Repeated Liquid Level Detection

① Addressing Liquid Surface Fluctuations and Interference

Minor liquid surface fluctuations caused by temperature changes, reagent evaporation, or mechanical vibrations can lead to false readings with single-point detection. Repeated detection validates measurements through multi-cycle verification, eliminating errors and enhancing positioning reliability.

② Preventing Equipment Damage and Sample Loss

If initial detection fails due to pipette tip tilt or bubble interference, repeated detection adjusts immersion depth in real time to avoid tip damage from bottom contact or reagent waste from empty aspiration.

③ Reducing Tip Consumption

Maximizes tip utilization by enabling multi-cycle detection with a single tip, optimizing consumable costs while streamlining workflows to minimize waste and boost pipetting efficiency.

Capacitive/Pressure Hybrid Liquid Level Detection

Capacitive sensors detect conductive liquids; pressure sensors validate liquid resistance.

① High Precision and Stability

Dual detection limits liquid level positioning errors to ±0.5 mm, with real-time calibration to neutralize environmental interference (e.g., humidity drift, electromagnetic noise).

② Enhanced Fault Tolerance

Multi-sensor collaboration identifies abnormal liquid levels, triggering immediate alerts and operation pauses to reduce equipment failure rates.

③ Increased Experimental Efficiency

High-speed pipetting workflows eliminate redundant validation steps, cutting overall process time.

④ Compatibility with Complex Liquid Properties

Adapts to diverse liquid characteristics—conductivity (polar reagents), viscosity (blood samples), transparency (clear buffers)—through dual/multi-mode detection technology.

Auto Tip Ejection/Verification

① Cross-Contamination Prevention

Eliminates accidental liquid aspiration without tips, critically reducing contamination risks in high-throughput workflows like PCR and drug screening.

② Operational Efficiency Boost

Batch tip ejection in multi-channel pipetting scenarios reduces per-cycle operation time by over 30%, supporting continuous high-volume processing.

③ Extended Equipment Lifespan

Precision-controlled ejection mechanics minimize mechanical wear on pump components.

Single-Aspiration Multi-Dispensing (SAM)

① Workflow Optimization

Reduces repetitive aspiration-dispensing cycles (e.g., multi-well plate aliquoting) by ~40%.

② Residual Volume Control

Segmented dispensing minimizes liquid retention on tip walls, preserving high-value reagents.

9mm Parallel Configuration

Ultra-slim 9mm profile enables dense integration of pipettors (8-/16-channel) within compact footprints while maintaining compatibility with standard deep-well plates. Direct channel-to-well alignment eliminates positional calculation errors.

Piston-Style Cylinder Design: Superior Linearity and Precision

The piston-driven system achieves superior linear performance through precise synchronization between piston movement trajectories and motor/stepper drive signals, enabled by software-programmable compensation of displacement-to-flow curves. This advanced control architecture eliminates the volumetric inconsistencies seen in traditional plunger designs, which rely on single-action mechanisms and external seals. Unlike piston systems, plungers require external forces for return strokes, leading to flow decay at the end of the dispensing cycle and degraded linearity due to inherent mechanical limitations in their sealing structures.

Stay tuned for more information on new features...