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Product description

Specifications:
Model: UA5169
Material: ABS Plastic
Sensor Probe Type: Fe / NF
Working Principle: Magnetic Induction(Fe) / Eddy Current(NF)
Range: 0~1300um, 0~51.2mil
Units: μm, mil
Accuracy: ±(3%+2μm), ±(3%+0.08mil)
Resolution: 0.1μm, 0.01mil
Calibration Points: ZERO/50μm/100μm/250μm/500μm/1000μm
Minimum Curvature Radius of Convex Side: 1.5mm
Minimum Curvature Radius Concave: 25mm
Minimum Measuring Area: Diameter 6mm
Minimum Thickness of Substrate: 0.5mm(0.02") (Fe) / 0.3mm(0.012") (NF)
Operation Temperature: 0~40°(32~104°)
Working Humidity: 20%~90%RH
Power Supply: 1 * 9V 6F22 Battery(NOT Included)
Item Size: 120 * 65 * 32mm / 4.7 * 2.6 * 1.3in
Item Weight: 106 / 3.8oz
Package Size: 19.5 * 9.5 * 6.5cm / 7.7 * 3.7 * 2.6in
Package Weight: 250g / 8.8oz

Package List:
1 * Coating Thickness Gauge
1 * Iron Substrate
1 * Aluminum Substrate
1 * Protective Carrying Bag
5 * Thickness Calibration Foil
1 * User Manual

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The Wyss Institute for Biologically Inspired Engineering uses biological design principles to develop new engineering innovations that will transform medicine and create a more sustainable world.

At the Wyss Institute, we leverage recent insights into how Nature builds, controls and manufactures to develop new engineering innovations - a new field of research we call Biologically Inspired Engineering. By emulating biological principles of self assembly, organization and regulation, we are developing disruptive technology solutions for healthcare, energy, architecture, robotics, and manufacturing, which are translated into commercial products and therapies through formation of new startups and corporate alliances.

We have 8 major Focus Areas.

  • Bioinspired Therapeutics & Diagnostics
    Therapeutic discovery and diagnostics development enabled by microsystems engineering, molecular engineering, computational design, and organ-on-a-chip in vitro human experimentation technology.
  • Diagnostics Accelerator
    An initiative enabling the creation of new diagnostic technologies that solve high-value clinical problems through deep collaboration between the Wyss Institute and Brigham and Women’s Hospital. Candidate diagnostics will be driven by clinicians’ unmet needs, advanced in the Wyss Institute’s biomarker discovery and technology development labs, and validated in BWH’s CLIA lab, providing crucial clinical data to move them from the bench to the bedside faster.
  • Immuno-Materials
    Material-based systems capable of modulating immune cells ex vivo and in the human body to treat or diagnose disease. 
  • Living Cellular Devices
    Re-engineered living cells and biological circuits as programmable devices for medicine, manufacturing and sustainability.
  • Molecular Robotics
    Self-assembling molecules that can be programmed like robots to carry out specific tasks without requiring power.
  • 3D Organ Engineering
    Highly functional, multiscale, vascularized organ replacements that can be seamlessly integrated into the body.
  • Predictive BioAnalytics
    Computational approaches that apply the power of machine learning, neural networks, and other algorithmic architectures to complex problems in biology, generating faster, better insights and driving innovation.
  • Synthetic Biology
    Breakthrough approaches to reading, writing and editing nucleic acids and proteins for multiple applications, varying from healthcare to data storage.

Through our Innovation Funnel, we harness the creative freedom of academia to generate a pipeline of new ideas and potential breakthrough technologies; enable our staff with product development experience to prototype, mature and de-risk these technologies; and leverage our internal business development team, intellectual property experts, and entrepreneurs-in-residence to drive commercialization, through industrial partnerships, licensing agreements, and the creation of HP P2000 LFF Modular Smart Array Chassis AP838B.

  • Idea Generation
  • Concept Refinement
  • Technology Validation
  • Technology Optimization
  • Commercialization
  • Publications 0
  • Patent Filings 0
  • Licenses 0
  • Startups 0

Our scientists, engineers and clinicians, who come from Harvard's Schools of Medicine, Engineering, Arts & Sciences, and Design as well as 12 collaborating academic institutions and hospitals, work alongside staff with industrial experience in product development to engineer transformative solutions to some of the world’s greatest problems.

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