Non-ambiguous sixteen-point chart recording of wind direction from a standard eight-point contacting wind vane

1947 ◽  
Vol 28 (4) ◽  
pp. 534 ◽  
Author(s):  
Ronald L. Ives
Author(s):  
R. S. Amano ◽  
Ryan Malloy

The project has been completed, and all of the aforementioned objectives have been achieved. An anemometer has been constructed to measure wind speed, and a wind vane has been built to sense wind direction. An LCD module has been acquired and has been programmed to display the wind speed and its direction. An H-Bridge circuit was used to drive a gear motor that rotated the nacelle toward the windward direction. Finally, the blade pitch angle was controlled by a swash plate mechanism and servo motors installed on the generator itself. A microcontroller has been programmed to optimally control the servo motors and gear motor based on input from the wind vane and anemometer sensors.


2018 ◽  
Vol 3 (1) ◽  
pp. 395-408 ◽  
Author(s):  
Niko Mittelmeier ◽  
Martin Kühn

Abstract. Upwind horizontal axis wind turbines need to be aligned with the main wind direction to maximize energy yield. Attempts have been made to improve the yaw alignment with advanced measurement equipment but most of these techniques introduce additional costs and rely on alignment tolerances with the rotor axis or the true north. Turbines that are well aligned after commissioning may suffer an alignment degradation during their operational lifetime. Such changes need to be detected as soon as possible to minimize power losses. The objective of this paper is to propose a three-step methodology to improve turbine alignment and detect changes during operational lifetime with standard nacelle metrology (met) mast instruments (here: two cup anemometer and one wind vane). In step one, a reference turbine and an external undisturbed reference wind signal, e.g., met mast or lidar are used to determine flow corrections for the nacelle wind direction instruments to obtain a turbine alignment with optimal power production. Secondly a nacelle wind speed correction enables the application of the previous step without additional external measurement equipment. Step three is a monitoring application and allows the detection of alignment changes on the wind direction measurement device by means of a flow equilibrium between the two anemometers behind the rotor. The three steps are demonstrated at two 2 MW turbines together with a ground-based lidar. A first-order multilinear regression model gives sufficient correction of the flow distortion behind the rotor for our purposes and two wind vane alignment changes are detected with an accuracy of ±1.4∘ within 3 days of operation after the change is introduced. We show that standard turbine equipment is able to align a turbine with sufficient accuracy and changes to its alignment can be detected in a reasonably short time, which helps to minimize power losses.


2019 ◽  
Vol 4 (2) ◽  
pp. 355-368 ◽  
Author(s):  
Jennifer Annoni ◽  
Christopher Bay ◽  
Kathryn Johnson ◽  
Emiliano Dall'Anese ◽  
Eliot Quon ◽  
...  

Abstract. Wind turbines in a wind farm typically operate individually to maximize their own performance and do not take into account information from nearby turbines. To enable cooperation to achieve farm-level objectives, turbines will need to use information from nearby turbines to optimize performance, ensure resiliency when other sensors fail, and adapt to changing local conditions. A key element of achieving a more efficient wind farm is to develop algorithms that ensure reliable, robust, real-time, and efficient operation of wind turbines in a wind farm using local sensor information that is already being collected, such as supervisory control and data acquisition (SCADA) data, local meteorological stations, and nearby radars/sodars/lidars. This article presents a framework for developing a cooperative wind farm that incorporates information from nearby turbines in real time to better align turbines in a wind farm. SCADA data from multiple turbines can be used to make better estimates of the local inflow conditions at each individual turbine. By incorporating measurements from multiple nearby turbines, a more reliable estimate of the wind direction can be obtained at an individual turbine. The consensus-based approach presented in this paper uses information from nearby turbines to estimate wind direction in an iterative way rather than aggregating all the data in a wind farm at once. Results indicate that this estimate of the wind direction can be used to improve the turbine's knowledge of the wind direction. This estimated wind direction signal has implications for potentially decreasing dynamic yaw misalignment, decreasing the amount of time a turbine spends yawing due to a more reliable input to the yaw controller, increasing resiliency to faulty wind-vane measurements, and increasing the potential for wind farm control strategies such as wake steering.


2013 ◽  
Vol 459 ◽  
pp. 475-478
Author(s):  
Tao Yu ◽  
Shu Qin Xu

In order to ensure maximum effectiveness of wind turbines, the cabin must be accurate to the wind, only wind turbine impeller in the normal direction and the wind direction is agreed upon, to ensure that the wind turbine power absorption maximum, to ensure the normal operation of fan safety and full use of wind resources. Therefore, the wind vane and anemometer in the wind turbine system plays an important role, this study focused on the gold 1.5MW wind turbine with wind vane and anemometer common fault..


2021 ◽  
Vol 4 (2) ◽  
pp. 70-73
Author(s):  
Ahmad Rossydi ◽  
Andi Yuyun Irmayanti ◽  
Sugiyanto

Windsock adalah sebagai penanda angin dan relatif kecepatan angin. Alat ini sangat berfungsi di dunia penerbangan. Setiap bandara wajib memiliki windsock sebagai penunjang penentu arah angin. Alat ini dipasang di suatu bandara udara yang dapat dilihat dengan jelas oleh petugas lalu lintas udara (ATC). Tetapi di bandara A.P.T. Pranoto-Samarinda masih menggunakan sistem manual untuk melihat windsock menggunakan teropong jarak jauh. Pengembangan alat ini dilatar belakangi dikarenakan kurang efektif dan efisiennya saat penggunaan windsock yang sudah tersedia di Bandar Udara A.P.T. Pranoto Samarinda. Maka di sini penulis tertarik untuk mengangkat sebuah judul dalam tugas akhir ini yaitu  “Rancangan Monitoring Wind Direction Indicator berbasis Arduino di Bandar Udara Aji Pangeran Tumenggung  Pranoto Samarinda ”. Hasil akhir yang dicapai dari pengembangan windsock ini adalah dengan tujuan agar tidak mencari arah angin secara manual, dengan dikembangkannya alat ini dapat mencari arah angin secara otomatis. Windsock ini juga dilengkapi dengan wind vane dan wind cone sebagai pengukur arah mata angin dan kecepatan angin disekitar alat tersebut. Perancangan sistem monitoring Wind Direction Indicator berbasis Arduino, diharapkan dapat mendeteksi kecepatan dan arah angin yang mampu memberikan data secara real time. Agar data yang diperoleh dapat tersampaikan kepada masyarakat dengan cepat dan akurat, maka dibutuhkan suatu sistem yang memadai. Sistem yang sekarang ini sedang berkembang pesat yaitu Personal Computer (PC) dan jaringan internet. Perancangan alat Wind Direction Indicator ini terdiri dari hardware yang berupa Arduino, sensor arah dan sensor kecepatan angin. Alat Wind Direction Indicator dapat membantu memudahkan ATC dalam memantau arah dan kecepatan angin yang sangat penting bagi penerbangan, dimana sebelumnya proses ini menggunakan teropong untuk memantau arah angin. Proses pemantauan arah angin menjadi lebih mudah dengan menggunakan alat ini, karena hasil pembacaan arah dan kecepatan angin akan langsung muncul pada monitor.


2018 ◽  
Author(s):  
Niko Mittelmeier ◽  
Martin Kühn

Abstract. Upwind horizontal axis wind turbines need to be aligned with the main wind direction to maximize energy yield. Attempts have been made to improve the yaw alignment with advanced measurement equipment but most of these techniques introduce additional costs and rely on alignment tolerances with the rotor axis or the true north. Turbines that are well aligned after commissioning, may suffer an alignment degradation during their operational lifetime. Such changes need to be detected as soon as possible to minimize power losses. The objective of this paper is to propose a three-step methodology to improve turbine alignment and detect changes during operational lifetime with standard nacelle metrology (met) mast instruments (here: two cup anemometer and one wind vane). In step one, a reference turbine and an external undisturbed reference wind signal, e.g. met mast or lidar are used to determine flow corrections for the nacelle wind direction instruments to obtain a turbine alignment with optimal power production. Secondly a nacelle wind speed correction is enabling the application of the previous step without additional external measurement equipment. Step three is a monitoring application and allows to detect alignment changes on the wind direction measurement device by means of a flow equilibrium between the two anemometers behind the rotor. The three steps are demonstrated at two 2 MW turbines together with a ground based lidar. A first order multi linear regression model gives sufficient correction of the flow distortion behind the rotor for our purposes and two wind vane alignment changes are detected with an accuracy of ±1.4 ° within three days of operation after the change is introduced. We could show, that standard turbine equipment is able to align a turbine with sufficient accuracy and changes to its alignment can be detected in a reasonable short time which helps to minimize power losses.


2008 ◽  
Vol 2 (1) ◽  
pp. 131-138 ◽  
Author(s):  
Brent M. Bowen

A year of data from sonic anemometer and mechanical wind sensors was analyzed and compared at a low-wind site. Results indicate that 15-minute average and peak 1-second wind speeds (u) from the sonic agree well with data derived from a co-located cup anemometer over a wide range of speeds. Wind direction data derived from the sonic also agree closely with those from a wind vane except for very low wind speeds. Values of standard deviation of longitudinal wind speed (σu) and wind direction fluctuations (σø) from the sonic and mechanical sensors agree well for times with u > 2 ms-1 but show significant differences with lower u values. The most significant differences are associated with the standard deviation of vertical wind fluctuations (σw): the co-located vertical propeller anemometer yields values increasingly less than those measured by the sonic anemometer as u decreases from 2.5 approaching 0 ms-1. The combination of u over-estimation and under-estimation of σw from the mechanical sensors at low wind speeds causes considerable underestimation of the standard deviation of vertical wind angle fluctuations (σø), an indicator of vertical dispersion. Calculations of σø from sonic anemometer measurements are typically 5° to 10° greater than from the mechanical sensors when the mechanical instruments indicate that σø < 5° or so. The errors with the propeller anemometer, cup anemometer and wind vane, caused by their inability to respond to higher frequency (smaller scale) turbulent fluctuations, can therefore lead to large (factors of 2 to 10 or more) errors in both the vertical and horizontal dispersion during stable conditions with light winds. The sonic anemometer clearly provides more accurate and reliable wind data than the mechanical wind sensor with u < 2.5 ms-1


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