Thermal Analysis Instruments
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| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | DSC 404 F1 Pegasus |
| Temperature Range | −150 to 2000 °C |
| Temperature Accuracy | ±0.1 K |
| Heating/Cooling Rate | 0–50 K/min |
| Sensor Types | Replaceable DSC (−150 to 1650 °C) and DTA (up to 2000 °C) |
| Vacuum Capability | High-vacuum sealed system |
| Gas Control | Integrated stainless-steel gas lines with metal-encapsulated mass flow controllers (MFCs) |
| Optional Automation | Stepper-motor-driven dual-furnace configuration and 20-position auto-sampler |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | DSC 404 F1 |
| Temperature Range | −150 °C to 1000 °C (extendable to 2000 °C with optional furnaces) |
| Heating/Cooling Rate | 0.001–50 K/min (up to 20 K/min for Rh furnace) |
| Vacuum Capability | Down to 10⁻⁴ mbar |
| Sensor Types | DSC (Cp-optimized up to 1600 °C), DTA (up to 2000 °C with W/Re thermocouples) |
| Compliance | ASTM E793, E1269, ISO 11357, USP <1158>, GLP/GMP-ready with audit trail (Proteus® software) |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | DSC 404 F3 Pegasus |
| Temperature Range | −150 to 2000 °C |
| Temperature Accuracy | ±0.1 K |
| Heating/Cooling Rate | 0–50 K/min |
| Brand | NETZSCH |
|---|---|
| Origin | Germany |
| Model | NETZSCH GABO EPLEXOR |
| Instrument Type | Dynamic Mechanical Analyzer (DMA/DMTA) |
| Temperature Range | –160 °C to 500 °C |
| Temperature Accuracy | ±0.1 °C |
| Static Force Range | up to 500 N (optional 1500 N) |
| Dynamic Force Range | ±25 N, ±100 N, ±150 N, or ±500 N |
| Displacement Range | 60 mm |
| Frequency Range | 0.01 Hz to 100 Hz (optional: 0.0001 Hz and 200 Hz) |
| Brand | NETZSCH |
|---|---|
| Origin | Germany |
| Model | NETZSCH-GABO METER |
| Instrument Type | Dynamic Mechanical Analyzer (DMA/DMTA) |
| Temperature Range | RT to 300 °C |
| Temperature Accuracy | ±0.1 °C |
| Maximum Applied Force | 5000 N |
| Displacement Range | 50 mm |
| Frequency Range | 0.1–50 Hz |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | GHP456 Titan |
| Measurement Principle | Guarded Hot Plate Method |
| Applicable Standards | ISO 8302, DIN EN 12667, DIN EN 12939, DIN EN 13163, ASTM C177, GB 10294 |
| Temperature Range | −160 °C to 600 °C |
| Sample Dimensions | 300 mm × 300 mm (max thickness 100 mm) |
| Thermal Conductivity Range | 0–2 W/(m·K) |
| Accuracy | ±2% |
| Repeatability | ±1% |
| Vacuum Capability | Yes |
| Control Sensors | 29 Pt-100 resistance thermometers |
| Footprint (L×W×H) | 3000 mm × 1500 mm × 2000 mm |
| Operating Environment | Ambient temperature laboratory conditions |
| Sample Throughput | Multi-sample sequential testing supported |
| Brand | NETZSCH |
|---|---|
| Origin | Germany |
| Model | HFM 446 L Lambda |
| Measurement Principle | Heat Flow Method (ASTM C518, ISO 8301, DIN EN 12667) |
| Cold/Hot Plate Temperature Range | –20 °C to +90 °C |
| Temperature Setpoints | Up to 10 independent points |
| Sample Dimensions (L×W×H) | 600 mm × 600 mm × 200 mm (max) |
| Thermal Conductivity Range | 0.002 – 2.0 W/(m·K) |
| Thermal Resistance Range | 0.05 – 8.0 m²·K/W |
| Accuracy | ±1% (relative to NIST-traceable reference materials) |
| Repeatability | ≤0.5% (RSD, under controlled ambient and sample conditioning) |
| Applied Sample Pressure Range | 0 – 5 kPa (motorized, programmable load control) |
| Thickness Resolution | <1 µm (integrated high-precision micrometer displacement sensor) |
| Integrated Peltier Cooling System | Yes |
| Optional Modules | Specific Heat Capacity (Cp) measurement via dual-plate calorimetry mode |
| Overall Dimensions (L×W×H) | 1000 mm × 1000 mm × 1500 mm |
| Compliance | Fully compatible with GLP/GMP data integrity requirements |
| Brand | NETZSCH |
|---|---|
| Origin | Germany |
| Instrument Type | Heat Flow Meter (HFM) |
| Model | HFM 446 M Lambda |
| Dimensions (L×W×H) | 500 mm × 500 mm × 500 mm (sample chamber footprint) |
| Temperature Range (Hot/Cold Plate) | –20 °C to +90 °C |
| Temperature Points | Up to 10 programmable setpoints |
| Sample Size | Up to 300 mm × 300 mm × 100 mm (L×W×H) |
| Thermal Resistance Range | 0.05 to 8.0 m²·K/W |
| Thermal Conductivity Range | 0.002 to 2.0 W/(m·K) |
| Accuracy | ±1% |
| Repeatability | 0.5% |
| Maximum Sample Load Pressure | 21 kPa |
| Compliance | ASTM C518, ISO 8301, DIN EN 12667, GB/T 10294 |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Instrument Type | Heat Flow Method |
| Dimensions (L×W×H) | 490 mm × 300 mm × 390 mm |
| Accuracy | ±1% |
| Thermal Conductivity Range | 0.002 – 2.0 W/(m·K) |
| Repeatability | 0.5% |
| Cold/Hot Plate Temperature Range | −20 °C to +90 °C |
| Temperature Setpoints | 10 |
| Sample Size Max | 200 mm × 200 mm × 50 mm |
| Thermal Resistance Range | 0.05 – 8.0 m²·K/W |
| Maximum Sample Load | 21 kPa |
| Optional Features | SMART MODE, Specific Heat Measurement Module, High-Conductivity Extension Kit |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | HMOR422 |
| Temperature Range | RT to 1450°C (optional up to 1500°C) |
| Sample Dimensions | 125 × 25 × 25 mm (standard) |
| Load Capacity | 1 N to 5000 N |
| Loading Rate | 1.25 N/s to 125 N/s (4 selectable steps) |
| Test Atmosphere | Air |
| Feed Mechanism | Continuous feed with preheating zone |
| Bending Mode | Three-point bending (standard) |
| Deformation Measurement | Differential high-precision displacement system (compatible with RUL/CIC421 architecture) |
| Compliance | ISO 5013 |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | LFA 427 |
| Measurement Principle | Laser Flash Method (LFM) |
| Temperature Range | –120 °C to 2800 °C (depending on furnace configuration) |
| Laser Source | Nd:Glass, energy-adjustable pulse |
| Thermal Conductivity Range | 0.1–2000 W/(m·K) |
| Accuracy | ±3% |
| Repeatability | ±2% |
| Vacuum Level | ≤10⁻⁵ mbar |
| Sample Dimensions | Square: 8×8 mm, 10×10 mm |
| Circular | Ø6, Ø10, Ø12.7, Ø20 mm |
| Thickness | 0.1–6 mm |
| Sample Types | Solids, powders, thin films, liquids (with specialized holders) |
| Furnace Options | Dual-furnace capability |
| Pulse Control | Software-adjustable pulse width |
| Key Technology | PulseMapping™ |
| Atmosphere Control | Vacuum, inert (Ar, N₂), or reactive gases (e.g., O₂, CO₂) |
| Sample Holders | Graphite, alumina, silicon carbide |
| Dimensions (L×W×H) | 800 mm × 800 mm × 1900 mm |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | LFA 467 HyperFlash HT |
| Measurement Principle | Laser Flash Method (LFA) |
| Temperature Range | RT to 1250 °C |
| Thermal Conductivity Range | 0.1 – 4000 W/(m·K) |
| Accuracy | ±3% |
| Repeatability | ±2% |
| Pulse Source | Adjustable-energy xenon lamp, pulse width <2 µs |
| Detection Rate | up to 2 MHz |
| Sample Forms | Solid, liquid, powder, thin film |
| Atmosphere Options | Inert or oxidative (vacuum-tight chamber) |
| Dimensions (L×W×H) | 600 mm × 500 mm × 600 mm |
| Sample Capacity | Up to 4 positions with independent thermocouples |
| Compliance | ASTM E1461, ASTM E2585, ISO 22007-4, ISO 18755, ISO 13826, DIN EN 821-2, DIN 30905, DIN EN 1159-2 |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | LFA 467 HyperFlash Laser |
| Measurement Principle | Laser Flash Method (ASTM E1461, ISO 13826, DIN EN 821-2) |
| Temperature Range | −100 °C to 500 °C (single furnace) |
| Light Source | Adjustable-energy Xenon Flash Lamp (max. 10 J/pulse) |
| Detection | Non-contact IR Detector with ZoomOptics™ |
| Data Acquisition Rate | Up to 2 MHz |
| Sample Capacity | 16-position Automated Sample Changer |
| Sample Diameter | 6–25.4 mm (including square) |
| Sample Thickness | 0.01–6 mm (thickness limit depends on thermal diffusivity) |
| Thermal Diffusivity Range | 0.01–1000 mm²/s |
| Thermal Conductivity Range | <0.1–2000 W/(m·K) |
| Atmosphere Options | Inert, oxidizing, static/dynamic, vacuum-compatible |
| Cooling | Integrated Auto-refill Liquid Nitrogen System for Detector & Furnace |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | LFA 717 HyperFlash |
| Measurement Principle | Laser Flash Method (LFA) |
| Temperature Range | -100 °C to 500 °C |
| Thermal Conductivity Range | 0.1 – 4000 W/(m·K) |
| Accuracy | ±3% |
| Repeatability | ±2% |
| Sample Forms | Solid, Liquid, Powder, Thin Film |
| Atmosphere Options | Inert or Oxidizing |
| Sample Capacity | Up to 16 positions with automated carousel |
| Dimensions (L×W×H) | 600 mm × 500 mm × 600 mm |
| Data Acquisition Rate | 2 MHz |
| Compliance Standards | ASTM E1461, ASTM E2585, ISO 22007-4, ISO 18755, ISO 13826, DIN EN 821-2, DIN 30905, DIN EN 1159-2 |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | MMC274 Nexus |
| Instrument Type | Accelerating Rate Calorimeter (ARC) |
| Measurement Mode | Adiabatic Calorimetry |
| Temperature Range | RT to 500°C |
| Temperature Resolution | 0.01°C |
| Pressure Range | 0–100 bar |
| Heating Rate | 0–2°C/min |
| Tracking Rate | 0–50°C/min (standard) or 0–250°C/min (high-speed module) |
| Temperature Control Accuracy | ±0.01°C |
| Pressure Accuracy | ±0.01 bar |
| Sample Volume | 0.1–2.5 mL |
| Heat Flow Sensitivity | 25–250 µW/g (mode-dependent) |
| Scan Sensitivity | 0.002°C/min |
| Sample Types | Solids, Liquids, Powders |
| Optional | Custom sample vessels, button-cell test fixture, VariPhi™ thermal compensation technology |
| Brand | NETZSCH |
|---|---|
| Origin | Germany |
| Model | NanoTR |
| Measurement Principle | Laser-based Thermal Reflectance (Time-Domain Thermoreflectance, TDTR) |
| Instrument Type | Thin-Film Thermal Conductivity Analyzer |
| Temperature Range | Ambient (RT) to 300 °C (optional heating stage) |
| Sample Dimensions | 10 × 10 mm to 20 × 20 mm |
| Film Thickness Range | 30 nm to 20 µm (dependent on material and measurement mode) |
| Thermal Diffusivity Range | 0.01 to 1000 mm²/s |
| Thermal Conductivity Range | 0.1 to 2000 W/(m·K) |
| Accuracy | ±5% |
| Repeatability | ±5% |
| Pulse Width | 1 ns |
| Probe Beam Diameter | 100 µm |
| Pump Laser Power | 100 mW |
| Measurement Modes | RF (Rear-Heating/Forward-Detection) and FF (Front-Heating/Forward-Detection) |
| Footprint (L×W×H) | 600 mm × 500 mm × 700 mm |
| Compliance | ISO 13826, ASTM E1461 (adapted for thin-film extension), NIST-traceable calibration protocols |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | PicoTR |
| Measurement Principle | Time-Domain Thermoreflectance (TDTR) |
| Instrument Type | Thin-film thermal property analyzer |
| Dimensions (L×W×H) | 600 mm × 500 mm × 700 mm |
| Accuracy | ±5% |
| Thermal Conductivity Range | 0.1 – 2000 W/(m·K) |
| Repeatability | ±5% |
| Temperature Range | Ambient (RT) to 500 °C (optional stage) |
| Measurement Modes | RF (rear-heating/front-detection) and FF (front-heating/front-detection) |
| Sample Size | 10 mm × 10 mm to 20 mm × 20 mm |
| Film Thickness Range | 10 nm – 900 nm (material- and mode-dependent) |
| Thermal Diffusivity Range | 0.01 – 1000 mm²/s |
| Pump Laser Pulse Width | 0.5 ps |
| Probe Beam Diameter | 45 µm |
| Laser Power | 20 mW |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | RUL/CIC421 |
| Temperature Range | RT to 1600°C (standard), up to 1700°C (optional) |
| Sample Dimensions | Ø50 mm × 50 mm height |
| Deformation Measurement Range | 20 mm |
| Resolution | 5 nm |
| Load Range | 1 N to 1000 N |
| Atmosphere Options | Air or inert/protective gas (model-dependent) |
| Sample Geometry Requirement | Cylindrical specimen with coaxial 12.5 mm central bore |
| Measurement Principle | Differential displacement sensing under controlled load and temperature |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA 2500 Regulus |
| Heating Rate | 0–100 °C/min |
| Temperature Range | RT to 1100 °C (standard furnace) / RT to 1600 °C (high-temperature furnace) |
| Temperature Stability | ±0.3 K |
| Maximum Sample Mass | 250 mg |
| Atmosphere Options | Oxidizing, Reducing, Inert, Vacuum (dynamic or static) |
| Gas Control | Integrated Mass Flow Controllers (MFCs), software-regulated |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA 2500 Regulus |
| Temperature Range | RT to 1100°C (low-temperature furnace) / RT to 1600°C (high-temperature furnace) |
| Heating Rate | 0.001–100 °C/min (RT–1100°C) |
| Temperature Stability | ±0.1 °C |
| Maximum Sample Mass | 1 g |
| Thermogravimetric Resolution | 0.03 µg |
| Temperature Accuracy | ±0.3 K |
| Atmosphere Options | Inert, oxidizing, reducing, vacuum (dynamic or static) |
| Vacuum Tightness | ≤10⁻⁴ mbar (≤10⁻² Pa) |
| Gas Control | Integrated mass flow controllers (MFCs) with software-defined flow programming |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA 449 F3 Jupiter |
| Temperature Range | −150 to 2400 °C |
| Heating Rate | 0–50 °C/min (standard) |
| Temperature Stability | ±0.3 K |
| Maximum Sample Mass | 35 g |
| Balance Resolution | 0.1 µg |
| Vacuum Level | 10⁻⁴ mbar |
| Atmosphere Options | Oxidizing, Reducing, Inert, Vacuum |
| Optional Modules | TMDSC, Tau-R® Cp Calibration, BeFlat® Baseline Optimization, ASC Auto-sampler (20 positions), Coupling to FTIR/MS/GC-MS, Steam Furnace, Corrosive Gas Kit |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA 509 Jupiter Classic |
| Temperature Range | RT to 1600 °C |
| Heating Rate | 0.001–50 °C/min |
| Max Sample Mass | 35 g |
| Atmosphere Options | Inert, Oxidizing, Static, Dynamic, Vacuum, Corrosive (optional) |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA 509 Jupiter Supreme |
| Temperature Range | –150 °C to 2000 °C |
| Maximum Sample Mass | 5 g |
| Atmosphere Options | Inert, Oxidizing, Static, Dynamic, Vacuum, Corrosive (optional) |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA-GC-MS |
| Operating Temperature Range | RT to 350 °C |
| Coupling Interface | Heated Transfer Line (up to 350 °C) with Six-Port Valve Box |
| Trigger Mode | Event-Driven Synchronization |
| Software | Fully Integrated, Real-Time Hardware Synchronization |
| Standalone Operation | Yes (STA and GC-MS operate independently) |
| Compliance | Designed for GLP/GMP environments |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA/TG-FTIR |
| Operating Temperature Range | RT to 350 °C |
| Gas Transfer Path | Heated Entirely (Prevents Condensation) |
| Gas Residence Time | Short |
| Carrier Gas Flow Rate | Low (Minimizes Dilution Effect) |
| Measurement Mode | Synchronized Simultaneous STA–FTIR Acquisition or Independent Operation |
| Software Architecture | Fully Integrated, Core-Embedded Control with Hardware-Automated Triggering |
| Sample Introduction | Top-Loading Vertical TGA Configuration (Ensures Quantitative Evolved Gas Transfer) |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA/TG-FTIR-GC-MS |
| Operating Temperature Range | RT to 350 °C |
| Gas Transfer Path | Heated (up to 350 °C) |
| Coupling Architecture | Parallel FTIR and GC-MS interfaces |
| Sample Introduction | Top-loading vertical TGA configuration |
| Trigger Mode | Event-driven hardware synchronization |
| Software | Fully integrated, real-time synchronized control platform |
| Compliance Support | ASTM E1131, ISO 11358, USP <621>, GLP-compliant audit trail capability |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA/TG-FTIR-MS |
| Mass Range | 1–300 amu |
| Transfer Line Temperature | RT to 350 °C |
| Gas Path | Heated, Condensation-Free |
| Detection Sensitivity | High |
| Gas Residence Time | Short |
| Carrier Gas Dilution Effect | Minimal |
| FTIR & MS Operation Modes | Simultaneous or Standalone |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | STA/TG-MS |
| Mass Range | 1–300 amu (capillary interface) / 1–1024 amu (SKIMMER® interface) |
| Interface Temperature Range | RT–350 °C (capillary) / RT–2000 °C (SKIMMER®) |
| Sample Introduction | Top-loading vertical TGA configuration |
| Gas Transfer | Heated capillary or SKIMMER® transfer line, fully temperature-controlled |
| Data Synchronization | Hardware-triggered real-time coupling with dual acquisition control |
| Software Architecture | Fully integrated native-core platform with synchronized thermal and MS data acquisition |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | TAURUS GHP 500 |
| Measurement Principle | Guarded Hot Plate (GHP) |
| Standard Compliance | ISO 8302, ASTM C177, EN 12664, EN 12667, EN 12939, EN 1946-2 |
| Thermal Conductivity Range | 0.005 – 2.0 W/(m·K) |
| Accuracy | ±1.0% |
| Repeatability | ±0.5% |
| Sample Thickness (Single-Sided) | 15 – 200 mm |
| Sample Thickness (Double-Sided) | 2 × 15 – 100 mm |
| Sample Area | 100 × 100 – 300 × 300 mm (optional 500 × 500 mm) |
| Hot Plate Temperature Range | −5 to 70 °C |
| Cold Plate Temperature Range | −15 to 60 °C |
| Enclosure Dimensions (H × W × D) | 186 × 75 × 75 cm |
| Brand | Netzsch |
|---|---|
| Origin | Germany |
| Model | TAURUS GHP 600 |
| Measurement Principle | Guarded Hot Plate Method |
| Sample Capacity | Multiple sequential tests |
| Operating Environment | Ambient temperature |
| Dimensions (H×W×D) | 186 × 85 × 85 cm |
| Accuracy | ±1.0% |
| Thermal Conductivity Range | 0.005 – 2.0 W/(m·K) |
| Repeatability | ±0.5% |
| Compliant Standards | ISO 8302, ASTM C177, EN 1946-2, EN 12664, EN 12667, EN 12939 |
| Sample Thickness | 15–200 mm (single-plate), 15–100 mm per plate (double-plate) |
| Sample Area | 100×100 – 300×300 mm² (standard), up to 600×600 mm² (optional) |
| Hot Plate Temperature Range | –5 to 70 °C |
| Cold Plate Temperature Range | –15 to 60 °C |