From an online article in Australian Flying magazine dated 2011.....
Part II
At that time, engine overheating was occurring with the use of continuous climb outlet to 20,000 feet, but it was felt that fan cooling, then being planned, would cure this. Turbine exhaust temperature was at 780C, 35C below the maximum permissible, while turbine cooling and lubrication were satisfactory. Initial intercooling deficiency was overcome by removing the two lower cowl gills on the port side, thereby obviating engine cooling efflux inflow to the intercooler. Ignition breakdown at high altitude was overcome by replacing the Scintilla magnetos with Bosch high-altitude types. Further flights revealed that the aircraft was neutral stable in the lateral plane, directionally unstable, and rudder-trim changes with speed were excessive.
To overcome these latter two faults, the fin area was increased and redesigned, while lateral stability was improved by sweeping the wing tips up, as had been done on the Boomerangs. The supercharger installation was considered to be very satisfactory, but, due to the restricted climb, a cable was sent to Wackett on 15 April recommending that he obtain a four-blade eleven-foot propeller for the aircraft, similar to that fitted to the P-51B.
Performance and handling tests, at which time it was fitted with a large spinner, were completed by CAC (including flying to 35,000 feet) and it was delivered to the RAAF in April. On its return from Laverton in May, a new fin and rudder were fitted to further increase vertical area, and these improved the aircraft's handling qualities as reported by the company test pilot.
It was returned to the RAAF for further evaluation. Board had flown it to 41,000 feet, its upper limit, and found that controllability was then almost non-existent, and that it fell away out of control very easily, (as was to be expected). From the lessons learnt with the CA-14, the same aircraft was developed into the CA-14A, still as A46-1001. Design calculations showed it to have a better all-round performance than the Thunderbolt and the Spitfire VC, comparative operational ceilings (at which rate of climb falls below 1,000fpm) were 34,400 feet, 32,000 feet, and 29,700 feet respectively. With 30 hours of CAC test flying and ten hours of RAAF evaluation on the CA-14, the conversion was carried out through June and July, with the following changes and new equipment scheduled for incorporation.
1) CAC-built R-2000 Twin Wasp replacing the R-1830. (not achieved.)
2) A B9 turbo-supercharger (actually a B13 was fitted).
3) The four-blade 11 foot Hamilton Standard propeller with blade-activity-factor of 113.5.
4) Ten-bladed cooling fan mounted behind the propeller, and driven through the reduction gearing at three times propeller speed.
5) Sliding cowl gills in place of the conventional hinged type.
6) Retractable tail wheel (not achieved).
7) The intake for the intercooler and engine air was fed from directly behind the fan, gaining considerably from ram effect, and also further increasing critical altitude. The ducting was set nearer the fuselage centre line and did not protrude as far out from the fuselage as it did on the CA-14.
8) The Airesearch intercooler. (40 pounds lighter than the Harrison)
9) A bulkhead in the rear fuselage (not achieved, it is believed, unless the autoobserver
panel was so described).
10) Changes in the oil-cooler installation and ducting.
With the original hinged gills opened, there was a tremendous increase in drag and buffeting and a reduction in controllability and forward vision. To overcome these liabilities, sliding gills were developed on A46-157 and a variable exit orifice, which was capable of controlling the cooling airflow within laid-down limits, was achieved. Operated hydraulically, as were the standard hinged gills, these slid backwards and forwards along a series of rails to alter the exit.
For some reason, the hinged gills were reinstated at some later stage, and were still on the aircraft when it was eventually broken-up. (It has not been possible to find detail of the changes in item 10, necessary because the exit ducting from the oil-coolers could not be allowed to feed the exhausted air into the extended intercooler/engine intake in the CA-14A, on thermodynamic grounds, and so as not to detract from maximum power).
The first graduate from the Sydney University Aeronautical Engineering Course, completed in 1941, was Alan Bolton, who went straight to CAC on Boomerang stressing, and then worked on the CA-14/14A design - he was able to advise in January 1994 that, to the best of his recollection, the outlet had been relocated to the starboard side into the duct which carried the exhaust tailpipe.
However, it is not known how oil-temperature control was effected in such a position, seemingly without the pilot-controlled exit flap, which had been on the port-side of the CA-14 and all production Boomerangs. During the conversion, a further increase in fin area was added, and the centre-section leading edges were straightened and swept forward, thus cutting out the wheel well fairings. During high-speed dive tests, up to 400 mph IAS, on A46-27, shock waves at the fuselage wheel-well junction occurred at about 360 mph by obviating this junction, wind-tunnel tests, showed the shock waves disappeared unti1 420mph was reached.
A limiting dive speed of 410mph was then placed on the CA-14A. Weight increase with these modifications was 100 pounds, making the all-up weight 8,132 pounds. Wackett wrote to DAP Secretary Letcher on 29 June 1943 to recommend production of the CA-14A before CA-17 manufacture could be started. With almost all of the detail parts for the 200 Boomerangs completed, various departments would be out of work within the next two months, and the assembly task would be completed in October.
With at least six months to the start of detail work on the CA-17, dependent on the arrival of information from the USA, and manufacture of the necessary tooling to begin fabrication, at least 200 more Boomerangs could be built, and such was necessary to keep the organisation intact, pending the start of CA-17 work. As there was need for an urgent decision, for either standard Boomerangs or the CA-14A development, he recommended the latter. It used fully 75% of the tooling for the standard Boomerang, and it was therefore possible to issue production orders for much of the detail parts immediately, while producing tooling for the new parts necessary to suit the supercharger installation. He summarised the project and company hopes in a report