| Description | How Fast Is Heat Transferred?
The LFA 717 HyperFlash® HT is a state-of-the-art instrument designed to accurately measure the thermal diffusivity of various materials. With its advanced calculation models, it is at the forefront of scientific innovation, ensuring accurate results essential for How Fast Is Heat Transferred?
The LFA 717 HyperFlash® HT is a state-of-the-art instrument designed to accurately measure the thermal diffusivity of various materials. With its advanced calculation models, it is at the forefront of scientific innovation, ensuring accurate results essential for materials analysis.
- Measurements up to 1250°C: The LFA 717 HyperFlash® HT is an advanced thermal analysis instrument that uses the latest xenon flash lamp technology to measure temperatures up to 1250°C. This innovative system eliminates the need for laser classification, making it easy to use and compliant with safety regulations.
- Broad sample range: The LFA 717 HyperFlash® can accommodate a wide range of sample materials, including both round and square shapes.
- Vacuum-tight furnace for controlled atmosphere: The vacuum-tight furnace is designed to create controlled atmospheres that effectively prevent oxidation during heating processes. The vacuum-tight furnace features an internal pump that automatically evacuates the chamber prior to each measurement, maintaining a defined atmosphere for accurate results. It also provides additional ports for external pumping equipment, increasing operational flexibility.
- Time-saving mini-tube furnaces: With the ability to support rapid heating rates of up to 50 K/min, the four alumina mini-tube furnaces provide exceptional sample throughput across the temperature range for unmatched test speed. Each of the four sample positions is equipped with its own thermocouple, resulting in fast stabilization times. With the ability to measure ten temperature steps from RT to 1250°C in just one hour, these furnaces are designed for efficiency and precision, making them ideal for demanding applications in laboratories and research facilities.
- Advanced corrections specifically for thin and highly conductive samples: The latest version of our analysis software introduces an enhanced analysis pulse correction feature designed for high-precision applications where exceptional time resolution is critical. This enhancement is particularly beneficial when analyzing thin and highly conductive samples, and in situations where the light pulse coincides with the thermal response of the sample.
The LFA 717 HyperFlash® HT is an essential tool for researchers and industries requiring precise thermal property measurements, making it an invaluable asset in the field of materials science.... Read More | Innovative Guarded Hot Plate System GHP 456 Titan® for Determination of Thermal Conductivity of Insulations
The GHP 456 Titan® is the ideal tool for researchers and scientists in the field of insulation testing. Based on the well-known, standardized guarded hot plate technique (e.g. ISO Innovative Guarded Hot Plate System GHP 456 Titan® for Determination of Thermal Conductivity of Insulations
The GHP 456 Titan® is the ideal tool for researchers and scientists in the field of insulation testing. Based on the well-known, standardized guarded hot plate technique (e.g. ISO 8302, ASTM C177, DIN EN 12939 or DIN EN 12667), the system features unrivalled performance over an unmatched temperature range.
Combining state-of-the-art technology with the highest quality standards, NETZSCH has designed a robust and easy-to-operate instrument, featuring unparalleled reliability and optimum accuracy over a broad temperature range.
The NETZSCH GHP 456 Titan® is the new benchmark in Guarded Hot Plate measurements.... Read More | Three Instrument Versions for Every Sample Size: Small, Medium, and Large The HFM 706 Lambda Series offers three versatile instrument versions designed to fit your unique sample dimensions perfectly. Whether you're testing small laboratory specimens or large industrial materials, our models ensure Three Instrument Versions for Every Sample Size: Small, Medium, and Large The HFM 706 Lambda Series offers three versatile instrument versions designed to fit your unique sample dimensions perfectly. Whether you're testing small laboratory specimens or large industrial materials, our models ensure precise and reliable measurements.
- The HFM 706 Lambda Small is Ideal for Samples up to 203 mm x 203 mm x 51 mm in Height.
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The HFM 706 Lambda Medium is Ideal for Samples up to 305 mm x 305 mm x 105 mm in Height.
- The HFM 706 Lambda Large is Ideal for Samples up to 611 mm x 611 mm x 200 mm in Height.
Features:- High-Sensitivity Heat Flux Transducers for Accurate Thermal Analysis - The HFM 706 Lambda Series is equipped with dual heat flux transducers that continuously monitor heat flow with exceptional sensitivity and accuracy. Our advanced calibration process uses reference materials with known Thermal Conductivity. By combining multiple calibration methods, we guarantee a high measurement precision. This way, you get reliable, reproducible data, every time.
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Achieve Faster Results and Enhanced Performance with Modern Peltier Technology - Experience precise temperature management with our advanced Peltier temperature control system for hot and cold plates. Powerful, bidirectional Peltier elements paired with an external chiller ensure rapid and accurate heating and cooling of each plate. This optimized temperature control quickly achieves thermal equilibrium, providing reliable, consistent data in less time and boosting your laboratory’s productivity and efficiency.
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Optimized Test Chamber Design Provides Reliable Results and Minimal Condensation -Our innovative test chamber minimizes environmental interference and significantly reduces reduces condensation effects inside the testing chamber and on the plate surfaces. For even better control, an optional dry gas purge feature maintains optimal humidity levels, creating consistent test conditions and enhancing measurement reliability.
... Read More | Outstanding attributes of the LFA 427 are high precision and reproducibility, short measuring times, variable sample holders and precisely adjustable atmosphere conditions in the application range from -120°C to 2800°C. The LFA 427 is the most powerful LFA system for use in research & development.
Outstanding attributes of the LFA 427 are high precision and reproducibility, short measuring times, variable sample holders and precisely adjustable atmosphere conditions in the application range from -120°C to 2800°C. The LFA 427 is the most powerful LFA system for use in research & development.
Laser Flash technique over the broadest temperature range Thermal conductivity and thermal diffusivity are the most important thermophysical material parameters for characterizing the thermal transport properties of a material or component. The Laser Flash technique is currently the most widely accepted method for precise measurement of the thermal diffusivity and the LFA 427 is the number one instrument on the world market. High precision and reproducibility, short measurement times, variable sample holders and defined atmospheres are outstanding features of LFA measurements over the entire application range from -120°C to 2800°C.
A special version with a pyrometer allows measurements from room temperature to 2800°C.
The thermal conductivity of disk-shaped samples of ceramic, glass, metals, melts and liquids, powders, fibers and multi-layer materials ranging from vacuum insulation panels to diamonds is measured with equal speed and accuracy. The temperature-dependent measured thermal diffusivity value along with the corresponding specific heat (DSC 404 F1 Pegasus®) and density (DIL 402 C) data are used to calculate the thermal conductivity. The laser power, pulse width, gas and vacuum are variable over a wide range, making it possible to set the optimum measurement conditions for the very different sample properties.
The LFA 427 is the most powerful and versatile LFA system for research and development as well as all applications involving characterization of standard and high-performance materials in automobile manufacturing, aeronautics, astronautics and energy technology.... Read More | FOR HIGHLY ACCURATE AND FAST THERMAL DIFFUSIVITY MEASUREMENTS
The LFA 717 HyperFlash® is a state-of-the-art instrument designed to accurately measure the thermal diffusivity of various materials. With its advanced calculation models, it is at the forefront of scientific innovation, ensuring FOR HIGHLY ACCURATE AND FAST THERMAL DIFFUSIVITY MEASUREMENTS
The LFA 717 HyperFlash® is a state-of-the-art instrument designed to accurately measure the thermal diffusivity of various materials. With its advanced calculation models, it is at the forefront of scientific innovation, ensuring accurate results essential for materials analysis.
- Broad sample range: The LFA 717 HyperFlash® can accommodate a wide range of sample materials, including both round and square-shaped specimens. It features an automatic sample changer that can handle up to 16 samples simultaneously, increasing laboratory efficiency.
- Flexible temperature control: The instrument offers remarkable flexibility in selecting the measurement range up to 500°C. Using liquid nitrogen, it can analyze samples at temperatures as low as -100°C. In addition, a compressed air unit allows sub-ambient measurements down to 0°C. The integrated evacuation system permits measurements in defined atmospheres.
- Advanced corrections specifically for thin or highly conductive samples: The latest version of our analysis software introduces an enhanced analysis pulse correction feature designed for high-precision applications where exceptional time resolution is critical. This enhancement is particularly beneficial when analyzing thin or highly conductive samples, and in situations where the light pulse coincides with the thermal response of the sample.
The LFA 717 HyperFlash® is an essential tool for researchers and industries requiring precise thermal property measurements, making it an invaluable asset in the field of materials science.... Read More |