Projects

• Lidar and Directed Energy Components
  • 2-micron Laser
  • Roof Periscope
  • AEROTEL Chopper Wheel
  • AROTEL Receiver for the SOLVE Mission
  • Fiber Optic Couplers
  • Raman Lidar Chimney
  • Telescope Assemblies
  • 400mm aperture elevation-over-azimuth scanner
  • Large aperture mirror mounts
    • SOR
    • ABLTB
  • Lidar-In-A-Box
  • Titanium-Sapphire Laser
  • Single Point Diamond Turning
• Complete Lidar/Active Instruments
  • Raman Airborne Spectroscopic Lidar (RASL)
  • LVIS
  • Micro-Pulse Lidar
  • THOR Lidar
  • Phasers - Prototype Holographic Atmospheric Scanner for Environmental Remote Sensing
  • HARLIE (Holographic Airborne Rotating Lidar Instrument Experiment) Hemisphere Scanning Stage
  • High Spectral Resolution Lidar (HSRL)
  • GOLD
  • 2-micron CO2 Lidar
  • DAWN AIR1
• Support Equipment
  • ESTAR Calibration Scanner
  • Cloud Physics Lidar Handling Cart
• Aircraft Installations
  • ER-2 Doppler Radar Data System Enclosure
  • Cloud Radar System Data System Enclosure
  • King Air Rear Cargo Area Riser plate and electronics racks
  • King Air 4-bay electronics rack with shock isolation
  • RSP Instrument installation in King Air
  • HSRL instrument installation
  • 400mm aperture window port for King Air HSRL-247-X
  • Raman Airborne Spectroscopic Lidar (RASL)
  • RASL segmented window and external heat exchanger
  • LVIS installation in King Air
  • MASTER installation in King Air
  • HiWRAP in WB-57
• Complete Passive Optical Instruments
  • Offner Spectrometers (grating based)
  • Refractive Spectrometers
  • Lens assemblies
  • Telescope Assemblies
    • Conventional telescopes with glass optics
      • 150mm, 400mm CN, 400mm Newt, 200mm athermal for MPL
    • SPDT telescope
• RF Instruments
  • UAV Radar
  • HiWRAP
  • ER-2 Doppler Radar Data System Enclosure
  • Cloud Radar System Data System Enclosure
• Single Point Diamond Turning
  • Large Diameter Scanner
  • Lidar-In-A-Box
  • Diamond Turned Telescope Assemblies
    • 400mm series 1
    • 400mm series 2
    • 200mm
    • 150mm
    • 100mm
• Space-based Instruments
  • Geoscience Laser Altimeter System (GLAS)
    • Laser Pickoff System
    • Stellar Reference System - Bench Checkout Equipment
    • Fiber Optic Splitter
    • Light Emitting Diode Coupler
  • ISIR-AL
  • Simplesat Optical Microsatellite
  • HICO Spectrometers

Cloud Physics Lidar Handling Cart

Time Period

May 2001 to June 2001

Project Description

The Cloud Physics Lidar (CPL) instrument was designed to fly in the Superpod on the NASA ER-2 high-altitude research aircraft. The instrument is shown in the renderings as a blue box (transceiver), two gray electronics boxes, and a gold-colored standard ER-2 frame made from aluminum angle brackets. For aircraft integration, the CPL instrument slides into the Superpod along the rails on the side of the frame. Previously, the approximately 200-pound (90.7-kilogram) instrument was lifted by three to four people and then slid onto the rails in the ER-2 Superpod.

A cart was needed to hold the instrument when it was not installed in the ER-2. These were the cart’s requirements:

• The cart height had to be adjustable. The side rails had to reach 54 inches (1.4 meters) from the ground to match the rail height in the Superpod. It had to drop as low as possible all other times for stability.
• The CPL instrument had to be completely supported by the cart until the Superpod could support it.

A desired attribute of the cart was to hold the CPL so that the instrument could be pointed in various directions. In the Superpod, the instrument looked downward; therefore, the CPL had to be in this position on the cart prior to installation. However, it was desirable to be able to rotate the instrument to look upward or at various angles to allow testing while on the ground. All of the required and desired design elements were incorporated into the design shown in the renderings and photographs. The first image shows the cart in its lowered position for transport. The second image shows the instrument rotated 135 degrees from its normal position to look up at the sky. The third image shows the cart raised and with the instrument sliding off the cart into the Superpod.

Challenges and Lessons Learned

This project required integration of many commercial off-the-shelf parts and the design of many custom parts. Commercial parts were used as often as possible to reduce costs and speed delivery on this project.

A challenging element of this project was modeling the cart in the mechanical design software so that the motion and performance of the mechanisms could be checked. This required forethought during the early phases of the design to create a computer model that was robust enough to allow many changes and modifications later without corrupting the model.