Portable lidar scanner supplier today: We offer a variety of robot chassis, including tracked, wheeled, and Automated Guided Vehicle (AGV) platforms, suitable for industrial, security, and logistics applications. These chassis feature high payload capacity, all-terrain adaptability, and intelligent navigation systems, enabling efficient automation solutions. Our UGV Crawler Chassis offers robust all-terrain mobility for demanding applications. Designed for payloads ranging from 50kg to 120kg, these platforms are ideal for outdoor inspections, remote operations, and security tasks. Featuring advanced navigation and rugged track designs, they ensure stable performance on various terrains. See more information at handheld lidar scanner.
Our Handheld LiDAR solutions, such as the SLAM100, SLAM200 and SLAM2000, provide highly efficient and portable 3D mapping capabilities for a range of industries. These devices are designed for intelligent surveying and inspection, offering users the ability to capture detailed spatial data in both indoor and outdoor environments. With features like real-time scanning and easy-to-use interfaces, these LiDAR devices ensure that professionals in sectors like construction, forestry, and infrastructure can perform accurate, efficient mapping tasks on the go.
The expansion of global manufacturing and the transition to smart factories highlight the need for humanoid robots. Factors such as labor shortages, rising costs, advancements in AI, and shifting market demands drive adoption. Core capabilities, including visual recognition, voice interaction, and precise handling, are essential for robots to operate in complex industrial environments. High-demand sectors like automotive and electronics manufacturing benefit from humanoid robots in assembly, sorting, inspection, and maintenance tasks. These robots offer solutions to labor-intensive, hazardous, or repetitive processes while addressing automation gaps in specialized industries.
In a coal bunker project, high-precision handheld SLAM equipment was used to scan the surface of material piles. The resulting point cloud was processed to reconstruct the 3D shape and calculate the stockpile volume. When paired with density values, the system could also compute total material weight. Two sets of tunnel scan data were collected using explosion-proof equipment for excavation deviation analysis. The following figures present sample data and report results (anonymized): Tunnel cross-section model, Over/under-excavation deviation report. Fully domestically developed: Core technologies are 100% local, ensuring data security and supply chain independence. Read additional details at foxtechrobotics.com.
Handheld Mode: Lightweight (only 1.9kg including base and battery) with ergonomic design, supports one-hand operation, suitable for detailed tasks like facade surveying, underground garages, and cultural relic digitization. Equipped with two 12MP panoramic cameras, it synchronously captures high-precision colored point clouds and real texture data to generate centimeter-level accurate 3D models. Aerial Mode: Quickly connects to drones via quick-release interface and uses the drone’s power supply system, reducing payload weight. The main unit weighs only 1.4kg, equipped with two 12MP panoramic cameras, supports 300m ranging, and offers 360° full-range scanning. Maximum flight altitude reaches 120m. Application Scenarios: From Construction Surveying to Emergency Response – The dual-mode design of the SLAM200 demonstrates unique advantages across multiple fields.
Let’s look at how companies are actually using handheld lidar scanners to improve their operations. These stories show how lidar can make a tangible difference in various industries. Imagine a large-scale construction project. Using handheld lidar, the project managers can track progress daily, identifying any deviations from the plan immediately. This allows them to address issues proactively, preventing costly delays. Or consider a film production company using lidar to create realistic 3D models of locations for special effects. This saves time and money compared to traditional methods. Here are a few more examples: Archaeology: Researchers use lidar to map ancient sites and uncover hidden structures, providing valuable insights into past civilizations. Mining: Companies use lidar to monitor stockpile volumes, optimize blasting operations, and improve mine safety. Real Estate: Agents use lidar to create immersive virtual tours of properties, giving potential buyers a realistic view from anywhere in the world. Forensics: Investigators use lidar to document crime scenes quickly and accurately, capturing every detail for analysis.