Why the SICK TiM100-3010200?
The SICK TiM100-3010200 stands out because it delivers wide-angle 2D LiDAR coverage in an extremely compact and energy-efficient form. It brings together fast response, stable indoor detection, and simple integration, making it ideal for modern automation where space is limited but precision is essential. Its versatility allows engineers to upgrade reliability without increasing system complexity.
What Problem Does It Solve?
This model solves the challenge of achieving dependable, high-coverage detection in tight indoor environments. Many machines struggle with blind spots or unstable sensing when objects vary in reflectivity—this sensor overcomes both. With its 200° scan and dependable short-range measurement, it ensures smoother navigation, safer movement, and more predictable automation workflows.
Key Features & Specifications – SICK TiM100-3010200 (Part No. 1077524)
| Feature | Details | Benefit |
|---|---|---|
| Application | Indoor use | Designed for indoor automation where consistent detection is essential |
| Measurement Principle | HDDM+ infrared time-of-flight | Provides stable, high-quality distance readings even on varied surfaces |
| Light Source | Infrared, 850 nm, Class 1 laser | Safe for human environments with reliable optical performance |
| Aperture Angle | 200° horizontal scan | Covers wide areas with a single sensor, reducing blind spots |
| Scanning Frequency | 14.5 Hz | Supports smooth movement, ideal for mobile platforms |
| Angular Resolution | 1° | Enables more precise detection and shape recognition |
| Working Range | 0.05 m to 3 m | Optimized for short-range indoor positioning and monitoring |
| Scanning Range at 10% Remission | 1.2–1.5 m depending on angle | Maintains detection on darker or low-reflective objects |
| Response Time | Typical 70 ms | Ensures fast reaction in navigation or presence-detection tasks |
| Integrated Application | Built-in field evaluation | Reduces need for external controllers in simple monitoring setups |
| Inputs / Outputs | 1 input, 2 push-pull outputs | Supports flexible triggering and signal feedback |
| Interface | IO-Link | Enables easy configuration, diagnostics, and parameter access |
| Optical Indicators | Dual-status LEDs | Quick visual status feedback for installation and troubleshooting |
| Supply Voltage | 9–28 V DC | Works across common industrial power profiles |
| Power Consumption | Typical 2.2 W | Very low energy demand for compact devices |
| Enclosure Rating | IP65 | Resistant to dust and light water exposure in controlled zones |
| Ambient Light Immunity | Up to 80,000 lx | Reliable detection even in brightly lit areas |
| Operating Temperature | –10 °C to +50 °C | Suitable for typical indoor industrial climates |
| Housing Color & Material | Light blue RAL 5012 | Standardized appearance for SICK TiM series devices |
| Dimensions (L×W×H) | 60 × 60 × 75.8 mm | Small footprint for limited-space installations |
| MTBF | 50 years | Long design life for reduced maintenance planning |
| Vibration Resistance | 10–500 Hz (per IEC testing) | Operates reliably in environments with mechanical movement |
| Protection Class | III | Added electrical safety in low-voltage systems |
| Object Remission Range | 4% to 1000% | Handles both low-contrast and highly reflective surfaces |
Download SICK TiM100-3010200 (1077524) Datasheet
Commercial Information – SICK TiM100-3010200 (Article No. 1077524)
| Item | Details |
|---|---|
| EAN Number | 4047084396571 |
| Weight | 211 g |
| Country of Origin | Malaysia |
The Applications of the TiM100-3010200
1. Obstacle Detection for Compact Indoor Mobile Robots
Small indoor robots that navigate between shelves or machinery often operate in tight corridors with limited visibility. The TiM100-3010200 can be installed as a forward-facing sensor to continuously scan a broad arc around the robot. Its wide 200° coverage reduces blind zones, while the short-range accuracy helps the robot react quickly to carts, containers, or workers entering its route. Because the sensor maintains stable readings even on darker or less reflective surfaces, the robot can slow down or change direction with confidence. This improves the safety and fluidity of movement, especially in facilities where space is restricted and directions change frequently.
2. Item Presence Verification in Indoor Material-Flow Systems
Automated storage and transport systems rely on precise confirmation of whether a bin, tray, or package is positioned correctly before moving it onward. The TiM100-3010200 can be mounted above conveyor sections to monitor entry points or buffer zones. Its broad scanning angle allows one device to oversee several lanes, reducing the need for multiple single-point sensors. Because it works reliably on surfaces with varying reflectivity, it avoids misreads with worn boxes or dark plastics. The integrated evaluation capability simplifies logic setup, making it easier to trigger downstream actions. This strengthens the accuracy of indoor material-flow processes and reduces stoppages caused by missing detection.
3. Safety Buffering for Small Indoor Transport Vehicles
Compact pallet carriers or shuttle vehicles used inside warehouses need a dependable way to monitor the space directly ahead during slow, precise movements. The TiM100-3010200 can create a virtual protective zone that adapts as the vehicle moves. Its fast response helps detect unexpected objects within the 3-meter range before they become a hazard. Because it performs well even in brightly lit aisles or reflective floor conditions, unnecessary emergency stops are reduced. The lightweight construction benefits mobile platforms with strict weight and power constraints. This combination supports smoother transport flow, better operator protection, and more controlled navigation in narrow indoor work areas.
4. Indoor Environment Awareness for Service and Inspection Robots
Service robots used for cleaning, monitoring, or routine indoor tasks rely on consistent surface detection to guide their routes. The TiM100-3010200 provides a simple way for these robots to scan surrounding walls, fixtures, and temporary obstacles. With its 1° angular steps and wide field of view, the robot gains enough spatial understanding to adjust routes or avoid collisions without relying on heavier mapping systems. The sensor’s tolerance to bright lighting and reflective flooring helps maintain stable data in public spaces, lobbies, and wide halls. Its low power consumption supports long battery operation, making it suitable for robots expected to work through extended cycles.