Optical Dilatometer | DIL 806
This optical dilatometric measurement method used in DIL 806 is an absolute process, entirely independent of any possible expansion or contraction of the instrument. Consequently, measured results do not need to be corrected or calibrated for different temperature programs. Coupled with the fast response of the DIL806 furnace, this makes the system particular well-suited for the analysis of dynamic processes that involve multiple temperature steps and dynamic heating rates.
A high-performance LED emits a broad-width planar light beam onto the sample. The sample shadow is detected by a high-resolution CCD sensor. The signal is then evaluated by a digital edge-detection processor which provides a sensitive and precise measurement of dimensional change. This principle is known as the shadowed light method and provides an accurate and absolute measurement of the sample dimension with changing temperature.
The sample, positioned on a platform in the center of the disc-shaped furnace, is not subjected to external forces. Hence DIL 806 is a dilatometer particluarly suited for the measurement of metals and, with the optional sub-zero furnace, plastic samples.
Thin samples are also easily analyzed with the sample holder specifically designed for this purpose.
The broad width of the incident light means that sample preparation is not as demanding as in other classic dilatometric techniques, and the sample does not need to have be positioned precisely on the platform, improving usability also for unexpereinced operators.
The initial length is automatically determined and saved for the subsequent calculation of the linear thermal expansion coefficient.
The furnace is capable of rapid heating speeds up to 100 °C/min and cooling times from 1400 °C to 50 °C in under 10 minutes.
Applications
Metals – Thermal expansion of thin film
Traditionally, the measurement of a thin film in a push-rod dilatometer can be problematic due to the contact forces associated with the push-rod. The DIL 806 optical dilatometer is ideal for characterizing thin films and other materials with sample size/preparation restrictions. In this example, the thermal expansion and phase transformation of a thin steel foil is characterized by the DIL 806 non-contact optical dilatometer. The measurement process is both absolute and non-contact, so no system calibration curves are required. Sample holders are available to support thin films.
Fast fired ceramics
The very fast heating rates, outstanding temperature uniformity and simple programming inherent to the DIL 806 make it ideally suited to simulating industrial processes. The fast-firing process of a green body ceramic is desirable because it conserves energy and time. However, in many cases, this type of heat treatment can produce incomplete densification in the final product. In this example the sample is rapidly heated until it reaches a user-defined contraction. At this time, multiple isothermal dwells and cooling rates were used in order to closely monitor the sintering behavior of the material. By fine-tuning these temperature control parameters, based on dilatometer measurements, the industrial process can be streamlined to produce a final product with the desired physical properties and cost-advantageous processing conditions.
Specifications
Sample length: | 0.3 – 30 mm |
Sample height: | max. 10 mm |
Change of length: | max. 29 mm |
Length Resolution: | 50 nm |
Temperature Resolution: | 0.1°C |
Accuracy in α: | 0.03 x 10-6 K-1 |
Temperature range: | -150°C to 650°C RT to 900°C RT to 1350°C |
Atmosphere: | Vacuum, inert gas, air |
To contact TA Instruments about Optical Dilatometer | DIL 806 use Get a quote.
This optical dilatometric measurement method used in DIL 806 is an absolute process, entirely independent of any possible expansion or contraction of the instrument. Consequently, measured results do not need to be corrected or calibrated for different temperature programs. Coupled with the fast response of the DIL806 furnace, this makes the system particular well-suited for the analysis of dynamic processes that involve multiple temperature steps and dynamic heating rates.
A high-performance LED emits a broad-width planar light beam onto the sample. The sample shadow is detected by a high-resolution CCD sensor. The signal is then evaluated by a digital edge-detection processor which provides a sensitive and precise measurement of dimensional change. This principle is known as the shadowed light method and provides an accurate and absolute measurement of the sample dimension with changing temperature.
The sample, positioned on a platform in the center of the disc-shaped furnace, is not subjected to external forces. Hence DIL 806 is a dilatometer particluarly suited for the measurement of metals and, with the optional sub-zero furnace, plastic samples.
Thin samples are also easily analyzed with the sample holder specifically designed for this purpose.
The broad width of the incident light means that sample preparation is not as demanding as in other classic dilatometric techniques, and the sample does not need to have be positioned precisely on the platform, improving usability also for unexpereinced operators.
The initial length is automatically determined and saved for the subsequent calculation of the linear thermal expansion coefficient.
The furnace is capable of rapid heating speeds up to 100 °C/min and cooling times from 1400 °C to 50 °C in under 10 minutes.
Applications
Metals – Thermal expansion of thin film
Traditionally, the measurement of a thin film in a push-rod dilatometer can be problematic due to the contact forces associated with the push-rod. The DIL 806 optical dilatometer is ideal for characterizing thin films and other materials with sample size/preparation restrictions. In this example, the thermal expansion and phase transformation of a thin steel foil is characterized by the DIL 806 non-contact optical dilatometer. The measurement process is both absolute and non-contact, so no system calibration curves are required. Sample holders are available to support thin films.
Fast fired ceramics
The very fast heating rates, outstanding temperature uniformity and simple programming inherent to the DIL 806 make it ideally suited to simulating industrial processes. The fast-firing process of a green body ceramic is desirable because it conserves energy and time. However, in many cases, this type of heat treatment can produce incomplete densification in the final product. In this example the sample is rapidly heated until it reaches a user-defined contraction. At this time, multiple isothermal dwells and cooling rates were used in order to closely monitor the sintering behavior of the material. By fine-tuning these temperature control parameters, based on dilatometer measurements, the industrial process can be streamlined to produce a final product with the desired physical properties and cost-advantageous processing conditions.
Specifications
Sample length: | 0.3 – 30 mm |
Sample height: | max. 10 mm |
Change of length: | max. 29 mm |
Length Resolution: | 50 nm |
Temperature Resolution: | 0.1°C |
Accuracy in α: | 0.03 x 10-6 K-1 |
Temperature range: | -150°C to 650°C RT to 900°C RT to 1350°C |
Atmosphere: | Vacuum, inert gas, air |
To contact TA Instruments about Optical Dilatometer | DIL 806 use Get a quote.
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