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DSC-1200 High-Temperature Differential Scanning Calorimeter with 1200°C Range, High Sensitivity, and Touch Screen
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DSC-1200 High-Temperature Differential Scanning Calorimeter with 1200°C Range, High Sensitivity, and Touch Screen
| MOQ: | 1 set |
| Price: | Negotiable |
| Standard Packaging: | Plywood packing |
| Delivery Period: | 5~8 working days |
| Payment Method: | L/C,T/T |
| Supply Capacity: | 500 sets/month |
Detail Information
Place of Origin
China
Brand Name
SHUOBODA
Certification
ISO/CE
Model Number
DSC-1200
Temperature Range:
Room Temperature~1200°C
Temperature Resolution:
0.01°C
Temperature Fluctuation:
±0.01°C
Temperature Repeatability:
±0.1°C
Heating Rate:
0.1~100°C/min
Curve Scan:
Heating Scan, Constant Temperature Scan
Highlight:
1200°C Differential Scanning Calorimeter
,High Sensitivity DSC
,Touch Screen High-Temperature DSC
Product Description
DSC-1200 High-Temperature Differential Scanning Calorimeter
The DSC-1200 High-Temperature Differential Scanning Calorimeter detects changes in temperature difference (heat flux) between a sample and reference over time or temperature. When both sample and reference are in a homogeneous temperature zone without thermal changes, temperatures change at a predetermined rate. However, when the sample undergoes transitions like melting, heat is absorbed to maintain the process, creating a temperature difference between sample and reference. This differential data forms the basis for DSC analysis.
Featuring an imported material sensor with high sensitivity, the instrument includes shielded signal acquisition circuits for strong anti-interference capability and exceptional baseline stability.
This touch screen differential scanning calorimeter supports glass transition temperature testing, phase transition analysis, melting and enthalpy measurement, product stability assessment, solidification studies, oxidation induction period testing, and specific heat capacity determination.
Technical Features
- Advanced furnace structure ensures superior baseline performance and measurement accuracy
- Indirect conduction heating provides high uniformity and stability while reducing pulse radiation
- Ultra-high sensitivity with temperature detection to 0.001℃ for improved measurement precision
- Dual-control system (host and software) for convenient operation and enhanced testing efficiency
- Automatic switching between two atmosphere flow paths with rapid stabilization
- Additional protective gas input for enhanced experimental flexibility
- 7-inch color touchscreen display with high clarity and comprehensive information presentation
- High-sensitivity constantan sensor with excellent temperature and corrosion resistance
- Multi-segment temperature programming for heating, isothermal control, and cooling cycles
- Real-time spectral recording with online data analysis and direct report generation
- Custom instrument configurations available for specialized testing requirements
Technical Parameters
| Parameter | Specification |
|---|---|
| Model | DSC-1200 |
| Temperature Range | Room temperature to 1200°C |
| Temperature Resolution | 0.01°C |
| Temperature Fluctuation | ±0.01°C |
| Temperature Repeatability | ±0.1°C |
| Heating Rate | 0.1 to 100°C/min |
| Curve Scan Modes | Heating scan, constant temperature scan |
| Constant Temperature Duration | Program setting ≤24h |
| Temperature Control Method | PID temperature control with automated programming |
| DSC Range | 0 to ±1000mW |
| DSC Resolution | 0.01uW |
| DSC Accuracy | 0.01mW |
| Power Supply | AC220V/50Hz or customized |
| Atmosphere Control Gases | Nitrogen, oxygen (automatic switching) |
| Gas Flow Rate | 0-300mL/min |
| Gas Pressure | ≤1MPa |
| Display Mode | 24bit color, 7-inch LCD touch screen |
| Data Interface | Standard USB interface |
| Calibration Standards | Equipped with standard materials (indium, tin, lead) for user calibration |
| Thermocouple Configuration | Multiple thermocouple sets for sample and ambient temperature monitoring |
| Calibration Function | Multi-point calibration for precise testing across sample types |
| Software Capabilities | Adjustable data collection frequency with EXCEL and PDF report export |
| Data Acquisition Frequency | 33 points per second, multi-point adjustable |
| Flow Meter | Float flow meter (mass flow meter optional) |
| Sensor Type | Type K |
| Sensor Material | Nickel-chromium-scandium copper |
Sample Test Patterns
Oxidation Induction Period Testing for PE, PPR and Other Pipes
Oxidation Induction Time (OIT) measurement involves heating samples to specified temperatures under nitrogen atmosphere, then switching to oxygen. Material oxidation releases detectable heat, analyzed by software to determine OIT values. This parameter is critical for assessing oxidative decomposition resistance in buried plastic pipes.
Glass Transition Testing of Resins and Other Materials
Glass transition occurs when amorphous polymers transition between high elastic and glass states during heating or cooling. The transition temperature is a fundamental polymer property, though glass transitions also occur in some small molecule compounds.
Material Melting Point and Enthalpy Testing (Thermal Stability)
Melting point analysis identifies the temperature where solids transition to liquids, with multi-component mixtures displaying multiple peaks in the thermal analysis curve.
Curing Testing of Adhesives and Other Materials
Curing analysis monitors the transformation from low to high molecular weight compounds, resulting in increased material strength upon completion.
Applications
- Advanced Ceramics and Inorganic Non-Metallic Materials: Analysis of crystal transformation, sintering densification, and high-temperature decomposition in materials like silicon nitride, silicon carbide, and zirconium oxide ceramics.
- Curie Point or Superconducting Critical Temperature: Study of thermally induced property changes in functional ceramics including piezoelectric ceramics and high-temperature superconducting materials.
- Metals and High-Temperature Alloys: Investigation of solid solution decomposition, precipitate formation, and oxidation behavior in nickel-based superalloys, titanium alloys, and intermetallic compounds.
- High-Temperature Composite Materials: Thermal stability assessment and oxidation kinetic parameter quantification for carbon fiber reinforced ceramic matrix composites and high-temperature coating materials.
- Special Functional Materials: Analysis of high-temperature superconducting materials, geological/mineral materials, and chemical/energy materials including petroleum coke, asphalt, and solid oxide fuel cell electrolytes.
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