Design Case Study of 200KW On-Grid Solar Power Plant -Part 1

🌞 Design Case Study of 200KW On-Grid Solar Power Plant - Part 1

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Course Description:

Embark on a comprehensive learning journey with our expert-led course, "Design Case Study of 200KW On-Grid Rooftop Solar Power Plant - Part 1" tailored for individuals passionate about solar power plant design. Whether you're a student aspiring to deepen your knowledge, a solar technician seeking advanced insights, a job seeker aiming to enter the solar industry, or an entrepreneur looking to tap into the potential of renewable energy, this course is designed to cater to your needs.

What You'll Learn:

• The Fundamentals of Rooftop Solar Installation Design: Gain a solid foundation in all the key aspects of rooftop solar power plant design, including manual calculation skills that are essential for any project.
• Scientific Insight into Components: Understand the scientific principles behind each component necessary for a rooftop solar power plant, from the panels to the inverters.
• Practical Application: Apply theoretical concepts to practical scenarios through hands-on exercises and real-world case studies.

Course Outline:

1] Preparation of Feasibility Study Report

• Site Details 🏢
• Geographical Information 🌍
• GHI Assessment with PVGIS ☀️
• Area Assessment in Google Earth 🌎
• Metering Room Details 📏
• Electricity Bill Assessment in Excel Sheet 📊
• Power Demand Calculation in Excel Sheets 🔢
• Solar Project Size Estimation 📈
• Feasibility Report Generation 📑

2] Solar Array Sizing

• Reading the Datasheet of Solar Panel 📋
• Reading Datasheet of Solar Inverter 💡
• Solar String Calculation ⚖️
• Solar Array Calculation 🔬
• Total No. of Solar Panels Calculation 🌞
• Solar Panel Connections 🔗

3] Shadow Analysis in Google Sketch Up

• Basics of Google Sketch up Commands 🖥️
• Design of 3D Objects in Google Sketch up 🛠️
• Making of Solar Panels in Sketch up 🌡️
• Setting Tilt and Orientation of Solar Panel in Sketch up 🎯
• Making of Solar Array in Sketch up ☀️
• Shadow Length Calculation in Excel Sheet 📝
• Setting the Tilt and Orientation of Solar Array 🌞
• Preparation of Solar Panel Placement Layout 📐
• Shadow Analysis in Sketch up 🌄

4] Energy Yield Estimation

• Monthly Energy Yield Estimation 💫
• Energy Yield over 25 Years 📆
• Probability Exceedance (P50, P75 and P90 Estimate) 📊

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Throughout the course, you'll engage with practical exercises that mirror real-life scenarios. You'll learn to conduct feasibility studies, size solar arrays accurately, perform shadow analysis with SketchUp, and estimate energy yields with confidence. This course is the perfect blend of theoretical knowledge and practical application, ensuring that by the end, you're equipped with the skills needed to design a 200kW on-grid solar power plant.

Join us and transform your passion for renewable energy into actionable expertise under the guidance of Prof. Kiran Beldar, an esteemed expert in the field. 🌡️☀️🔋

Enroll now and take the first step towards becoming a solar power plant designer! 🚀💚

🌟 Course Review: Solar PV System Design & Optimization 🌟

Overview: The course has received a global rating of 4.60 from recent reviews, indicating high satisfaction among the learners. The content is praised for its clarity and relevance to those with a background in solar PV systems, as well as its applicability to large-scale projects.

Pros:

• Comprehensive Content: Reviewers found the course content to be thorough and satisfying, especially for those with an existing foundation in solar PV. It covers essential topics that are practical and directly applicable to real-world scenarios.

• Educational Value: The information provided is considered excellent by some users, who have expressed that this knowledge isn't thoroughly explained at their workplaces, making the course content invaluable for their professional projects.

• Real-World Application: The course materials are praised for their relevance to practical tasks such as sizing components, designing electrical layouts, and calculating cable sizes, which are critical in large-scale PV projects.

• Learner Satisfaction: Learners appreciate the ease of understanding the course material and have expressed a positive response to the teaching methodology, indicating that it is straightforward and clear.

Cons:

• Document Accessibility: Some learners suggested that providing course documents for reference when doubts arise would be beneficial. This could help reinforce the concepts taught in the course.

• Additional Resources: There is a demand for additional resources such as downloadable XLSX files for monthly irradiation data and PPT files for further study. Including these materials could enhance the learning experience.

• Technical Instructions Clarification: One review pointed out a lack of guidance on how to download specific files from a referenced website, which is an aspect that could be improved for completeness.

Suggestions for Improvement:

• Expanded Topics: There is interest in a course that covers the sizing of components for large-scale PV projects in greater detail, including AC/DC cables, trays design, and insulation calculations.

• Educational Materials: Learners have requested more hands-on materials, such as downloadable files and templates, to complement the video content and enhance practical learning.

• Instructional Clarity: Ensuring that all technical instructions are clear and that opportunities to download course materials are provided could further improve the learner experience.

In conclusion, the Solar PV System Design & Optimization course is highly recommended for its comprehensive and practically oriented content. While there is room for improvement in terms of additional resources and technical guidance, the course has been positively received by learners who have found it to be both informative and relevant to their professional needs.