overall performance compared to the original design.
Thermal Characteristics of Different Shaped Fin Protracted Heat Exchanger in ...YogeshIJTSRD
The current presents looks at exhaust gases potential to recover low grade waste heat energy from internal combustion engines ICEs . A Prolonged Fin Counter Flow Heat Exchange PFCHE double tube was planned, analyzed, and supplied with water as working fluids to achieve this objective. The structure of a double pipe, Protracted Fin Heat Exchanger PFCHE , which performs a simulation study, is derived with exact measurements from one by Rajesh Ravi et al. 2020 research scholar, and then different shapes of the fin profiles were introduced in the designs suggested. The Fluent 17.0 is used for numerical analysis. The CFD results showing that the PFCHE with triangular fin outperforms the PFCHE with circular fin, and previous studies by Rajesh Ravi et al. 2020 showing that the PFCHE with triangular fin outperforms the PFCHE with circular fin. When compared to the PFCHE with circular fin, the PFCHE net heat transfer rate is 1.76 percent higher and 2.82 percent higher than Rajesh Ravi et al. 2020 report. Prof. Ranjeet Arya | Rahul Ade "Thermal Characteristics of Different Shaped Fin Protracted Heat Exchanger in Diesel Engine Exhaust using CFD" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-3 , April 2021, URL: https://www.ijtsrd.com/papers/ijtsrd39939.pdf Paper URL: https://www.ijtsrd.com/engineering/mechanical-engineering/39939/thermal-characteristics-of-different-shaped-fin-protracted-heat-exchanger-in-diesel-engine-exhaust-using-cfd/prof-ranjeet-arya
IRJET-Detailed Energy Audit in a Captive Cogeneration PlantIRJET Journal
D.Rajani Kant , B.Sudheer Prem Kumar, N.Ravi Kumar, R.Virendra,J.Suresh Babu " Detailed Energy Audit in a Captive Cogeneration Plant ", International Research Journal of Engineering and Technology (IRJET), Volume2,issue-01 April 2015.e-ISSN:2395-0056, p-ISSN:2395-0072. www.irjet.net
Abstract
The rate of exploitation of the energy resources has been expanding over time and resulted in reduction of fossil fuel reserves. Efficiency of all resources is crucial both in environmental and economic sense. Using energy inefficiently creates waste in all the world’s economies. It has environmental impacts with regional, local and global implications.The key object is to adopt energy management in every field in order to reduce the wastage of energy sources and cost effectiveness without affecting productivity and growth.
Airbus - Topology Optimization Methods for Optimal Aircraft ComponentsAltair ProductDesign
Application of Topology, Sizing and Shape Optimization Methods to Optimal Design of Aircraft Components - a Technical Engineering & Analysis Paper from Altair ProductDesign
Optimization of Bolted Joints for Aircraft Engine Using Genetic AlgorithmsIJMER
Genetic Algorithms mimic the evolving technique of nature to better fit populations to a certain environment. Despite this technique has proved its adequacy in several fields, its application in Aerospace is still limited, mostly because of the high quantity of acceptability criteria that the design
must pass and the amount of design parameters. The presented paper explores required GA architecture’s adaptations to be applied in highly restricted systems such as those commonly found in Aerospace applications. The proposed GA was applied to the design of an Aircraft Engine’s Axial Casing bolted joint following static strength restrictions as per FAR 33 regulations. The set of Elitism,
interdependent geometric restrictions, Crossing, and Reproduction modules proved the applicability of
the presented multi-objective GA architecture under 14 restrictions for normal, limit and ultimate loads.
As it is described, the conversion is quickly achieved due to the shortage of the search space; therefore a
modified Variable Crossing per Scheme is proposed to expand the diversity of the genome to compensate
the relatively low impact of the Mutation module. Finally, the process and solutions found were compared against the traditional design process, showing the feasibility of this technique in complex applications in terms of quality of the solution and developing time.
Comparative Assessment of Two Thermodynamic Cycles of an aero-derivative Mari...IOSR Journals
Abstract: This paper explores the gas turbine potentials that are fully enhanced by the use of intercooling and
thermal recuperation as an engineering option available in the design of gas turbines and offered for marine
applications. It examines the off-design performance of two different cycle designs of a 25MW aero-derivative
engine by modelling and simulating each of them to operate under conditions other than those of their design
point. The simple cycle model consists of a single-spool dual shaft layout while the advanced model is
represented by an intercooled-recuperated cycle that runs on a dual-spool and is driven through a three shaft
configuration. In each case, the output shaft is coupled to a power turbine through which the propulsion power
may be transmitted to the propeller of the vessel to operate in a virtual marine environment. An off-design
performance simulation of both engines has been conducted in order to investigate and compare the effect of
ambient temperature variation during their part-load operation and particularly when subjected to a variety of
marine operating conditions. The study assesses the techno-economic impact of the complex design of the
advanced cycle over its simple cycle counterpart and demonstrates its potential for improved operating cost
through reduced fuel consumption as a significant step in the current drive for establishing the marine gas
turbine engine as a viable alternative to traditional prime movers in the ship propulsion industry.
Thermal Characteristics of Different Shaped Fin Protracted Heat Exchanger in ...YogeshIJTSRD
The current presents looks at exhaust gases potential to recover low grade waste heat energy from internal combustion engines ICEs . A Prolonged Fin Counter Flow Heat Exchange PFCHE double tube was planned, analyzed, and supplied with water as working fluids to achieve this objective. The structure of a double pipe, Protracted Fin Heat Exchanger PFCHE , which performs a simulation study, is derived with exact measurements from one by Rajesh Ravi et al. 2020 research scholar, and then different shapes of the fin profiles were introduced in the designs suggested. The Fluent 17.0 is used for numerical analysis. The CFD results showing that the PFCHE with triangular fin outperforms the PFCHE with circular fin, and previous studies by Rajesh Ravi et al. 2020 showing that the PFCHE with triangular fin outperforms the PFCHE with circular fin. When compared to the PFCHE with circular fin, the PFCHE net heat transfer rate is 1.76 percent higher and 2.82 percent higher than Rajesh Ravi et al. 2020 report. Prof. Ranjeet Arya | Rahul Ade "Thermal Characteristics of Different Shaped Fin Protracted Heat Exchanger in Diesel Engine Exhaust using CFD" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-3 , April 2021, URL: https://www.ijtsrd.com/papers/ijtsrd39939.pdf Paper URL: https://www.ijtsrd.com/engineering/mechanical-engineering/39939/thermal-characteristics-of-different-shaped-fin-protracted-heat-exchanger-in-diesel-engine-exhaust-using-cfd/prof-ranjeet-arya
IRJET-Detailed Energy Audit in a Captive Cogeneration PlantIRJET Journal
D.Rajani Kant , B.Sudheer Prem Kumar, N.Ravi Kumar, R.Virendra,J.Suresh Babu " Detailed Energy Audit in a Captive Cogeneration Plant ", International Research Journal of Engineering and Technology (IRJET), Volume2,issue-01 April 2015.e-ISSN:2395-0056, p-ISSN:2395-0072. www.irjet.net
Abstract
The rate of exploitation of the energy resources has been expanding over time and resulted in reduction of fossil fuel reserves. Efficiency of all resources is crucial both in environmental and economic sense. Using energy inefficiently creates waste in all the world’s economies. It has environmental impacts with regional, local and global implications.The key object is to adopt energy management in every field in order to reduce the wastage of energy sources and cost effectiveness without affecting productivity and growth.
Airbus - Topology Optimization Methods for Optimal Aircraft ComponentsAltair ProductDesign
Application of Topology, Sizing and Shape Optimization Methods to Optimal Design of Aircraft Components - a Technical Engineering & Analysis Paper from Altair ProductDesign
Optimization of Bolted Joints for Aircraft Engine Using Genetic AlgorithmsIJMER
Genetic Algorithms mimic the evolving technique of nature to better fit populations to a certain environment. Despite this technique has proved its adequacy in several fields, its application in Aerospace is still limited, mostly because of the high quantity of acceptability criteria that the design
must pass and the amount of design parameters. The presented paper explores required GA architecture’s adaptations to be applied in highly restricted systems such as those commonly found in Aerospace applications. The proposed GA was applied to the design of an Aircraft Engine’s Axial Casing bolted joint following static strength restrictions as per FAR 33 regulations. The set of Elitism,
interdependent geometric restrictions, Crossing, and Reproduction modules proved the applicability of
the presented multi-objective GA architecture under 14 restrictions for normal, limit and ultimate loads.
As it is described, the conversion is quickly achieved due to the shortage of the search space; therefore a
modified Variable Crossing per Scheme is proposed to expand the diversity of the genome to compensate
the relatively low impact of the Mutation module. Finally, the process and solutions found were compared against the traditional design process, showing the feasibility of this technique in complex applications in terms of quality of the solution and developing time.
Comparative Assessment of Two Thermodynamic Cycles of an aero-derivative Mari...IOSR Journals
Abstract: This paper explores the gas turbine potentials that are fully enhanced by the use of intercooling and
thermal recuperation as an engineering option available in the design of gas turbines and offered for marine
applications. It examines the off-design performance of two different cycle designs of a 25MW aero-derivative
engine by modelling and simulating each of them to operate under conditions other than those of their design
point. The simple cycle model consists of a single-spool dual shaft layout while the advanced model is
represented by an intercooled-recuperated cycle that runs on a dual-spool and is driven through a three shaft
configuration. In each case, the output shaft is coupled to a power turbine through which the propulsion power
may be transmitted to the propeller of the vessel to operate in a virtual marine environment. An off-design
performance simulation of both engines has been conducted in order to investigate and compare the effect of
ambient temperature variation during their part-load operation and particularly when subjected to a variety of
marine operating conditions. The study assesses the techno-economic impact of the complex design of the
advanced cycle over its simple cycle counterpart and demonstrates its potential for improved operating cost
through reduced fuel consumption as a significant step in the current drive for establishing the marine gas
turbine engine as a viable alternative to traditional prime movers in the ship propulsion industry.
Selection of prime mover type was investigated for use in combined cooling, heat and power systems. Selection was determined from comparison of performance criteria for economic, energy and emissions savings. Simulations were run for three different types of prime movers in one climate zone and compared to a reference case with a typical separate heating and power system in the same climate zone. A hybrid load following method was implemented, with a suggested improvement. Performance parameters were compared and results indicated emissions and energy savings for all three prime movers. The prime mover types were reciprocating internal combustion engine (ICE), micro-turbine and phosphoric acid fuel cell. The climate zone was chosen to be a cold, humid climate represented by Chicago, IL. Economic savings were seen for both the ICE and micro-turbines. Emissions savings for carbon, nitrogen oxides and methane, for all three types, were greater than 9%, 12%, and 13%, respectively. Primary energy consumption savings for all three were greater than 8%.
Design of Naca63215 Airfoil for a Wind TurbineIOSR Journals
The ultimate objective of the work is to increase the reliability of wind turbine blades through the development of the airfoil structure and also to reduce the noise produced during the running period of the wind turbine blades. The blade plays a pivotal role, because it is the most important part of the energy absorption system. Consequently, the blade has to be designed carefully to enable to absorb energy with its greatest efficiency. In this work, Pro/E, Hypermesh software has been used to design blades effectively. NACA 63-215 airfoil profile is considered for analysis of wind turbine blade. The wind turbine blade is modeled and several sections are created from root to tip with the variation from the standard design for improving the efficiency. For the further improvement required in the efficiency of the wind turbine the winglet is to be included at the tip of the blade which would help in increasing the efficiency and reducing the noise produced from the blades in working condition. The existing turbine blade and the modified blade with the winglet are compared for their results.
Dynamic Modeling and Simulation on GE90 Enginetheijes
The paper talks about a better numerical method for predicting on-design performance on a High-Bypass Turbofan engine GE90. A dynamic optimization turbofan engine for GE90 has been designed using MATLAB/Simulink software. Individual components including Ambient, Fan, Low Pressure Compressor (LPC), High Pressure Compressor (HPC), Combustion Chamber, High Pressure Turbine (HPT), Low Pressure Turbine (LPT), Exit Nozzle and Plenum volumes, Makes a combination to identify the performance characteristics of a turbofan engine throughout the flight condition. The specific engine characteristics are matched and adopted through the use of variables from developed a model. The results will validate through simulation with the software to look through for problems and understand the air flow from the intake to the nozzle. Good designs can intensify a better performance to the engine, which performance analysis can be applied and tested to each component of the GE90 engine during design point condition.
Soot Formation in Diesel Engines By Using CfdIJERA Editor
In order to meet the stringent emission standards significant efforts have been imparted to the research and
development of cleaner IC engines. Diesel combustion and the formation of pollutants are directly influenced by
spatial and temporal distribution of the fuel injected. The development and validation of computational fluid
dynamics (CFD) models for diesel engine combustion and emissions is described. The complexity of diesel
combustion requires simulations with many complex interacting sub models in order to have a success in
improving the performance and to reduce the emissions. In the present work an attempt has been made to
develop a multidimensional axe-symmetric model for CI engine combustion and emissions. Later simulations
have been carried out. Commercial validation tool FLUENT was used for simulation. The tool solves basic
governing equations of fluid flow that is continuity, momentum, species transport and energy equation. Using
finite volume method turbulence was modeled by using RNG K-ɛ model. Injection was modeled using La
Grangian approach and reaction was modeled using non premixed combustion which considers the effects of
turbulence and detailed chemical mechanism into account to model the reaction rates. The specific heats were
approximated using piecewise polynomials. Subsequently the simulated results have been validated with the
existing experimental values
A computer Model of Fuel Consumption Estimation for Different Agricultural Fa...Agriculture Journal IJOEAR
Abstract— A computer programme was developed to estimate fuel consumption rate in liter per hour for medium agric-tractor with load and without load under different soil conditions. The programme enables the user to insert the input data through the input interface and obtain the output rapidly. The model was verified, validated and tested by using data from literature and a private agricultural services company in Sudan, for two types of heavy disc harrow (AH280, BH360), (H56,CH65C) driven by challenger track tractors, on the other hand, seeder and ridger separately operated with wheeled 4WD tractors. It was also tested by data from Sennar Agricultural Services Center, using heavy disc harrow with 4WD tractor. The sensitivity analysis showed that the change in any of input parameters, e.g. speed, unit draft, engine power affected directly the estimated fuel consumption rate. Accordingly, the computer programme performed very well in estimating fuel consumption and can be used as a good guide to the farmer or any interested person in machinery management and for quick decision-making.
Modification of Cost Equation for Optimization of Cutting Parameters in Turni...IJLT EMAS
With depleting pace of natural energy resources and
pollution in the environment it is necessary to reduce the amount
of energy consumption. On the other hand price of energy is
increasing due to likely increase in oil prices. So it is necessary to
see the effect of energy cost in total machining cost. In the
present work conventional cost equation is modified to consider
the energy cost as variable of v, f and d instead of energy cost as
constant in conventional cost equation. Different costs are
compared by taking the particular value of parameters v, f and
d. It was found that energy as a variable cost have considerable
portion in total machining cost.
The performance expectations for commercial wind turbines, from a variety of geograph- ical regions with differing wind regimes, present significant techno-commercial challenges to manufacturers. The determination of which commercial turbine types perform the best under differing wind regimes can provide unique insights into the complex demands of a concerned target market. In this paper, a comprehensive methodology is developed to explore the suitability of commercially available wind turbines (when operating as a group/array) to the various wind regimes occurring over a large target market. The three major steps of this methodology include: (i) characterizing the geographical variation of wind regimes in the target market, (ii) determining the best performing turbines (in terms of minimum COE accomplished) for different wind regimes, and (iii) developing a metric to investigate the performance-based expected market suitability of currently available tur- bine feature combinations. The best performing turbines for different wind regimes are determined using the Unrestricted Wind Farm Layout Optimization (UWFLO) method. Expectedly, the larger sized and higher rated-power turbines provide better performance at lower average wind speeds. However, for wind resources higher than class-4, the perfor- mances of lower-rated power turbines are fairly competitive, which could make them better choices for sites with complex terrain or remote location. In addition, turbines with direct drive are observed to perform significantly better than turbines with more conventional gear-based drive-train. The market considered in this paper is mainland USA, for which wind map information is obtained from NREL. Interestingly, it is found that overall higher rated-power turbines with relatively lower tower heights are most favored in the onshore US market.
The development of large scale wind farms that can produce energy at a cost comparable to that of other conventional energy resources presents significant challenges to today’s wind energy industry. The consideration of the key design and environmental factors that influence the performance of a wind farm is a crucial part of the solution to this challenge. In this paper, we develop a methodology to account for the configuration of the farm land (length-to-breadth ratio and North-South-East-West orientation) within the scope of wind farm optimization. This approach appropriately captures the correlation between the (i) land configuration, (ii) the farm layout, and (iii) the selection of turbines-types. Simultaneous optimization of the farm layout and turbine selection is performed to minimize the Cost of Energy (COE), for a set of sample land configurations. The optimized COE and farm efficiency are then represented as functions of the land aspect ratio and the land orientation. To this end, we apply a recently developed response surface method known as the Reliability-Based Hybrid Functions. The overall wind farm design methodology is applied to design a 25MW farm in North Dakota. This case study provides helpful insights into the influence of the land configuration on the optimum farm performance that can be obtained for a particular site.
Selection of prime mover type was investigated for use in combined cooling, heat and power systems. Selection was determined from comparison of performance criteria for economic, energy and emissions savings. Simulations were run for three different types of prime movers in one climate zone and compared to a reference case with a typical separate heating and power system in the same climate zone. A hybrid load following method was implemented, with a suggested improvement. Performance parameters were compared and results indicated emissions and energy savings for all three prime movers. The prime mover types were reciprocating internal combustion engine (ICE), micro-turbine and phosphoric acid fuel cell. The climate zone was chosen to be a cold, humid climate represented by Chicago, IL. Economic savings were seen for both the ICE and micro-turbines. Emissions savings for carbon, nitrogen oxides and methane, for all three types, were greater than 9%, 12%, and 13%, respectively. Primary energy consumption savings for all three were greater than 8%.
Design of Naca63215 Airfoil for a Wind TurbineIOSR Journals
The ultimate objective of the work is to increase the reliability of wind turbine blades through the development of the airfoil structure and also to reduce the noise produced during the running period of the wind turbine blades. The blade plays a pivotal role, because it is the most important part of the energy absorption system. Consequently, the blade has to be designed carefully to enable to absorb energy with its greatest efficiency. In this work, Pro/E, Hypermesh software has been used to design blades effectively. NACA 63-215 airfoil profile is considered for analysis of wind turbine blade. The wind turbine blade is modeled and several sections are created from root to tip with the variation from the standard design for improving the efficiency. For the further improvement required in the efficiency of the wind turbine the winglet is to be included at the tip of the blade which would help in increasing the efficiency and reducing the noise produced from the blades in working condition. The existing turbine blade and the modified blade with the winglet are compared for their results.
Dynamic Modeling and Simulation on GE90 Enginetheijes
The paper talks about a better numerical method for predicting on-design performance on a High-Bypass Turbofan engine GE90. A dynamic optimization turbofan engine for GE90 has been designed using MATLAB/Simulink software. Individual components including Ambient, Fan, Low Pressure Compressor (LPC), High Pressure Compressor (HPC), Combustion Chamber, High Pressure Turbine (HPT), Low Pressure Turbine (LPT), Exit Nozzle and Plenum volumes, Makes a combination to identify the performance characteristics of a turbofan engine throughout the flight condition. The specific engine characteristics are matched and adopted through the use of variables from developed a model. The results will validate through simulation with the software to look through for problems and understand the air flow from the intake to the nozzle. Good designs can intensify a better performance to the engine, which performance analysis can be applied and tested to each component of the GE90 engine during design point condition.
Soot Formation in Diesel Engines By Using CfdIJERA Editor
In order to meet the stringent emission standards significant efforts have been imparted to the research and
development of cleaner IC engines. Diesel combustion and the formation of pollutants are directly influenced by
spatial and temporal distribution of the fuel injected. The development and validation of computational fluid
dynamics (CFD) models for diesel engine combustion and emissions is described. The complexity of diesel
combustion requires simulations with many complex interacting sub models in order to have a success in
improving the performance and to reduce the emissions. In the present work an attempt has been made to
develop a multidimensional axe-symmetric model for CI engine combustion and emissions. Later simulations
have been carried out. Commercial validation tool FLUENT was used for simulation. The tool solves basic
governing equations of fluid flow that is continuity, momentum, species transport and energy equation. Using
finite volume method turbulence was modeled by using RNG K-ɛ model. Injection was modeled using La
Grangian approach and reaction was modeled using non premixed combustion which considers the effects of
turbulence and detailed chemical mechanism into account to model the reaction rates. The specific heats were
approximated using piecewise polynomials. Subsequently the simulated results have been validated with the
existing experimental values
A computer Model of Fuel Consumption Estimation for Different Agricultural Fa...Agriculture Journal IJOEAR
Abstract— A computer programme was developed to estimate fuel consumption rate in liter per hour for medium agric-tractor with load and without load under different soil conditions. The programme enables the user to insert the input data through the input interface and obtain the output rapidly. The model was verified, validated and tested by using data from literature and a private agricultural services company in Sudan, for two types of heavy disc harrow (AH280, BH360), (H56,CH65C) driven by challenger track tractors, on the other hand, seeder and ridger separately operated with wheeled 4WD tractors. It was also tested by data from Sennar Agricultural Services Center, using heavy disc harrow with 4WD tractor. The sensitivity analysis showed that the change in any of input parameters, e.g. speed, unit draft, engine power affected directly the estimated fuel consumption rate. Accordingly, the computer programme performed very well in estimating fuel consumption and can be used as a good guide to the farmer or any interested person in machinery management and for quick decision-making.
Modification of Cost Equation for Optimization of Cutting Parameters in Turni...IJLT EMAS
With depleting pace of natural energy resources and
pollution in the environment it is necessary to reduce the amount
of energy consumption. On the other hand price of energy is
increasing due to likely increase in oil prices. So it is necessary to
see the effect of energy cost in total machining cost. In the
present work conventional cost equation is modified to consider
the energy cost as variable of v, f and d instead of energy cost as
constant in conventional cost equation. Different costs are
compared by taking the particular value of parameters v, f and
d. It was found that energy as a variable cost have considerable
portion in total machining cost.
The performance expectations for commercial wind turbines, from a variety of geograph- ical regions with differing wind regimes, present significant techno-commercial challenges to manufacturers. The determination of which commercial turbine types perform the best under differing wind regimes can provide unique insights into the complex demands of a concerned target market. In this paper, a comprehensive methodology is developed to explore the suitability of commercially available wind turbines (when operating as a group/array) to the various wind regimes occurring over a large target market. The three major steps of this methodology include: (i) characterizing the geographical variation of wind regimes in the target market, (ii) determining the best performing turbines (in terms of minimum COE accomplished) for different wind regimes, and (iii) developing a metric to investigate the performance-based expected market suitability of currently available tur- bine feature combinations. The best performing turbines for different wind regimes are determined using the Unrestricted Wind Farm Layout Optimization (UWFLO) method. Expectedly, the larger sized and higher rated-power turbines provide better performance at lower average wind speeds. However, for wind resources higher than class-4, the perfor- mances of lower-rated power turbines are fairly competitive, which could make them better choices for sites with complex terrain or remote location. In addition, turbines with direct drive are observed to perform significantly better than turbines with more conventional gear-based drive-train. The market considered in this paper is mainland USA, for which wind map information is obtained from NREL. Interestingly, it is found that overall higher rated-power turbines with relatively lower tower heights are most favored in the onshore US market.
The development of large scale wind farms that can produce energy at a cost comparable to that of other conventional energy resources presents significant challenges to today’s wind energy industry. The consideration of the key design and environmental factors that influence the performance of a wind farm is a crucial part of the solution to this challenge. In this paper, we develop a methodology to account for the configuration of the farm land (length-to-breadth ratio and North-South-East-West orientation) within the scope of wind farm optimization. This approach appropriately captures the correlation between the (i) land configuration, (ii) the farm layout, and (iii) the selection of turbines-types. Simultaneous optimization of the farm layout and turbine selection is performed to minimize the Cost of Energy (COE), for a set of sample land configurations. The optimized COE and farm efficiency are then represented as functions of the land aspect ratio and the land orientation. To this end, we apply a recently developed response surface method known as the Reliability-Based Hybrid Functions. The overall wind farm design methodology is applied to design a 25MW farm in North Dakota. This case study provides helpful insights into the influence of the land configuration on the optimum farm performance that can be obtained for a particular site.
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Design Optimization of Reinforced Concrete Slabs Using Various Optimization T...ijtsrd
This paper presents Reinforced Concrete RC slab design optimization technique for finding the best design parameters that satisfy the project requirements both in terms of strength and serviceability criteria while keeping the overall construction cost to a minimum. In this paper four different types of RC slab design named as simply supported slab, one end continuous slab, both end continuous slab and cantilever slab are optimized using three different metaheuristic optimization algorithms named as Genetic Algorithms GA , Particle Swarm Optimization PSO and Gray Wolf Optimization GWO . The slabs with various end conditions are formulated according to the ACI code. The formulated problem contains three optimization variables, the thickness of the slab, steel bar diameter, and bar spacing while objective involves the minimization of overall cost of the structure which includes the cost of concrete, cost of reinforcement and the constraints involves the design requirement and ACI codes limit. The proposed method is developed using MATLAB. Finally, to validate the performance of the proposed algorithm the results are compared with the previously proposed algorithms. The comparison of results shows that the proposed method provides a significant improvement over the previously proposed algorithms. Dinesh Kumar Suryavanshi | Dr. Saleem Akhtar "Design Optimization of Reinforced Concrete Slabs Using Various Optimization Techniques" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-5 , August 2019, URL: https://www.ijtsrd.com/papers/ijtsrd25231.pdfPaper URL: https://www.ijtsrd.com/engineering/civil-engineering/25231/design-optimization-of-reinforced-concrete-slabs-using-various-optimization-techniques/dinesh-kumar-suryavanshi
Cfd Studies of Two Stroke Petrol Engine ScavengingIJERA Editor
This project deals with the numerical analysis of 2 stroke engine scavenging in two cases. One with an existing condition (Flat headed pistons) and another with a new design (Dome headed piston) .The numerical analysis is done with help of CFD software ANSYS FLUENT 14.5. Here, the modeling of engine piston with flat headed type and with dome headed types was done in workbench. In ANSYS FLUENT after the geometrical design, for the dynamic motion meshing is used and set up species transport model also. At first the scavenging effect of flat headed piston is analyzed. Later the simulation of piston with dome headed type was also checked. Analyzing the variations from each and selected the best method for scavenging. Finally the scavenging efficiency is calculated for both type arrangements.
STRUCTURAL OPTIMIZATION OF A POWERED INDUSTRIAL LIFT TRUCK FRAMEIAEME Publication
The purpose of this paper is to re-design a lift truck frame (Chassis) with the optimum mass while maintaining stress constraints. The paper also demonstrate how Optimization techniques can be applied mainly when product is already launched in market and optimized design is to be implemented without altering any existing assembly fitment parameters /functional requirement.
Apprioprate Boundary Condition for FEA of member isolated from global modelAun Haider
The wing of a fighter aircraft has various structural members which support aerodynamic and
inertial loads, and transmit these loads to the fuselage. As a foremost step to evaluate the structural
behaviour of the wing assembly, component contribution analysis is carried out. A finite element
analysis of wing tulip of fighter aircraft isolated from the wing was performed under the design
load case. Since aircraft wing is a statically indeterminate structure, reaction forces and moments
at the supports depend upon the stiffness characteristics of the wing itself. In addition, stiffness of
wing also affects the distribution of load and resulting deformation of the wing. These require that
support structure of tulip isolated from the global wing model is represented by appropriate boundary
conditions for the analysis. A comparative study for three boundary conditions (fixed support, nodal
displacements and elastic support) was carried out to determine the representative boundary
condition for the analysis of structural members isolated from the global model. It was found that
elastic support represents the stiffness of the global model and is a more appropriate boundary
condition for the analysis of local models which are isolated from a global model.
International Journal of Engineering Research and Applications (IJERA) is an open access online peer reviewed international journal that publishes research and review articles in the fields of Computer Science, Neural Networks, Electrical Engineering, Software Engineering, Information Technology, Mechanical Engineering, Chemical Engineering, Plastic Engineering, Food Technology, Textile Engineering, Nano Technology & science, Power Electronics, Electronics & Communication Engineering, Computational mathematics, Image processing, Civil Engineering, Structural Engineering, Environmental Engineering, VLSI Testing & Low Power VLSI Design etc.
Determining the Pareto front of distributed generator and static VAR compens...IJECEIAES
The integration of distributed generators (DGs), which are based on renewable energy sources, energy storage systems, and static VAR compensators (SVCs), requires considering more challenging operational cases due to the variability of DG production contributed by different characteristics for different time sequences. The size, quantity, technology, and location of DG units have major effects on the system to benefit from the integration. All these aspects create a multi-objective scope; therefore, it is considered a multi-objective mixed-integer optimization problem. This paper presents an improved multi-objective salp swarm optimization algorithm (MOSSA) to obtain multiple Pareto efficient solutions for the optimal number, location, and capacity of DGs and the controlling strategy of SVC a radial distribution system. MOSSA is a bio-inspired optimizer based on swarm intelligence techniques and it is used in finding the optimal solution for a global optimization problem. Two sets of objective functions have been formulated minimizing DGs and SVC cost, voltage violation, energy losses, and system emission cost. The usefulness of the proposed MOSSA has been tested with the 33-bus and 141-bus radial distribution systems and the qualitative comparisons against two well-known algorithms, multiple objective evolutionary algorithms based on decomposition (MOEA/D), and multiple objective particle swarm optimization (MOPSO) algorithm.
Suitability of Composite Material for Flywheel Analysis IJMER
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Cosmetic shop management system project report.pdfKamal Acharya
Buying new cosmetic products is difficult. It can even be scary for those who have sensitive skin and are prone to skin trouble. The information needed to alleviate this problem is on the back of each product, but it's thought to interpret those ingredient lists unless you have a background in chemistry.
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Data file handling has been effectively used in the program.
The automated cosmetic shop management system should deal with the automation of general workflow and administration process of the shop. The main processes of the system focus on customer's request where the system is able to search the most appropriate products and deliver it to the customers. It should help the employees to quickly identify the list of cosmetic product that have reached the minimum quantity and also keep a track of expired date for each cosmetic product. It should help the employees to find the rack number in which the product is placed.It is also Faster and more efficient way.
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Advancements in technology unveil a myriad of electrical and electronic breakthroughs geared towards efficiently harnessing limited resources to meet human energy demands. The optimization of hybrid solar PV panels and pumped hydro energy supply systems plays a pivotal role in utilizing natural resources effectively. This initiative not only benefits humanity but also fosters environmental sustainability. The study investigated the design optimization of these hybrid systems, focusing on understanding solar radiation patterns, identifying geographical influences on solar radiation, formulating a mathematical model for system optimization, and determining the optimal configuration of PV panels and pumped hydro storage. Through a comparative analysis approach and eight weeks of data collection, the study addressed key research questions related to solar radiation patterns and optimal system design. The findings highlighted regions with heightened solar radiation levels, showcasing substantial potential for power generation and emphasizing the system's efficiency. Optimizing system design significantly boosted power generation, promoted renewable energy utilization, and enhanced energy storage capacity. The study underscored the benefits of optimizing hybrid solar PV panels and pumped hydro energy supply systems for sustainable energy usage. Optimizing the design of solar PV panels and pumped hydro energy supply systems as examined across diverse climatic conditions in a developing country, not only enhances power generation but also improves the integration of renewable energy sources and boosts energy storage capacities, particularly beneficial for less economically prosperous regions. Additionally, the study provides valuable insights for advancing energy research in economically viable areas. Recommendations included conducting site-specific assessments, utilizing advanced modeling tools, implementing regular maintenance protocols, and enhancing communication among system components.
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introduce a novel volumization algorithm, which transforms 2D images into 3D volumetric representations.
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using contemporary CNN architectures and the modified Canadian Institute for Advanced Research (CIFAR-10
and CIFAR-100) and ImageNet Large Scale Visual Recognition Challenge (ILSVRC12) datasets, showcasing
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A hierarchical digital twin of a Naval DC power system has been developed and experimentally verified. Similar to other state-of-the-art digital twins, this technology creates a digital replica of the physical system executed in real-time or faster, which can modify hardware controls. However, its advantage stems from distributing computational efforts by utilizing a hierarchical structure composed of lower-level digital twin blocks and a higher-level system digital twin. Each digital twin block is associated with a physical subsystem of the hardware and communicates with a singular system digital twin, which creates a system-level response. By extracting information from each level of the hierarchy, power system controls of the hardware were reconfigured autonomously. This hierarchical digital twin development offers several advantages over other digital twins, particularly in the field of naval power systems. The hierarchical structure allows for greater computational efficiency and scalability while the ability to autonomously reconfigure hardware controls offers increased flexibility and responsiveness. The hierarchical decomposition and models utilized were well aligned with the physical twin, as indicated by the maximum deviations between the developed digital twin hierarchy and the hardware.
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Energies 09-00066
1. energies
Article
Aerodynamic and Structural Integrated Optimization
Design of Horizontal-Axis Wind Turbine Blades
Jie Zhu 1,2,*, Xin Cai 2 and Rongrong Gu 2
1 College of Civil Engineering and Architecture, Jiaxing University, Jiaxing 314001, China
2 College of Mechanics and Materials, Hohai University, Nanjing 210098, China;
xcai@hhu.edu.cn (X.C.); gurr99@126.com (R.G.)
* Correspondence: zhukejie2222@163.com; Tel.: +86-573-8364-6050
Academic Editor: Frede Blaabjerg
Received: 14 December 2015; Accepted: 18 January 2016; Published: 22 January 2016
Abstract: A procedure based on MATLAB combined with ANSYS is presented and utilized for
the aerodynamic and structural integrated optimization design of Horizontal-Axis Wind Turbine
(HAWT) blades. Three modules are used for this purpose: an aerodynamic analysis module using
the Blade Element Momentum (BEM) theory, a structural analysis module employing the Finite
Element Method (FEM) and a multi-objective optimization module utilizing the non-dominated
sorting genetic algorithm. The former two provide a sufficiently accurate solution of the aerodynamic
and structural performances of the blade; the latter handles the design variables of the optimization
problem, namely, the main geometrical shape and structural parameters of the blade, and promotes
function optimization. The scope of the procedure is to achieve the best trade-off performances
between the maximum Annual Energy Production (AEP) and the minimum blade mass under
various design requirements. To prove the efficiency and reliability of the procedure, a commercial
1.5 megawatt (MW) HAWT blade is used as a case study. Compared with the original scheme,
the optimization results show great improvements for the overall performance of the blade.
Keywords: integrated optimization design; horizontal axis wind turbine; multi-objective
optimization; annual energy production; blade mass
1. Introduction
Blades are regarded as the key components of the Horizontal-Axis Wind Turbine (HAWT) system
and have been paid much attention by most of the leading wind turbine manufacturers to develop
their own blade design. As world wind energy market continuously grows, a number of blade
manufacturers have emerged recently, especially in China. However, their independent design and
manufacturing capabilities are weak, and the wind blade market is still dominated by the leading wind
turbine system manufacturers [1]. Thus, to enter the market successfully and be more competitive,
improving the fundamental technology on design and production of multi-megawatt (MW) class
blades is indispensable.
The design process of the blades can be divided into two stages: the aerodynamic design and
the structural design [2]. From the perspective of aerodynamic design, aerodynamic loads, power
performance, aerodynamic efficiency, and Annual Energy Production (AEP) are important, and from
the perspective of structural design, composite material lay-up, mass, stiffness, buckling stability, and
fatigue loads are concerned [3]. A successful blade design should take into account the interaction
between the two stages and satisfy a wide range of objectives, so the design process is a complex
multi-objective optimization task characterized by numerous trade-off decisions. Nevertheless, in
order to simplify the process, the aerodynamic design and the structural design are separated by the
Energies 2016, 9, 66; doi:10.3390/en9020066 www.mdpi.com/journal/energies
2. Energies 2016, 9, 66 2 of 18
conventional methods. As of now, most of the research is focused mainly on the optimization of either
aerodynamic or structural performances, which are unable to get the overall optimal solutions [4–9].
Only a limited number of works are concerned with the optimization of both aerodynamic and
structural performances, and the relative procedure for this purpose is scarce.
Grujicic [10] developed a multi-disciplinary design-optimization procedure for the design of
a 5 MW HAWT blade with respect to the attainment of a minimal Cost of Energy (COE), and
several potential solutions for remedying the performance deficiencies of the blade were obtained.
Bottasso [11] described procedures for the multi-disciplinary design optimization of wind turbines.
The optimization was performed by a multi-stage process that first alternates between an aerodynamic
shape optimization to maximize the AEP and a structural blade optimization to minimize the blade
weight, and then combined the two to yield the final optimum solution. However, the problems
only take a single objective function into account at each time, thus they can not obtain the trade-off
solutions among conflicted objectives.
Benini [12] described a two-objective optimization method to design stall regulated HAWT blades,
the aim was to achieve the trade-off solutions between AEP per square meter of wind park and COE.
Wang [13,14] applied a novel multi-objective optimization algorithm for the design of wind turbine
blades by employing the minimum blade mass and the maximum power coefficient, the maximum
AEP and minimum blade mass as the optimization objectives, respectively. However, the blades are
treated as beam models to calculate the structural performances in the above research, and the material
layups were not considered.
This paper describes a procedure for the aerodynamic and structural integrated multi-optimization
design of HAWT blades to maximize the AEP and minimize the blade mass. The scope is to find
the balance between the design process to obtain the optimum overall performance of the blades,
by varying the main aerodynamic parameters (chord, twist, span-wise locations of airfoils, and the
rotational speed) as well as structural parameters (material layup in the spar cap and the position of
the shear webs) under various design requirements.
2. Modeling of the Blade
2.1. Finite Element Method (FEM) Model of the Blade
As a starting point for the optimization, an initial definition of the blade aerodynamic and
structural configuration is required. In this paper, a commercial 1.5 MW HAWT blade with a length of
37 m and a mass of 6580.4 kg is used for a case study.
Figure 1 shows the geometry shape of the blade, which can be divided into three areas: root,
transition region and aerodynamic region. The root area is normally circular in cross section in order
to match up with the bolted flange, the aerodynamic region uses aerofoil section to capture the wind,
and the transition region from the root section to the aerofoil section should be a smooth one for
structural reasons.
Energies 2016, 9, 66 2 of 18
optimization of either aerodynamic or structural performances, which are unable to get the overall
optimal solutions [4–9]. Only a limited number of works are concerned with the optimization of both
aerodynamic and structural performances, and the relative procedure for this purpose is scarce.
Grujicic [10] developed a multi‐disciplinary design‐optimization procedure for the design of a
5 MW HAWT blade with respect to the attainment of a minimal Cost of Energy (COE), and several
potential solutions for remedying the performance deficiencies of the blade were obtained. Bottasso [11]
described procedures for the multi‐disciplinary design optimization of wind turbines. The
optimization was performed by a multi‐stage process that first alternates between an aerodynamic
shape optimization to maximize the AEP and a structural blade optimization to minimize the blade
weight, and then combined the two to yield the final optimum solution. However, the problems
only take a single objective function into account at each time, thus they can not obtain the trade‐off
solutions among conflicted objectives.
Benini [12] described a two‐objective optimization method to design stall regulated HAWT
blades, the aim was to achieve the trade‐off solutions between AEP per square meter of wind park
and COE. Wang [13,14] applied a novel multi‐objective optimization algorithm for the design of
wind turbine blades by employing the minimum blade mass and the maximum power coefficient,
the maximum AEP and minimum blade mass as the optimization objectives, respectively. However,
the blades are treated as beam models to calculate the structural performances in the above research,
and the material layups were not considered.
This paper describes a procedure for the aerodynamic and structural integrated
multi‐optimization design of HAWT blades to maximize the AEP and minimize the blade mass.
The scope is to find the balance between the design process to obtain the optimum overall
performance of the blades, by varying the main aerodynamic parameters (chord, twist, span‐wise
locations of airfoils, and the rotational speed) as well as structural parameters (material layup in the
spar cap and the position of the shear webs) under various design requirements.
2. Modeling of the Blade
2.1. Finite Element Method (FEM) Model of the Blade
As a starting point for the optimization, an initial definition of the blade aerodynamic and
structural configuration is required. In this paper, a commercial 1.5 MW HAWT blade with a length
of 37 m and a mass of 6580.4 kg is used for a case study.
Figure 1 shows the geometry shape of the blade, which can be divided into three areas: root,
transition region and aerodynamic region. The root area is normally circular in cross section in order
to match up with the bolted flange, the aerodynamic region uses aerofoil section to capture the wind,
and the transition region from the root section to the aerofoil section should be a smooth one for
structural reasons.
Figure 1. The geometry shape of the blade.
The geometrical shape of the blade can be described by the airfoil series and the chord, twist
and percent thickness distributions. The main geometrical features are summarized in Table 1.
Seven control points (CP) with fixed radial locations are used for the chord and twist distributions,
as shown in Figure 2. The radial locations of the CP3‐7 are defined using half‐cosine spacing, CP1 is
Figure 1. The geometry shape of the blade.
The geometrical shape of the blade can be described by the airfoil series and the chord, twist
and percent thickness distributions. The main geometrical features are summarized in Table 1. Seven
control points (CP) with fixed radial locations are used for the chord and twist distributions, as shown
3. Energies 2016, 9, 66 3 of 18
in Figure 2. The radial locations of the CP3-7 are defined using half-cosine spacing, CP1 is at root,
CP3 is at the maximum chord station and CP7 is at the tip. Then, the chord and twist are defined
with an 8th order Bezier curve and a 5th Bezier curve, except the twist remains constant inboard of
the maximum chord. As Figure 3 illustrates, the percent thickness distribution is represented by the
span-wise location of airfoils listed in Table 1. Six more control points with fixed percent thickness are
defined. Then, a cubic polynomial is fit through the control points.
Table 1. The main geometrical features of the blade.
Location (m) Airfoil Chord (m) Twist (˝) Percent Thickness (%)
0 Circle 1.88 10.00 100
1.0 Circle 1.88 10.00 100
6.8 DU400EU 3.02 10.00 40
9.3 DU300EU 2.98 7.30 30
13.7 DU91_W2_250 2.51 4.35 25
29.8 NACA_64_618 1.68 ´0.33 18
36.5 NACA_64_618 1.21 ´1.13 18
Energies 2016, 9, 66 3 of 18
at root, CP3 is at the maximum chord station and CP7 is at the tip. Then, the chord and twist are
defined with an 8th order Bezier curve and a 5th Bezier curve, except the twist remains constant
inboard of the maximum chord. As Figure 3 illustrates, the percent thickness distribution is
represented by the span‐wise location of airfoils listed in Table 1. Six more control points with fixed
percent thickness are defined. Then, a cubic polynomial is fit through the control points.
Table 1. The main geometrical features of the blade.
Location (m) Airfoil Chord (m) Twist (°) Percent Thickness (%)
0 Circle 1.88 10.00 100
1.0 Circle 1.88 10.00 100
6.8 DU400EU 3.02 10.00 40
9.3 DU300EU 2.98 7.30 30
13.7 DU91_W2_250 2.51 4.35 25
29.8 NACA_64_618 1.68 −0.33 18
36.5 NACA_64_618 1.21 −1.13 18
0 5 10 15 20 25 30 35 40
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
7
Control points
6
5
4
3
2
Chord(m)
1
0 5 10 15 20 25 30 35 40
-3
1
5
9
13
7
6
5
4
321
Twist()
Blade length (m)
Control points
(a) (b)
Figure 2. (a) Chord and (b) twist distribution of the blade.
0 5 10 15 20 25 30 35 40
0
20
40
60
80
100
12 13
11
10
9
Percentthickness(%)
Blade length (m)
Control points
8
Figure 3. Percent thickness distribution of the blade.
Figure 4 shows a typical structural cross section of the blade, which is composed of four parts:
leading edge, trailing edge, spar cap and shear webs. The spar cap mainly consists of glass fiber
composite materials, while the other three parts consist of glass fiber composite materials with
Balsa and PVC core materials. The material properties are listed in Table 2.
Figure 4. A typical structural cross section of the blade.
Figure 2. (a) Chord and (b) twist distribution of the blade.
Energies 2016, 9, 66 3 of 18
at root, CP3 is at the maximum chord station and CP7 is at the tip. Then, the chord and twist are
defined with an 8th order Bezier curve and a 5th Bezier curve, except the twist remains constant
inboard of the maximum chord. As Figure 3 illustrates, the percent thickness distribution is
represented by the span‐wise location of airfoils listed in Table 1. Six more control points with fixed
percent thickness are defined. Then, a cubic polynomial is fit through the control points.
Table 1. The main geometrical features of the blade.
Location (m) Airfoil Chord (m) Twist (°) Percent Thickness (%)
0 Circle 1.88 10.00 100
1.0 Circle 1.88 10.00 100
6.8 DU400EU 3.02 10.00 40
9.3 DU300EU 2.98 7.30 30
13.7 DU91_W2_250 2.51 4.35 25
29.8 NACA_64_618 1.68 −0.33 18
36.5 NACA_64_618 1.21 −1.13 18
0 5 10 15 20 25 30 35 40
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
7
Control points
6
5
4
3
2
Chord(m)
1
0 5 10 15 20 25 30 35 40
-3
1
5
9
13
7
6
5
4
321Twist()
Blade length (m)
Control points
(a) (b)
Figure 2. (a) Chord and (b) twist distribution of the blade.
0 5 10 15 20 25 30 35 40
0
20
40
60
80
100
12 13
11
10
9
Percentthickness(%)
Blade length (m)
Control points
8
Figure 3. Percent thickness distribution of the blade.
Figure 4 shows a typical structural cross section of the blade, which is composed of four parts:
leading edge, trailing edge, spar cap and shear webs. The spar cap mainly consists of glass fiber
composite materials, while the other three parts consist of glass fiber composite materials with
Balsa and PVC core materials. The material properties are listed in Table 2.
Figure 4. A typical structural cross section of the blade.
Figure 3. Percent thickness distribution of the blade.
Figure 4 shows a typical structural cross section of the blade, which is composed of four parts:
leading edge, trailing edge, spar cap and shear webs. The spar cap mainly consists of glass fiber
composite materials, while the other three parts consist of glass fiber composite materials with Balsa
and PVC core materials. The material properties are listed in Table 2.
Energies 2016, 9, 66 3 of 18
at root, CP3 is at the maximum chord station and CP7 is at the tip. Then, the chord and twist are
defined with an 8th order Bezier curve and a 5th Bezier curve, except the twist remains constant
inboard of the maximum chord. As Figure 3 illustrates, the percent thickness distribution is
represented by the span‐wise location of airfoils listed in Table 1. Six more control points with fixed
percent thickness are defined. Then, a cubic polynomial is fit through the control points.
Table 1. The main geometrical features of the blade.
Location (m) Airfoil Chord (m) Twist (°) Percent Thickness (%)
0 Circle 1.88 10.00 100
1.0 Circle 1.88 10.00 100
6.8 DU400EU 3.02 10.00 40
9.3 DU300EU 2.98 7.30 30
13.7 DU91_W2_250 2.51 4.35 25
29.8 NACA_64_618 1.68 −0.33 18
36.5 NACA_64_618 1.21 −1.13 18
0 5 10 15 20 25 30 35 40
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
7
Control points
6
5
4
3
2
Chord(m)
1
0 5 10 15 20 25 30 35 40
-3
1
5
9
13
7
6
5
4
321
Twist()
Blade length (m)
Control points
(a) (b)
Figure 2. (a) Chord and (b) twist distribution of the blade.
0 5 10 15 20 25 30 35 40
0
20
40
60
80
100
12 13
11
10
9
Percentthickness(%)
Blade length (m)
Control points
8
Figure 3. Percent thickness distribution of the blade.
Figure 4 shows a typical structural cross section of the blade, which is composed of four parts:
leading edge, trailing edge, spar cap and shear webs. The spar cap mainly consists of glass fiber
composite materials, while the other three parts consist of glass fiber composite materials with
Balsa and PVC core materials. The material properties are listed in Table 2.
Figure 4. A typical structural cross section of the blade.
Figure 4. A typical structural cross section of the blade.
4. Energies 2016, 9, 66 4 of 18
Table 2. The material properties of the blade.
Material E1 (GPa) E2 (GPa) G12 (GPa) v12 ρ (kg/m3) Thickness (mm)
UD-1200-xxx 42.2 12.5 3.5 0.24 1910 0.873
2AX-1200-0660 11.5 11.5 11.8 0.61 1909 0.878
3AX-1200-6330 26.9 13.4 7.5 0.47 1910 0.906
3AX9060-1200-0336 31.8 11.4 6.5 0.49 1910 0.906
Balsa 3.5 0.8 0.16 0.39 151 25.4
PVC 0.05 0.05 0.02 0.09 60 10/15/20/25
The FEM model of the blade is generated by using ANSYS Parametric Design Language (ADPL) in
ANSYS software, which enables the creation of various FEM models by changing the main aerodynamic
and structural parameters. The model is entirely created with SHELL99 element for modeling the
spar cap and SHELL91 element for modeling the thick sandwich structures, namely the leading edge,
trailing edge and shear webs. The two types of elements model the layup as orthotropic in given layers
by real constants, which contain the material properties, orientation and thickness. The number of real
constants should be reasonably determined, as a small number of real constants could result in big
calculation errors, while a large number of them would be time- consuming. Based on a reasonable
simplification of the layup, 290 real constants are defined through adjusting the model many times, as
shown in Figure 5, each color represents a real constant. In order to prevent erroneous results, a regular
quadrilateral mesh generation method is used to generate elements with low aspect ratios. The FEM
model with a mass of 6555.2 kg is shown in Figure 6. The validation process of the FEM model had
been carried out in our previous work [15] to guarantee the reliability of the numerical simulation.
Energies 2016, 9, 66 4 of 18
Table 2. The material properties of the blade.
Material E1 (GPa) E2 (GPa) G12 (GPa) v12 (kg/m3) Thickness (mm)
UD‐1200‐xxx 42.2 12.5 3.5 0.24 1910 0.873
2AX‐1200‐0660 11.5 11.5 11.8 0.61 1909 0.878
3AX‐1200‐6330 26.9 13.4 7.5 0.47 1910 0.906
3AX9060‐1200‐0336 31.8 11.4 6.5 0.49 1910 0.906
Balsa 3.5 0.8 0.16 0.39 151 25.4
PVC 0.05 0.05 0.02 0.09 60 10/15/20/25
The FEM model of the blade is generated by using ANSYS Parametric Design Language
(ADPL) in ANSYS software, which enables the creation of various FEM models by changing the
main aerodynamic and structural parameters. The model is entirely created with SHELL99 element
for modeling the spar cap and SHELL91 element for modeling the thick sandwich structures,
namely the leading edge, trailing edge and shear webs. The two types of elements model the layup
as orthotropic in given layers by real constants, which contain the material properties, orientation
and thickness. The number of real constants should be reasonably determined, as a small number of
real constants could result in big calculation errors, while a large number of them would be time‐
consuming. Based on a reasonable simplification of the layup, 290 real constants are defined
through adjusting the model many times, as shown in Figure 5, each color represents a real constant.
In order to prevent erroneous results, a regular quadrilateral mesh generation method is used to
generate elements with low aspect ratios. The FEM model with a mass of 6555.2 kg is shown in
Figure 6. The validation process of the FEM model had been carried out in our previous work [15]
to guarantee the reliability of the numerical simulation.
Figure 5. Real constant distribution of the blade.
Figure 6. Finite Element Method (FEM) model of the blade.
In order to determine the flap‐wise, edge‐wise and torsional rigidities of the FEM model,
two concentrated forces are applied at the tip in the corresponding directions, respectively.
From the deformed results, the bending deflections and the node displacements are recorded,
Figure 5. Real constant distribution of the blade.
Energies 2016, 9, 66 4 of 18
Table 2. The material properties of the blade.
Material E1 (GPa) E2 (GPa) G12 (GPa) v12 (kg/m3) Thickness (mm)
UD‐1200‐xxx 42.2 12.5 3.5 0.24 1910 0.873
2AX‐1200‐0660 11.5 11.5 11.8 0.61 1909 0.878
3AX‐1200‐6330 26.9 13.4 7.5 0.47 1910 0.906
3AX9060‐1200‐0336 31.8 11.4 6.5 0.49 1910 0.906
Balsa 3.5 0.8 0.16 0.39 151 25.4
PVC 0.05 0.05 0.02 0.09 60 10/15/20/25
The FEM model of the blade is generated by using ANSYS Parametric Design Language
(ADPL) in ANSYS software, which enables the creation of various FEM models by changing the
main aerodynamic and structural parameters. The model is entirely created with SHELL99 element
for modeling the spar cap and SHELL91 element for modeling the thick sandwich structures,
namely the leading edge, trailing edge and shear webs. The two types of elements model the layup
as orthotropic in given layers by real constants, which contain the material properties, orientation
and thickness. The number of real constants should be reasonably determined, as a small number of
real constants could result in big calculation errors, while a large number of them would be time‐
consuming. Based on a reasonable simplification of the layup, 290 real constants are defined
through adjusting the model many times, as shown in Figure 5, each color represents a real constant.
In order to prevent erroneous results, a regular quadrilateral mesh generation method is used to
generate elements with low aspect ratios. The FEM model with a mass of 6555.2 kg is shown in
Figure 6. The validation process of the FEM model had been carried out in our previous work [15]
to guarantee the reliability of the numerical simulation.
Figure 5. Real constant distribution of the blade.
Figure 6. Finite Element Method (FEM) model of the blade.
In order to determine the flap‐wise, edge‐wise and torsional rigidities of the FEM model,
two concentrated forces are applied at the tip in the corresponding directions, respectively.
From the deformed results, the bending deflections and the node displacements are recorded,
Figure 6. Finite Element Method (FEM) model of the blade.
In order to determine the flap-wise, edge-wise and torsional rigidities of the FEM model, two
concentrated forces are applied at the tip in the corresponding directions, respectively. From the
deformed results, the bending deflections and the node displacements are recorded, the bending
angles and bending rate per unit length, the twist angle and corresponding rate of twist are calculated
5. Energies 2016, 9, 66 5 of 18
following the same approach used in [16]. Then, the flap-wise and edge-wise rigidities can be computed
as the ration between the moment M acting on a given cross section and the rate of rotation dθ/dz; the
torsional rigidity can be computed by the ration between the torque T transmitted across a given section
and the corresponding rate of twist dϕ per unit of length dz [8,17]. Figure 7 shows the comparisons
between the rigidities of the FEM model and the original blade. As can be seen, the rigidities are in
good agreement in the flap-wise, edge-wise and torsional directions.
Energies 2016, 9, 66 5 of 18
the bending angles and bending rate per unit length, the twist angle and corresponding rate of twist
are calculated following the same approach used in [16]. Then, the flap‐wise and edge‐wise
rigidities can be computed as the ration between the moment M acting on a given cross section and
the rate of rotation dθ/dz; the torsional rigidity can be computed by the ration between the torque T
transmitted across a given section and the corresponding rate of twist dφ per unit of length dz [8,17].
Figure 7 shows the comparisons between the rigidities of the FEM model and the original blade.
As can be seen, the rigidities are in good agreement in the flap‐wise, edge‐wise and torsional directions.
0 5 10 15 20 25 30 35 40
0
1
2
3
4
5
6EI(GN·m2
)
Blade length (m)
Original blade
FEM model
(a)
0 5 10 15 20 25 30 35 40
0
1
2
3
4
5
6
7
Original blade
FEM model
EI(GN·m2
)
Blade length (m)
(b)
0 5 10 15 20 25 30 35 40
0.0
0.5
1.0
1.5
2.0
2.5
3.0
GJ(GN·m2
)
Blade length (m)
Original blade
FEM model
(c)
Figure 7. (a) comparison of the flap‐wise rigidity; (b) comparison of the edge‐wise rigidity;
(c) comparison of the torsional rigidity.
2.2. Aerodynamic Loads of the Blade
Aerodynamic loads for design are computed using Blade Element Momentum (BEM)
theory [18,19], which include the operational and the ultimate load cases. The operational load case
considers the wind condition corresponding to the maximum root flap bending moment under
Figure 7. (a) comparison of the flap-wise rigidity; (b) comparison of the edge-wise rigidity;
(c) comparison of the torsional rigidity.
6. Energies 2016, 9, 66 6 of 18
2.2. Aerodynamic Loads of the Blade
Aerodynamic loads for design are computed using Blade Element Momentum (BEM)
theory [18,19], which include the operational and the ultimate load cases. The operational load
case considers the wind condition corresponding to the maximum root flap bending moment under
operational state. The range of flow speeds from cut-in to cut-out is divided into different values every
0.5 m/s, and the flap bending moment under each wind speed is calculated using Equation (1):
Mf lap “
ż R
0
4πρu2
ap1 ´ aqFr2
dr (1)
where ρ is the air density, u is the wind speed, a is the axial induction factor, F is the Prandtl’s correction
factor and R is the blade length.
The maximum value is derived from all the flap bending moments experienced over the range of
flow speeds, then the corresponding wind speed u can be obtained. Afterwards, the force normal to
the rotor plane dpN and the force tangential to the rotor plane dpT are calculated as follows:
$
’’&
’’%
dpN “
1
2
ρW2cprqpClcosφ ` Cdsinφqdr
dpT “
1
2
ρW2cprqpClsinφ ´ Cdcosφqdr
(2)
Where W is relative velocity composed of the axial velocity and the tangential velocity, cprq is the local
chord, Cl and Cd are the lift and drag coefficients, φ is the angle between the plane of rotation and the
relative velocity.
The ultimate load case takes the gust speed with a return period of 50 years into account to make
the wind turbine last for the design period. In this case, the blades are parked or idling and the ultimate
load can be calculated approximately by empirical formula [20]:
pprq “ q2sCf cprq (3)
where Cf is a force coefficient, and q2s “
1
2
ρV2
2s is the dynamic pressure from an extreme wind speed
time averaged over 2 s. For a homogeneous terrain, V2s can be computed using:
V2s “ Vbkt
„
ln
ˆ
hhub ` 2{3R
z0
˙
` 3
, (4)
where Vb “ 27m{s is a basis wind speed, hhub is the hub height, z0 is the roughness length and kt is
a terrain factor. If the surrounding landscape has no nearby obstacles and very low vegetation, the
roughness length is approximately 0.01 m and the terrain factor is 0.17.
The operational and the ultimate load distributions of the FEM model are shown in Figure 8.
Energies 2016, 9, 66 6 of 18
operational state. The range of flow speeds from cut‐in to cut‐out is divided into different values
every 0.5 m/s, and the flap bending moment under each wind speed is calculated using Equation (1):
2 2
R
flap 0
M 4πρu a ‐ a Fr dr(1 ) (1)
where ρ is the air density, u is the wind speed, a is the axial induction factor, F is the Prandtl’s
correction factor and R is the blade length.
The maximum value is derived from all the flap bending moments experienced over the range of
flow speeds, then the corresponding wind speed u can be obtained. Afterwards, the force normal to
the rotor plane Ndp and the force tangential to the rotor plane Tdp are calculated as follows:
2
2
N l d
T l d
dp ρW c r C cos C sin dr
dp ρW c r C sin C cos dr
1
= ( )( )
2
1
= ( )( )
2
(2)
Where W is relative velocity composed of the axial velocity and the tangential velocity, c r( ) is the
local chord, Cl and Cd are the lift and drag coefficients, is the angle between the plane of rotation
and the relative velocity.
The ultimate load case takes the gust speed with a return period of 50 years into account to
make the wind turbine last for the design period. In this case, the blades are parked or idling and
the ultimate load can be calculated approximately by empirical formula [20]:
2s fp r q C c r( ) ( ) (3)
where Cf is a force coefficient, and 2
2s 2sq ρV
1
2
is the dynamic pressure from an extreme wind
speed time averaged over 2 s. For a homogeneous terrain, V2s can be computed using:
hub
2s b t
0
h + R
V V k ln +
z
2 3
3
,
(4)
where bV = m / s27 is a basis wind speed, hubh is the hub height, 0z is the roughness length
and tk is a terrain factor. If the surrounding landscape has no nearby obstacles and very low
vegetation, the roughness length is approximately 0.01 m and the terrain factor is 0.17.
The operational and the ultimate load distributions of the FEM model are shown in Figure 8.
(a) (b)
Figure 8. (a) Operational load distribution of the FEM model; (b) Ultimate load distribution of the
FEM model.
Figure 8. (a) Operational load distribution of the FEM model; (b) Ultimate load distribution of the
FEM model.
7. Energies 2016, 9, 66 7 of 18
3. Formulation of the Optimization Problem
3.1. The Objective Functions
A successful blade design must satisfy a wide range of objectives, such as maximization of the
AEP and power coefficient, resistance to extreme and fatigue loads, restriction of tip deflections,
avoiding resonances, and minimization of weight and cost, some of these objectives are in conflict [2].
In order to make wind energy more competitive with other energy sources, manufacturers are
concentrating on increasing the energy output capacity and bringing down the cost of blades and
other components at the same time, so minimizing the COE is an attractive target pursued by many
researchers. However, the cost of the blades involves many factors such as cost of the materials,
production tooling, manufacturing labor and overland transportation, and some of them are hard
to estimate. According to some studies [21,22], reducing materials to minimize the blade mass can
not only cause cost reduction of the blade but also have a multiplier effect through out the system
including the foundation. Thus, the maximum AEP and the minimum blade mass are taken as the
objective functions.
The energy that can be captured by a wind turbine depends upon the power versus wind speed
characteristic of the turbine and the wind-speed distribution at the turbine site. The wind-speed
distribution is represented by the Weibull function. The AEP is defined as in Equations (5)–(7):
fp1q “ AEP “
Nÿ
i“1
1
2
rPpuiq ` Ppui`1qs¨ fpui ă u0 ă ui`1q ˆ 8760 (5)
Ppuiq “
ż R
0
4πr3
ρuiω2
a1
p1 ´ aqFdr (6)
fpui ă u0 ă ui`1q “ exp
ˆ
´
´ui
A
¯k
˙
´ exp
ˆ
´
´ui`1
A
¯k
˙
, (7)
where Ppuiq is the power under wind speed ui, fpui ă u0 ă ui`1q is the probability that the wind
speed lies between ui and ui` 1, ω is the rotational speed of the blade, a1 is the tangential induction
factor, k is a form factor and A is a scaling factor.
The blade mass depends upon the consumption of materials, which can be expressed as:
fp2q “ mass “
ÿ
i
ρi ˆ Vi (8)
where ρi is the material density, Vi is the volume of the material.
3.2. Design Variables
The geometrical shape and the rotational speed of the blade contribute directly to the aerodynamic
performances. Therefore, the values of the control points in Figures 2 and 3 and the rotational speed are
selected as aerodynamic design variables, while the blade length and the airfoil series are employed
as the basic parameters. In order to match up with the bolted flange conveniently, the root diameter
remains unchanged, which means the chord value of CP1 is fixed. Moreover, the chord of CP2 is equal
to CP1, so the chord values of CP3-7 are defined as five aerodynamic variables (x1 to x5). As the twist
remains constant inboard of the maximum chord, which means the twists of CP1-3 are the same, then
the twist values of CP3-7 are defined as another five aerodynamic variables (x6 to x10). The span-wise
locations of CP8 and CP13 are also fixed, one is at root and the other is at tip, thus the locations
of CP9-12 (airfoils with relative thickness of 40%, 30%, 25% and 18%) are employed as four more
aerodynamic variables (x11 to x14). In addition, the rated rotational speed of the rotor is selected as the
last aerodynamic variable (x15).
The spar cap of the blade is primarily designed with a relatively large thickness to carry the
aerodynamic loads, so it makes a major contribution to the blade mass [23]. In addition, the blade
mass can further decrease by positioning the shear webs appropriately. Therefore, the number and
8. Energies 2016, 9, 66 8 of 18
location of layers in the spar cap, the width of the spar cap, and the position of the shear webs are
selected as the structural design variables.
Figure 9 shows the original material layup in the spar cap. The region from 4.4 m to 25.3 m
(shown in green) will be optimized as it has a much greater number of layers than the other regions.
Eight control points are used to simulate the layup in the selected region, and the number of layers
are defined to change linearly between the control points, as shown in Figure 10. CP16-19 each has
two parameters that are the number and the location of layers, while the other CPs each have one
parameter that is the number of layers. In addition, CP17 and CP18 have the same number of layers.
Thus, the number of layers of CP14-21 is defined as seven structural variables (x16 to x22), the location
of layers of CP16-19 are defined as another four structural variables (x23 to x26). Two more structural
variables (x27 and x28) are used to define the width of the spar cap and the position of the shear webs,
respectively, as shown in Figure 4.
The spar cap of the blade is primarily designed with a relatively large thickness to carry the
aerodynamic loads, so it makes a major contribution to the blade mass [23]. In addition, the blade
mass can further decrease by positioning the shear webs appropriately. Therefore, the number and
location of layers in the spar cap, the width of the spar cap, and the position of the shear webs are
selected as the structural design variables.
Figure 9 shows the original material layup in the spar cap. The region from 4.4 m to 25.3 m
(shown in green) will be optimized as it has a much greater number of layers than the other regions.
Eight control points are used to simulate the layup in the selected region, and the number of layers
are defined to change linearly between the control points, as shown in Figure 10. CP16‐19 each has
two parameters that are the number and the location of layers, while the other CPs each have one
parameter that is the number of layers. In addition, CP17 and CP18 have the same number of layers.
Thus, the number of layers of CP14‐21 is defined as seven structural variables (x16 to x22), the
location of layers of CP16‐19 are defined as another four structural variables (x23 to x26). Two more
structural variables (x27 and x28) are used to define the width of the spar cap and the position of the
shear webs, respectively, as shown in Figure 4.
Figure 9. Original material layup of the spar cap.
0 5 10 15 20 25 30
30
35
40
45
50
55
60
65
21
20
19
1817
16
15
Numberoflayers
Blade length (m)
Control points
14
Figure 10. Parametric material layup of the spar cap.
Twenty‐eight variables in total are defined, which can be expressed in the following form:
T
1 2 nX x x x ,n =[ ] 28
.
(9)
3.3. Constraint Conditions
The blade design is a multi‐criteria constrained optimization problem, and the aerodynamic
and structural requirements should be well satisfied [24,25]. In this paper, the following constraint
Figure 9. Original material layup of the spar cap.
aerodynamic loads, so it makes a major contribution to the blade mass [23]. In addition, the blade
mass can further decrease by positioning the shear webs appropriately. Therefore, the number and
location of layers in the spar cap, the width of the spar cap, and the position of the shear webs are
selected as the structural design variables.
Figure 9 shows the original material layup in the spar cap. The region from 4.4 m to 25.3 m
(shown in green) will be optimized as it has a much greater number of layers than the other regions.
Eight control points are used to simulate the layup in the selected region, and the number of layers
are defined to change linearly between the control points, as shown in Figure 10. CP16‐19 each has
two parameters that are the number and the location of layers, while the other CPs each have one
parameter that is the number of layers. In addition, CP17 and CP18 have the same number of layers.
Thus, the number of layers of CP14‐21 is defined as seven structural variables (x16 to x22), the
location of layers of CP16‐19 are defined as another four structural variables (x23 to x26). Two more
structural variables (x27 and x28) are used to define the width of the spar cap and the position of the
shear webs, respectively, as shown in Figure 4.
Figure 9. Original material layup of the spar cap.
0 5 10 15 20 25 30
30
35
40
45
50
55
60
65
21
20
19
1817
16
15
Numberoflayers
Blade length (m)
Control points
14
Figure 10. Parametric material layup of the spar cap.
Twenty‐eight variables in total are defined, which can be expressed in the following form:
T
1 2 nX x x x ,n =[ ] 28
.
(9)
3.3. Constraint Conditions
The blade design is a multi‐criteria constrained optimization problem, and the aerodynamic
and structural requirements should be well satisfied [24,25]. In this paper, the following constraint
Figure 10. Parametric material layup of the spar cap.
Twenty-eight variables in total are defined, which can be expressed in the following form:
X “ r x1 x2 . . . xn s
T
, n “ 28. (9)
3.3. Constraint Conditions
The blade design is a multi-criteria constrained optimization problem, and the aerodynamic
and structural requirements should be well satisfied [24,25]. In this paper, the following constraint
conditions are mainly taken into account: the strain, the tip deflection, the vibration and the buckling
9. Energies 2016, 9, 66 9 of 18
constraints. These constraints represent the strength, stiffness, dynamic behavior, and stability design
requirements, respectively.
(1) Generally, the stress and the strain criterions should be considered to reflect the strength of
the blade. However, the maximum stress generated in the considered 1.5 MW blade under different
loads is far less than the allowable stress, while the maximum strain is much closer to the design value.
Therefore, only the strain criterion is used to verify that no elements in the model exceeded the design
strains of the material [22]. This is expressed as follows:
εmax ď εd{γS1, (10)
where εmax is the maximum equivalent strain, εd is the permissible strain, and γs1 is the strain
safety factor.
(2) In order to prevent the collision between the blade tip and the tower, the maximum tip
deflection should be less than the set value. This can be expressed as follows:
dmax ď dd{γS2, (11)
where dmax is the maximum tip deflection, dd is the allowable tip deflection, and γs2 is the tip deflection
safety factor.
(3) In order to avoid resonance, the natural frequency of the blade should be separated from the
harmonic vibration associated with rotor rotation. This is expressed in the inequality form:
|Fblade´1 ´ 3Frotor| ě ∆, (12)
where Fblade´1 is the first natural frequency of the blade, Frotor is the frequency of the rotor rotation,
and ∆ is the associated allowable tolerance.
(4) Since the blade is a thin-walled structure, its surface panels near the root are particularly
vulnerable to elastic instability, and the buckling problem must be addressed [23]. In order to avoid
buckling failure, the buckling load should be greater than ultimate loads. This can be expressed
as follows:
λ1 ě 1.0 ˆ γS3, (13)
where λ1 is a ratio of the buckling load to the maximum ultimate load, called lowest buckling
eigenvalue, and γs3 is the buckling safety factor.
In addition, the lower and upper bounds of design variables should be set appropriately to control
the change range, shown in Equation (14a). The twist, chord, and relative thickness distributions
are all required to be monotonically decreasing, so the corresponding variables should be satisfied
with the inequality form in Equation (14b,c). Considering the manufacturing maneuverability and
the continuity of the material layup, the variables that represent the number of layers are required
to be monotonically increasing to a maximum value and then monotonically decreasing, shown in
Equation (14d,e). $
’’’’’’’’’&
’’’’’’’’’%
xL
i ď xi ď xU
i i “ 1, 2, ..., 28 paq
xj ´ xj`1 ą 0 j “ 1, 2, 3, 4, 6, 7, 8, 9 pbq
xk ´ xk`1 ă 0 j “ 11, 12, 13 pcq
xg ´ xg`1 ď 0 g “ 16, 17, 18 pdq
xh ´ xh`1 ě 0 h “ 19, 20, 21 peq
, (14)
where xL is the lower bound of the variables, and xU is the upper bound of the variables.
The lower and upper bounds of the variables and the constraint conditions are shown in Table 3.
10. Energies 2016, 9, 66 10 of 18
Table 3. Lower and upper bounds of the variables and the constraint conditions.
Parameter Lower Bound Upper Bound Unit
x1-x5 1.0 3.3 m
x6-x10 ´2.0 12.0 ˝
x11-x14 6.0 30.0 m
x15 10 25 rpm
x16 28 38 -
x17 28 48 -
x18 33 58 -
x19 35 65 -
x20 33 55 -
x21 28 45 -
x22 28 40 -
x23 7.0 9.0 m
x24 10.0 13.0 m
x25 16.0 19.0 m
x26 20.5 22.0 m
x27 0.13 0.25 m
x28 0.50 0.70 m
εmax - 0.005 -
dmax - 5.5 m
λ1 1.2 - -
Fblade´1 ď3Frotor ´ 0.3 or ě3Frotor + 0.3 Hz
4. The Integrated Optimization Design Procedure
The purpose of the present work is to improve the overall performance of HAWT blades by means
of an optimization of its aerodynamic and structural integrated design, a procedure that interfaces
both the MATLAB optimization tool and develops the finite element software ANSYS. Three modules
are used in the procedure: an aerodynamic analysis module, a structural analysis module and a
multi-objective optimization module. The former two provide a sufficiently accurate solution of
the aerodynamic performances and structural behaviors of the blade; the latter handles the design
variables of the optimization problem and promotes functions optimization. The non-dominated
sorting genetic algorithm (NSGA) II [26–28] is adapted for the integrated optimization design. It is one
of the most efficient and well-known multi-objective evolutionary algorithms and has been widely
applied to solve complicated optimization problems. According to the method, the Pareto optimal
front can be obtained considering the set of Non-Dominated Solutions.
Figure 11 shows the flowchart of the integrated optimization process. After inputting the original
parameters, an initial population is generated randomly in MATLAB with the aerodynamic and
structural variables written in a string of genes. The aerodynamic variables are used to define the
geometry shape of the blade while the structural variables are used to define the internal structure.
Then, the BEM theory is applied to evaluate the aerodynamic performance, such as power, power
coefficient, aerodynamic loads, etc. Meanwhile, a macro file that can transfer the variables from
MATLAB into ANSYS is created using APDL language. Through some specific commands, the
procedure opens the software ANSYS, calls the macro file to generate a parametric FEM model of
the blade and simulates the load cases in order to obtain the structural behaviors, namely, the strain
level, the tip deflection, the natural frequencies, the bulking load factors, etc. After several constraint
conditions have been checked, two appropriate fitness functions are evaluated. The next step is to
classify the solutions according to a fast non-dominated sorting approach and assign the crowding
distance. Finally, a new population is created and the process can restart until the optimization
procedure converges.
11. Energies 2016, 9, 66 11 of 18
Energies 2016, 9, 66 11 of 18
Figure 11. Flowchart of the integrated optimization process.
5. Optimization Application and Results
The basic parameters of the rotor, wind condition and NSGA‐II algorithm are listed in Table 4.
The Weibull form factor and scaling factor are determined from local meteorological data of inland
China with an annual average wind speed of 6 m/s, namely, k = 1.91 and A = 6.8 m/s.
The probability distribution of the specified wind speed is shown in Figure 12.
Table 4. Parameters of rotor, wind condition and non‐dominated sorting genetic algorithm
(NSGA)‐II algorithm.
Parameter Value Unit
Rotor diameter 77 m
Number of blades 3 ‐
Hub diameter 3 m
Hub height 75 m
Rated wind speed 12 m/s
Rated rotational speed 19 rpm
Rated power 1500 kW
Cut‐in wind speed 4 m/s
Cut‐out wind speed 25 m/s
Air density 1.225 kg/m3
Weibull form factor k 1.91 ‐
Weibull scaling factor A 6.8 m/s
Number of individuals 40 ‐
Number of iterations 30 ‐
Probability of crossover 0.8 ‐
Probability of mutation 0.05 ‐
Figure 11. Flowchart of the integrated optimization process.
5. Optimization Application and Results
The basic parameters of the rotor, wind condition and NSGA-II algorithm are listed in Table 4.
The Weibull form factor and scaling factor are determined from local meteorological data of inland
China with an annual average wind speed of 6 m/s, namely, k = 1.91 and A = 6.8 m/s. The probability
distribution of the specified wind speed is shown in Figure 12.
Table 4. Parameters of rotor, wind condition and non-dominated sorting genetic algorithm
(NSGA)-II algorithm.
Parameter Value Unit
Rotor diameter 77 m
Number of blades 3 -
Hub diameter 3 m
Hub height 75 m
Rated wind speed 12 m/s
Rated rotational speed 19 rpm
Rated power 1500 kW
Cut-in wind speed 4 m/s
Cut-out wind speed 25 m/s
Air density 1.225 kg/m3
Weibull form factor k 1.91 -
Weibull scaling factor A 6.8 m/s
Number of individuals 40 -
Number of iterations 30 -
Probability of crossover 0.8 -
Probability of mutation 0.05 -
12. Energies 2016, 9, 66 12 of 18
Energies 2016, 9, 66 12 of 18
0 5 10 15 20 25
-0.02
0.00
0.02
0.04
0.06
0.08
0.10
0.12
0.14
Probability
Wind speed (m/s)
k=1.91 c=6.8 Weibull distribution
Figure 12. Weibull probability distribution of wind speed.
Figure 13 shows the Pareto front obtained by taking the maximum AEP and the minimum
blade mass as the optimization objectives. The points on the left hand of the front identify design
solutions having low mass yet low energy production, whereas the points on the right hand of the
front present design solutions having high energy production but also high mass, which indicates
there are some conflicts between the two objectives. It cannot be said which point is the best, the
choice of the solution in the practical design should be made according to the designer’s favor.
In order to explain the formation of the Pareto front better, four optimized schemes extracted
at different positions on the Pareto front are analyzed, as marked in Figure 13. The values of the
design variables of schemes A, B, C, D and the original scheme are listed in Table 5.
3.400 3.415 3.430 3.445 3.460 3.475 3.490 3.505 3.520 3.535 3.550
5450
5500
5550
5600
5650
5700
5750
5800
5850
5900
Ⅰ
Ⅱ
D
C
B
A
Blademass(kg)
AEP (GWh/yr)
Figure 13. Pareto front of two objectives.
Table 5. Values of the design variables.
Parameter Original Scheme Scheme A Scheme B Scheme C Scheme D Unit
x1 3.08 2.70 2.60 2.47 2.44 m
x2 2.88 2.64 2.56 2.43 2.41 m
x3 2.30 2.21 2.15 2.10 2.08 m
x4 1.82 1.66 1.64 1.61 1.60 m
x5 1.21 1.16 1.16 1.19 1.17 m
x6 8.73 10.69 10.38 9.70 9.56 °
x7 6.64 6.72 6.61 6.59 6.60 °
x8 3.14 3.84 3.49 3.80 3.58 °
x9 0.43 0.85 0.82 0.88 0.97 °
x10 −1.13 −0.49 −0.81 −0.22 0.02 °
x11 6.75 7.73 6.96 7.10 7.03 m
Figure 12. Weibull probability distribution of wind speed.
Figure 13 shows the Pareto front obtained by taking the maximum AEP and the minimum blade
mass as the optimization objectives. The points on the left hand of the front identify design solutions
having low mass yet low energy production, whereas the points on the right hand of the front present
design solutions having high energy production but also high mass, which indicates there are some
conflicts between the two objectives. It cannot be said which point is the best, the choice of the solution
in the practical design should be made according to the designer’s favor.
In order to explain the formation of the Pareto front better, four optimized schemes extracted at
different positions on the Pareto front are analyzed, as marked in Figure 13. The values of the design
variables of schemes A, B, C, D and the original scheme are listed in Table 5.
Energies 2016, 9, 66 12 of 18
0 5 10 15 20 25
-0.02
0.00
0.02
0.04
0.06
0.08
0.10
0.12
0.14
Probability
Wind speed (m/s)
k=1.91 c=6.8 Weibull distribution
Figure 12. Weibull probability distribution of wind speed.
Figure 13 shows the Pareto front obtained by taking the maximum AEP and the minimum
blade mass as the optimization objectives. The points on the left hand of the front identify design
solutions having low mass yet low energy production, whereas the points on the right hand of the
front present design solutions having high energy production but also high mass, which indicates
there are some conflicts between the two objectives. It cannot be said which point is the best, the
choice of the solution in the practical design should be made according to the designer’s favor.
In order to explain the formation of the Pareto front better, four optimized schemes extracted
at different positions on the Pareto front are analyzed, as marked in Figure 13. The values of the
design variables of schemes A, B, C, D and the original scheme are listed in Table 5.
3.400 3.415 3.430 3.445 3.460 3.475 3.490 3.505 3.520 3.535 3.550
5450
5500
5550
5600
5650
5700
5750
5800
5850
5900
Ⅰ
Ⅱ
D
C
B
A
Blademass(kg)
AEP (GWh/yr)
Figure 13. Pareto front of two objectives.
Table 5. Values of the design variables.
Parameter Original Scheme Scheme A Scheme B Scheme C Scheme D Unit
x1 3.08 2.70 2.60 2.47 2.44 m
x2 2.88 2.64 2.56 2.43 2.41 m
x3 2.30 2.21 2.15 2.10 2.08 m
x4 1.82 1.66 1.64 1.61 1.60 m
x5 1.21 1.16 1.16 1.19 1.17 m
x6 8.73 10.69 10.38 9.70 9.56 °
x7 6.64 6.72 6.61 6.59 6.60 °
x8 3.14 3.84 3.49 3.80 3.58 °
x9 0.43 0.85 0.82 0.88 0.97 °
x10 −1.13 −0.49 −0.81 −0.22 0.02 °
x11 6.75 7.73 6.96 7.10 7.03 m
Figure 13. Pareto front of two objectives.
Table 5. Values of the design variables.
Parameter Original Scheme Scheme A Scheme B Scheme C Scheme D Unit
x1 3.08 2.70 2.60 2.47 2.44 m
x2 2.88 2.64 2.56 2.43 2.41 m
x3 2.30 2.21 2.15 2.10 2.08 m
x4 1.82 1.66 1.64 1.61 1.60 m
x5 1.21 1.16 1.16 1.19 1.17 m
x6 8.73 10.69 10.38 9.70 9.56 ˝
x7 6.64 6.72 6.61 6.59 6.60 ˝
x8 3.14 3.84 3.49 3.80 3.58 ˝
x9 0.43 0.85 0.82 0.88 0.97 ˝
x10 ´1.13 ´0.49 ´0.81 ´0.22 0.02 ˝
x11 6.75 7.73 6.96 7.10 7.03 m
13. Energies 2016, 9, 66 13 of 18
Table 5. Cont.
Parameter Original Scheme Scheme A Scheme B Scheme C Scheme D Unit
x12 9.50 9.81 9.32 10.51 9.73 m
x13 14.10 14.18 14.32 14.34 14.21 m
x14 28.95 24.32 25.16 24.35 24.20 m
x15 19.0 15.5 15.6 15.2 14.9 rpm
x16 33 32 30 30 29 -
x17 43 38 36 35 34 -
x18 53 48 46 44 44 -
x19 62 53 51 50 48 -
x20 53 41 39 38 38 -
x21 43 33 31 30 30 -
x22 33 29 29 29 28 -
x23 7.8 7.6 8.0 7.6 7.8 m
x24 11.0 12.1 11.8 11.9 11.8 m
x25 18.0 17.9 17.9 17.7 17.7 m
x26 21.4 21.3 21.3 21.3 21.2 m
x27 0.188 0.195 0.180 0.193 0.191 m
x28 0.620 0.589 0.558 0.553 0.551 m
Figure 14 shows the chord distributions of the original scheme and optimized schemes. Due to
the blade root diameter remaining the same, the chords of the optimization schemes change slightly in
the root area. After the root area, the chords of the optimized schemes show an obvious decrease when
compared to the original scheme, especially in the maximum chord region and near the blade tip. This
indicates that the original scheme is possibly designed by the conventional methods (Wilson method
or Glauert method), which leads to a larger chord. The reduction of the chord could reduce the power
production to some extent, but it can result in a lighter blade and a lower thrust at the same time.
Figure 14 shows the chord distributions of the original scheme and optimized schemes. Due to
the blade root diameter remaining the same, the chords of the optimization schemes change slightly
in the root area. After the root area, the chords of the optimized schemes show an obvious decrease
when compared to the original scheme, especially in the maximum chord region and near the blade
tip. This indicates that the original scheme is possibly designed by the conventional methods
(Wilson method or Glauert method), which leads to a larger chord. The reduction of the chord
could reduce the power production to some extent, but it can result in a lighter blade and a lower
thrust at the same time.
0 5 10 15 20 25 30 35 40
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
Chord(m)
Blade length (m)
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Figure 14. Comparison of chord distribution.
Figure 15 shows the twist distributions of the five schemes. The twists of the optimized
schemes also change slightly in the root area for structural reasons. Then, the twists increase from
the maximum chord region, but the distribution trends almost remain the same as the original
scheme. Due to the decreasing of the rotational speed ( 15x listed in Table 5), the angle between the
mean relative velocity and tangential direction will increase. With the incensement of the twist, the
angle of attacks can almost remain the same, which guarantees the airfoils still have higher
lift‐to‐drag ratios to partly make up for the power loss caused by the reduction of the chord.
x12 9.50 9.81 9.32 10.51 9.73 m
x13 14.10 14.18 14.32 14.34 14.21 m
x14 28.95 24.32 25.16 24.35 24.20 m
x15 19.0 15.5 15.6 15.2 14.9 rpm
x16 33 32 30 30 29 ‐
x17 43 38 36 35 34 ‐
x18 53 48 46 44 44 ‐
x19 62 53 51 50 48 ‐
x20 53 41 39 38 38 ‐
x21 43 33 31 30 30 ‐
x22 33 29 29 29 28 ‐
x23 7.8 7.6 8.0 7.6 7.8 m
x24 11.0 12.1 11.8 11.9 11.8 m
x25 18.0 17.9 17.9 17.7 17.7 m
x26 21.4 21.3 21.3 21.3 21.2 m
x27 0.188 0.195 0.180 0.193 0.191 m
x28 0.620 0.589 0.558 0.553 0.551 m
Figure 14. Comparison of chord distribution.
Figure 15 shows the twist distributions of the five schemes. The twists of the optimized schemes
also change slightly in the root area for structural reasons. Then, the twists increase from the maximum
chord region, but the distribution trends almost remain the same as the original scheme. Due to the
decreasing of the rotational speed (x15 listed in Table 5), the angle between the mean relative velocity
and tangential direction will increase. With the incensement of the twist, the angle of attacks can
almost remain the same, which guarantees the airfoils still have higher lift-to-drag ratios to partly
make up for the power loss caused by the reduction of the chord.
14. Energies 2016, 9, 66 14 of 18
Energies 2016, 9, 66 14 of 18
0 5 10 15 20 25 30 35 40
-3
-1
1
3
5
7
9
11
13
Twist()
Blade length (m)
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Figure 15. Comparison of twist distribution.
The percent thickness distributions are shown in Figure 16. The locations of the airfoils with
40% and 30% thicknesses for the optimized schemes move toward the tip. From the structural point
of view, this is good for increasing the section moment of inertia. The location of the airfoil with
25% thickness almost remains the same, while that of the airfoil with 18% thickness moves toward
the root. As the airfoil with 18% thickness has a higher lift‐to‐drag ratio, the aerodynamic region
composed by this airfoil is the main part of the blade to capture wind energy. Moving the location
of the airfoil with 18% thickness towards the root can increase the length of this region, which is
beneficial to capture more energy, thus improving the power efficiency from the aerodynamic point
of view. The blade shapes become much smoother after optimization, which is more convenient for
manufacturing. The decreasing of the rotational speed could reduce the rotor rotation times during
a 20 year life span, and thus improve the fatigue life of the blade.
0 5 10 15 20 25 30 35 40
0
20
40
60
80
100
Percentthickness(%)
Blade length (m)
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Figure 16. Comparison of percent thickness distribution.
Figures 17 and 18 show the comparison of power coefficients and powers between the original
scheme and optimized schemes, respectively. When compared to the original scheme, the power
coefficients of the optimized schemes increase significantly in the speed range of 4 to 8 m/s, and
decrease slightly in the peed range of 10 to 13 m/s. The power coefficients of the optimized schemes
all reach the maximum values of about 0.49 at 8 m/s wind speed (a 7.7% increase compared to the
original scheme), and keep relatively high values in the speed range of 6 to 9 m/s. With the
reduction of chord, the rated wind speeds of the 4 optimized schemes gradually change from 12 to
15 m/s, as shown in Figure 15. The comparisons in Figures 17 and 18 reveal that the optimized
schemes have better aerodynamic performances than the original scheme at low wind speeds, but
the performances gradually become worse when the wind speed increases. As can be seen from
Figure 12, for a turbine site with an annual average wind speed of 6 m/s, the probabilities of the wind
Figure 15. Comparison of twist distribution.
The percent thickness distributions are shown in Figure 16. The locations of the airfoils with
40% and 30% thicknesses for the optimized schemes move toward the tip. From the structural point
of view, this is good for increasing the section moment of inertia. The location of the airfoil with
25% thickness almost remains the same, while that of the airfoil with 18% thickness moves toward
the root. As the airfoil with 18% thickness has a higher lift-to-drag ratio, the aerodynamic region
composed by this airfoil is the main part of the blade to capture wind energy. Moving the location
of the airfoil with 18% thickness towards the root can increase the length of this region, which is
beneficial to capture more energy, thus improving the power efficiency from the aerodynamic point
of view. The blade shapes become much smoother after optimization, which is more convenient for
manufacturing. The decreasing of the rotational speed could reduce the rotor rotation times during a
20 year life span, and thus improve the fatigue life of the blade.
Energies 2016, 9, 66 14 of 18
0 5 10 15 20 25 30 35 40
-3
-1
1
3
5
7
9
11
13
Twist()
Blade length (m)
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Figure 15. Comparison of twist distribution.
The percent thickness distributions are shown in Figure 16. The locations of the airfoils with
40% and 30% thicknesses for the optimized schemes move toward the tip. From the structural point
of view, this is good for increasing the section moment of inertia. The location of the airfoil with
25% thickness almost remains the same, while that of the airfoil with 18% thickness moves toward
the root. As the airfoil with 18% thickness has a higher lift‐to‐drag ratio, the aerodynamic region
composed by this airfoil is the main part of the blade to capture wind energy. Moving the location
of the airfoil with 18% thickness towards the root can increase the length of this region, which is
beneficial to capture more energy, thus improving the power efficiency from the aerodynamic point
of view. The blade shapes become much smoother after optimization, which is more convenient for
manufacturing. The decreasing of the rotational speed could reduce the rotor rotation times during
a 20 year life span, and thus improve the fatigue life of the blade.
0 5 10 15 20 25 30 35 40
0
20
40
60
80
100
Percentthickness(%)
Blade length (m)
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Figure 16. Comparison of percent thickness distribution.
Figures 17 and 18 show the comparison of power coefficients and powers between the original
scheme and optimized schemes, respectively. When compared to the original scheme, the power
coefficients of the optimized schemes increase significantly in the speed range of 4 to 8 m/s, and
decrease slightly in the peed range of 10 to 13 m/s. The power coefficients of the optimized schemes
all reach the maximum values of about 0.49 at 8 m/s wind speed (a 7.7% increase compared to the
original scheme), and keep relatively high values in the speed range of 6 to 9 m/s. With the
reduction of chord, the rated wind speeds of the 4 optimized schemes gradually change from 12 to
15 m/s, as shown in Figure 15. The comparisons in Figures 17 and 18 reveal that the optimized
schemes have better aerodynamic performances than the original scheme at low wind speeds, but
the performances gradually become worse when the wind speed increases. As can be seen from
Figure 12, for a turbine site with an annual average wind speed of 6 m/s, the probabilities of the wind
Figure 16. Comparison of percent thickness distribution.
Figures 17 and 18 show the comparison of power coefficients and powers between the original
scheme and optimized schemes, respectively. When compared to the original scheme, the power
coefficients of the optimized schemes increase significantly in the speed range of 4 to 8 m/s, and
decrease slightly in the peed range of 10 to 13 m/s. The power coefficients of the optimized schemes
all reach the maximum values of about 0.49 at 8 m/s wind speed (a 7.7% increase compared to the
original scheme), and keep relatively high values in the speed range of 6 to 9 m/s. With the reduction
of chord, the rated wind speeds of the 4 optimized schemes gradually change from 12 to 15 m/s, as
shown in Figure 15. The comparisons in Figures 17 and 18 reveal that the optimized schemes have
better aerodynamic performances than the original scheme at low wind speeds, but the performances
gradually become worse when the wind speed increases. As can be seen from Figure 12, for a turbine
site with an annual average wind speed of 6 m/s, the probabilities of the wind speed lying between
15. Energies 2016, 9, 66 15 of 18
4 m/s and 8 m/s are much higher than those lying between 10 m/s and 13 m/s, so the optimized
schemes are more reasonable as they can utilize more wind energy resources.
Energies 2016, 9, 66 15 of 18
speed lying between 4 m/s and 8 m/s are much higher than those lying between 10 m/s and 13 m/s,
so the optimized schemes are more reasonable as they can utilize more wind energy resources.
0 5 10 15 20 25 30
0.0
0.1
0.2
0.3
0.4
0.5
Original scheme
Blade A
Blade B
Blade C
Blade D
PowerCoefficientCp
Wind speed (m/s)
Figure 17. Comparison of power coefficient under different wind speed.
0 5 10 15 20 25 30
0
200
400
600
800
1000
1200
1400
1600
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Power(kW)
Wind speed (m/s)
Figure 18. Comparison of power under different wind speed.
Figure 19 shows the comparison of material layup in the spar cap between the original scheme
and optimized schemes. From Figure 19 and Table 4, it can be seen that the number of layers
changes slightly from 4.4 m to 8 m and 21.5 m to 25.3 m while it decreases obviously from 8 m to
21.5 m along span‐wise of the blade, and the thickest region becomes smaller. This indicates that the
two regions from 4.4 m to 8 m and 21.5 m to 25.3 m have less impact on the blade mass than the
middle part. The reason is that the original number of layers in these two regions is less, and the
relatively large lower bounds limit it to change significantly. As the region from 4.4 m to 8 m
withstands higher loads, the number of layers in this region is a bit more than it in the region from
21.5 m to 25.3 m after optimization.
The position of the shear webs decrease after optimization, which means that the shear webs
move toward the centerline of the spar cap. According to the sensitive analysis in our previous
work [29], although the blade mass will increase from 6555.2 kg to 6560.2 kg when the position was
reduced by 20%, the maximum strain can reduce from 0.00429 to 0.00412, i.e., improve the blade
strength on the premise that the mass is almost unchanged. Thus, the number of layers in the spar
cap could decrease further, which makes the blade much lighter. The width of the spar cap also
decreases after optimization, and a smaller width of the spar cap can reduce the amount of
materials, which is beneficial for reducing the blade mass.
Figure 17. Comparison of power coefficient under different wind speed.
Energies 2016, 9, 66 15 of 18
speed lying between 4 m/s and 8 m/s are much higher than those lying between 10 m/s and 13 m/s,
so the optimized schemes are more reasonable as they can utilize more wind energy resources.
0 5 10 15 20 25 30
0.0
0.1
0.2
0.3
0.4
0.5
Original scheme
Blade A
Blade B
Blade C
Blade DPowerCoefficientCp
Wind speed (m/s)
Figure 17. Comparison of power coefficient under different wind speed.
0 5 10 15 20 25 30
0
200
400
600
800
1000
1200
1400
1600
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Power(kW)
Wind speed (m/s)
Figure 18. Comparison of power under different wind speed.
Figure 19 shows the comparison of material layup in the spar cap between the original scheme
and optimized schemes. From Figure 19 and Table 4, it can be seen that the number of layers
changes slightly from 4.4 m to 8 m and 21.5 m to 25.3 m while it decreases obviously from 8 m to
21.5 m along span‐wise of the blade, and the thickest region becomes smaller. This indicates that the
two regions from 4.4 m to 8 m and 21.5 m to 25.3 m have less impact on the blade mass than the
middle part. The reason is that the original number of layers in these two regions is less, and the
relatively large lower bounds limit it to change significantly. As the region from 4.4 m to 8 m
withstands higher loads, the number of layers in this region is a bit more than it in the region from
21.5 m to 25.3 m after optimization.
The position of the shear webs decrease after optimization, which means that the shear webs
move toward the centerline of the spar cap. According to the sensitive analysis in our previous
work [29], although the blade mass will increase from 6555.2 kg to 6560.2 kg when the position was
reduced by 20%, the maximum strain can reduce from 0.00429 to 0.00412, i.e., improve the blade
strength on the premise that the mass is almost unchanged. Thus, the number of layers in the spar
cap could decrease further, which makes the blade much lighter. The width of the spar cap also
decreases after optimization, and a smaller width of the spar cap can reduce the amount of
materials, which is beneficial for reducing the blade mass.
Figure 18. Comparison of power under different wind speed.
Figure 19 shows the comparison of material layup in the spar cap between the original scheme
and optimized schemes. From Figure 19 and Table 4, it can be seen that the number of layers changes
slightly from 4.4 m to 8 m and 21.5 m to 25.3 m while it decreases obviously from 8 m to 21.5 m
along span-wise of the blade, and the thickest region becomes smaller. This indicates that the two
regions from 4.4 m to 8 m and 21.5 m to 25.3 m have less impact on the blade mass than the middle
part. The reason is that the original number of layers in these two regions is less, and the relatively
large lower bounds limit it to change significantly. As the region from 4.4 m to 8 m withstands higher
loads, the number of layers in this region is a bit more than it in the region from 21.5 m to 25.3 m
after optimization.
The position of the shear webs decrease after optimization, which means that the shear webs move
toward the centerline of the spar cap. According to the sensitive analysis in our previous work [29],
although the blade mass will increase from 6555.2 kg to 6560.2 kg when the position was reduced
by 20%, the maximum strain can reduce from 0.00429 to 0.00412, i.e., improve the blade strength on
the premise that the mass is almost unchanged. Thus, the number of layers in the spar cap could
decrease further, which makes the blade much lighter. The width of the spar cap also decreases
after optimization, and a smaller width of the spar cap can reduce the amount of materials, which is
beneficial for reducing the blade mass.
16. Energies 2016, 9, 66 16 of 18
Energies 2016, 9, 66 16 of 18
0 5 10 15 20 25 30
25
30
35
40
45
50
55
60
65
Numberoflayers
Blade length (m)
Original scheme
Scheme A
Scheme B
Scheme C
Scheme D
Figure 19. Comparison of material layup of the spar cap.
The AEP, blade mass and structural performances of the schemes are presented in Table 6.
Compared with the original scheme, the AEP of schemes A, B, C, D increase by 11.40%, 10.99%,
9.48% and 7.56%, respectively, while the blade mass decreases by 10.39%, 13.53%, 15.33% and
15.96%, respectively. The maximum strain increases, the tip deflection decreases firstly and then
increases, and the lowest buckling load factor decreases, but they still satisfy the constraint conditions
set in the procedure. The structural stiffness reduces with the decreasing of the blade. However, the
reduced ratio of the stiffness is greater than that of the mass of the blade. Therefore, the first natural
frequency decreases, but there is no occurrence of resonance. Compared with the best result having
a blade mass of 6064.6 kg in [15], the reduction of chords and spar width can further decrease the
blade mass obviously in the case of a small difference between the material layups.
Table 6. Comparison of the annual energy production (AEP), blade mass and structural performance.
Scheme
AEP
(GWh/Year)
Blade
Mass (kg)
Maximum
Strain
Maximum Tip
Deflection (m)
The Lowest
Buckling
Eigenvalue
The First
Natural
Frequency (Hz)
Original 3.175 6555.2 0.00429 4.60 2.024 1.027
A 3.537 5874.1 0.00481 4.13 1.491 0.969
B 3.524 5668.4 0.00485 4.36 1.358 0.938
C 3.476 5550.3 0.00491 4.75 1.252 0.907
D 3.415 5509.1 0.00498 4.92 1.216 0.884
6. Conclusions
This paper describes a multi‐objective optimization method for the aerodynamic and structural
integrated design of HAWT blades. The method is used to obtain the best trade‐off solutions
between the two conflict objectives of maximum AEP and minimum blade mass.
A procedure uses BEM theory and an FEM model, and the NSGA II algorithm is developed for
this purpose. The BEM theory and FEM model are utilized to determine the aerodynamic and
structural performances of HAWT blades, and the optimization fitness functions as well. The NSGA
II algorithm is adopted to handle the design variables chosen for optimization and search for the
group of optimal solutions following the basic principles of Genetic Programming and Pareto concepts.
The procedure has been applied successfully to a 1.5 MW commercial HAWT blade, and
satisfactory schemes to increase the AEP and decrease the blade mass are achieved under a specific
annual average wind speed. The results indicate that the maximum AEP requires blades having
large chords and layer thicknesses, thus high masses, while the requirement of the maximum blade
mass is just the opposite. The further aerodynamic and structural analysis of the optimization
schemes show great improvements for the overall performances of the blade, which indicates the
efficiency and reliability of the proposed procedure.
In future work, an attempt will be made to define the chord and the twist distributions more
appropriately with Non‐Uniform Rational B‐Splines (NURBs) curves. The optimization of the
Figure 19. Comparison of material layup of the spar cap.
The AEP, blade mass and structural performances of the schemes are presented in Table 6.
Compared with the original scheme, the AEP of schemes A, B, C, D increase by 11.40%, 10.99%,
9.48% and 7.56%, respectively, while the blade mass decreases by 10.39%, 13.53%, 15.33% and 15.96%,
respectively. The maximum strain increases, the tip deflection decreases firstly and then increases,
and the lowest buckling load factor decreases, but they still satisfy the constraint conditions set in the
procedure. The structural stiffness reduces with the decreasing of the blade. However, the reduced
ratio of the stiffness is greater than that of the mass of the blade. Therefore, the first natural frequency
decreases, but there is no occurrence of resonance. Compared with the best result having a blade
mass of 6064.6 kg in [15], the reduction of chords and spar width can further decrease the blade mass
obviously in the case of a small difference between the material layups.
Table 6. Comparison of the annual energy production (AEP), blade mass and structural performance.
Scheme
AEP
(GWh/Year)
Blade
Mass (kg)
Maximum
Strain
Maximum Tip
Deflection (m)
The Lowest Buckling
Eigenvalue
The First Natural
Frequency (Hz)
Original 3.175 6555.2 0.00429 4.60 2.024 1.027
A 3.537 5874.1 0.00481 4.13 1.491 0.969
B 3.524 5668.4 0.00485 4.36 1.358 0.938
C 3.476 5550.3 0.00491 4.75 1.252 0.907
D 3.415 5509.1 0.00498 4.92 1.216 0.884
6. Conclusions
This paper describes a multi-objective optimization method for the aerodynamic and structural
integrated design of HAWT blades. The method is used to obtain the best trade-off solutions between
the two conflict objectives of maximum AEP and minimum blade mass.
A procedure uses BEM theory and an FEM model, and the NSGA II algorithm is developed
for this purpose. The BEM theory and FEM model are utilized to determine the aerodynamic and
structural performances of HAWT blades, and the optimization fitness functions as well. The NSGA II
algorithm is adopted to handle the design variables chosen for optimization and search for the group
of optimal solutions following the basic principles of Genetic Programming and Pareto concepts.
The procedure has been applied successfully to a 1.5 MW commercial HAWT blade, and
satisfactory schemes to increase the AEP and decrease the blade mass are achieved under a specific
annual average wind speed. The results indicate that the maximum AEP requires blades having large
chords and layer thicknesses, thus high masses, while the requirement of the maximum blade mass
is just the opposite. The further aerodynamic and structural analysis of the optimization schemes
show great improvements for the overall performances of the blade, which indicates the efficiency and
reliability of the proposed procedure.
In future work, an attempt will be made to define the chord and the twist distributions more
appropriately with Non-Uniform Rational B-Splines (NURBs) curves. The optimization of the material
17. Energies 2016, 9, 66 17 of 18
layup in the whole spar cap will also be carried out to further improve the overall performances of
the blade.
Acknowledgments: This work is financially supported by the key disciplines of Zhejiang Province-Building
Energy Saving Technology (Grant No. 71012005Z-2).
Author Contributions: Jie Zhu carried out most of the work presented here, Xin Cai was the supervisors of this
work, and Rongrong Gu had a relevant contribution with her extensive knowledge about the FEM modeling of
the blade.
Conflicts of Interest: The authors declare no conflict of interest.
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