Off late, it has become
extremely fashionable to refer to the MoD-owned Hindustan Aeronautics Ltd (HAL)
as a ‘strategic asset’ and shed crocodile tears about the ‘diminishing status’
of India’s premier and oldest aerospace manufacturing corporate entity.
However, a fact-check reveals that those very political parties and their ‘netas’
who are today crying hoarse over HAL receiving step-motherly treatment were in
the yesteryears the very ones responsible for subjecting HAL to multi-phase
castrations which have since proven to be catastrophic for HAL today.
Phase-1 Of Castration: The 1960s
During this period, the
process of castration started soon after the 1962 Sino-Indian border war, when
a confused India refused to heed the well-intentioned advice of the US (which,
as the quiet but steadfast ally of India) to devote her limited financial
resources on the creation of an indigenous combat aircraft development-cum-manufacturing
capability. While the US had advised India to import only limited quantities of
combat aircraft of foreign origin, it had also offered to bear the cost of developing
the indigenous, supersonic HF-24 Marut medium multi-role combat aircraft
(M-MRCA).
The US had
proposed for the Indian Air Force (IAF) the importation of highly subsidised (as
part of a military assistance programme) Douglas F-4D Skyray, equipped with a Westinghouse
APQ-50A search radar and 16,000lb thrust Pratt & Whitney J57-P-8 turbojet.
This combat aircraft was designed exclusively
for the high-altitude interception role, with a high rate and angle of climb.
It had set a new time-to-altitude record, flying from a standing start to 49,221
in 2 minutes and 36 seconds, all while flying at a 70-degree pitch angle. The proposed
F-5D Skylancer was derived from the F-4D and was intended to be a Mach 2-capable
successor to the Skyray when powered by a General Electric J-79
turbofan.
However, for reasons that have only been
partially explained to date, India refused to procure either the Douglas F-4D Skyray or the Northrop F-5A Freedom
Fighter, and instead kept on insisting on the need to procure off-the-shelf up
to three squadrons of Lockheed F-104G Starfighter interceptors, along with the
parallel importation of MiG-21PF interceptors and the subsequent licenced-manufacturing
of follow-on variants of the MiG-21. It was this lack of clarity-of-thought
that sealed the fate of the HF-24 Marut, as explained by the slides below.
The HF-24 Marut was conceived to meet an
IAF Air Staff Requirement (ASR) that called for a multi-role aircraft suitable
for both high-altitude interception and low-level ground attack. The specified
performance parameters called for a speed of Mach 2 at altitude, service ceiling
of 60,000 feet, and a combat radius of 805km. Additionally, the ASR demanded
that the basic design be suitable for adaptation as a lead-in fighter trainer, an
all-weather combat aircraft and for ‘navalisation’ as an aircraft carrier-based
aircraft.
India’s first Prime Minister Pandit Jawaharlal ‘Chaachaa’ Nehru
tried to attract leading aeronautical designers from the West to develop the
HF-24. It was to his credit that he convinced Dr Kurt Tank from Germany to take
up this assignment along with his able deputy Engineer Mittelhuber. Both
arrived at HAL in Bangalore in August 1956. As head of the design team it was Tank
who gave the design shape and substance. A full-scale representation
(wooden glider) of the projected HF-24 was ready by early 1959. A flight-test
programme was initiated with this glider on April 1, 1959. The design was given
the designation of Hindustan Fighter 24 or simply HF-24.
Assembly of the first HF-24 prototype
(HF-001) commenced in April 1960 and after a comprehensive three-month
ground-test programme, HF-001 (later re-numbered BR-462), with the late Wing
Commander (later Group Captain) Suranjan Das at the controls, flew for the
first time on June 17, 1961. The HF-24 was then powered by twin Bristol
Siddeley Orpheus 703 Mk.1 turbojets each rated at 21.57kN thrust. The wings
were designed to carry four pylons rated at 454kg each. In addition, each wing
carried about 700 litres of fuel in the integral tanks. An integral tank means
the internal space within the wing is sealed up and filled with fuel floating between
the structural members. This means each wing carried a payload of about 1,425kg
of fuel and weapons. All this
was achieved within a commendably short period of 15 months from starting of design to
assembling a flightworthy airframe and finally, to the maiden flight.
On June 27, 1961 the BR-462 prototytpe
was shown to Prime Minister Nehru. By November 1961, a structural test airframe
had been completed and was subjected to extensive structural and functional
tests in rigs designed and fabricated by HAL. On October 4, 1962 a second
prototype (BR-463) joined the flight-test programme and the two prototypes were
extensively tested by Das and a team of three IAF test pilots for aerodynamic
stability, engine operating protocols, armament stowage, instrumentation, emergency
procedures, etc. HAL and the IAF conducted 1,800 test-flights between 1962 and
1967 to iron out the defects of the Marut. In April 1967 No.10 ‘Flying Daggers’
Squadron became the first unit to be equipped with India’s first indigenous MRCA. The
Marut eventually equipped three IAF Squadrons: No.10 Sqn, No.220 ‘Desert Tigers’
converted in May 1969 and the No.31 ‘Lions’ in March 1974. India thus
became the sixth country to design and fly a homegrown supersonic combat
aircraft after the US, UK, USSR, France and Sweden.
The design of the HF-24 had been based
around the expected availability of the afterburning Bristol Siddeley (later
Rolls-Royce) Orpheus BOr.12 engine rated at 30.29kN dry and 36.34kN with
afterburning, which Rolls-Royce had planned to develop. Unfortunately, the
British requirement for this powerplant was discarded and the Indian Govt of
India under the then Prime Minister Lal Bahadur Shastri in a shortsighted
decision declined to underwrite its continued development even though the developmental
budget (which the US had offered to provide) was only £13 million. This catastrophic
decision was to bedevil the Marut programme permanently.
The HF-24’s design team
was consequently forced to adopt the non-afterburning Orpheus 703 Mk.1, which also
powered the Folland Gnat L-MRCA, as the permanent solution. Although HAL did
develop an afterburning version of the Orpheus 703 Mk.1, and called it the HJE-2500 (rated
at 25.44KN thrust with reheat),
the IAF refused to service-induct the HF-24 Mk.1R variant using such engines. Though
the IAF considered the prospect of using the Tumansky RD-9F turbojet (rated at 37kN with
afterburner, it was ultimately rejected on grounds of surging and limited MTBO.
Phase-2 Of Castration:
The 1980s
As revealed below, the IAF had a
detailed plan for up-sizing the Folland Gnat as a contemporary L-MRCA with the
help of HAL and friendly international; aerospace OEMs like BAE Systems (then
British Aerospace, which had proposed to co-develop with HAL a digital
fly-by-wire flight-control system for both the Jaguar IS interdictors of the
IAF as well as for the projected L-MRCA) and SNECMA Moteurs, whose turbofans
were available for import.
However, all such well-intentioned roadmaps were
junked by India’s then gullible, ill-informed and ignorant political leadership
and instead, the programme for indigenously developing the ‘Tejas’ light combat
aircraft (LCA) was initiated in August 1983, when the MoD sanctioned an interim
development cost of Rs5.6 billion for carrying out the project definition phase
(PDP). The MoD consequently split the programme into the Technical Development
Phase and Operational Vehicle Development Phase. The
DRDO subsequently obtained feasibility studies from three leading aircraft
companies (British, French and German). Use was made of these studies in
presenting a case to the Govt of India for indigenously designing and
developing the LCA. In an unusual step, a ‘Society’ was set up to oversee the
LCA’s developmental process. At its apex was and still is a 15-member General
Body, whose President is the Defence Minister. The next rung is a 10-member
Governing Body, whose Chairman is the Scientific Adviser to the Defence
Minister and Secretary DRDO. The third rung is a 10-member Technical Committee,
headed by the Director of the DRDO’s Aeronautical Development Agency (ADA),
which was established on June 16, 1984. In October 1985, the IAF issued the
LCA’s ASR. The projected requirement then was
for 220 LiCAs (200 single-engined combat aircraft and 20 tandem-seat operational
conversion aircraft), with service-induction commencing by 1994. On
January 7, 1986 at a conference room in Delhi’s South Block which houses the
offices of the MoD, officials of ADA unveilled detailed plans for developing
and manufacturing the LCA. Subsequently, the Project definition (PD) phase
commenced in October 1987 with the help of Dassault Aviation as project
consultant, and the PD phase was completed in September I988. So, what went
wrong and why? It is all explained in the following slides.
And where do matters
now stand? The slide below illustrates how GE Aero Engines had in mid-1987 envisioned
the LCA Mk.1’s airframe to be.
Instead, this is how it
has turned out to be!
Phase-3 Of Castration: The 1990s
This decade was the most critical and
disastrous. What was required was long-term strategizing, which was to have
been followed by the articulation of an industrial roadmap catering to both
military and commercial aviation requirements. Instead, that decade turned out
to be all about lost opportunities and ill-conceived decision-making processes.
For instance, while the IAF had decided in the mid-1980s itself that it would
require basic turboprop trainers (BTT), advanced jet trainers (AJT) and lead-in
fighter trainers (LIFT) for its future fixed-wing flying training requirements,
there was no corresponding industrial roadmap conceived for indigenously meeting
such requirements. Despite this, the HTT-35 BTT’s full-scale mock-up, was
designed and fabricated in-house by HAL in the late 1980s and rolled out in the
early 1990s—all in all a four-year effort.
The objective at that time was to team
up with a global avionics supplier (most probably THALES) and co-design the
semi-glass tandem cockpits and offer the aircraft for evaluation by the IAF by
1998. However, after 1994 the HTT-35 disappeared, literally! One can only
speculate on what exactly happened to this full-scale mock-up, or on why did
the MoD or the IAF develop a coordinated ‘memory loss’ on the need to
series-produce the HTT-35 almost a decade ago! For it was realised as far back
as 1998 that the induction of fourth-generation combat aircraft would force the
IAF sooner than later into undertaking a critical revision of its flying
training practices that included basic flying training, advanced flying
training, and lead-in fighter training (LIFT).
Despite this, the HTT-35 BTT was
scrapped (only to be reborn in the following decade as the HTT-40), and instead
of calling for the development by HAL of the HJT-36 as a swept-wing AJT, the
IAF in its all-knowing wisdom wrongly decided 19 years ago to have the HJT-36
as an intermediate jet trainer (IJT). This perhaps explains why the IAF has,
since 2008, been maintaining sustained silence over HAL’s inability to develop
the HJT-36.
On September 29, 2009 the MoD
cleared the acquisition of 181 BTTs for the IAF and on May 24, 2012 a contract
worth US$640 million (Rs 3,780 crore) was inked with Switzerland-based Pilatus
Aircraft Ltd for procuring off-the-shelf an initial 75 PC-7 Mk.2 BTTs (with 38 more to be ordered later), together with an integrated ground-based training
system and a comprehensive logistics support package. Concurrently, the MoD decreed
that HAL develop the indigenous HTT-40 BTT, for which an order for 106 units
was promised. However, the MoD
on February 28, 2015 approved the IAF’s move to exercise options for procuring
an additional 38 PC-7 Mk.2s, thereby reducing the number of HTT-40s to be
acquired to 68. HAL was required to set up a production line in
Bengaluru with a rated output of two HTT-40s in the first year (2017), followed
by eight in the second year and 20 aircraft from year-three onwards. By 2012 HAL had sanctioned Rs.177 crore ($30 million from its
own internal funds for the preliminary design phase and detailed design phase
activities.
The first HTT-40, powered by a Honeywell
Garrett TPE 331-12B engine, was first rolled out in February 2016
and was first test-flown in May. On October 29, 2015, the MoD decided to carry on with the HTT-40’s
development despite the IAF stonewalling HAL’s detailed project report (DPR).
The IAF stated that while an imported PC-7 Mk.2 would cost Rs.38.3 crore, the
HTT-40 would be 25% more expensive, or Rs.43.59
crore at 2011 prices. The extra cost per HTT-40 includes Rs.1.81 crore as the
cost of production; and Rs.7.11 crore as the cost of design and development, of
which the IAF is required to pay 80%. A 16% rise in the cost of foreign exchange
at that time added another Rs.1.97 crore per aircraft, taking the price up to
Rs.43.59 crore. To this was to be added another 4.5% annual inflation costs to,
which were on a 2011 base. That raised the HTT-40’s per-unit cost to Rs.59.31
crore in 2018 and Rs.64.77 crore in 2020.
Added finally to all these was the
direct operating costs of maintaining the airworthiness of two separate types
of BTTs equipped with two different types of turboprop engines and avionics
suites—a luxury no other air force in the world enjoys! All such headaches
could have been avoided had the HTT-35 BTT been developed and ordered by the
late 1990s.
Similar was the case
the HAL-developed HJT-36 IJT, whose development was
sanctioned in 1999 with an initial funding of Rs.180 crore. On March 7, 2003
the first HJT-36 prototype made its maiden flight, following which the Cabinet Committee on National Security in March 2005 approved
an order for 12 limited series-production HJT-36s, which were slated for
rollout by 2008 and service-induction by 2011. Following this, another 73 series-production aircraft were to be ordered. In mid-2005, HAL and Russia’s Rosoboronexport
State Corp signed a $350 million contract to licdence-build 250 NPO Saturn-developed
AL-55I turbofans, with an option for 1,000 more. HAL had then estimated that the
per-unit price of each HJT-36 would be around $10 million for a 225-unit order.
The first batch of AL-55Is began arriving two years later than
scheduled in June 2008 and the first HJT-36 prototype equipped with it undertook
a 30-minute flight on May 9, 2009. HAL was, however, not able to fit the standby
generator on the aircraft. The HJT-36 prototypes subsequently met
with accidents in February 2007, February 2009 and April 2011, causing further
setbacks. Eventually in August 2014, the MoD admitted in
Parliament that the project was well behind schedule, while HAL admitted that
the HJT-36 was overweight and suffering from serious aerodynamic problems that
have implications for air safety due a design flaw.
The AL-55I, which
initially had a time-between-overhauls (TBO) of only 100 hours, subsequently
had its TBO increased to 300 hours, with its total technical service-life (TTSL)
being pegged at 400 hours. But the IAF wanted the TBO be about 1,200 hours,
since an IJT is required to fly six to eight sorties daily, clocking around 10
hours. If the TBO is just 100 hours, the turbofan will have to be replaced
every 10 days. This will require more engines and overhauls, apart from the IJTs
sitting on ground for longer periods.
In all, the project to develop the
HJT-36 has proven to be a total waste of the Indian taxpayers’ money, since the
IJT requirement became redundant and unnecessary from the day (March 26, 2004)
the MoD had inked the contract with BAE Systems for procuring an initial 66 of 123 Hawk Mk.132 AJTs (including 17
for the Indian Navy). The final nail in the coffin of the GJT-36 was struck on May
24, 2012 when the initial 75 PC-7 Mk.2 BTTs were contracted for.
The 1990s also
witnessed total lack of clarity when it came to commercial aviation industrial developmental
activities. What was required was a holistic approach that encompassed not just
the co-development and series-production of a family of regional commuter
jetliners (starting with 30-seaters, and then stretching the airframe to
include 40-seaters and 50-seaters as had been done by Brazil’s Embraer and
Canada’s Bombardier Aerospace), but also the domestic production of a range of
aircraft cabin interior fixtures and upholstery, plus the localisation of periodic
maintenance, repair and overhaul (MRO) activities for those airliners that were
being imported from Boeing and Airbus (such activities, to this day, are
outsourced from MRO centres located in Malaysia, Singapore and Sri Lanka).
By the early 1990s, while
HAL had settled down to licence-build more than 100 Dornier Do-228 19-seat STOL
twin-turboprop aircraft for both commercial and military customers in India, the
time was then ripe for HAL’s Aircraft Research & Design Centre (ARDC) to be
expanded for undertaking the co-development and co-production of another
new-generation product from Dornier—the 33-seat Do-328 was designed and initially
series-produced by Germany’s Dornier Luftfahrt GmbH (in 1996 that firm was
acquired by the US-based Fairchild Aircraft Inc and the resulting corporation,
named Fairchild-Dornier, continued series-production of the 328 family in Germany,
and also developed and produced the follow-on 44-seat 428JET variant of
the regional commuter jetliner).
Instead, HAL was ONCE
AGAIN totally sidelined and the then Govt of India in May 1998 created the Centre
for Civil Aircraft Design & Development
(C-CADD) as the nodal point of the National Aerospace
Laboratories (NAL) under the Council of Scientific & Industrial Research
(CSIR), with a mandate to play a lead role in the design and
development of small and medium sized civil aircraft. So henceforth, NAL became
the lead designer-cum-developer for civil aviation aircraft, with HAL merely
acting as the prime industrial contractor. Consequently, NAL, being essentially
a laboratory like ADA with no available human resource expertise required for
designing and developing any type of aircraft, quickly began the process of
making erroneous decisions, starting with the attempt to develop a 14-seat twin
turboprop-powered commuter aircraft called ‘Saras’.
The ‘Saras’ had already been developed in
1991 as the ‘M-102 Duet’ by Russia’s JSC V Myasishchev Experimental Machine Building Plant
which later opted out of the project due to financial constraints and offered
to sell all IPRs of this project to C-CADD in June 1998. The then NDA Govt’s
Cabinet Committee on Economic Affairs in June 1999 approved sanction for the
C-CADD to complete the M-102 Diet’s developmental process, following which in
September 1999 the project was renamed as ‘Saras’. Russia’s Central Aerohydrodynamic Institute TsAGI and Gromov Flight Research Institute (GFRI) were roped in as project consultants. NAL next received an order from the IAF to supply 15
‘Saras’ aircraft, whose deliveries were to begin in 2014 and conclude in 2017.
The first HAL-built prototype (PT-1) was powered by two Pratt & Whitney
PT6A-66 turboprop engines and its maiden flight took place on May 29, 2004. The
‘Saras’ was originally proposed to have a weight of 4,125kg but it increased by
about 24% to 5,118kg. Two prototypes have been
produced to date. The second prototype (PT-2) was built by HAL with
composite materials to decrease its overall weight by 400kg compared to that of
the PT-1. PT-2 was powered by twin uprated Pratt & Whitney PT6A-67A engines
and it made its maiden flight on April 18, 2007.
This prototype crashed near Bidadi, situated 30km away from Bengaluru, in March
2009 during a routine flight-test.
Another consultancy contract
was inked between the C-CADD and TsAGI and GFRI on February 18, 2011 under
which the two Russian parties were required to assist C-CADD in weight-budgeting
and aerodynamic optimising the airframe of the ‘Saras’ (by conducting
wind-tunnels tests at TsAGI), plus assistance for ensuring the certification of
airworthiness of the aircraft, since India’s state-owned Directorate General of
Civil Aviation is only an endorser of foreign CoAs and it does not possess the
kind of human resources required for undertaking any CoA-related tasking of an
industrial nature.
Thus, as a result of Russian assistance, the C-CADD was able
to make the following modifications to the airframe of PT-1N: significant
reduction of control forces, optimisation of nacelle design
(for the engine mounts), modifications of the environmental control system and
cabin pressurisation system, installation of an automatic
stall-warning system, modification of linear flap-tracks and trim-taps on the elevators,
enhancement of rudder area for better controllability, modification of flight-test
instrumentation, modification of electrical
systems for reducing voltage losses, and provision of nose boom for the air-data
system for redundancy, .Apart from above modification on the aircraft, the
following additional safety measures have also been ensured by the team.
Despite all this, the project’s funding was terminated
in 2012, but was revived in 2016 following
which NAL assembled a young team of 40 engineers and technicians for working on
the project for the next nine months. The modified
PT-1N prototype made its maiden flight on January 24, 2018 from the IAF’s Aircraft
& Systems Testing Establishment (ASTE) in Bengaluru. According to C-CADD,
the production version of ‘Saras’ will be a 19-seater and will undergo both
civil and military certification processes for which two Limited Series prototypes
will have to be built at a cost of Rs.500 crore. If all goes well, then
the first series-produced ‘Saras’ will be handed over to the IAF. The
C-CADD has estimated a total domestic requirement for 160 ‘Saras’ aircraft. What, however, eludes an answer is what exactly will
the ‘Saras’ be able to offer that the 19-seat HAL-built Do-228 STOL commuter
aircraft cannot? And why was C-C-CADD tasked to develop a 14-seater twin-turboprop
commuter when HAL had already begun licence-producing 19-seater twin-turboprop
commuters more than a decade earlier? Why was the development or co-development
of a 30-seater twin-turboprop or twin turbofan-powered commuter not considered
at all?
But the greatest
failure in the last decade of the last century was the inability to
series-produce the Hansa (swan)—the all-Indian, all-composite low-wing tricycle
gear two-seater general aviation monoplane for flight training as well as
personal flying. The first Hansa prototype flew on November 23, 1993, while the first definitive version
of the aircraft--built by Taneja Aerospace & Aviation Ltd—flew on May 14, 1999.
Subsequently, only 14 production version Hansa-3s were built from 2001 to 2010 of which 11 were delivered
to India’s Directorate General of Civil Aviation, one to IIT-Kanpur and two to
CSIR-NAL. Absolutely no further efforts were made to series-produce the Hansa
in large numbers, as a result of which on July
14, 2018 a Rs.105.5 crore contract was signed with Slovenia-based Pipistrel for
the Virus SW-80 aircraft, whose Indian version is known as ‘Garur’. These
aircraft, for which the RFP was floated way back in 2011, are now being operated
by the IAF (72 were ordered), Indian Navy (12 were ordered) and the NCC (110
were ordered). It was only on September
8, 2018 that NAL inked a contract with Delhi based Mesco Aerospace Ltd for the
design, development, production and marketing of the Hansa-NG, which will be
ready for its first flight by around September or October 2019 and would begin commercial
flights from 2020. Mesco Aerospace will also set up a service centre and
undertake marketing of Hansa-NG in India and abroad. The targetted selling cost
of the aircraft would be around Rs.80 lakh for the basic version and Rs.1 crore
for fully loaded version. The Hansa-NG is expected to be used for pilot
training in order to obtain private pilot and commercial pilot licenses, and
also for bird reconnaissance at airfield, cadet training, coastal surveillance
and hobby-flying in the country. The ultimate irony is that while India had
succeeded in designing and producing an all-composite light aircraft way back
in the early 1990s, China's first all-composite
five-seat aircraft, the Sunward SA-160L, completed its first flight at the
Lusong airport in Hunan only on October 8, 2018. Hunan Sunward Science
& Technologies Co Ltd, a subsidiary of Sunward Intelligent Equipment Co
Ltd, produced this aircraft with an empty weight of 900kg and a maximum takeoff
weight of 1,600kg. The company had started developing the SA-160L in 2015 and
plans to series-produce it from 2019.
Phase-4 Of Castration: The Previous Decade
In
a text-book example of reinforcing failure, the then Govt of India in 2003
decided out of the blue to co-develop with Russia’s Ilyushin OKB a
turbofan-powered tactical transport aircraft, which was initially known as
IRTA-21. Russia and India signed a protocol agreement in June 2004
to begin joint development of the IL-214. Engineering and feasibility studies
were completed in late 2004 with unusual alacrity.
JSC Irkut Aviation &
Industrial Association (JSC IAIA) was selected by Russia as the lead industrial
partner, while HAL was chosen by India. HAL revealed the withdrawal of JSC IAIA
from the project in March 2008. In its place, Ilyushin Aviation Complex (IAC)
was selected as the new lead industrial contractor from Russia. As per the
plans drawn up then, all design and prototype development activities were to be
the responsibility of Ilyushin OKB, while the front fuselage, wings and
avionics were to be built by HAL, with IAC producing the aft and centre
fuselage sections.
The IL-214 was to have featured
a high-wing monoplane design, glazed-in nose, T-shaped tail empennage,
semi-monocoque fuselage, two telphers, a cargo winch and rollers comprising
cargo handling equipment. The airframe was to be built with aluminium alloys
and composite materials. The stepped cockpit was to be equipped with six
multifunctional displays along with two heads-up indicators. The cockpit was to
have accommodated three flight crew-members, including the pilot, co-pilot and
flight engineer.
Developmental prototypes and
early production examples of the IL-214 MRTA were to have twin Aviadvigatel
PS-90A1 turbofans, each developing 17.4 tons of thrust, while series-production
aircraft were to be powered by twin Aviadvigatel PD-14M turbofans each rated at
152.98kN thrust.
The aircraft was expected to conduct its first flight by 2017, and was to
enter service by
2018.
Russia’s United Aircraft Corp (UAC) and India’s HAL
subsequently set up a subsidiary company to co-develop the MRTA. The new
company was supported by US$600.7 million in funding. The Indian portion of the
MRTA's serial production was to take place at HAL’s Transport Aircraft Division
in Kanpur. India was to have acquired 45 IL-214s and Russia 105.
However, in January 2016 it was announced that the HAL
would no longer be involved in the project and that Russia would proceed with
the project alone. On January 13,
2016, it emerged that IAC had frozen the project, and that Russia would assume
full responsibility for detailed design and production of the MRTA. As a result,
in June 2017 the aircraft received its new official designation of IL-276. Documentation
for the manufacturing plant—Aviastar in Ulianovsk—will be prepared after IAC
completes similar work on the smaller Il-112V tactical airlifter for production
at the VASO plant in Voronezh.
So
what went so horribly wrong? Firstly, the R & D workshares worked out by
Russia and India were non-implementable. While Russia possessed all the
infrastructure and human resources required for prototype development, none
existed in India. Consequently, in reality, all that HAL was required to do was
finance the prototype development phase for IAC, while IAC was to ensure that a
fully functional and certified aircraft was made available to HAL for only
part-production. As a result, HAL would not have benefitted in any manner as
far as prototype development of the IL-214 was concerned. Secondly, it was realised
that the full bill for co-developing the IL-214 MRTA would well have reached
the US$3 billion mark, for which the total number of aircraft to be ordered
would have had to be in excess of 300 aircraft in order for the project to
remain financially viable. Despite this writing on the wall, no one in either
Russia or India even bothered to co-develop a commercial air transport variant
of the IL-214, which would have created the required extra demand for such
aircraft.
Now, contrast this with Embraer
of Brazil’s effort to develop the KC-390 tactical airlifter. Brazil sanctioned
money for this project in May 2008, following which Embraer inked an
industrial partnership agreement with Boeing Co. The first KC-390
prototype made its maiden flight on February 3, 2015, followed by Embraer
declaring the KC-390 to have initial operating capability in December 2017,
ahead of full operational capability which is expected before the end of this
year.
(to be concluded)
