Reinventing Surgical Energy Through Intelligent Engineering

Establishing the intelligent energy foundation for the future of surgery.
Explore Our Technologies

Core Technology Pillars

ReinnoMed Core Engineering Architecture
A system-level technology framework supporting next-generation ultrasonic surgical solutions.
01. Ultrasonic Energy Chain Design & Optimization

  • Ultrasonic generator structural design

  • High-frequency power control & dynamic tuning

  • System-level energy transmission efficiency optimization

02. Precision Transducer Control Technology

  • FEA simulation + experimental calibration

  • Vibration output characteristics optimization

  • Mechanical fatigue validation of transducer components

03. Amplitude & Shaft Structure Optimization

  • Structural modal simulation

  • Node position optimization

  • High-power energy amplification engineering

04. Blade Materials & Biocompatibility Research

  • Metallic material fatigue engineering

  • Microstructure optimization

  • Biocompatibility evaluation

05. System-Level Intelligent Feedback Technology

  • Frequency auto-tracking (stable output under complex anatomy)

  • Power auto-matching

  • Dynamic impedance feedback

  • Overload protection

Three Breakthrough Innovations

Engineered to solve the core challenges of ultrasonic surgery — sealing reliability, structural durability, and surgical efficiency.

1. Intelligent Algorithmic Vessel Sealing

Built on extensive biological experiments and tissue-simulation datasets, the system dynamically adjusts ultrasonic amplitude based on tissue thickness, density, hydration, and elasticity.

Clinical Effects:

  • Reliable sealing of ≤5 mm vessels

  • Faster sealing speed

  • Lower risk of insufficient sealing or overheating

Core Capability: Algorithm-driven, predictable vessel sealing.

2. Fishbone Anti-Fracture Engineering Method

A systematic Ishikawa-model engineering approach analyzing every root cause of shaft/blade fracture across four domains:

Design Factors

  • Shaft geometry, length, curvature

  • Shaft segmentation optimization

  • Transducer base-depth engineering

Material Factors

  • Alloy composition optimization

  • Microstructure engineering

Manufacturing Factors

  • Tolerance control

  • Screw burr removal

  • End-face precision polishing

Heat Treatment Factors

  • Fatigue-enhancement thermal processes

Result:
✔ Significant reduction in fracture risk
✔ Substantial improvement of fatigue life

3. ADV Side-Key Efficiency Boost

The ADV button instantly switches the device into a high-efficiency mode.

Benefits:

  • Faster dissection in blood-rich or thick tissues

  • Fewer touch interactions → smoother surgical flow

  • Future versions support ≤7 mm vessel coagulation (animal data)

Core Advantage: Higher efficiency with reduced surgeon workload.

Three Breakthrough Innovations

Engineered to solve the core challenges of ultrasonic surgery — sealing reliability, structural durability, and surgical efficiency.

Main Console — Five Key Design Features

  • TRT Tissue-Responsive Feedback Technology

  • Overload protection system

  • Automated module self-check (transducer / circuit / load)

  • Optimized HMI UI for glove-friendly operation

  • Acoustic output feedback system

Transducer — Three Engineering Features

  • Imported piezoceramic + titanium electrode

  • 5-layer electromagnetic shielding cable

  • Multi-seal structure tolerating ≥100 steam-sterilization cycles

Blade & Shaft — Four Structural Features

  • 360° rotating adjustment wheel

  • Anti-reflection matte shaft

  • Multi-functional jaw geometry

  • PTFE high-temperature insulation pad