RESEARCH & DEVELOPMENT
An Industry Leader
We’re a young and talented group of entrepreneurs and engineers with a groundbreaking idea designed to contribute towards a better tomorrow. We provide smart solutions for companies of all sizes, Residentials and pride ourselves on our unparalleled, dedicated service. At Animagtics Technologies, we believe that the right understanding and technological edge can lead companies towards a successful future.
HOW ENERGY STORAGE TECHNOLOGY WORKS?
Who We Are
1) VOICE AND APP CONTROLLED
Smart and easy-to-use battery storage system with wireless control capabilities is an excellent innovation that aligns with the growing trend of smart home technologies. The integration of smartphone app control and Radio Frequency (RF) remote control offers users convenient and flexible ways to manage their energy storage systems.
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Smartphone App Control: The inclusion of a smartphone app allows users to control and monitor their battery storage system from anywhere with internet connectivity. They can easily check the system's status, battery levels, energy usage, and adjust settings on the go. The app's user-friendly interface ensures effortless control and makes managing energy storage hassle-free.
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Remote Control via RF: Alongside the smartphone app, the system can be operated using a dedicated RF remote control. This feature provides a quick and convenient way to manage the storage system without needing a smartphone or internet connection. Users can change settings, switch between modes, and control power flow at their convenience.
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Plug-and-Play Installation: Emphasize that the battery storage system is designed for easy installation, ensuring users can set it up without the need for specialized technical knowledge or assistance. The plug-and-play approach simplifies the process and reduces installation time.
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Energy Efficiency and Savings: Highlight the benefits of using the storage system in conjunction with renewable energy sources, such as solar panels. By storing excess energy during times of low consumption and using it during peak hours or at night, users can optimize energy usage and potentially reduce utility bills.
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Integration with Smart Home Ecosystems: If applicable, mention the system's compatibility with popular smart home ecosystems like Amazon Alexa or Google Assistant. This integration enables voice commands, making the energy storage system even more convenient and seamlessly integrated into the user's existing smart home setup.
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Real-time Notifications and Alerts: The app can be programmed to send real-time notifications and alerts, such as low battery warnings or system malfunctions. This feature ensures that users are always informed about their energy usage and system performance.
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Safety Features: Assure customers about the safety of the battery storage system. Mention features like overcharge protection, short-circuit protection, and temperature monitoring to ensure the system operates safely and reliably.
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Scalability: If the system allows for scalability, highlight this benefit. Customers might appreciate the option to expand their energy storage capacity in the future as their energy needs change.
2) HMI (HUMAN MACHINE INTERFACE CONTROLLED)
HMI is a user interface that serves as a bridge between humans and machines, enabling users to interact with and control a system or device in a more intuitive and user-friendly manner.
Key points about HMI:
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Graphical Interface: HMIs typically use graphical elements such as icons, buttons, and menus displayed on a touchscreen or monitor. This visual representation makes it easier for users to understand and operate the system.
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User Communication: The primary purpose of an HMI is to facilitate communication between the user and the system, allowing users to input commands and receive feedback or information from the system.
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Touchscreen Technology: Touchscreen interfaces are common in modern HMIs, offering a more interactive and seamless user experience. Users can directly interact with the displayed elements using touch gestures.
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Real-time Data Display: HMIs can display real-time data from the connected system, providing users with instant information about system status, performance, and any issues that may arise.
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Intuitive Design: A well-designed HMI aims to be intuitive and user-friendly, reducing the learning curve for operators and minimizing the chances of errors during operation.
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Customization and Configuration: Depending on the application, HMIs can be customized and configured to suit specific user needs and industry requirements. This adaptability makes them versatile for various applications.
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Remote Access: Some advanced HMIs support remote access, allowing users to monitor and control systems from a distance, which is particularly beneficial for industrial automation and remote monitoring scenarios.
Overall, Human Machine Interface plays a crucial role in enhancing user interaction with complex systems, enabling efficient control, monitoring, and decision-making. Its intuitive nature and graphical representation make it a key component in modern automation and industrial applications.
DESIGNING OF LITHIUM ION BATTERY PACK
Designing lithium-ion battery packs, for internal or external use, requires careful consideration of various factors to ensure safety, performance, and longevity. Incorporating thermal monitoring is crucial to prevent overheating and thermal runaway, which can lead to catastrophic failure. Here's a general outline of the design process and considerations for both internal and external lithium-ion battery packs with thermal monitoring:
1. Battery Selection: High-quality lithium-ion cells with a good track record for safety and performance. Consider factors such as capacity, voltage, energy density, and cycle life.
2. Battery Configuration: Decide on the battery pack configuration based on your application's voltage and capacity requirements. Common configurations include series and parallel combinations of cells.
3. Battery Management System (BMS): Integrate a sophisticated BMS that monitors and controls various parameters, including voltage, current, temperature, and state of charge (SOC). Ensure that the BMS can communicate with an external monitoring system.
4. Thermal Monitoring: Implement a robust thermal monitoring system to regulate battery temperature. This can involve:
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Temperature sensors: Place thermistors or other temperature sensors strategically within the battery pack to monitor cell temperatures.
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Thermal management system: Use passive or active cooling methods, such as heat sinks, fans, or liquid cooling, to dissipate excess heat.
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Temperature feedback: Integrate temperature data into the BMS to adjust charging and discharging rates and prevent overheating.
5. Enclosure and Packaging: Choose appropriate materials for the battery pack enclosure to provide physical protection and thermal insulation. Ensure proper ventilation for heat dissipation.
6. Charging and Discharging Circuit: Design a charging and discharging circuit that adheres to the recommended voltage and current limits for the chosen battery cells. Implement safeguards to prevent overcharging, over-discharging, and short circuits.
7. Safety Mechanisms: Incorporate safety features like fuses, circuit breakers, and isolation devices to protect the battery pack and users from potential hazards.
8. Communication Interfaces: Enable communication interfaces such as UART, CAN, or I2C between the BMS and external monitoring/control systems to provide real-time data and enable remote monitoring.
9. External Battery Pack: For external packs, design a user-friendly housing, considering factors such as portability, ease of connection, and mechanical stability.
10. Internal Battery Pack: For internal packs, work closely with the product design team to integrate the battery safely within the device's form factor, ensuring proper thermal insulation and ventilation.
11. Testing and Certification: Thoroughly test the battery pack under various conditions, including extreme temperatures and loads, to ensure its safety and performance.
12. Maintenance and Monitoring: Provide guidance to users on proper charging, storage, and usage practices. Develop a system for regular maintenance and monitoring of the battery pack's health.
It's important to note that lithium-ion battery design is complex and safety-critical. Consider consulting with experts in battery technology, electrical engineering, and thermal management to ensure the best possible design
Designing Of Energy Storage Systems
Designing energy storage systems (ESS) is a multidisciplinary process that involves a combination of engineering, technology, and economic considerations. Energy storage systems play a crucial role in modernizing and optimizing energy grids, integrating renewable energy sources, and ensuring reliable power supply.
Designing Of Hardware Compatible With ESS Control Software
Designing hardware that is compatible with control software involves several important steps to ensure seamless communication and functionality.
Requirement Analysis.
System Architecture Design.
Communication Protocols.
Hardware Design.
Firmware Development.
Testing and Validation.
Integration with Control Software.
Compatibility Testing.
Optimization and Performance Tuning.
Maintenance and Upgrades.
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End To End Technology Development Of Energy Storage Systems
End-to-end technology development is the process of creating a complete and integrated solution that spans across various layers of technology, from hardware to software and everything in between. This approach ensures that all components of a system work seamlessly together to achieve a specific goal or provide a comprehensive solution.
Product development, from conceptualization to market-ready product, involves several key stages, including product design, PCB (Printed Circuit Board) design, and research and development (R&D).
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. Conceptualization and Product Design:
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Identify Market Needs: Understand the market and identify needs or problems that your product aims to address.
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Market Research: Conduct thorough market research to analyze competitors, target audience, and potential demand.
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Conceptualization: Develop a conceptual design for the product, considering functionality, aesthetics, and user experience.
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Prototyping: Create initial prototypes or mock-ups to test and refine the design concept
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Detailed Design and Engineering:
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CAD Modeling: Use Computer-Aided Design (CAD) software to create detailed 3D models of the product. This includes mechanical components and outer casing.
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Material Selection: Choose appropriate materials based on the product's requirements, considering factors such as durability, cost, and manufacturability.
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Design Validation: Perform simulations and analysis to validate the design's performance and identify any potential issues.
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Iterative Design: Iterate on the design based on testing and validation results to optimize performance and manufacturability.
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PCB Design:
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Schematic Design: Create a schematic diagram outlining the electrical connections and components.
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PCB Layout: Use PCB layout software to design the physical arrangement of components on the board, considering factors like signal integrity and thermal.
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PCB Fabrication.
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PCB Assembly.