Shutting down environmental radiation! IMPROMAT gamma radiation measurement device.
Equipped with a NaI(Tl) scintillation detector, it amplifies the weak light emitted from the scintillator using a photomultiplier tube and converts it into an electrical signal to measure radiation. It is capable of detecting radioactive contaminants that emit gamma rays with energies ranging from 50 keV to 2000 keV, with a detection limit of 0.02 Bq/g (Co-60 equivalent) or better for steel samples under normal environmental radiation levels with a measurement time of 30 seconds. The detector and sample chamber are shielded by a 70 mm thick lead box, which blocks environmental radiation (gamma rays) and allows for high-precision measurement of the sample's inherent radioactivity. Additionally, after startup, it continuously measures the background radiation, accommodating fluctuations in the operating environment. Not only manual measurements but also integration into an automated robotic circle connected to a master PC via TCP/IP communication is possible. - NaI(Tl) scintillation detector - Capable of measuring approximately 0.02 Bq/g Co60-eq - Automation is possible through connection with automated robots - Software reflecting the half-life of standard samples - Data transfer to higher systems is possible - Compatible with a wide range of samples including steel, non-ferrous metals (copper, aluminum), and food.
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basic information
For more details, please contact us.
Price information
Negotiable
Delivery Time
Applications/Examples of results
Steel, food
Detailed information
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No sample; measurement in the measurement room (with lead shielding)
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No sample; environmental measurement (without lead shielding)
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Company information
Hartzok Japan has been a specialized company in preprocessing equipment for about 30 years. The preprocessing equipment we handle refers to devices that create samples in optimal conditions for analytical instruments. In recent years, the performance of analytical instruments has improved, allowing for more precise analyses. However, as the accuracy of analysis increases, the results can vary significantly based on the preprocessing steps. For example, even if there is a high-spec microscope, poor preprocessing due to contamination, loss, or uneven polishing can lead to low analytical accuracy. Conversely, even a low-spec microscope can yield high-accuracy results if the polishing is done well. Preprocessing equipment is often postponed in capital investments, but the results of the preprocessing steps become more critical as higher analytical accuracy is sought. Furthermore, this preprocessing process is largely analog and relies heavily on empirical knowledge. Hartzok Japan will contribute to improving our customers' quality with the know-how we have cultivated over many years in the preprocessing field.
