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DFF, 2000 Series, Medical Dry X-ray Imaging Clear Blue Base Thermal Film

Dry Film

DFF, 2000 Series, Medical Dry X-ray Imaging Clear Blue Base Thermal Film

Built on a 175μm-thickness PET base, medical dry x-ray imaging clear blue base thermal film (DFF) combines the advantages of thermal imaging with the features of high-quality grayscale films. Combined with excellent image stability, the silver-free environmental imaging layer of the film is heat-sensitive rather than light-sensitive, guaranteeing low fog, low minimum density, reduced glare and light transmission, and high perceived contrast. Contributing to liner gradations from low-through-high density areas, the warm-toned imaging film in a variety of conventional practical sizes delivers optimum diagnostic image clarity for all image modalities as wet infrared laser films. The high-resolution, thermographic film is suitable for continuous-tone medical imaging to provide the aesthetic and diagnostic qualities, and sharp image rendition.

    Film Structure 

    The film contains blue transparent PET base, a thermal imaging layer coated on the PET base, a protective layer formed on the imaging layer, and a back-coat layer coated on the other side of the PET base. The total thickness of the film without any surface defects is controlled between 205-210μm to ensure that the thickness of the film does not exceed the limited gap between the print head and the press roll inside the "2000 Series" imager.
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    Manual Printer Image Quality Correction (MPIQC)

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    The film is system-matched with "2000 Series" Dry Imagers, offering a maximum density selected up to 3.0D after the Manual Printer Image Quality Correction (MPIQC) on by image printers' built-in densitometer. This one-click quality control in advance is performed by menu keys with no extra operation intervention to enhance subsequent productivity.

    Relaxed Printing Process 

    The strong friction resistance for the printing film from the print head can be increased due to the influence of high temperature printing and the surface roughness of the protective layer. By adding appropriate lubricants in the protective layer and selecting adhesives with high glass-transition point both for the protective layer and the imaging layer, this printing process emits less noise for the user-friendly quiet working environment on account of little friction resistance.
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    Antistatic Back Layer Guards Print Head 

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    Due to the action of a film feeding wheel in the printing process, a thermal film with insulation properties could produce friction. The Friction allows the film to be continuously cumulatively charged, as the number of prints increases. Electrostatic energy can accumulate to reach a potential at which sparking can occur. Sparking can destroy vital electronic components in the imager, particularly the thermal head. The film (F) has an antistatic back layer which acts against the build-up of electrostatic energy.

    Varied Printing Capability 

    The film is employed in recording the images from Computed Tomography (CT), Digital Subtraction Angiography (DSA), Magnetic Resonance Imaging (MRI), Computed Radiography (CR), Digital Radiography (DR), and other medical imaging devices.
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