In future planning of the city, it is very important to consider the proper intelligent integration of renewable energy sources into the built environment for developing smart cities. Analysis of the wind velocity profile in the built environment is very important for finding out the energy content in the wind and also to analyze the performance of wind turbines in the built environment. In this study, building topologies of smart city are investigated for finding out the wind velocity profile and the wind turbine power output in the built environment. The wind velocity distribution across buildings is numerically simulated by using commercial CFD (Computational Fluid Dynamics) software CFD-ACE+. Wind turbine power output is estimated by using the power curve of real commercial wind turbine and wind velocity distribution simulated by CFD software. It has been observed that the wind is accelerated in the intervening space between the buildings irrespective of distance between the walls of adjacent buildings under the condition, which are investigated in this study. The wind is accelerated across buildings, and is reduced rapidly after blowing through buildings, and recovered gradually. Since the wind is accelerated in the intervening space between buildings and reduced in the area at the back of buildings, a wind turbine should be installed at the area at the back of the buildings and located on center between the buildings. In this work, it is observed that size dimensions and layout of the building are effective in realizing a smart city for utilizing renewable energy such as wind turbine in the built environment.
Since a fossil fuel reserve is limited and a global warming by greenhouse gas like CO2 is a worldwide problem, environment friendly energy sources are requested to fulfill the growing energy demand and also to replace the fossil fuelled existing power plants. Renewable energy sources such as wind, photovoltaic, solar thermal, geothermal and bio-energy draw attention from the world as an alternative environment friendly energy sources. Since the energy density of these described renewable energy sources is low and they are also nature dependent. It is very important to develop proper strategies to integrate these renewable energy sources into the network for buffering their intermittency and also to improve the power system stability with higher penetration of renewable energy sources. The smart grid is an effective way to integrate renewable energy sources into the existing energy system network [1-6]. A future smart grid power system network will serve as a dynamic network for multi-directional energy flows, linking widely distributed small capacity renewable energy systems at consumer level (distribution network) and centralized higher-capacity power generators, facilitating active participation of customer choice for energy production/source and demand management, and also providing real-time information on the performance and optimal operation of the power system network [
In Japan, some demonstration projects of smart city are under contemplation [
In this study, building topologies of smart city are investigated for finding out the wind velocity profile in the built environment. Analysis of the wind velocity profile in the built environment is very important for finding out the energy content in the wind and also to analyze the performance of wind turbines in the built environment. The micro/mini-scale wind turbines are emerging as building integrated renewable energy technology due to advances in aerodynamic design, electric generators, power condition devices, increasing energy prices and the financial incentives provided by the government. The output from these built environment wind turbines are affected by the shear and shadow effects of the wind velocity profile distribution in the built environment. The generalized quantification of built environment wind turbines is uncertain. In the first phase, this study focuses on the size and layout of buildings in the smart city. In the built environment, the wind velocity distribution is mainly influenced by the dimensions, design and layout of the buildings. The analysis of the wind velocity profile in the built environment is very important to find the energy content in the wind. It will help in finding the effective wind energy input on the wind turbine and its output.
The concept diagram of this study has been illustrated in
The main objective of this study is to estimate the generated power output of wind turbine for wind velocity variations in the built environment by taking into account the building profiles and their layouts. Also, the effective design of building layouts are analyzed for obtaining the higher output from the building integrated wind turbines. As far as the authors’ survey literatures, there is no study that analyzes the wind velocity distribution around building to obtain the higher output of wind turbine. In this study, the estimation of the power output of the building integrated wind turbine is analyzed by using the wind velocity distribution across the buildings. The wind velocity distribution across the buildings is developed/ simulated through a CFD (Computational Fluid Dynamics) software. The output power of the wind turbine is estimated by using the power curve of real commercial wind turbine and the wind velocity distribution around buildings.
In this study, a commercial CFD software CFD-ACE+ (WAVE FRONT) is adopted for numerical simulation of wind velocity distribution. This CFD software has many simulation code/tools for solving the fluid dynamics. The validation of the simulation procedure of this CFD software has been well established [9-14]. The standard model is adopted in this study. In the CFD software, the continuity equation is given by [15,16]:
where is density, is time and is velocity vector.
The momentum equation is given by [15,16]:
where is velocity at component of coordinate system, is pressure, is effective viscosity coefficient, is viscosity coefficient and is eddy viscosity coefficient.
In the CFD software, the standard model is given by [15,16]:
where is turbulent energy, is dissipation rate, δij is Kronecker delta, is 0.09, is 1.44, is 1.92, is 1.0, is 1.3. Regarding which represent components of coordinate system,. Regarding which represent velocities, , ,. is the velocity component of coordinate system, respectively.
To validate the simulation code in the CFD software, the simulation result on wind velocity distribution around a block is compared with the reference [
where is the mixing length, 0.41 is Karman coefficient, is distance from wall of block.
After validation of the simulation procedure, the wind velocity distribution around the buildings, which is proposed in this study, is simulated.
building model which indicates the case of building distance of 20 m. Building dimensions are 20 m × 20 m × 40 m. The representative length of this model is set at 20 m. As shown in
where = 10.0 m/s which is the rated wind velocity of AEOLOS wind turbine of 50 kW class (AEOLOS: wind turbine manufacturer) [
In Equation (9), wind velocity is 10.0 m/s at the height of 30 m which is the hub height of the wind turbine when the wind reaches to the building.
Most of the boundary conditions in this simulation, excluding wind velocity at inlet of the model, follow the boundary conditions of simulation validation as shown in
This study assumes that building in the model is multi storied apartment. According to the statistics data collected by ministry of internal affairs and communications in Japan [
The wind at the area at the back of buildings is thought to be available for power generation by wind turbine, since the wind would be accelerated by blowing through buildings. The area at the back of buildings of 20 m, 30 m, and 40 m is assumed as the installation point of wind
turbine. The wind velocity for calculating the power generated by wind turbine is obtained on 1049 points located in the area where the rotor of wind turbine rotates, that is, the swept rotor area. The wind velocity at each point on the swept rotor area is the averaged velocity in the local area of 0.5 m × 0.5 m. By using the wind velocity distribution of this local wind velocity, the wind energy can be calculated. Average wind velocity is estimated by using the following equation:
where is the average wind velocity, is the wind energy calculated for area where rotor of wind turbine rotates, is points for calculating wind velocity distribution (= 1049 points), is the area where rotor of wind turbine rotates. is summation of wind energy on each point for calculating wind velocity distribution. Wind energy at each point on the swept rotor area is calculated by the following equation:
where is the wind energy at each point, is the area of each point which is equal to 0.5 m × 0.5 m, is the wind velocity at each point for calculating wind energy. In estimation of power generation, the wind energy at the point whose wind velocity is below 3 m/s is omitted since the cut-in wind speed of AEOLOS wind turbine of 50 kW class is 3 m/s.
The power curve of AEOLOS wind turbine of 50 kW is shown in
The power curve which is adopted in this study is as follows:
where is a power of wind turbine.
To validate the performance of the present numerical simulation procedure, the wind velocity distribution around the block is compared with the result of reference [
section between this study and reference. In this figure, the wind velocity distribution to direction at is shown.
According to Figures 6 and 7, the results obtained by present numerical simulation procedure are in good agreement with the established results in reference [
Figures 8 and 9 show the comparison of wind velocity distribution around block on cross section between this study and reference [
According to Figures 8 and 9, the results obtained by present numerical simulation procedure are in good agreement with the established results in reference. The wind velocity distribution near the top of the model for this study is a little different from the reference, and it is due to the difference of the boundary condition as mentioned above.
However, this difference near the top of the model is not important in this study, since this work analyzes the wind velocity distribution around the building of 40 m height which is equal to in the validation. Since the good agreement is obtained around in the validation, therefore it can be said that the availability of numerical simulation procedure in this study is proved.
(), is investigated (where represents the distance between walls of adjacent buildings). In this model, and is located at the center of middle building among three buildings irrespective of. In this figure, black lines mean the separation lines which distinguish the different calculation domain in the model used for numerical simulation in this study. From this figure, it is seen that the wind is accelerated in the intervening space between buildings irrespective of under the investigating condition of this study, since some wind is over the initial wind velocity
of of 10 m/s. In addition, the area where the accelerated wind is obtained is wider towards y direction with increasing. To obtain good wind velocity distribution, a wind turbine should be installed at the area at the back of buildings and located on center between two buildings.
In addition, the wind velocity drops rapidly after blowing through buildings, and recovered gradually. Though the highest wind velocity is obtained for D/L = 1.0, the wind velocity drops rapidly after blowing through buildings. The wind velocity at the area at the back of buildings is recovered faster with increasing D except for D/L = 0.50. Regarding D/L = 0.50, most of wind cannot blow through buildings since the distance between buildings is narrow. The wind blows keeping from space between buildings, resulting that the wind velocity in the area at back of buildings is slow compared to other D. Since most of wind blows through surrounding of buildings, the wind velocity at area at the back of buildings which have enough distance from buildings are recovered rapidly by wind energy supply from surrounding wind.
Figures 12-15 show the contour of the wind velocity distribution around buildings at x = 20 m, 30 m and 40 m (= 1.0, 1.5 and 2.0) on cross section for = 0.50, 1.0, 2.0 and 3.0, respectively. In these figures, black cross line represents the rotor diameter of wind turbine, and black rectangular lines represent the location of buildings. From these figures, the higher wind velocity is obtained for smaller, that is, near the building as described above. However, the wind velocity drop toward x direction is relatively small excluding = 0.50 if x is within 40 m (). In addition, it is known that the wind is accelerated in the intervening space between buildings and reduced in the area at the back of buildings irrespective of and under the investigating condition in this study. Therefore, a wind turbine should be installed at the area at the back of buildings and located on center between the two buildings. Moreover, when is narrow such as = 0.50 and 1.0, it can be seen that slow wind velocity is in the area where the rotor of wind turbine rotates. Hence, it reveals that the optimum buildings distance exists for obtaining good wind velocity distribution.
According to Figures 12-15, Tables 4-7 list, and at = 1.0, 1.5 and 2.0 for = 0.50, 1.0, 2.0 and 3.0, respectively. It is observed from Tables 4 and 5 that and are small, when D is narrow such as = 0.50 and 1.0. On the other hand, high and are obtained at = 2.0 and 3.0 and they are shown in Tables 6 and 7.
Though and increase with increasing, the difference of and between = 2.0 and = 3.0 is a small. Hence, it reveals that the optimum
buildings distance exists for obtaining good wind velocity distribution. Since is over for = 2.0 and 3.0, it can be said that the accelerated wind is obtained by wind blowing through buildings. Finally, it is clarified that size, dimensions and layout of building are effective to realize a smart city for utilizing renewable energy in the built environment.
In future planning of the city, it is very important to consider the proper intelligent integration of renewable energy sources into the built environment for developing smart cities. In this study, building topologies of smart city are investigated for finding out the wind velocity profile in the built environment. Analysis of the wind velocity profile in the built environment is very important for finding out the energy content in the wind and also to analyze the performance of wind turbines in the built environment. The output from these built environment wind turbines are affected by the shear and shadow effects of the wind velocity profile distribution in the built environment. The wind velocity distribution across the buildings is simulated by CFD software. Wind turbine power output is estimated by using the power curve of real commercial wind turbine and wind velocity distribution simulated by CFD software. As a result, the following conclusions have been obtained from this study.
1) The results obtained by using the numerical simulation procedure are in good agreement with the established results in reference [
2) The wind is accelerated in the intervening space between the buildings irrespective of under the investigating condition of this study.
3) The accelerated wind is obtained across buildings, and wind velocity drops rapidly after blowing through buildings, and recovered gradually. When the back distance from building is within 40 m (), the wind is accelerated and wind velocity drop toward x direction is relatively small.
4) The wind is accelerated in the intervening space between the buildings and reduced in the area at the back of buildings irrespective of and under the investigating condition of this study. A wind turbine should be installed at the area at the back of buildings and located on center between two buildings.
5) There is an optimum for obtaining good wind velocity distribution, in other words, high and.