Servo Electric Axial Shake Table BI-7350
The BI-7350 Servo Electric Table Top Shake Table is a compact, plug-and-play vibration simulation system tailored for structural testing, component qualification, and earthquake motion reproduction. With an integrated servo-electric actuator, high-fidelity motion control, and digital feedback mechanisms, it delivers precise, repeatable dynamic loads up to 10 Hz on a rigid tabletop platform.
Engineered for academic labs, R&D units, and OEM product developers, this system features a single-footprint design with no need for grouting, hydraulic utilities, or external vibration isolation. Its robust actuator performance, high data acquisition rate (up to 8 kHz), and intuitive PC software make it ideal for fatigue life assessment, seismic qualification, and dynamic structural analysis in both academic and industrial environments.
Specifications of Servo Electric Axial Shake Table BI-7350
| Feature | Details |
|---|---|
| Payload Capacity | 100 kg |
| Table Stroke | 300 mm |
| Table Size | 0.5 x 0.5 meters |
| Mounting Surface | Threaded mounting holes for specimen fixation |
| Linear Bearings | Low friction, wear-resistant design |
| Displacement Measurement | Digital, encoder-based |
| Operating Frequency | Up to 10 Hz |
| Noise and Performance | Zero backlash, virtually silent operation |
| DSP Performance | 3648 MIPS DSP, 2746M FLOPS, 24-bit analog conversion |
| Data Acquisition | 32-bit with 40-bit servo-loop, up to 8 kHz sampling |
| Control Software | User-friendly application interface with waveform control |
| Installation | Single footprint, no grouting required |
| Power Supply | 220V, 50Hz, single phase – plug and play |
Key Features of Servo Electric Axial Shake Table BI-7350
Payload capacity of 100 kg, supporting a wide variety of specimens and model configurations.
Table stroke of 300 mm for simulating real-world displacements in seismic or structural response studies.
Compact table size of 0.5 x 0.5 meters, perfect for bench-top applications and confined lab spaces.
Low friction, wear-resistant linear motion bearings for smooth, long-life operation with minimal maintenance.
Threaded mounting holes on the tabletop allow easy and secure installation of test specimens and fixtures.
Digital displacement measurement system provides accurate tracking and feedback of platform motion.
Adaptable for a wide range of dynamic tests, from structural verification to soil liquefaction studies.
Zero backlash performance ensures precise, jitter-free motion replication during high-frequency simulations.
Quiet operation suitable for clean rooms, NVH labs, and shared lab environments.
Operating frequency up to 10 Hz, sufficient for most civil, structural, and vibration qualification scenarios.
State-of-the-art digital control platform powered by 3648 MIPS DSP and 2746M FLOPS floating point processing.
24-bit analog data conversion, 32-bit data acquisition, and 40-bit servo-loop calculations for maximum accuracy.
High-speed data acquisition up to 8 kHz ensures detailed response capture for fast transient events.
User-friendly application software with programmable motion profiles, waveform generation, real-time monitoring, and auto-reporting.
Single footprint, no grouting required, making it portable and easy to install in most lab environments.
Runs on standard 220V, 50 Hz single-phase supply, offering true plug-and-play functionality without external dependencies.
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Application of Servo Electric Axial Shake Table BI-7350
Structural and component qualification testing in research laboratories for verifying material and system performance under dynamic loads.
Accelerated reliability testing of mechanical assemblies and industrial products subjected to repeated motion and vibration.
Soil liquefaction testing under cyclic loading conditions to simulate seismic-induced ground behavior.
Earthquake motion simulation for small-scale models of buildings, bridges, or substructures in seismic zones.
Seismic qualification testing for critical components such as electronics, piping systems, and civil infrastructure.
Dynamic response studies of reinforced soil slopes to assess stability under earthquake-like conditions.
Evaluation of reinforced soil retaining walls, analyzing structural integrity under horizontal shaking forces.
Testing of wrap-faced reinforced soil retaining wall systems, assessing resilience and deformation patterns in geotechnical simulations.