Business Collaboration
小型風力發電之解決方案與業務合作 

在可再生能源快速發展的時代,本研究室協助小型風力發電機之設計與技術開發,致力於為城市和偏遠地區提供高效且永續之能源解決方案。與業界廠商之實例研究涵蓋水平軸垂直軸風力發電機,這兩種風機系統已被證明能在不同類型之環境中高效運行。水平軸風力發電機在開闊地區具備出色的能量捕捉能力,而垂直軸風力發電機則因其占地小、噪音低,特別適合城市屋頂和狹小空間。本研究室不僅在實驗室內進行精密研究與測試,還與多家知名廠商緊密合作,提供從設計、安裝到技術支援的全方位服務,已成功將技術應用於實際項目中,確保系統能在實際運行環境中發揮最大效益。憑藉在風力發電領域之專業知識和實際經驗,為各類場景提供最佳之風能解決方案,助力企業與機構實現能源轉型與永續ESG目標。無論是水平軸還是垂直軸風力系統,本研究室技術皆已經落實實際應用驗證,期待能夠協助更多業界廠商攜手推動綠色能源之未來。

In an era of rapidly advancing renewable energy technologies, our lab focuses on the design and development of small-scale wind turbines, offering efficient and sustainable energy solutions for both urban and remote areas. Our research encompasses both horizontal-axis and vertical-axis wind turbines, which have proven to be highly efficient in different environments. Horizontal-axis wind turbines excel in open areas for maximum energy capture, while vertical-axis turbines, known for their compactness and low noise, are particularly suitable for rooftop installations and limited spaces in urban settings. Beyond conducting precise research and testing in the lab, we have partnered with well-established manufacturers to implement our technologies in real-world projects. These collaborations allow us to offer comprehensive services, from design and installation to technical support, ensuring that our systems perform optimally in real operational environments. With our expertise and hands-on experience in wind energy, we are confident in providing the best wind energy solutions for a variety of applications, helping businesses and institutions achieve their energy transition and sustainability goals. Whether it is horizontal-axis or vertical-axis wind systems, our technology has been successfully applied, and we look forward to working with you to drive the future of green energy.

水平軸風力發電機
Horizontal Axis Wind Turbine (HAWT)

WT2000小型水平軸風力發電機風技綠能科技股份有限公司開發,本研究室作為技術合作夥伴,協助其系統設計與性能優化。這款最新一代的風力發電機可應用於多種情境,例如電池充電系統或市電併網發電,展現出極大的靈活性。WT2000採用了創新的葉片設計,搭配三支1.2公尺長的葉片,在每秒10公尺的風速下可產生1500瓦特的電力。風機的轉向系統能夠自動隨風向調整,確保最大化的風能捕捉效益。其結構設計穩固且高效。

The WT2000 Small Horizontal Axis Wind Turbine, developed by WindTek Green Energy Technology Co., Ltd., was designed with technical assistance from our lab. As a collaborative partner, we supported the system design and performance optimization. This next-generation wind turbine is versatile and can be used in a variety of settings, including battery charging systems and grid-connected power generation.
The WT2000 features an innovative blade design with three 1.2-meter-long blades, capable of generating 1500 watts of power at wind speeds of 10 meters per second. Its directional system automatically adjusts to changing wind directions, ensuring optimal energy capture. 

垂直軸風力發電機
Vertical Axis Wind Turbine (VAWT) 

新高能源科技股份有限公司開發多種功率等級的小型垂直軸風力發電機,包括DS-300、DS-700、DS-1500和DS-3000。這些VAWT機型採用升力型與阻力型葉片的互補設計,實現微風啟動與強風高效運行,且能夠在各種風速下穩定運行,並可與太陽能等其他再生能源系統整合,成為城市及離網應用的理想解決方案。直驅式發電技術消除傳統齒輪箱摩擦,提升系統可靠性並減少噪音。本研究室作為技術合作夥伴,協助進行風場數值分析,找出最佳建置位置和數量,最大化運行效率。還可通過空氣動力學分析,設計導流系統,即使在不理想的安裝條件下,也能提升風力發電效能。

HI-VAWT Technology Corp. has developed small vertical axis wind turbines (VAWT) in various power ratings, including the DS-300, DS-700, DS-1500, and DS-3000. These turbines feature a complementary design of lift-type and drag-type blades, achieving optimal performance in both low and high wind speeds. The direct-drive technology eliminates friction from traditional gearboxes, improving reliability and reducing noise. VAWT captures wind energy efficiently across different wind conditions and can be integrated with solar systems, making it ideal for urban and off-grid applications. As a technical partner, our lab assists with wind field analysis to determine optimal installation locations and numbers for maximum efficiency. We also provide aerodynamic analysis to design deflection systems, enhancing wind energy potential even in less-than-ideal conditions.

再生能源併網回收
Renewable Energy Grid Recovery 

本研究室致力於推動再生能源併入電網的技術創新專注於微型水平軸風力發電系統之設計,包括高效電力轉換器,能將多餘的能源回收並回傳至電網中。此技術確保風能,特別是小型城市風機之能源,能夠被充分利用,提供可靠且永續之能源解決方案。採用先進的最大功率點追蹤(maximum power point tracking, MPPT)技術,系統能動態調整以應對變化的風況,優化能源回收並減少對化石燃料的依賴

At our lab, we are advancing technologies for integrating renewable energy sources into the power grid. Our focus on micro-horizontal wind power systems includes designing efficient power converters that recover excess energy and return it to the grid. This ensures that wind energy, particularly from small-scale urban turbines, is fully utilized, providing a reliable and sustainable energy solution for various locations, including rooftops. By employing state-of-the-art maximum power point tracking (MPPT) techniques, our system dynamically adjusts to changes in wind conditions, optimizing energy recovery and reducing reliance on fossil fuels.

風機系統諧波噪音消除
Harmonic Noise Reduction
in Wind Turbine Systems 

風機系統產生之諧波噪音是城市環境中一大挑戰。本研究室專注於開發技術來減少這些不必要之諧波,從而提高系統整體效率並減少運行噪音。運用創新的控制演算法,使風機系統在不影響性能的情況下,達到降噪效果,非常適合住宅和商業環境。這些技術突破允許更安靜、更高效的風能收集,促進城市風能之廣泛應用​ 

Harmonic noise generated by wind turbine systems is a significant challenge, especially in urban environments. Our research is dedicated to developing technologies that reduce these unwanted harmonics, thus improving the overall efficiency and reducing operational noise. Utilizing innovative control algorithms, our wind turbine systems can minimize noise without compromising performance, making them ideal for residential and commercial settings. These advancements allow for quieter and more efficient wind energy harvesting, promoting wider acceptance of urban wind power solution.

動態調整型風力葉片設計
Dynamic Adjustable Wind Blade Design 

本研究室動態調整型風力葉片設計使風機能夠實時適應不同之風況允許小型風力發電機之葉片自動調整其伸縮掃略面積、角度和傾斜,以在各種風速下提高性能。通過優化葉片效率,該系統確保在變動風況下仍能穩定地發電。不僅提升能量輸出,還通過減少機械應力延長風機使用壽命,為更可靠且經濟效益更高之風能解決方案做出貢獻

Our dynamic adjustable wind blade design allows wind turbines to adapt to varying wind conditions in real-time. This technology enables the blades to adjust their pitch and angle automatically, enhancing performance across a wide range of wind speeds. By optimizing blade efficiency, the system ensures consistent power generation even under fluctuating wind conditions. This innovation not only boosts energy output but also extends the turbine's lifespan by reducing mechanical stress, contributing to a more reliable and cost-effective wind energy solution.

風能最大功率點功率動平衡
Maximum Power Point Power Balance
in Wind Energy Systems 

最大化風能系統的功率輸出對其經濟性和環境影響至關重要。本研究室專注於最大功率點追蹤(MPPT)演算法,確保風機在最佳性能點運行。通過不斷監測風速風機動態,將針對系統調整功率輸出,保持在最大功率點,從而提高整體效率顯著改善能源捕捉,縮短達到峰值性能所需的時間,讓風能成為小型和大型應用之可行解決方案​

Maximizing the power output of wind energy systems is critical for their economic and environmental impact. Our lab specializes in MPPT (Maximum Power Point Tracking) algorithms, which ensure that wind turbines operate at their optimal performance point. By continuously monitoring wind speed and turbine dynamics, our system adjusts power output to maintain balance at the maximum power point, increasing overall efficiency. This approach significantly improves energy capture and reduces the time required to reach peak performance, making wind energy a more viable solution for both small-scale and large-scale applications.

24V DC 馬達驅動發電機系統
Motor Driven Generator System

This system features a 24V DC motor connected to a generator for testing power output. It is mounted on a stable base for easy setup and mobility. The system integrates control electronics for efficient performance tracking and monitoring, making it suitable for both experimental and applied wind energy research.

Applications: Ideal for simulating wind turbine power generation in urban environments, this system allows for real-time adjustments and data collection on motor efficiency and generator performance.

MPPT 充電控制板
MPPT Charging Control Board 

The Maximum Power Point Tracking (MPPT) charge controller is designed to optimize the efficiency of power harvested from wind turbines. It ensures that the wind generator operates at its peak performance by dynamically adjusting to the changing wind conditions.

Applications: This controller is critical for improving the energy efficiency of off-grid and hybrid power systems, particularly in settings that utilize both wind and solar energy sources.

DC-AC Inverter

This component converts the direct current (DC) generated by the wind turbine into alternating current (AC) for practical use in standard electrical systems. The inverter is coupled with an MPPT system to ensure maximum energy conversion and minimal power loss during the process.

Applications: Suitable for small-scale residential or commercial renewable energy systems, this inverter allows the generated power to be fed into the grid or used in standalone applications.

業務聯絡Business Contact 

For inquiries regarding our wind turbine systems, renewable energy solutions, or research collaborations, please contact: 

Dr. Su 

📧 Email: soeasyer@gmail.com