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Included File Formats
This model is provided in 14 widely supported formats, ensuring maximum compatibility:
• - FBX (.fbx) – Standard format for most 3D software and pipelines
• - OBJ + MTL (.obj, .mtl) – Wavefront format, widely used and compatible
• - STL (.stl) – Exported mesh geometry; may be suitable for 3D printing with adjustments
• - STEP (.step, .stp) – CAD format using NURBS surfaces
• - IGES (.iges, .igs) – Common format for CAD/CAM and engineering workflows (NURBS)
• - SAT (.sat) – ACIS solid model format (NURBS)
• - DAE (.dae) – Collada format for 3D applications and animations
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• - 3DS (.3ds) – Legacy format with broad software support
• - 3ds Max (.max) – Provided for 3ds Max users
• - Blender (.blend) – Provided for Blender users
• - SketchUp (.skp) – Compatible with all SketchUp versions
• - AutoCAD (.dwg) – Suitable for technical and architectural workflows
• - Rhino (.3dm) – Provided for Rhino users

Model Info
• - All files are checked and tested for integrity and correct content
• - Geometry uses real-world scale; model resolution varies depending on the product (high or low poly)
• • - Scene setup and mesh structure may vary depending on model complexity
• - Rendered using Luxion KeyShot
• - Affordable price with professional detailing

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More Information About 3D Model :
IOT HYDROPONIC PLANT PLASTIC BOTTLE CONTAINER SOLAR PANEL POWER

This integrated system delineates a sophisticated yet accessible approach to plant cultivation, merging the principles of hydroponics with the data-driven capabilities of the Internet of Things (IoT), the resourcefulness of repurposed materials, and the sustainability of solar energy. It constitutes a self-sufficient, intelligent platform for soilless plant growth, offering real-time monitoring, automated control, and operational autonomy from traditional power grids. The system is designed for efficiency, environmental responsibility, and educational utility, typically employed in urban, educational, or off-grid settings.

Hydroponic System Design and Repurposed Containers:
At its foundation, the system employs hydroponics, a method of cultivating plants without soil, utilizing mineral nutrient solutions dissolved in water. The defining characteristic of this specific implementation is the ingenious repurposing of post-consumer plastic bottles as cultivation containers. These bottles, otherwise destined for waste streams, are adapted to house individual plants or form modular components of larger setups. Common hydroponic techniques, such as Deep Water Culture (DWC), Nutrient Film Technique (NFT) variations, or wick systems, are tailored to these plastic containers. The design typically ensures structural support for the plant, adequate volume for the nutrient solution, and often features opaque exteriors or coverings to inhibit the growth of algae, which competes with plants for nutrients and light. This upcycling strategy significantly reduces material costs, promotes circular economy principles, and mitigates plastic waste.

Internet of Things (IoT) Integration:
The IoT framework elevates the system from a manual operation to a smart, automated one. It comprises a network of interconnected sensors, microcontrollers (e.g., ESP32, Arduino), and communication modules. These components continuously gather data on critical parameters essential for optimal plant growth, including:

• pH levels: To maintain the correct acidity or alkalinity of the nutrient solution for efficient nutrient absorption.
  
• Electrical Conductivity (EC) or Total Dissolved Solids (TDS): To quantify the concentration of essential mineral nutrients.
  
• Water temperature: Affecting dissolved oxygen levels and root metabolism.
  
• Ambient temperature and humidity: Influencing plant transpiration, growth rates, and potential for pest/disease.
  
• Water level: To prevent the drying out of roots and ensure consistent nutrient delivery.
  
• Light intensity: For optimizing photosynthesis, especially when supplementary LED grow lights are incorporated.
  Data acquired by these sensors is transmitted wirelessly (e.g., via Wi-Fi, Bluetooth, LoRa) to a centralized processing unit, which can then relay it to a cloud-based platform or local server. This enables users to remotely monitor the system's status and plant health through web dashboards or mobile applications. Crucially, the IoT integration facilitates automation; the system can trigger actions such as activating nutrient pumps to adjust EC, regulating pH using precise dosing, turning on/off supplemental lighting, or controlling ventilation based on predefined thresholds or user-programmed schedules.
  
  Solar Panel Power System:
  To achieve energy autonomy and enhance its environmental credentials, the system is powered by renewable solar energy. Photovoltaic (PV) panels convert sunlight directly into direct current (DC) electricity. This energy is then routed through a charge controller, which regulates the power flow to a rechargeable battery (commonly lead-acid or lithium-ion) for storage. The stored energy ensures continuous operation of the IoT components (sensors, microcontroller, communication modules) and low-power peripherals (e.g., nutrient pumps, air pumps, small fans) during periods of low light, at night, or when solar input is insufficient. This off-grid power solution not only minimizes the system's carbon footprint but also makes it highly adaptable for deployment in remote areas, developing regions, or locations with unstable electricity infrastructure, contributing to decentralized food production.
  
  Advantages and Applications:
  The IOT Hydroponic Plant Plastic Bottle Container Solar Panel Power system presents a compelling model for sustainable and intelligent agriculture, offering several key advantages:
  
• Environmental Sustainability: Drastically reduces plastic waste through upcycling, minimizes water consumption compared to traditional soil-based farming (due to recirculation), and utilizes clean, renewable solar energy.
  
• Resource Efficiency: Precise monitoring and automated control of nutrient delivery optimize plant growth, minimize nutrient waste, and conserve energy.
  
• Accessibility and Affordability: The use of repurposed plastic bottles significantly lowers material costs, making advanced hydroponics more accessible to a broader demographic, including DIY enthusiasts and educational institutions.
  
• Off-Grid Capability: Solar power ensures self-sufficiency, enabling cultivation in areas without reliable grid electricity.
  
• Educational Value: Serves as an excellent hands-on platform for teaching principles of botany, electronics, programming, renewable energy, and sustainable living.
  
• Urban and Small-Scale Agriculture: Facilitates compact, efficient plant production in limited urban spaces, balconies, or community gardens.
  
  Challenges include the potential degradation of plastic materials over extended periods, the initial technical knowledge required for IoT setup and calibration, and the ongoing maintenance of both the hydroponic components and electronic systems. Nevertheless, this integrated approach underscores a significant step towards resilient, decentralized, and environmentally conscious food production systems.