Aetherdyne Ae-16 Fuyuhana (Pacifica): Difference between revisions
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|status = In service | |status = In service | ||
|primary user = {{flagicon|Pelinai|jack}}[[Royal Pelinese Navy (Pacifica)|Royal Pelinese Navy]] | |primary user = {{flagicon|Pelinai|jack}}[[Royal Pelinese Navy (Pacifica)|Royal Pelinese Navy]] | ||
|number built = | |number built = Approx. 800+ (as of 2023) | ||
|produced = {{start and end dates|2003|8|9|present}} | |produced = {{start and end dates|2003|8|9|present}} | ||
}} | }} | ||
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==Variants== | ==Variants== | ||
===Production models=== | ===Production models=== | ||
====Ae-16A/B==== | |||
Initial production variants. The Ae-16A is a single-seat aircraft, while the Ae-16B is twin-seat to support both trainer usage and employment of a WSO. The Ae-16A/B block incorporates relatively simple electronic systems, a [[Wikipedia:Passive electronically scanned array|PESA]] radar and conventional HUD. | |||
The Ae-16A/B suffered from myriad technical and structural issues over its eight-year service life, contributing to a low ratio of flight hours to maintenance hours; all airframes of the block received a major overhaul in 2010 to correct a severe structural flaw in the design of the landing gear. Both types, totaling 83 airframes, are fully withdrawn from RPNAS service as of 2017. | |||
====Ae-16V/G==== | |||
The Ae-16V is a single-seat model, while the Ae-16G is twin-seat. | |||
The Block 2 Fuyuhana was designed in order to eliminate many severe issues that had manifested in the Fuyuhana’s initial production run as a result of development difficulties, and both constituent variants exhibit significantly increased reliability; multiple avionics and electronics systems are also upgraded from the A/B variant, including an AESA radar, the addition of a combat networking datalink and an IRST system, an improved ECM suite, and the replacement of the IR-based missile approach warning sensor with one using an IR/UV combination system. Parts of the airframe structure and external panels are also modified in order to improve structural strength and reduce weight. | |||
====Ae-16D/E==== | |||
The single-seat Ae-16D and the twin-seat Ae-16E are the two newest variants of the Ae-16, and comprise the Block 3 Fuyuhana. Block 3 airframes began serial production in 2018 and use both modern flight systems and larger engines, along with more sophisticated integrated weapons targeting systems for use in both air-to-ground and air-to-air missions. | |||
===Research aircraft=== | ===Research aircraft=== | ||
==Operators== | ==Operators== | ||
==Specifications (Ae- | ==Specifications (Ae-16D)== | ||
{{Aircraft specs | {{Aircraft specs | ||
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|eng1 number = 2 | |eng1 number = 2 | ||
|eng1 name = Yuzimashi AF- | |eng1 name = Yuzimashi AF-13V | ||
|eng1 type = [[Wikipedia:Afterburner|afterburning]] [[Wikipedia:Turbofan#Low-bypass turbofan|low-bypass turbofan]] engines | |eng1 type = [[Wikipedia:Afterburner|afterburning]] [[Wikipedia:Turbofan#Low-bypass turbofan|low-bypass turbofan]] engines | ||
|eng1 kn = 67 | |eng1 kn = 67 |
Revision as of 04:57, 11 January 2024
Ae-16 Fuyuhana | |
---|---|
Role | Carrier-based strike fighter |
National origin | Pelinai |
Manufacturer | Aetherdyne IDB |
First flight | November 18, 2004 |
Introduction | March 7, 2009 |
Status | In service |
Primary user | Royal Pelinese Navy |
Produced | August 9, 2003 – present |
Number built | Approx. 800+ (as of 2023) |
The Aetherdyne Ae-16 Fuyuhana is a Pelinese carrier-cabale, twin-engine, all-weather strike fighter aircraft developed and manufactured by Pelinese aerospace bureau Aetherdyne. The Fuyuhana was developed to provide fleet defense and sea attack capabilities for aircraft carriers of the Royal Pelinese Navy, and is the standard tactical fighter aircraft of the Royal Pelinese Navy Air Service. Low-rate production of the type is ongoing as new airframes cycle in upgraded technology or replace planes lost to accidents, and over 800 airframes of all variants have been produced as of 2023.
The Fuyuhana was the first fixed-wing naval aircraft to be designed in Pelinai and the first to be operated by the Royal Pelinese Navy, with it taking its first flight in 2004 and receiving full adoption in 2009 alongside the newly commissioned KPF Pelograd. Various upgrade packages targeting electronics systems and other areas have allowed the Fuyuhana to maintain technological parity and resolve technical problems present in initial production models, and the type is expected to remain in active RPNAS service well into the 2040s.
Development
Background
The Royal Pelinese Navy first began identifying an outstanding procurement need for a series of fixed-wing naval aircraft in 1997, when it first implemented plans to steer its ongoing modernization initiatives towards the attainment of an carrier-based naval structure. Chief among these was what would later be referred to as the At-Sea Tactical Aircraft (ASTA), which was imagined as a medium-weight fighter that would primarily serve to provide air cover for Pelinese naval vessels while outside the range of land-based fighter support. As the primary aircraft necessitated by a carrier design that was then quickly gravitating towards a STOBAR configuration, the ASTA role was deemed to be the most likely candidate for navy adoption and was allocated the largest share of technical expertise.
Initial proposals for ASTA included searching for a suitable foreign-designed aircraft, as well designing a navalized variant for the currently serving Ae-12 Bara; a foreign aircraft purchase was quickly ruled out, however, and initial design studies concluded that the Bara could not be efficiently adapted to achieve the minimum stall speed and other performance standards necessary for the safe conduct of carrier takeoff and landing operations. Thus, after budgetary and technical considerations, the Pelinese Ministry of Defense opted to fund the development program for a new aircraft type to be operated by the Royal Pelinese Navy.
Initial proposal
Design
Overview
Airframe
Avionics
Engines
Upgrades
Operational history
Variants
Production models
Ae-16A/B
Initial production variants. The Ae-16A is a single-seat aircraft, while the Ae-16B is twin-seat to support both trainer usage and employment of a WSO. The Ae-16A/B block incorporates relatively simple electronic systems, a PESA radar and conventional HUD.
The Ae-16A/B suffered from myriad technical and structural issues over its eight-year service life, contributing to a low ratio of flight hours to maintenance hours; all airframes of the block received a major overhaul in 2010 to correct a severe structural flaw in the design of the landing gear. Both types, totaling 83 airframes, are fully withdrawn from RPNAS service as of 2017.
Ae-16V/G
The Ae-16V is a single-seat model, while the Ae-16G is twin-seat.
The Block 2 Fuyuhana was designed in order to eliminate many severe issues that had manifested in the Fuyuhana’s initial production run as a result of development difficulties, and both constituent variants exhibit significantly increased reliability; multiple avionics and electronics systems are also upgraded from the A/B variant, including an AESA radar, the addition of a combat networking datalink and an IRST system, an improved ECM suite, and the replacement of the IR-based missile approach warning sensor with one using an IR/UV combination system. Parts of the airframe structure and external panels are also modified in order to improve structural strength and reduce weight.
Ae-16D/E
The single-seat Ae-16D and the twin-seat Ae-16E are the two newest variants of the Ae-16, and comprise the Block 3 Fuyuhana. Block 3 airframes began serial production in 2018 and use both modern flight systems and larger engines, along with more sophisticated integrated weapons targeting systems for use in both air-to-ground and air-to-air missions.
Research aircraft
Operators
Specifications (Ae-16D)
General characteristics
- Crew: 1 (pilot)
- Length: 16.1 m (52 ft 10 in)
- Wingspan: 10.9 m (35 ft 9 in)
- Height: 4.3 m (14 ft 1 in)
- Wing area: 40.7 m2 (438 sq ft)
- Empty weight: 15,000 kg (33,069 lb)
- Gross weight: 24,000 kg (52,911 lb)
- Max takeoff weight: 32,000 kg (70,548 lb)
- Fuel capacity: roughly 9,000kg internally
- Powerplant: 2 × Yuzimashi AF-13V afterburning low-bypass turbofan engines, 67 kN (15,000 lbf) thrust each dry, 109 kN (25,000 lbf) with afterburner
Performance
- Maximum speed: 2,450 km/h (1,520 mph, 1,320 kn)
- Maximum speed: Mach 2.0
- Cruise speed: 1,400 km/h (870 mph, 760 kn)
- Range: 2,400 km (1,500 mi, 1,300 nmi)
- Combat range: 1,200 km (750 mi, 650 nmi)
- Service ceiling: 17,000 m (56,000 ft)
- Rate of climb: 290 m/s (57,000 ft/min)
- Wing loading: 516.0 kg/m2 (105.7 lb/sq ft)
- Thrust/weight: 1.06
Armament
- Guns: 1 x 30mm autocannon, 160 rounds
- Hardpoints: 4 x external hardpoints, 3 x internal weapons bays with a capacity of 8,000kg,with provisions to carry combinations of:
- Rockets:
- S-80 80mm unguided rockets
- S-120 120mm unguided rockets
- S-240 240mm unguided rockets
- Missiles:
- Bombs:
- BVN-100, BVN-250, BVN-500, BVN-750, BVN-1000 gravity bombs
- Laser, satellite guided bombs
- Cluster bombs
- N91B Prasiolite anti-runway bombs
- N12B Rose Quartz guided anti-fortification bombs
- Other: external fuel tanks
- Rockets:
- Bombs: 3 internal weapons bays with a maximum capacity of 2,000 kilograms of ordnance.
Avionics
- Sensors:
- Pelektronik ATP-3A AESA radar
- Electro-optical targeting system
- IRST sensor array
- Defensive systems:
- ECM system
- Combination IR/UV missile approach detector
- Radar warning receiver
- Towed radar decoys
- CNI systems:
- High-speed datalink transceiver
- Multifunction radio
- TACAN
- Pilot support systems:
- Helmet-mounted pilot night vision system
- Type 014 helmet-mounted display/sight system