DIY Tesla Coil Mini Kit Wireless Electric Power Transmission

Official Raspberry Pi 4 Model B 4GB RAM The Raspberry Pi 4 Model B 4GB is a compact and versatile single-board computer that provides desktop-level performance in a credit card-sized device. The RPI 4B is powered by a Broadcom Quad-Core Cortex-A72 (ARM v8) 64-bit SoC that runs at 1.5GHz and has 4GB of LPDDR4-3200 SDRAM for efficient multitasking and basic desktop programs. This device is designed for a wide range of DIY projects, including media centres, file servers, robotics, and smart home systems. The Raspberry Pi 4B 4GB supports dual 4K displays ( 4K@30Hz ) through its micro-HDMI ports, making it perfect for high-definition video and creative endeavours. It has dual-band WiFi 2.4 GHz and 5.0 GHz IEEE 802.11ac , Bluetooth 5.0 , and Gigabit Ethernet for a consistent connection. It also features two USB 3.0 connections and two USB 2.0 ports to connect devices. The Raspberry Pi 4 4GB is popular among programmers and makers. It comes with native Python support , making it a fantastic platform for coding education and automation project development. It is capable of running both 32-bit and 64-bit operating systems , offering versatility for different uses. Whether for teaching, prototyping, or creative projects, it serves as a potent and affordable computing option. Shop Raspberry Pi 4 4GB Full Kit – Plug & Play Setup Affordable power for your projects – Raspberry Pi 4 2GB ! What makes this model Great? The speed and performance of the new Raspberry Pi 4 4GB are a noticeable improvement from earlier models. For the first time, the Raspberry Pi Foundation has created a complete desktop experience. Whether you're editing documents, browsing the web with multiple tabs open, managing spreadsheets, or creating a presentation, you'll find the experience smooth and familiar. It is a more energy-efficient and cost-effective machine. Features Broadcom 2711 Quad-Core Cortex A72 @ 1.5GHz delivers 20% faster performance with improved power and thermal efficiency. Dual micro-HDMI outputs support dual 4K displays with hardware video decode at 4Kp60 (H.265, H.264, MPEG-4). Dual-band WiFi (802.11b/g/n/ac) on 2.4GHz & 5GHz with advanced PCB antenna for robust wireless connectivity. Bluetooth 5.0 offers an extended range of wireless peripherals. Upgraded USB 3.0 Ethernet provides wired speeds up to 10x faster than previous models. 2 USB 3.0 and 2 USB 2.0 ports enable versatile peripheral connections. 40-pin GPIO header is fully backwards-compatible with earlier Pi models. Optional PoE support is available, with PoE header pins designed to work with proper standoffs. Comparison Table Raspberry Pi 4 Model B Raspberry Pi 5 Raspberry Pi 3 Model B+ Price (INR) ?3599 VIEW ?5129 VIEW ?3649 VIEW Processor 1.5GHz Quad-Core ARM Cortex-A72 2.4GHz Quad-Core ARM Cortex-A76 1.4GHz Quad-Core ARM Cortex-A53 RAM 1GB, 2GB, 4GB, 8GB LPDDR4 2GB, 4GB, 8GB, 16GB LPDDR4 1GB LPDDR2 Wi-Fi Dual-band 802.11ac Dual-band 802.11ac Dual-band 802.11ac Bluetooth 5.0 5.0 4.2 USB Ports 2× USB 3.0, 2× USB 2.0 2× USB 3.0, 1× USB 2.0 4× USB 2.0 Ethernet Gigabit Ethernet Gigabit Ethernet Gigabit Ethernet Video Output 2× Micro HDMI (4Kp60) 2× Micro HDMI (4Kp60) 1× HDMI (1080p) GPIO Pins 40 40 40 Storage MicroSD (SDXC up to 2TB) MicroSD (SDXC up to 2TB) MicroSD (SDHC) Power Supply USB-C USB-C Micro USB Click for Complete Raspberry Pi Kits – Learn, Build, and Innovate! Pin Diagram:

Waveshare UGV Rover ROS 2 Open-source 6 Wheels 4WD AI Robot With Jetson Orin Nano 4GB Kit, Dual controllers, 360° Flexible Omnidirectional Pan-Tilt Waveshare UGV Rover ROS 2 Open-Source 6-Wheel 4WD AI Robot is a powerful mobile robotics platform designed for Jetson Orin series boards. Built for advanced AI, perception, and autonomous navigation tasks, it features a rugged 6-wheel 4WD design, dual controllers, and a 360° flexible omnidirectional pan-tilt system for full-range vision. Ideal for research, prototyping, and robotics development, this UGV offers seamless ROS 2 integration and high performance for real-world robotic applications Features Supports Pan-Tilt drag-and-drop control via mouse or touch panel of the laptop, providing a better control experience as FPS games Powered by Jetson Orin series computer Supports Jetson Orin Nano 4GB Kit, provides up to 20 TOPS AI Performance. High-speed reading/writing, to meet the development needs of large AI projects Advanced AI Recognition & Tracking Based on OpenCV, supports color recognition and automatic targeting with one-key Pan-Tilt control and auto LED lighting. Expandable for additional AI functions. Face Detection & Recognition Automatically captures photos or records videos when a face is detected, providing enhanced security and AI interaction. Cross-Platform Web Control No app installation required! Simply connect via a web browser on mobile, tablet, or PC. Supports WASD keyboard shortcuts and mouse control for seamless navigation. WebRTC real-time video transmission Adopts Flask lightweight web application, based on WebRTC ultra-low latency real-time transmission, using Python language and easy to extend, working seamlessly with OpenCV Features at a glance Multiple Autonomous Navigation Modes UGV Rover supports multiple autonomous navigation modes, allowing it to navigate complex environments with precision. Whether following predefined paths, avoiding obstacles, or performing AI-assisted route planning, the robot adapts intelligently to real-world terrains. Dimensions

Pludo STEM Kit DIY AIRCRAFT – DIY Science Kit for Kids 11–14 | Grade 6–8 Learn Concepts of Propulsion Ignite your child’s curiosity with the Pludo STEM Kit DIY AIRCRAFT, an exciting science experiment kit designed to make learning physics fun and hands-on. This educational kit introduces children to the fascinating concepts of aerodynamics, motion, and electric energy through a creative DIY aircraft project. As kids build their own wooden electric taxiing aircraft, they discover how power and motion work together in real machines. The model operates by converting electrical energy from a battery into mechanical motion using a small DC motor. When powered, the motor spins the front propeller at high speed, generating forward thrust. This thrust moves the lightweight aircraft along the ground on its wheels, clearly demonstrating how electric motors drive propellers in real aircraft systems. As one of the most engaging STEM kits and kids learning toys, it promotes active learning through play and experimentation. Whether used at home, in classrooms, or for school science projects, this science toy offers an enriching educational experience that blends fun, learning, and real-world application. What Your Child Will Learn: Discover how electric energy powers motion through an engaging aircraft experiment. Understand aerodynamic design principles that keep vehicles stable and efficient. Strengthen logical thinking, creativity, and fine motor skills through hands-on construction. Encourage curiosity and innovation by connecting theoretical science to practical application. Build confidence through problem-solving and experimentation that makes learning exciting. Educational Outcomes Energy Conversion: Explore how electrical energy transforms into motion and kinetic energy. Aerodynamics & Mechanics: Learn about airflow, balance, and motion through practical observation. Physics in Action: Connect real-world concepts of force, friction, and motion with fun experiments. STEM Skill Development: Build confidence in scientific reasoning, assembly, and testing. Collaborative Learning: Encourages teamwork and communication through group or classroom experiments. Did You Know? Aircraft wings are designed to create lift by shaping airflow — the same principle your Electrotaxi model uses to glide smoothly! Features Hands-on DIY science experiment kit that helps kids explore aerodynamics, motion, and electric energy through a fun aircraft-building activity. Encourages curiosity, logical thinking, and creativity as children assemble and test their own electric wooden aircraft model. Designed as an educational kit that supports experiential learning and enhances understanding of basic physics and energy conversion. Made from durable, safe, and eco-friendly materials, ensuring a secure and enjoyable playtime experience. Ideal for children aged 11–14 years (Grades 6–8), offering age-appropriate exposure to science and engineering principles. Promotes teamwork and problem-solving, making it perfect for classroom experiments, home learning, or group science activities. Included manual provides step-by-step guidance for easy assembly, testing, and understanding of the working model. Makes a perfect science toy gift for birthdays, holidays, or school science fairs — a fun way to inspire young minds in STEM learning.

Pludo Pinhole Projector – DIY STEM Kit for Kids 8–11 | Grade 3 to 5 Small Hole Imaging Learning Project Discover the fascinating world of light and imaging with the Pludo STEM Kit Pinhole Projector - a hands-on DIY STEM kit designed for kids aged 8-11. This engaging project lets children build their own pinhole imaging device, helping them understand how light travels and forms images in a simple, interactive way. Perfect for classroom activities or home learning, this kit encourages curiosity, critical thinking, and problem-solving while making science fun and accessible. As one of the most engaging science experiment kits, it transforms complex concepts into practical experiences, turning it into a memorable educational adventure. A great addition to any collection of educational toys or science kits for kids, it also makes a thoughtful gift for young learners interested in hands-on STEM projects. What Your Child Will Learn Learn how light rays travel in straight lines and how they form images through a pinhole. Understand the basic principles of optics, including light, shadows, and image inversion. Strengthen critical thinking and problem-solving through guided experimentation. Boost fine motor skills and focus while building and testing the model. Foster curiosity and creativity by exploring how simple tools can reveal big scientific ideas. Ideal for home learning, classroom demonstrations, or science fairs. Educational Outcomes Optical Science: Discover how light behaves and how images are formed in cameras and the human eye. Physics in Practice: Observe real-world applications of light behavior and image projection. STEM Integration: Combines science, creativity, and design thinking for an engaging learning experience. Critical Thinking: Encourages observation, prediction, and analysis of visual outcomes. Curiosity & Confidence: Builds enthusiasm for scientific exploration through practical, hands-on discovery. 💡 Did You Know? The pinhole camera is one of the earliest forms of imaging technology — it uses the same principles that modern digital cameras are built on! Features DIY STEM Kit: Kids assemble their own working pinhole imaging device, making learning interactive and rewarding. Learn Light & Imaging: Explores the principles of light, shadows, and image formation through fun experiments. Enhances STEM Skills: Encourages critical thinking, problem-solving, and fine motor development. Safe & Durable Materials: Made with high-quality, child-safe components for worry-free learning and play. Perfect for Home or Classroom: Great for guided STEM lessons, school projects, or independent exploration. Great Educational Gift: Inspires curiosity and practical understanding - perfect for birthdays, holidays, or science-loving kids.

NVIDIA Jetson Orin NX 8GB RAM 70 TOPS AI Embedded Module T801 AI Developer Kit The NVIDIA Jetson Orin NX 8GB RAM 70 TOPS AI Embedded Module T801 AI Developer Kit is a compact yet powerful edge AI platform built for developers and innovators who need serious computing performance in a small footprint. Equipped with 8GB RAM and delivering up to 70 TOPS of AI performance, this module enables real-time machine learning, computer vision, and autonomous processing directly on the device—without depending on cloud connectivity. It is perfectly suited for robotics, smart surveillance systems, industrial automation, and advanced IoT solutions. With full support for popular AI frameworks like TensorFlow and PyTorch, along with NVIDIA’s JetPack SDK, the kit streamlines development, testing, and deployment of intelligent systems. Whether you are prototyping an AI concept or building a production-ready solution, this developer kit offers the performance, flexibility, and reliability required for next-generation embedded AI applications. Hardware Overview: Applications: 1. Practical Application in Security Monitoring Scenarios 2. Practical Application in Smart Gas Station 3. Practical Application in Smart Petroleum Providing simultaneous assistance for channel video analysis. Provide support for smoke, fire, personnel area monitoring, fall detection, safety helmet recognition, tools, gauges, oil level, and valve direction. 4. Practical Application | Identification of Unidentified Objects in Power Transmission Providing simultaneous support for four-channel video analysis Unidentified object recognition, fireworks, and engineering vehicles. Subsequent additions, aberrant insulators, pins, bird spikes, Features: Built on NVIDIA Jetson Orin NX architecture 8GB RAM for smooth AI model execution Up to 70 TOPS AI performance for real-time inference Optimized for edge AI and embedded systems Supports TensorFlow, PyTorch & NVIDIA JetPack SDK Low power consumption with high computational efficiency Ideal for robotics, smart vision, and industrial automation applications

Pludo DIY Mini Guibiao Kit – DIY Science Experiment Kit for Kids 8–11 | Grade 3–5 Celestial Movements STEM Toy The Pludo DIY Mini Guibiao Kit is an engaging science experiment kit that allows children aged 8–11 to explore the fascinating world of astronomy through hands-on learning. With this DIY project, kids can assemble their own astronomical instrument and understand the basic principles of celestial observation in a fun and interactive way. The kit works as a basic angle-measuring and direction-finding tool. A built-in compass uses Earth’s magnetic field to point toward magnetic north, helping learners understand orientation. The vertical stand and marked scale allow children to align the instrument with the Sun and measure the length of the shadow using a ruler. By combining shadow measurement with directional guidance, kids learn how traditional navigation methods and time cycles (such as estimating the length of a year) were calculated in ancient astronomy. This educational kit promotes critical thinking, problem-solving, and creativity while making science accessible and enjoyable. Ideal for home learning or classroom activities, it also serves as one of the most engaging activity kits for curious minds. Perfect for parents looking for smart toys for kids or science toys for kids, it turns complex concepts into practical, memorable experiences. What Your Child Will Learn Learn how ancient instruments were used to measure angles and track stars. Understand basic astronomy concepts such as celestial positioning and observation. Strengthen fine motor skills and logical thinking through hands-on construction. Develop problem-solving abilities and creativity by experimenting with the instrument. Build confidence by completing a functional model that connects history, science, and STEM learning. Educational Outcomes Celestial Observation: Learn how astronomers observe and track objects in the sky. Science & History Integration: Understand the evolution of early scientific tools used for navigation and measurement. STEM Skill Development: Improve analytical thinking, concentration, and spatial reasoning. Practical Learning: Connect textbook astronomy with interactive, real-world experimentation. Curiosity & Exploration: Encourage a deeper interest in space, science, and discovery through guided play. 💡 Did You Know? Ancient astronomers used devices like the Guibiao to measure the height of stars - helping them develop calendars, track seasons, and predict celestial events! Features Hands-on DIY Project: Kids assemble their own astronomical instrument, learning astronomy concepts practically. STEM-Aligned Learning: Introduces basic celestial observation, boosting understanding of science and space. Safe & Durable Materials: Made from eco-friendly, child-safe components for worry-free play. Guided Assembly: Includes clear instructions; best used under adult or STEM tutor supervision. Perfect Educational Gift: Great for birthdays, school projects, or STEM-themed gifting, combining fun and learning. Encourages Curiosity: Promotes creativity, problem-solving, and independent scientific exploration.

Pludo Seesaw Science STEM Kit– DIY Physics Learning Kit for Kids 8–11 | Explore Torque & Rotation (Grade 3–5) Pludo Seesaw Science STEM Kit, a hands-on educational kit that helps children aged 8–11 (Grade 3–5) explore the fascinating principles of torque, balance, and rotation through an engaging DIY project. Designed to nurture curiosity and logical thinking, this STEM toy encourages kids to build, test, and understand real-world physics concepts in a fun, interactive way. Crafted to align with learning goals, this kit promotes creativity while enhancing problem-solving and fine motor skills. As children place and adjust weights on the seesaw, they learn how torque—the turning force that causes rotation-affects balance. The side with greater torque, calculated by weight multiplied by distance from the center, moves downward. By changing the position of the weights, kids can balance or tilt the seesaw, helping them understand how rotation and balance work in a clear, hands-on way. Ideal for home or classroom activities, it also makes a thoughtful choice for parents looking for smart toys for kids that combine fun with learning. A perfect addition to your child’s activity kits collection, it turns playtime into a meaningful educational experience. What Your Child Will Learn: Understand how torque, balance, and rotational motion make a seesaw move. See physics come alive through hands-on experimentation instead of textbook diagrams. Strengthen critical thinking and problem-solving while assembling and testing the model. Improve fine motor skills, focus, and hand–eye coordination with guided DIY building. Connect real-world play to classroom concepts for a deeper understanding of physics. Educational Outcomes: Physics Concepts: Learn torque, pivot points, center of gravity, and balance through practical demonstration. STEM Skill Development: Encourages observation, prediction, measurement, and logical reasoning. Concept Reinforcement: Helps children relate textbook physics to everyday objects and motion. Confidence & Curiosity: Builds scientific thinking and encourages children to ask why things work the way they do. Aligned With NEP 2020: Ideal for ages 8–11 (Grade 3–5), meeting recommended hands-on learning standards. Did You Know? A seesaw is one of the simplest examples of a first-class lever, the same principle used in scissors, pliers, and crowbars! Features Age-Appropriate Learning: Designed for kids aged 8–11 years (Grade 3–5) as per NEP 2020 guidelines to make physics fun and understandable. Hands-On Physics Exploration: Introduces concepts of torque, balance, and rotation through a build-it-yourself seesaw model that blends learning with creativity. DIY Educational Experience: Kids assemble the components themselves, promoting critical thinking, problem-solving, and fine motor skills development. Safe & Engaging Materials: Made from child-friendly wooden parts that are durable, safe, and perfect for classroom or home learning environments. Perfect Gift for Young Innovators: A thoughtful educational gift for birthdays, science fairs, or learning enthusiasts that inspires curiosity through play. Guided Learning: Best used under the supervision of an adult or STEM tutor to help children grasp scientific principles through practical demonstration. Encourages Real-World Learning: Bridges the gap between theory and practice-making physics enjoyable and accessible for growing minds.

ACEBOTT QD028 ESP32 2-in-1 Football & Battle Car Robotics Kit ACEBOTT QD028 2-in-1 Football & Battle Car Kit is a unique and exciting programmable robotics kit built around the powerful ESP32 controller. Designed for hands-on learning and creativity, this kit lets users build and customize a dual-mode robot that switches seamlessly between football player and battle car modes. With modular expandability and intuitive programming support, the QD028 is perfect for STEM classrooms, home learning experiences, activities, and friendly competitions. Features 2-in-1 Dual Gameplay Modes – Switch instantly between Football Mode and Battle Car Mode for endless fun and creativity. Powered by ESP32 Controller – Supports Wi-Fi and Bluetooth, enabling smart control, coding, and expandable IoT possibilities. Modular Assembly Design – Easy-to-build, kid-friendly components that encourage hands-on learning and fast reconfiguration. STEM-Focused Learning – Teaches robotics, electronics, coding, and problem-solving, perfect for classrooms and home education. Programmable with Multiple Platforms – Supports Arduino IDE and ACECode (Scratch-style coding) for all learning levels. Durable, Competition-Ready Build – Designed for activities, challenges, and competitions with stable control and smooth movement.

Pludo STEM Air Glide Kit – DIY Science Kit for Kids 11–14 | Grade 6–8 Bernoulli’s Principle Air Levitation Experiment Bring the wonders of physics to life with the Pludo STEM Air Glide Kit, a hands-on science experiment kit designed to demonstrate Bernoulli’s Principle in action. As children assemble and experiment with the kit, they discover that fast-moving air creates low pressure. When the blower pushes air upward at high speed, the air pressure around the ball becomes lower than the pressure below it. This pressure difference lifts the ball and keeps it floating and balanced in the air. As long as the airflow remains steady, the ball stays levitated, clearly showing how air speed and pressure work together to produce lift. This engaging kit doubles as both a science toy and a STEM learning tool, helping young minds understand core concepts of motion, balance, and aerodynamics in a fun and interactive way. A great choice for parents and teachers seeking quality kids learning toys and STEM kits that inspire creativity and experimentation. What Your Child Will Learn: Discover how air pressure and velocity work together to create lift. Understand Bernoulli’s Principle through exciting real-world demonstrations. Learn about aerodynamics, balance, and fluid motion in a simple, interactive way. Strengthen observation, critical thinking, and problem-solving skills. Gain confidence through hands-on learning and self-exploration. Educational Outcomes: Conceptual Clarity: Builds a solid understanding of how air movement affects objects, connecting science to daily life. STEM Skill Development: Encourages experimentation, hypothesis testing, and logical reasoning. Real-World Application: Demonstrates how Bernoulli’s Principle applies to airplanes, drones, and sports physics. Creative Thinking: Inspires kids to design and test their own experiments based on air pressure and motion. Confidence in Learning: Promotes curiosity-driven discovery that helps children approach science with enthusiasm and confidence. Fun Fact: Bernoulli’s Principle is the same concept that keeps airplanes in the sky — your child will explore this fascinating science right at home! Features Hands-on DIY science experiment kit that demonstrates Bernoulli’s Principle through air pressure and lift experiments. Encourages curiosity, critical thinking, and problem-solving as children explore how airflow creates levitation. Made from durable, child-safe materials ensuring safe and long-lasting use during experiments. Suitable for children aged 11–14 (Grade 6–8) for an engaging and age-appropriate STEM learning experience. Promotes understanding of aerodynamics, balance, and fluid motion through fun, practical experiments. Perfect for classroom demonstrations, home learning sessions, or interactive STEM projects. Included manual provides step-by-step guidance for easy assembly and scientific exploration. Makes a thoughtful science gift for birthdays, science fairs, or young inventors interested in hands-on discovery.

Pludo Wooden Clown Tightrope STEM Kit – Balance and Centre of Gravity Learning Toy for Kids 8–11 | Grade 3–5 DIY Science Kit Get ready to explore the exciting world of balance and motion with the Pludo Wooden Clown Tightrope STEM Kit – Balance and Centre of Gravity Learning Toy for Kids 8–11 | Grade 3–5 DIY Science Kit. This engaging hands-on kit lets children build their own tightrope-walking clown while learning the principles of gravity, balance, and center of mass in a fun and interactive way. As kids assemble and test the model, they discover how balance works in real life. The kit operates on the concept of center of gravity. When placed on the rope or support, the toy’s weight is evenly distributed, keeping its center of gravity low and stable. As the clown moves or swings, gravity pulls it downward while the balanced design prevents it from tipping over. This allows the toy to walk or slide smoothly along the rope, clearly demonstrating how balance and gravity work together. A perfect addition to any range of science kits for kids, it turns simple concepts into exciting discoveries through creativity and experimentation. What Your Child Will Learn Learn how center of mass and gravity help objects remain stable. Understand why the clown can balance on a tightrope without tipping over. Strengthen fine motor skills, coordination, and spatial awareness through careful assembly. Build problem-solving skills by experimenting with movement, weight, and balance. Encourage an early interest in STEM concepts through playful, curiosity-driven learning. Educational Outcomes Physics Fundamentals: Explore how weight distribution and gravitational force affect stability. Balance & Motion: Understand why some objects balance easily while others fall-using a real working model. STEM Skill Development: Boost reasoning, observation, and creative thinking through trial-and-error experiments. Cognitive Growth: Improve focus, hand–eye coordination, and patience during hands-on building. Confidence Through Creation: Experience the joy of completing a functional scientific model independently. 💡 Did You Know? Tightrope walkers use poles and careful weight distribution to lower their center of mass, helping them stay steady-the same principle your child explores in this kit! Features: Hands-on STEM Kit that teaches balance, gravity, and center of mass through real experimentation. DIY Assembly Experience that boosts creativity, motor skills, and problem-solving abilities. Made with durable, eco-friendly wooden components for long-lasting and safe play. Perfect for home learning, classroom projects, weekend STEM activities, and science challenges. Encourages curiosity, focus, and active experimentation, making science approachable and fun. Comes with all required materials and easy-to-follow step-by-step instructions for a smooth experience.

Pludo Robotic Walking Dog - STEM Toy on Motion & Robotics for Ages 8–11 | Grade 3 to 5 This Robotic Walking Dog STEM Toy gives children aged 8–11 an exciting opportunity to explore robotics and engineering through hands-on play. Kids can assemble their own electric robot dog, learning how mechanical parts, circuits, and movement work together in a fun and interactive way. It’s a practical introduction to STEM concepts that makes learning feel like play. The kit encourages creativity, problem-solving, and critical thinking while helping children develop fine motor skills and hand-eye coordination. As they assemble and test their robot dog, children gain confidence and a deeper understanding of how science and technology work in the real world. As children build and test the robot dog, they develop creativity, problem-solving skills, critical thinking, fine motor skills, and hand–eye coordination. The kit works by converting electrical energy from a battery into mechanical motion using a motor. When powered on, the motor drives a set of internal gears that transfer and control movement. These interconnected gears move the legs in a coordinated way, creating lifelike walking motion and clearly demonstrating how motors, gears, and linkages are used in robotics. Perfect for curious young minds, this set also doubles as a smart toy, a versatile toy kit, and a DIY kit, offering hours of engaging and educational entertainment. It’s one of the most exciting DIY robotic kits for kids who love exploring, building, and experimenting, making it an ideal gift for home, school projects, or STEM learning activities. What Your Child Will Learn Build a motor-powered dog that walks and moves, learning how electricity converts into motion. Understand the basics of robotics and simple circuits through fun, guided experimentation. Strengthen fine motor skills, focus, and patience while assembling and wiring each part. Learn how motion, balance, and mechanics work together in real-world machines. Boost creative thinking and problem-solving by customizing and troubleshooting the build. Encourage confidence and curiosity — ideal for home learning, classroom activities, or STEM clubs. Educational Outcomes Electricity & Circuits: Discover how power flows through simple connections to make movement possible. Mechanics: Explore how gears, motors, and linkages work together to create motion. Engineering Thinking: Apply logical reasoning and sequencing while assembling the toy. Creativity & Confidence: Learn by doing - experiment, adapt, and see science come alive through play Features: DIY robotic dog that teaches the fundamentals of movement and electricity. Designed for kids aged 8–11 (Grades 3–5) — perfect for age-appropriate STEM learning. Encourages creativity, customization, and critical thinking through hands-on building. Lets kids explore mechanics and electronics in a safe, interactive way. Made from eco-friendly, high-quality materials for durable, safe playtime. Can be used as a smart toy, DIY project, or learning kit for both home and school environments. Sparks curiosity and love for science, technology, and problem-solving in every build.

DFRobot Gravity 7/24 Industrial Analog pH Sensor Meter Kit for Arduino The DFRobot Gravity 7/24 Industrial Analog pH Sensor Meter Kit for Arduino is a high-precision Analog pH Sensor designed for professional and industrial applications requiring continuous pH monitoring. This Arduino pH Sensor uses an industrial-grade glass membrane electrode with low impedance, delivering fast response, excellent thermal stability, and stable performance over long periods. It supports a full measurement range of 0 pH to 14 pH with linear voltage output, ensuring accurate and reliable readings. The sensor integrates easily through a BNC connector and PH2.0 interface, allowing direct connection to any Arduino analog input. Its reference system, based on Ag/AgCl gel electrolyte with a PTFE membrane, provides strong anti-pollution characteristics and prevents clogging, making it an ideal industrial pH sensor for Arduino for water treatment systems, environmental monitoring, and laboratory analysis. Attention: The probe's bottle top contains protective fluids (3.3mol/L KCL). Even if the bottle cap is tightly fastened, some protective liquid may leak around it, resulting in white crystals. However, as long as the bottle top contains protective liquid, the probe's life and accuracy will be unaffected. Please use it with confidence. It is recommended that the white crystals be returned to the bottle cap's protective liquid. Features Industrial-grade Analog pH Sensor for accurate measurement Compatible with Arduino and other microcontrollers Measures pH range from 0 to 14 Fast response with high stability BNC connector for secure sensor connection Plug-and-play PH2.0 analog interface Built-in power indicator LED Suitable for long-term online monitoring Low maintenance and long sensor life Ideal for water quality and lab applications Applications Water Quality Surveillance Aquaculture

Pludo Self Balancing Car – Balance & Motion Learning DIY Kit for Kids Ages 5–8 | Grade 1-3 Kick-start hands-on learning with a self-balancing car children can build from scratch, turning simple parts into real engineering moments that feel like play. This Robotic Diy Kit project guides young makers to assemble a motor-powered car with a battery holder, gears, and wheels, making energy and motion easy to see in a safe, screen-free activity. With clear steps and child-friendly parts, it introduces basic circuits and mechanics while building fine motor skills, problem-solving, and early confidence. The motor drives gears that rotate both wheels, creating smooth forward motion. Balanced force on each wheel keeps the robot stable, showing how motors and gears work together for controlled movement. Perfect for classrooms, makerspaces, and home learning, the kit rolls smoothly to demonstrate balance and cause-and-effect, ideal for demos, STEM fairs, and early physics lessons. Thoughtfully sized for easy storage, it fits naturally into a starter diy kit setup, complements broader diy science kits, and adds variety to any diy car kit collection, encouraging repeat builds and deeper exploration over time. What Your Child Will Learn Build a motorized car and explore how power, gears, and balance work together to create movement. Understand the flow of electricity and how it drives mechanical motion. Strengthen fine motor skills and spatial awareness through guided assembly. Learn the fundamentals of balance, speed, and direction in a fun, interactive way. Boost focus, patience, and creative thinking by experimenting with different setups. Ideal for STEM learning at home, classrooms, or science fairs, encouraging exploration beyond textbooks. Educational Outcomes Electricity & Circuits: Discover how motors and batteries work together to produce motion. Mechanics in Motion: Understand gear movement, friction, and balance in a two-wheel design. Engineering Mindset: Practice logical sequencing, trial and error, and system-based thinking. Fine Motor Development: Enhance coordination and concentration while assembling small components. Confidence Through Creation: Experience the satisfaction of building something functional from scratch. 💡 Did you know? Robots use the same principles of balance and motion control that your two-wheel car demonstrates - it’s the foundation of robotics! Features: Assemble a simple two-wheel car with motor, gears, wheels, and a battery holder for screen-free learning. Introduces basic electricity and mechanics using child-friendly parts and clear instructions. Demonstrates balance in motion as kids observe how power reaches the wheels and drives movement. Helps develop fine motor skills, problem-solving, focus, and confidence through guided tinkering. Perfect for classroom lessons, STEM fairs, or at-home experiments with easy setup and cleanup. Made with lightweight, durable components that allow repeated builds for continued learning.

Pludo Solar Racer Car DIY Kit – Build a Light Following Car for Ages 8–11 | Grade 3–5 Ignite your child’s curiosity with the Pludo Solar Racer Car DIY Kit, a hands-on stem toy for kids that introduces the basics of solar energy and motion. This engaging science kit for kids allows children to assemble their own wooden car powered by sunlight, turning learning into a fun, interactive experience. As kids assemble and experiment with the Solar Racer Car, they develop critical thinking, creativity, and problem-solving skills. The car works on the principle of solar energy conversion. When sunlight falls on the solar panel, it converts light into electrical energy. This electricity powers a small motor inside the car, which rotates and turns the gears connected to the wheels, making the car move forward. Through this process, children learn how sunlight can be transformed into usable power without batteries or fuel. What Your Child Will Learn Learn how solar panels convert sunlight into electrical energy to power movement. Understand the mechanics of gears and wheels through guided, real-world exploration. Strengthen fine motor skills and logical thinking while assembling each component. Encourage problem-solving and creative experimentation by testing the car under different lighting conditions. Build confidence and curiosity through independent discovery and practical play. Educational Outcomes Solar Energy Awareness: Understand how renewable energy sources can replace conventional power. Mechanics & Motion: Explore how energy is transferred to create movement in vehicles. STEM Skills Development: Connect concepts from physics and engineering through fun, applied learning. Critical Thinking: Encourage observation, analysis, and troubleshooting to improve performance. Sustainability Mindset: Inspire awareness about clean energy and the future of eco-friendly technology. 💡 Did You Know? The same solar energy principles used in this kit are applied in real solar-powered cars and satellites around the world! Features: Hands-on DIY STEM toy that teaches solar energy, motion, and basic mechanics. Encourages creativity, problem-solving, and critical thinking through interactive assembly. Made with safe, durable wooden components designed for long-lasting use. Includes easy-to-follow instructions, perfect for both independent and guided play. Ideal science kit for classrooms, home learning, or STEM fairs. Compact and lightweight design makes it easy to handle, store, and reuse. Combines fun and education, turning playtime into a meaningful learning experience.

Pludo Cable Bridge DIY Kit – Learn Force & Tension Through Bridge Building for Ages 8–11 | Grade 3–5 Discover the world of engineering with the Pludo Cable Bridge DIY Kit, an exciting hands-on learning experience designed for young innovators. This educational kit introduces children to the principles of force, tension, and structural design through a fun cable bridge-building activity. As kids assemble the bridge step by step, they explore how real-world engineering structures work while strengthening creativity, logical thinking, focus, and problem-solving skills. The kit demonstrates the concept of tension using a suspension-style bridge model. Tight cables or chains hold the bridge planks in place and distribute applied force evenly across the structure. This shows how tension in cables carries load and maintains stability, just like in real suspension bridges. Perfect for curious minds aged 8–11 years (Grade 3–5), this science experiment kit encourages interactive learning while improving focus, coordination, and logical thinking. Made from eco-friendly, durable materials, it ensures a safe and engaging experience for every young builder. Ideal for home learning, school projects, or group activities, this educational toy transforms playtime into a rewarding journey of discovery. What Your Child Will Learn Learn how tension and compression keep bridges strong and balanced. Understand how forces interact in structures through guided building. Strengthen fine motor skills, focus, and problem-solving while assembling the model. Encourage curiosity and creativity through practical, project-based learning. Experience the joy of building a real working cable bridge powered by imagination and science. Educational Outcomes Engineering Concepts: Understand the basic principles of tension, force distribution, and load-bearing structures. STEM Skills: Develop a foundation in mechanical design and civil engineering through hands-on assembly. Critical Thinking: Enhance reasoning and analytical abilities by experimenting with structural stability. Creativity & Design Thinking: Apply imagination to modify and strengthen bridge designs. Fine Motor Development: Build precision, patience, and attention to detail during construction. 💡 Did You Know? The same principles used in this kit are applied in designing real-world cable bridges like the Golden Gate Bridge! Features: Hands-on DIY science kit teaching tension, force, and bridge engineering. Encourages creativity, problem-solving, and structural understanding through play. Includes all components to build a working cable bridge model. Made from safe, eco-friendly, and durable materials for worry-free use. Helps children build fine motor skills, focus, and critical thinking. Designed for ages 8–11 years (Grade 3–5) following NEP 2020 learning standards. Comes with a detailed instruction manual for guided and easy assembly. A perfect educational gift for young science lovers and budding engineers.