Designed for university laboratories and research institutions, High-temperature High-pressure reactors integrate advanced magnetic drive technology and robust safety features, making them ideal for precision chemical synthesis and material development. Below is a detailed breakdown of their structure and advantages tailored for academic applications.
一.Core Components
1.Magnetic Drive System
• Face-mounted rare earth magnetic stirrer ensures zero leakage and maintenance-free operation.
• Supports torque up to 0.25 N·m with adjustable speeds (0–1,200 RPM), ideal for sensitive reactions.
2.Reactor Vessel
• Material options: 304/316L stainless steel, Hastelloy (C-276/B-2), or customized alloys.
• Standard capacity: 50 mL–5 L (expandable to 20 L for pilot studies).
3.Safety & Control Accessories
• High-precision pressure gauge (0–40 MPa range).
• Explosion-proof rupture disc (automatically activates at 110% rated pressure).
• Dual gas valves (inlet/outlet) with 3mm/6mm Swagelok fittings.
二.Key Features for Lab Environments
1.Leak-Free Design
Permanent magnetic coupling eliminates mechanical seal failures, critical for handling toxic gases (e.g., H₂, CO) in hydrogenation or catalysis experiments.
2.Extreme Condition Tolerance
• Withstands temperatures up to 350°C and pressures up to 35 MPa.
• Vacuum compatibility (≤10⁻³ Pa) for material synthesis under inert atmospheres.
3.Modular Configuration
Optional add-ons:
• Real-time temperature probe (PT100 sensor, ±0.5°C accuracy).
• Cooling fins for rapid heat dissipation.
• Multi-port lids for sampling, gas injection, or pressure monitoring.
4.Flexible Heating Methods
• Compatible with oil baths, electric jackets, or external circulation systems.
• Uniform thermal distribution (±2°C variance across the vessel).
三.Academic Use Cases
• Chemistry Labs: Catalytic hydrogenation, polymerization, nanomaterial synthesis.
• Pharmaceutical Research: Precursor compound development, solvent-free reactions.
• Energy Studies: Battery material testing (e.g., solid-state electrolytes), CO₂ conversion.
四.Why Choose Lab-Grade Reactors?
• Safety Compliance: Meets ISO 9001 and CE standards, with automatic pressure relief for student-operated projects.
• Cost Efficiency: Durable 316L steel construction reduces long-term maintenance costs.
• Scalability: Seamless transition from bench-scale (100 mL) to pilot systems.
Technical Specifications Table
|
Parameter |
Specification |
|
Max Temperature |
350°C (662°F) |
|
Pressure Range |
0–35 MPa (5,076 psi) |
|
Stirring Accuracy |
±1 RPM |
|
Vessel Finish |
Mirror polish (Ra ≤0.2 μm) |
|
Standard Ports |
3× 1/8" NPT threads |
Ideal for graduate-level research and industrial-academic collaborations, these reactors combine operational safety with precision control. Custom configurations are available to meet specific protocol requirements, including PTFE liners for corrosive media or quartz windows for in-situ observation.
Contact our engineering team for tailored solutions to enhance your lab’s research capabilities.
Post time: Mar-31-2025
