Q6 Antenna Structure

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{{SideMenuQ6}} {{SideMenuQ6}}
-[[Image:Q6-construct.jpg|left|thumbnail|140px|FPQ-6 under construction]]+[[Image:Q6-construct.jpg|left|thumbnail|135px|FPQ-6 under construction]]
The first shipment of Gemini equipment - included the FPQ-6 antenna pedestal its heaviest item - arrived in November 1966 and was transported to Carnarvon. An 80-ton crane - the largest vehicle then to have used the North West Coastal Highway - travelled north to lift the pedestal into position. The first shipment of Gemini equipment - included the FPQ-6 antenna pedestal its heaviest item - arrived in November 1966 and was transported to Carnarvon. An 80-ton crane - the largest vehicle then to have used the North West Coastal Highway - travelled north to lift the pedestal into position.
As befitting a precision instrument, the [[Tracking Antenna Mounts| Azimuth-Elevation]] antenna structure and 8.8m (29ft) parabolic dish was erected upon a specially designed rigid foundation; a thick concrete base which had been poured onto several foundation piles driven 10 metres into one ancient sand dune on Browns Range. As befitting a precision instrument, the [[Tracking Antenna Mounts| Azimuth-Elevation]] antenna structure and 8.8m (29ft) parabolic dish was erected upon a specially designed rigid foundation; a thick concrete base which had been poured onto several foundation piles driven 10 metres into one ancient sand dune on Browns Range.
-A NASA Technical Information Bulletin announcing the imminent construction stated:<BR>+A NASA '''Technical Information Bulletin''' announcing the imminent construction stated:<BR>
''“The antenna pedestal is a precision, two-axis mount, using hydrostatic bearing in azimuth and phase roller bearings in elevation to provide mobility and support to the counter-balanced, solid-surface antenna. The antenna is positioned through anti-backlash dual-drive pedestal gearing via a high ''“The antenna pedestal is a precision, two-axis mount, using hydrostatic bearing in azimuth and phase roller bearings in elevation to provide mobility and support to the counter-balanced, solid-surface antenna. The antenna is positioned through anti-backlash dual-drive pedestal gearing via a high
torque-to-inertia electro-hydraulic valve motor system. … A viscous coupler torque-to-inertia electro-hydraulic valve motor system. … A viscous coupler

Revision as of 04:43, 2 February 2007


FPQ-6 Radar

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FPQ-6 under construction
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FPQ-6 under construction

The first shipment of Gemini equipment - included the FPQ-6 antenna pedestal its heaviest item - arrived in November 1966 and was transported to Carnarvon. An 80-ton crane - the largest vehicle then to have used the North West Coastal Highway - travelled north to lift the pedestal into position.

As befitting a precision instrument, the Azimuth-Elevation antenna structure and 8.8m (29ft) parabolic dish was erected upon a specially designed rigid foundation; a thick concrete base which had been poured onto several foundation piles driven 10 metres into one ancient sand dune on Browns Range.

A NASA Technical Information Bulletin announcing the imminent construction stated:
“The antenna pedestal is a precision, two-axis mount, using hydrostatic bearing in azimuth and phase roller bearings in elevation to provide mobility and support to the counter-balanced, solid-surface antenna. The antenna is positioned through anti-backlash dual-drive pedestal gearing via a high torque-to-inertia electro-hydraulic valve motor system. … A viscous coupler located between the valve motor and pedestal drive gearing damped out undesired mechanical resonances.” [1]

Put simply, the whole 30-ton pedestal, plus the dish, floated and rotated on a thin film of hydraulic oil that covered the shallow dome beneath it, which in turn sat atop the huge mass of concrete.

Reference:

[1] Technical Information Bulletin, GSFC, MSFN: Vol.1 No.11; July 26, 1963

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