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IL1401 | Reciprocating diesel engine development and production technologies, including specially designed software, the following— | |
(a)Development and production technology, including specially dsigned software, for reciprocating diesel engine ground vehicle propulsion systems having all of the following characteristics— | D | |
(1)a box volume of 1.2m3 or less; (2)an overall power output of more than 750 kW based on 80/1269/EEC, ISO 2534 or national equivalents; (3)a power density of more than 700 kW/m3 of box volume. | ||
(b)Development and production technology for solid or dry film cylinder wall lubrication permitting operation at temperatures in excess of 723 K (450°C) measured on the cylinder wall at the top limit of travel of the top ring of the piston | D | |
In this entry the “box volume” means the product of three dimensions at right angles to each other measured in the following way—
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IL1416 | Vessels (including ships and surface-effect vehicles), water-screw propellers and hub assemblies, water-screw propeller systems, moisture and particulate separator systems and specially designed components, the following— | |
(a)Hydrofoil vessels with automatically controlled foil systems which are capable of speeds of above 40 knots in rough water (Sea State Five) | S, I | |
(b)Surface-effect vehicles, namely hovercraft, air cushion vehicles (both sidewall and skirted varieties) and all variations of vehicles using the wing-in-ground effect for positive lift | C | |
(c)Small waterplane area twin-hull (SWATH) vessels having underwater hulls whose cross-sectional area varies along the longitudinal axis between points two major diameters from the bow and two major diameters from the stern | C | |
(d)Ships and vessels fitted with any of the following— | ||
(1)equipment specified in Group 1, in entry IL1485 in this Group or in entry IL1501, IL1502 or IL1510 in Group 3F | S, I | |
(2)degaussing facilities | S, I | |
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(3)closed ventilation systems designed into the vessel which are designed to maintain air purity and positive pressure regardless of the conditions external to the vessel except where those closed ventilation systems are specially designed for and incorporated in the vessel’s medical facilities only | C | |
(e)Water-screw propellers and hub assemblies, the following— | ||
(1)supercavitating propellers rated at greater than 10,000 hp | C | |
(2)controllable-pitch propellers and hub assemblies rated at above 40,000 hp capacity | C | |
(f)Water-screw propeller systems, the following— | ||
(1)contrarotating propeller systems rated at greater than 20,000 hp | C | |
(2)ventilated, base-ventilated and super-ventilated propeller systems | C | |
(3)systems employing pre-swirl and post-swirl techniques for smoothing the flow into a propeller so as to improve propulsive efficiency of— | C | |
(i)SWATH vessels, hydrofoil vessels, and surface-effect vehicles, or | C | |
(ii)other vessels whose propeller rotation speed is above 200 rpm, or having propellers with a rating exceeding 50,000 hp per shaft | C | |
(g)Moisture and particulate separator systems which are capable of removing 99.9 per cent of particles larger than 2 micrometers in diameter with a maximum pressure loss of 1.6 kPa (16 millibar) for gas turbine engine air inlets | C | |
(gg)Technology for moisture and particulate separator systems specified in head (g) above only the following— | ||
(1)technology for preventing water leakage around the filter stages | D | |
(2)technology for integrating the components of such a system | D | |
(h)Specially designed components for vessels covered by heads (a), (b) and (c) above, the following— | ||
(1)advanced hull forms which incorporate any of the following— | ||
(i)stepped hull for hydrofoil vessels | C | |
(ii)hulls for air cushion vehicles with trapezoidal platforms | C | |
(iii)hulls for surface-effect vehicles with catamaran-like sidewalls | C | |
(iv)hulls for wing-in-ground effect vehicles | C | |
(v)underwater hulls and struts for SWATH vessels | C | |
(2)fully submerged subcavitating or supercavitating hydrofoils | C | |
(3)lightweight structural components for SWATH vessels, hydrofoil vessels and surface-effect vehicles, constructed using anisotropic, orthotropic or sandwich construction methods | C | |
In this subhead— 1. “Anisotropic construction methods” means the use of fibre reinforcing members aligned so that the load-carrying ability of the structure can be primarily orientated in the direction of expected stress. 2. “Orthotropic construction methods” means the means of stiffening plates, in which the structural members are at right angles to each other. 3. “Sandwich construction methods” means the use of structural members or plates which are fabricated and permanently affixed in layers to enhance their strength and reduce their weight. | ||
(4)flexible skirts, seals and fingers for surface-effect vehicles | C | |
(5)systems for automatically controlling the stability of SWATH vessels, hydrofoil vessels or surface-effect vehicles | C | |
(6)power transmission shaft systems which incorporate composite material components, for SWATH vessels, hydrofoil vessels or surface-effect vehicles | C | |
(7)lightweight, high capacity (K factor greater than 150) gearing (planetary, cross-connect and multiple input/output gears and bearings) for SWATH vessels, hydrofoil vessels and surface-effect vehicles | C | |
(8)water-cooled electrical propulsion machinery (motor and generator), including AC-AC synchronous and AC-DC systems, sectored-disc and concentric-drum rotors for DC homopolar machines, for SWATH vessels, hydrofoil vessels and surace-effect vehicles | C | |
(9)superconducting electrical propulsion machinery for SWATH vessels, hydrofoil vessels and surface-effect vehicles | C | |
(10)lift fans for surface-effect vehicles, rated at greater than 400 hp | C | |
(11)waterjet propulsor systems rated at 3,000 input hp or greater for hydrofoil vessels and surface-effect vehicles | C | |
PL7009 | Other vessels (including ships), the following: and specially designed components therefor— | |
(a)Vessels having special structural features for landing personnel and/or vehicles on a beach | I | |
(b)Vessels capable of supporting helicopter operations and maintenance | I | |
(c)Vessels capable of submerging | I | |
(d)Vessels not elsewhere specified in this Part of this Schedule of below 100 tonnes GRT including inflatable craft in an inflated or uninflated state except light vessels, fire floats and dredgers | I | |
(e)Ships with decks and platforms specially strengthened to receive weapons | S, L, I | |
IL1417 | Submersible systems including those incorporated in a submersible vehicle, the following: and specially designed components therefor— | |
(a)Automatically-controlled atmosphere-regeneration systems specially designed or modified for submersible vehicles which, in a single chemical-reaction cycle, ensure carbon dioxide removal and oxygen renewal | C | |
(b)Systems specially designed or modified for the automated control of the motion of a submersible vehicle using navigation data and having closed-loop servo-control(s) so as to– | ||
(1)enable the vehicle to move within ten metres of a predetermined point in the water column | C | |
(2)maintain the position of the vehicle within ten metres of a predetermined point in the water column | C | |
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(3)maintain the position of the vehicle within ten metres while following a cable on or under the sea bed | C | |
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(c)Underwater vision systems, the following— | ||
(1)television systems (comprising camera, lights, monitor and signal transmission equipment) specially designed or modified for remote operation with a submersible vehicle, having a limiting resolution, when measured in the air, more than 500 lines, using IEEE Standard 208/1960 or any equivalent standard | C | |
(2)systems specially designed or modified for remote operation with a submersible vehicle employing techniques to minimize the effects of back-scatter, such as range-gated illuminators | C | |
except television cameras used merely through a porthole. | ||
(d)Remotely controlled articulated manipulators specially designed or modified for use with submersible vehicles and having any of the following characteristics— | ||
(1)systems which control the manipulator using information from sensors which measure force or torque applied to an external object, distance from an external object, or tactile sense between the manipulator and an external object | C | |
except systems where force or torque are only measured and then displayed to the operator. | ||
(2)controlled by proportional master-slave techniques or by using a dedicated stored-programme computer | C | |
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(3)capable of exerting a force of 250 Newtons or more or a torque of 250 Newton-metres or more and using titanium based alloys or fibrous and filamentary composite materials in their structural members | C | |
(e)Photographic cameras and associated equipment specially designed or modified for use underwater, having a film format of 35 mm or larger, and capable of any of the following— | ||
(1)film advancement of more than 5 frames per second | C | |
(2)annotating the film with data provided by a source external to the camera | C | |
(3)taking more than 250 full frame exposures without changing the film | C | |
(4)autofocusing specially designed or modified for use underwater | C | |
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(5)operating at depths of more than 1,000 metres | C | |
(f)Light systems specially designed or modified for use under water, the following— (1)stroboscopic lights capable of— | ||
(i)light output energy of more than 150 joules per flash | C | |
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(ii)flash rates of more than 5 flashes per second at a light output energy of more than 10 joules per flash | C | |
(2)other lights and associated equipment, capable of operating at depths of more than 1,000 metres | C | |
In this entry “limiting resolution” in television is a measure of resolution usually expressed in terms of the maximum number of lines per picture height discriminated on a test chart. | ||
IL1418 | Deep submergence vehicles, manned or unmanned, tethered or untethered, capable of operating at depths exceeding 1,000 metres, and specially designed or modified associated systems, equipment, components and materials therefor, including the following— | C |
(a)pressure housings or pressure hulls; (b)propulsion motors and thrusters; (c)hull penetrators or connectors. | ||
IL1425 | Floating docks, and software and technology therefor, the following— (a) Floating docks specially designed for use at remote locations (i.e. without support from shore bases) incorporating all of the following facilities— (1) welding and pipe fitting repair shop(s); (2) electrical and electronic repair shop(s); (3) mechanical repair or metal working machine shop(s) | |
| C | |
(b)Floating docks specially equipped to permit the operation, maintenance or repair of nuclear reactors | C | |
(c)Floating docks having both the following characteristics— (1)a lifting capacity of more than 36,364 tonnes; (2)larger than 120 metres in length and 30 metres in width, measured between the pontoons. | ||
(d)Specially designed software for computer-controlled pumping and flooding systems for the above floating docks, to permit the docking of listing vessels | C | |
(e)Technology, the following— | ||
(1)for that portion of the design of a floating dock specified in head (a) above which relates to the incorporation of the three types of facilities specified in that head | D | |
(2)for design, production and use of onboard floating dock facilities specified in head (b) above which permit the operation, maintenance and repair of nuclear reactors | D | |
IL1431 | Marine gas turbine engines (marine propulsion or shipboard power generation engines), whether originally designed as such or adapted for such use, and specially designed components therefor | C |
Note: for the purpose of this entry “shipboard power generation” does not include offshore platform applications. | ||
IL1460 | Aircraft and helicopters, aero-engines and aircraft and helicopter equipment, and technology therefor, the following— | |
(a)Aircraft and helicopters, except those which do not contain equipment specified in Group 1 or in the entries IL1485 or IL1501 in Groups 3E and 3F and which are of types which are in bona fide normal civil use | C | |
(b)Technology for aircraft and helicopter airframes, for aircraft propellers, and for aircraft and helicopter airframe, aircraft-propeller and helicopter-rotor-systems components, and specially designed ODMA software therefor, the following— | ||
(1)design technology using computer-aided aerodynamic analyses for integration of the fuselage, propulsion system and lifting and control surfaces to optimize aerodynamic performance throughout the flight regime of an aircraft | D | |
(2)technology for the design of active flight control, the following— | ||
(i)technology for configuration design for inter-connecting multiple microelectronic processing elements (on-board computers) to achieve high-speed data transfer and high-speed data integration for control law implementation | D | |
(ii)technology for control law compensation for sensor location and dynamic airframe loads, namely compensation for sensor vibration environment and for variation of sensor location from centre of gravity | D | |
(iii)technology for electronic management of systems reducdancy and data redundancy for fault detection, fault tolerance and fault isolation | D | |
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(iv)technology for design of flight controls which permit in-flight reconfiguration of force and moment controls | D | |
(3)design technology for integration of flight control, navigation and propulsion control data into a flight management system for flight path optimzation | D | |
(4)design technology for protection of avionic and electrical sub-systems against electromagnetic pulse (EMP) and electromagnetic interference (EMI) hazards from sources external to the aircraft, the following— | ||
(i)technology for design of shielding systems | D | |
(ii)technology for the configuration design of hardened electrical circuits and sub-systems | D | |
(iii)technology for determination of hardening criteria for the above | D | |
(5)technology for the design, production and reconstruction of adhesively bonded airframe structural members designed to withstand operational temperatures in excess of 120°C | D | |
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(6)technology for the design and production of propeller blades constructed wholly or partly of composite materials, and specially designed hubs therefor | D | |
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(7)technology for the design and production of digital electronic synchrophasers specially designed for propellers; technology for the design of digital electronic controls for propellers; and technology for the production of digital electronic controls for the propeller blades and hubs described in sub-head (b)(6) above | D | |
(8)technology for the design and production of active laminar flow control lifting surfaces including design data used to substantiate the design approach | D | |
(9)technology for the development of helicopter multi-axis fly-by-light or fly-by-wire controllers which combine the functions of at least two of the following into one controlling element | D | |
(i)collective controls; (ii)cyclic controls; (iii)yaw controls. | ||
(10)technology for the development of circulation controlled anti-torque or directional control systems for helicopters | D | |
Note: “Circulation-controlled anti-torque and directional control systems” utilise air blown over aerodymamic surfaces to increase or control the forces generated by the surfaces. buried fan-in-fin anti-torque designs fitted or not fitted with guide vanes such as the fenestron are excluded from this subhead. | ||
(11)technology for the development of helicopter rotor blades incorporating variable geometry airfoils utilizing trailer edge flaps or tabs or pivotted nose droop, which can be controlled in position in flight | D | |
(12)technology for the development of active control of helicopter blades and other surfaces used to generate aerodynamic forces and moments | D | |
Note: “Active control” (of helicopter blades and other surfaces used to generate aerodynamic forces and moments) functions to prevent undesirable helicopter vibrations, structural loads or helicopter rotor dynamic behaviour by autonomously processing outputs from multiple sensors and then providing necessary preventive commands to effect automatic control. | ||
(c)Helicopter power transfer systems and technology therefor | C | |
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(d)Gas turbine engines and auxiliary power units (APUs) for use in aircraft or helicopters and technology therefor— | C | |
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(e)Specially designed components for gas turbine engines, APUs and helicopter power transfer systems specified in heads (c) and (d) above, the following— | ||
(1)embodying technologies listed in Tables 1 or 2 below | C | |
(2)hot-section components | C | |
(3)engine control system components | C | |
(4)gas turbine engine or APU rotor system components (including bearings) | C | |
Notes: 1. The period of civil use referred to in heads (c) and (d) above begins with the date that the particular engine or helicopter power transfer system (model and specifications) or its most recent modification was certified as airworthy for commercial service or commercial navigability under the standards and requirements of the government of the country in which it was manufactured: modification does not include minor safety or operational changes which do not significantly enhance the performance of a particular gas turbine aero-engine or improve its reliability. For the purposes of this entry: (a)A gas turbine aero-engine which is recertified as the result of incorporating any technology listed in Table 1 below is to be treated as a newly certified engine. Recertification which does not result from incorporation of such technology, or modifications which do not require recertification by national authorities, will not affect the period of civil use of the engine; (b)Modification of a gas turbine APU by incorporation of any technology listed in Table 1 will cause it to be treated as a new APU. Other modifications will not affect the period of civil use of the APU. (c)Modification of a helicopter power transfer system by incorporation of any technology listed in Table 2 will restart the period of civil use for the helicopter power transfer system as though it were newly certified in a helicopter. Other modifications will not affect the period of civil use of the helicopter power transfer system. 2. This entry does not include gas turbine engines, APUs and helicopter power transfer systems for civil use and modifications (and technology therefore) certified or re-certified for civil use, as described in Note 1 prior to the 1st January 1979, other than: Helicopters over 4,530 kg empty weight, and power transmissions systems therefor. Note: Empty weight is understood to include normal installation and normal minimum crew, but does not include fuel or payload. Aero-engines, the following— (i) Piston engines; (ii) Jet engines of less than 2,625 kg thrust; (iii) Turboprop or turboshaft engines of less than 2,500 horsepower or with a residual thrust of less than 453 kg. 3. Head (d) above does not include those engines which contain none of the technologies listed in Table 1 below for use in civil aircraft or civil helicopters. |
TECHNOLOGY RELATING TO THE FOLLOWING I. Materials and manufacturing procedures Ceramic, ceramic-composite or composite hot-section components (combuster, turbine blades and vanes, seals, discs, flow path) Turbine blades on basis of directional solidification or monocrystal technology
Turbine blades consisting of several parts connected by diffusion bonding Fibre technology in frames or in highly stressed discs, casings, blades and vanes Protective coating technology for air-cooled turbine blades and vanes with internal and external cooling passages and their related flow paths capable of operating in high gas temperature environments (in excess of 1,499°C), irrespective of the actual gas temperature environment in which they will be used, involving applications of metallic or ceramic material by vapour, pack, plasma, electron beam, sputtering or sintering processes Metallic coatings
Ceramic Coatings Application of powder metallurgy for fan compressor and turbine blades or vanes; discs, wheels, reduction gears, engine main shafts and frames
Cooled components on basis of electrostream or laser drilling methods;
Electron beam drilling for small holes in turbine blades and vanes Titanium or superalloy—casting on basis of centrifugal techniques Ceramic core casting technology for casting holes in turbine blades and vanes II. Construction methods Adjustable flow path geometry and associated control systems for:
(Adjustable flow path geometry and associated control systems do not include: inlet guide vanes, variable pitch fans, variable stators or bleed valves for compressors.) Full authority or hybrid digital electronic control and respective sensor equipment High temperature (capable of utilizing gases heated above 1,100°C) heat exchangers for preheating compressor exit air Combustors with combustion in several stages Maintenance of compressor or turbine tip clearance through methods employing active compensating casing technology:
Ceramic bearings Nozzles with thrust vectoring (not including reverse thrust) |
TECHNOLOGY RELATING TO THE FOLLOWING 1. Materials and manufacturing procedures A. Rotor heads, containing:
B. Gear boxes, containing:
C. Drive shaft systems containing super-critical drive shafts II. Construction methods A. Components fabricated by diffusion bonding B. High-survivability loss-of-lubrication technology for high-speed bearings (DN equal to or greater than 2.4 million where D is expressed in millimetres and N in rpm) |
In this entry— “civil aircraft” and “civil helicopters” means only those types of civil aircraft and civil helicopters which are listed by designation in published airworthiness certification lists by the civil aviation authorities to fly commercial civil internal and external routes or for legitimate civil, private or business use. “helicopter power transfer systems” means all those components which transfer power from the engine to the main and tail rotor blade(s). Note: Aero-engines, APUs or helicopter power transfer systems which have any special feature designed for a military application are specified in the entry ML10 in Group 1. | ||
PL7010 | Aircraft and helicopters having a maximum all up weight of 680 Kg or more | L, Z |
PL7011 | Specially designed components for aircraft and helicopters specified in head (a) of the entry IL1460 other than components falling within a description in Group 1 or under any other heading in Group 3 of Part II, of this Schedule | W |
IL1465 | Spacecraft and launch vehicles, the following— | |
(a)Spacecraft, manned or unmanned (not including their payloads) | C | |
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(b)Launch vehicles | C | |
(c)Propulsion systems, guidance equipment, attitude control equipment and on-board communications equipment for remote control of the equipment specified in head (a) or (b) above | C | |
(d)Specially designed components for the equipment specified in heads (a), (b) and (c) above | C | |
In this entry “spacecraft” means active and passive satellites and space probes. | ||
IL1485 | Compasses, gyroscopes, (gyros), accelerometers and inertial equipment, the following: and specially designed software and specially designed components therefor— | |
(a)Gyro compasses with provision for determining and transmitting ship’s level reference data (roll, pitch) in addition to own ship’s course data | C | |
(b)Integrated flight instrument systems which include tyrostabilisers or automatic pilots for aircraft and specially designed integration software therefor | C | |
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(c)Gyro-astro compasses and other devices which derive position or orientation by means of automatically tracking celestial bodies | C | |
(d)Gyro-stabilisers used for other purposes than aircraft control | C | |
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(e)Automatic pilots used for purposes other than aircraft control and specially designed integration software therefor, except marine types for surface vessels | C | |
(f)Accelerometers with a threshold of 0.005 g or less or a linearity error within 0.25 per cent of full scale output or both, which are designed for use in inertial navigation systems or in guidance systems of all types | C | |
(g)Gyros with a rated free directional drift rate (rated free precession) of less than 0.5 degree (1 Sigma or r.m.s.) per hour in a 1 g environment | C | |
(h)Continuous output accelerometers which utilize servo or force balance techniques and gyros, both specified to function at acceleration levels greater than 100 g | C | |
(i)Inertial or other equipment using accelerometers specified in head (f) or (h) above or gyros specified in head (g) or (h) above, and systems incorporating such equipmenmt, and specially designed integration software therefor | C | |
(j)Specially designed test, calibration and alignment equipment for goods specified in heads (a) to (i) above | C |
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