CN212023022U - Facilities or arrangements for taxiing aircraft without landing gear or tyres or brakes - Google Patents

Abstract

The utility model relates to a facility or a device which is not provided with an undercarriage, a tire or a braking component and is needed for taking off and landing in a sliding mode, wherein the facility or the device at least comprises a runway groove or a track groove or a raft vehicle or a stop aid or a booster or an accumulator or a controller or a detector or a fork element or a guiding device; the accumulator is provided with a pneumatic or hydraulic part or an elastic substance; the runway or the parking aid, the booster or the raft vehicle is provided with a power accumulator or a steam type catapult or an electromagnetic type catapult or a controller or a detector or a lifter; a hooking device or a guiding device or a lifting device or a fire fighting device or an emergency device or a medical device or a flying assisting slope or a ladder or a slide or a manned escalator or a freight elevator is arranged on the parking aid or the booster or the raft vehicle or the lifter or on the road surface of the runway; the guiding means can alternatively act as a hooking means.

Description

Facilities or arrangements for taxiing aircraft without landing gear or tyres or brakes

Technical Field

The utility model relates to a facility or device that aircraft take off and land required, especially a do not establish undercarriage or tire or arresting member the aircraft with the required facility or device of safe take off and land of mode of sliding.

Background

Aircraft are known to be provided with landing gear or tires or brakes for safe taxiing take-off and landing. Before the airplane lands, the landing gear is put down to spread the tires, then the tires are damped on the runway by means of the landing gear and the tires, meanwhile, the tires are enabled to slide on the runway and decelerate until the tires are stable, or the tires of the airplane are enabled to stop rotating after sliding for a short distance on the runway through a stopping cable or other various braking modes. The catapult takeoff or the taxi takeoff of the airplane requires that the tire can take off after moving on a runway at high speed through thrust generated by rotation of a steam catapult, an electromagnetic catapult, a fuel injection device or a propeller; vertical take-off and landing of an aircraft also requires landing gear or tires to be supported on the ground.

The shapes and weights of the landing gear, the tires and the braking part are different according to the weight of the airplane. The landing gear and tires of large passenger aircraft, heavy fighters, bombers are large and weigh one or several tons, which undoubtedly wastes the limited space and load capacity of the aircraft. In order to ensure that the airplane tire is wear-resistant, collision-resistant and high-pressure-resistant in high-speed rotation, the manufacturing process and the cost of the tire and the braking part thereof are high.

The recoverable missile or rocket is not provided with an undercarriage, tires and braking parts, and vertical launching and vertical landing modes are adopted for launching and landing. But vertical launch and vertical descent, consume fuel.

I have disclosed different methods and devices for landing, taking off and storing power of aircraft in the inventions of application numbers 201711326472.6, 201910889501.2, 201910873265.5, 201910757015.5, 201911265226.3, etc., but have not disclosed a method and technology for taking off and landing in a sliding manner without landing gear or tires or brakes on the aircraft.

Disclosure of Invention

The utility model aims at providing a do not have undercarriage or tire or the required facility or the device of braking part aircraft with the mode take off and land of coasting. The main technical problems to be solved are as follows: 1. no landing gear or tires or brakes are provided on the aircraft. 2. Corresponding facilities or devices are arranged on the runway. 3. The function of the landing gear or the tire or the braking part on the aircraft is transferred to the corresponding facility or device on the runway, so that the aircraft without the landing gear or the tire or the braking part can be safely lifted and descended in a sliding mode. 4. Is suitable for intelligent control.

To the above problem, the utility model discloses a following solution is solved: the runway is provided with facilities or devices which can replace the functions of landing gears or tires or braking members on the aircraft or can assist the taking off and landing of the aircraft, and the facilities or devices at least comprise runway grooves or track grooves or raft vehicles or assisted parking devices or boosted devices or accumulators or controllers or detectors or forks or guide devices; the forks include orbital forks or rotating forks or unmanned forks that can move the aircraft into position like a forklift, such as to fork the aircraft from an elevator for placement on a runway in a takeoff position. The accumulator is provided with a pneumatic or hydraulic part or an elastic substance, and can store the inertia impact force of the aircraft during landing by compressing or stretching the elastic substance or store the atmospheric pressure by pumping out the gas or liquid in the pneumatic or hydraulic part or the pneumatic or hydraulic part to enable the interior of the pneumatic or hydraulic part or the pneumatic or hydraulic part to tend to be vacuum or become vacuum so as to generate the atmospheric pressure. The stopping aid, the booster or the raft vehicle compresses or stretches elastic substances, or compresses or stretches gas or liquid in pneumatic or hydraulic parts or the pneumatic or hydraulic parts, or assists the aircraft to land or take off through a steam driving device or an electric driving device. The guide device comprises a rotating part or a wear-resistant part or a track groove or a track groove or a tubular object or a magnet or a magnetic suspension device or a buffer device or a positioning device or a clamping device or a steam driving device or an electric driving device; the magnet comprises a permanent magnet or an electromagnet. The main components or parts of the buffer device comprise a wheel, a flywheel, a tire, a gear, a rack, a track, a chain, a liquid filling piece, an inflating piece, an air pressing piece, a hydraulic piece, an air pressing piece, an anti-collision piece, a blocking piece, a braking piece or an elastic shock absorption device, and the elastic shock absorption device is composed of two or more layers; such as a resilient damping device consisting of two layers of steel plates or springs. The rotating part comprises a wheel or a flywheel or a ratchet wheel or a gear or a tire or a bearing or a roller or a conveyor belt or a crawler belt; the rotation of the rotating piece is controlled by a steam driving device, an electric driving device, a speed changer or a braking piece; the arresting piece comprises an arresting cable, an arresting rod, an arresting column, an arresting block, an arresting plate, an arresting wall, an arresting net or an arresting sleeve; the controller comprises a manual controller, a remote controller, an intelligent controller or an intelligent integrated controller; the main components in the positioning device comprise a magnet piece, a sucker piece, a bolt piece, a buckle piece, a spiral piece, an expansion piece, a binding piece, a hook piece, a hanging piece, a sleeve piece, a clamping piece or a surrounding piece; on the runway or in the runway groove or the track groove, or a liquid or guiding device or an accumulator or a steam ejector or an electromagnetic ejector is arranged; the carrier of the runway is the deck of a ground or liquid or surface ship. The facility or apparatus may be located directly or indirectly on the ground or on the deck.

Preferably, the runway or the parking aid or the booster or the raft vehicle is provided with an accumulator or a steam type ejector or an electromagnetic type ejector or a controller or a detector or a lifter; the parking aid, the booster or the raft vehicle is parallel to or connected with or combined with the elevator into a whole; a hooking device or a guiding device or a lifting device or a fire fighting device or an emergency device or a medical device or a flying assisting slope or a ladder or a slide or a manned escalator or a freight elevator is arranged on the parking aid or the booster or the raft vehicle or the lifter or on the road surface of the runway; the guiding device can be used as a hooking device; a boosting part is arranged on the booster, and a rotating part is arranged at the upper end of the boosting part; the booster or the raft vehicle or the runway or the deck is provided with a flame baffle plate, and the flame baffle plate is provided with a rotating part; a guide device is arranged on or on the flying assisting slope; the upper end face of the stop aid or the booster or the raft vehicle is as high as or almost as high as the road surface of the runway; or when the raft vehicle stays on the stopping aid or the booster, the upper end surface of the raft vehicle is equal to or almost equal to the road surface of the runway; the stop aid is combined with the booster into a whole.

Preferably, a booster or a stopping aid or an accumulator or a chemical energy pusher or a steam ejector or an electromagnetic ejector is arranged on the raft vehicle. The chemical energy impeller comprises a jet engine or a fuel injection device.

Preferably, the parking aid or the booster is of a double-layer or three-layer structure or is in a step shape, the parking aid or the booster in the step shape is at least provided with a first step and a second step, the upper end surface of the second step is equal to or almost equal to the pavement of the runway in height, and the upper end surface of the second step is provided with a guide device; when the raft vehicle stays on the first-stage step of the parking aid or the booster, the upper end face of the raft vehicle is equal to or almost equal to the upper end face of the second-stage step.

Preferably, the guiding device can be a clip-type lead-in and lead-out device or an arched or frame-shaped supporting device; the leading-in and leading-out device is in a lying type, one end of the leading-in and leading-out device can lead in a landing aircraft or lead out an aircraft needing to take off, two sides of the leading-in and leading-out device can move or can move, and the space between the two sides can be narrowed or widened; the controller can move the position of the lead-in and lead-out device or adjust the width of the space according to the real-time position of landing or takeoff of the aircraft; the supporting device is in a vertical or inclined type, two sides of the supporting device are erected on a runway or a stop aid or a booster or a raft vehicle, the two sides can be bent, rotated or stretched, the two sides can keep a vertical or inclined state or an arc shape through elastic force, the two sides are formed by combining superposed elastic sheets, and the two sides are connected into a frame shape through a rotating piece or a blocking rod; the barrier rod is provided with a buffer device; the supporting device can be arranged or combined by two or more pieces; the top surface of the supporting device is provided with a plate-shaped object or a strip-shaped object or a block, and the plate-shaped object or the strip-shaped object or the block is provided with a buffer device.

Preferably, the aircraft is provided with a tail hook or a telescopic piece or a detector or a controller or is provided with a power switch which allows or does not allow the ground command center to remotely control the aircraft to take off and land; the tail hook or the telescopic piece is provided with a rotating piece; the telescopic piece is in a plate shape, a block shape, a tubular shape, a strip shape or a column shape, and a groove, a convex object or a corner is arranged on or arranged on the telescopic piece; the turning piece or the corner can act as a tail hook; the number of the tail hooks or the telescopic pieces is two or more, the tail hooks can be straightened or folded, and the straightened state, the folded state or the hooked state of the tail hooks is controlled by a pneumatic or hydraulic piece, a pulley or a pulley block, a spring or a gear or a chain or a spiral device; the aircraft is connected with the tail hook through a rod-shaped object, a strip-shaped object or a block-shaped object, and the connection position of the rod-shaped object, the strip-shaped object or the block-shaped object and the tail hook can be rotated or is provided with a joint or is provided with a spring, a hydraulic piece, a pneumatic piece or a spiral device; the cross section of the rod-shaped object or the strip-shaped object or the block-shaped object can be in any geometric shape; the strip comprises a rope; the number of the rods, the strips or the blocks is two or more; the shaft or block may be bifurcated or may be flexible or resilient.

Preferably, the side of the aircraft, which faces the runway and is used for landing, is provided with a convex part or a groove or a rotating shaft or a transmission part or a guide device; the convex part or the groove or the rotating shaft or the transmission part or the guide device is magnetic or provided with a stealth coating; the cross section of the rotating shaft is a regular or irregular semicircle or trapezoid; the rotating shafts can be arranged together by two or more than two. The shape of the rotating shaft can also be square or diamond or crescent or any other geometrical shape.

Elastic substance divide into metal elastic substance and non-metal elastic substance, metal elastic substance includes spring, metal strip, sheetmetal, metal sheet, non-metal elastic substance includes rubber, silica gel, plastics, plastic, resin, gas. The conveyor belt is also called as a conveyor belt. The convex piece comprises a convex strip, a convex block, a convex plate and a convex sheet. The sliding mode comprises a rolling sliding mode, a sliding mode and a magnetic suspension sliding mode. The taking off and landing comprises taking off or landing, landing and stopping stably. The manned escalator comprises a manned elevator; the aircraft includes aircrafts and spacecrafts, such as civil or military aircrafts, space shuttles, missiles and rockets. The landing gear or the tire is not provided with the landing gear or the tire or the braking member, and the landing gear or the tire can completely support the aircraft to be separated from the ground, and the braking member can brake the tire.

The beneficial effects of the utility model are that, after having adopted above-mentioned method and device: (1) because related facilities or devices are arranged on the runway to replace the functions of the landing gear, the tire or the braking part on the aircraft, the landing gear, the tire or the braking part can not be arranged on the aircraft, the saved space and weight can enable the aircraft to carry more people or objects, and if the method and the technology are applied to civil aircrafts, the manufacturing cost can be saved, and the economic benefit can be improved. If the oil is applied to military aircraft, the range can be enlarged by adding oil, and the fighting capacity can be enhanced by increasing the loading capacity. If the device is applied to missiles and rockets and assisted by corresponding facilities or devices, the missiles and the rockets can take off like an unmanned aerial vehicle and cruise on the sky, fuel is exhausted, and for safety, the detonating fuse can be closed firstly to return to a take-off and landing field for replenishing fuel, and then cruise on the day again. The missile and rocket have the advantages of low cost, ultrahigh speed and long-time cruising, can be used as a killer of a stealth airplane, can also be used as a substitute of a bomber and a reconnaissance plane, and can also be used as a recoverable low-cost low-orbit attack type satellite. If the method is applied to the aircraft carrier, the carrying capacity of the carrier-based aircraft can be improved, and the take-off and landing efficiency of the carrier-based aircraft can be improved under the condition that the original area of a deck is not required to be increased. Theoretically, the carrier-based aircraft can take off and land for one rack time in five to twenty seconds on average. The speed is not lower than the take-off and landing speed of the existing vertical take-off and landing aircraft, and deck work can span towards the direction of mechanized, intelligent and unmanned management. (2) By arranging facilities or devices such as a parking aid, a booster, an accumulator, a guide device and the like, the take-off and landing runway can be greatly shortened, which is beneficial to the construction of airports in islands or places with limited conditions. (3) The aircraft directly lands on the raft vehicle or directly takes off from the raft vehicle, the aircraft can carry the passengers, goods, and the like on an airport in the whole process, the mechanical, fuel or electric power loss of the aircraft can be reduced, and compared with the aircraft, the manufacturing process and material, and the manufacturing, using and maintaining costs of the raft vehicle are greatly different. (4) The energy accumulator or the steel plate or the arresting rod is used for replacing the arresting cable, so that the manufacturing, using and maintaining costs are reduced, and the safety is higher.

Drawings

The following further describes the embodiments of the present invention with reference to the drawings, but the scope of the present invention is not limited to the drawings and the embodiments thereof.

Fig. 1 is a schematic side view of a first embodiment of the invention in relation to an aircraft landing on a runway and then taxiing above a stop-assist.

Fig. 2 is a schematic top view of the embodiment shown in fig. 1.

Fig. 3 is a schematic side view of a second embodiment of the invention in relation to a raft vehicle parked on a first step of a stop-assist and an aircraft parked on a second step of the stop-assist.

Fig. 4 is a schematic side view of the approach shown in fig. 3 with the docking aid moved from the head end to the tail end of the runway and the aircraft also moved onto the raft vehicle.

Fig. 5 is a schematic side view of a third embodiment of the present invention in relation to an accumulator, a booster, a raft vehicle, a guide device, and a flight assist ramp to assist in takeoff of an aircraft.

Fig. 6 is a schematic plan view of a fourth embodiment of the present invention, showing the arrangement of thrusters, stops and guides on the deck of an aircraft carrier.

FIG. 7 is a schematic top view of the version of FIG. 6 with the booster and the docking assist deployed.

Fig. 8 is a schematic side view of a fifth embodiment of the invention in relation to a missile landing on a stop aid.

FIG. 9 is a schematic top view of the docking aid, accumulator, assisting in landing a missile in the manner shown in FIG. 8.

Wherein, the first embodiment: the device comprises a runway 1, supporting devices 2 and 3, an elastic damping device 4, a stop aid 5, supporting devices 6 and 7, a track 8, a raft vehicle 9, a supporting device 10, a positioning device 11, an aircraft 12, a telescopic piece 13, a rotating piece 14, a chain 15, a gear 16, a piston 17, a cylinder 18, an intelligent controller 19, an electric pump 20, an air inlet 21, a positioning device 22 and rotating shafts 23 and 24. The second embodiment: runway 201, docking aid 202, raft vehicle 203, steel plates 204, 205, 206, arresting rod 207, aircraft 208, telescopic part 209, arresting rod 210, intelligent controller 211, motor 212, exhaust hole 213, air cylinder 214, piston 215, spring 216, bolt 217, hole 218, arresting parts 219, 220 and bolt 221. Third embodiment: the device comprises a runway groove 301, an air pressure member 302, a spring 303, a booster 304, bolts 305 and 306, a raft vehicle 307, an intelligent controller 308, an air pump 309, an aircraft 310, a flight assisting slope 311, a driving wheel 312, a conveyor belt 313, an air pressure member 314, an air pump 315, a booster 316, a clamping piece 317, a buffer device 318, a switch 319, a flame baffle 320, a clamping piece 321 and a flywheel 322. Fourth embodiment: elevators 401, 402, 403, 404, guides 405, 406, 407, 408, positioning devices 409, 410, 411, 412, docking aids 413, guides 415, clamping devices 416, rail ways 417, rotors 418, 419, transition decks 420, boosters 421, 422, flame shields 423, guides 424, rotors 425, guides 426, 427, 428, 429, warship islands 430, landing ramps 431, 432, fire suppression devices 433, rescue decks 434, barriers 435, clamping devices 436, rescue devices 437. Fifth embodiment: the parking aid comprises a parking aid 501, a steel plate 502, a rolling shaft 503, a steel plate 504, a steel plate 505, a blocking rod 506, a missile 507, a tail hook 508, a blocking rod 509, an accumulator 510, a folding wing 511, a tail rudder 512, a runway groove 513, a protective cover 514, fuel tanks 515 and 516 and a crawler 517.

Detailed Description

Referring to fig. 1 and 2, an arch support device 2, 3 and an elastic damping device 4 are disposed on a head end runway surface of a runway 1, the support device 2, 3 can rotate leftward and can be reset by the elastic force of a spring, and the elastic damping device 4 can move downward and can be reset by the elastic force of the spring. The upper end surface of the stopping aid 5 is as high as the head end track surface of the runway 1, the upper end surface of the stopping aid 5 is also provided with supporting devices 6 and 7, and the stopping aid 5 can move along a track 8. The tail end of the runway 1 is stopped with the raft vehicle 9, the upper end face of the raft vehicle 9 is also provided with a supporting device 10, and a positioning device 11 arranged at the tail end of the runway 1 is upwards bounced to fix the raft vehicle 9 in position. When the aircraft 12 lands on the supporting devices 2 and 3, the impact force of the aircraft can enable the supporting devices 2 and 3 to rotate towards the left lower side and press the elastic damping device 4, and at the moment, the aircraft 12 can bounce up and down; when the aircraft 12 moves to the position above the parking aid 5, the sliding tends to be stable, at this time, the telescopic piece 13 arranged on the aircraft 12 can be made to pop out downwards, meanwhile, the rotating piece 14 below the telescopic piece 13 and the lower part of the telescopic piece 13 are made to be in a tail hook shape through a hydraulic device so as to be convenient to hook the supporting device 6, the aircraft 12 drives the parking aid 5 and pulls the piston 17 to move through the chain 15 and the gear 16, the intelligent controller 19 arranged on the cylinder 18 can control the air inflow of the air inlet 21 through the electric pump 20, even completely close the air inlet 21, ensure that the piston 17 moves at a proper moving speed and obtains enough force to force the parking aid 5 to stop moving at the moment close to the raft vehicle 9, and meanwhile, the intelligent controller 19 instructs the positioning device 22 to pop out upwards to clamp the piston 17 to stop at the position. At this time, the aircraft 12 also changes the tail hook below the telescopic piece 13 into an extended state through a hydraulic device and retracts rapidly, the aircraft 12 after unhooking can automatically slide onto the raft vehicle 9 from the parking aid 5 under the pushing of the residual force of inertia impulse, and the raft vehicle 9 can drive away from the runway 1 to the place where the aircraft 12 should go. The side of the aircraft 12 facing the runway is provided with rotating shafts 23 and 24 in a transverse arrangement mode, the rotating shafts 23 and 24 are strip-shaped, the cross sections of the rotating shafts 23 and 24 are isosceles trapezoids, the waist of the rotating shafts are arc-shaped, the shape of the rotating shafts is irregular trapezoids, a wear-resistant layer is arranged on one side of the upper bottom of the rotating shafts and can cope with landing sliding friction, a stealth coating is arranged on one side of the lower bottom of the rotating shafts and can realize high-altitude stealth, and different selections can be completed by rotating the.

Referring to fig. 3 and 4, the runway 201, the second step of the stepped docking aid 202, and the upper end surface of the raft vehicle 203 are all at the same height, and are provided with elastic shock-absorbing devices, each of the elastic shock-absorbing devices is formed by arranging a plurality of steel plates 204, 205, 206 at intervals, the upper end of the steel plate 204 is coiled with a barrier rod 207, and the lower end of the steel plate is connected with the runway surface of the runway 201 in an inclined manner. The aircraft 208 can land on the steel plate 204, and after the aircraft 208 slides stably, the aircraft 208 enters the upper part of the second step of the parking aid 202, the telescopic part 209 is pushed downwards, the movable corner below the telescopic part 209 hooks the blocking rod 210, so that the inertial impulse of the aircraft 208 drives the parking aid 202 and the raft vehicle 203 staying on the first step of the parking aid 202 to move towards the left side, at the moment, the intelligent controller 211 can automatically control the air output of the exhaust hole 213 through the motor 212, and the inertial impulse of the aircraft 208 is counteracted by the air pressure in the air cylinder 214 and the elastic force of the spring 216 arranged on the piston 215. When the docking aid 202 moves to the end of the left direction, the bolt 217 arranged on the docking aid 202 is automatically inserted into the hole 218 arranged at the tail end of the runway 201, meanwhile, the hydraulic device on the aircraft 208 immediately breaks the movable corner arranged below the telescopic part 209 straight, the telescopic part 209 is quickly retracted, the aircraft 208 after unhooking can automatically slide from the upper end surface of the second-stage step to the upper end surface of the raft vehicle 203 by the residual force of inertia impulse and is clamped by the blocking parts 219 and 220 in the front-back direction, then, the intelligent controller 211 continuously instructs the bolt 221 arranged on the first-stage step to fall down, the positioning control on the raft vehicle 203 is released, and the raft vehicle 203 can drive away from the runway 201 with the aircraft 208.

As shown in fig. 5, an accumulator is arranged in the runway groove 301, the accumulator is composed of an air pressure part 302 and a spring 303, the head end of the air pressure part 302 is connected with a booster 304, the booster 304 is provided with bolts 305 and 306, the bolt 305 is responsible for positioning a raft vehicle 307, and the bolt 306 is responsible for positioning the booster 304. An intelligent controller 308 and an air pump 309 are arranged on the side surface of the tail end of the pneumatic component 302, the booster 304 is positioned through the bolt 306, and the air pump 309 can vacuumize the inside of the pneumatic component 302. The tail end of the pneumatic component 302 is provided with a flying assisting slope 311, and the flying assisting slope 311 is provided with a rotating component which consists of a driving wheel 312, a flywheel 322 and a conveying belt 313. The raft vehicle 307 is provided with a flame baffle 320 and an accumulator, the accumulator is composed of an air pressure part 314, the air pressure part 314 is provided with an air pump 315, and one end of the air pressure part 314 is connected with a boosting part 316. When the pneumatic member 314 is fully expanded by the force of the internal spring, the boosting member 316 is locked and positioned by the locking member 317, and at this time, the air pump 315 can completely pump out the air in the pneumatic member 314 to form a vacuum in the pneumatic member 314, so that the boosting member 316 stores a strong atmospheric pressure capable of moving in the left direction. When the aircraft 310 needs to be ejected for takeoff, firstly, the raft vehicle 307 is stopped above the booster 304 with the aircraft 310, the position of the raft vehicle is fixed by the bolt 305, then an engine of the aircraft 310 is started, then an electric driving device arranged on the flying-assisting slope 311 is started, the driving wheel 312 and the flywheel 322 drive the conveyor belt 313 to rotate at a high speed, when the rotating speed reaches a preset value, the intelligent controller 308 instructs the bolt 306 to release the control of the booster 304, so that the booster 304 ejects the aircraft 310 for the first time through the raft vehicle 307 under the action of the atmospheric pressure accumulated by the air pressure piece 302, before the raft vehicle 307 collides with the buffer device 318, the switch 319 is touched to release the positioning control of the aircraft 310 by the clamping piece 321 on the raft 307, and simultaneously the positioning control of the booster 316 by the clamping piece 317 is also released, so that the booster 316 can be under the action of the atmospheric pressure accumulated by the air pressure piece 314, the aircraft 310 is ejected for the second time, and the aircraft 310 also obtains the auxiliary thrust of the conveyor belt 313 during the process of the ski-jump takeoff. That is, this takeoff process of the aircraft 310, results in four successive thrust assisted flights: atmospheric pressure stored in the pneumatic element 302, atmospheric pressure stored in the pneumatic element 314, engine thrust of the aircraft 310, and auxiliary thrust of the conveyor belt 313.

With reference to fig. 6 and 7, four elevators 401, 402, 403, 404 are provided on the aircraft carrier deck, and each elevator is provided with a guiding device 405, 406, 407, 408 and a positioning device 409, 410, 411, 412, respectively, wherein the elevator 403 has two layers, the next layer is used for carrying and transporting carrier aircraft, the upper layer is the top layer of the elevator, and the top layer is also provided with a guiding device, so that the carrier aircraft landed from the parking aid 413 can slide on the top layer to reach the elevator 404. The docking aid 413 is provided with a guide 415 and a clamp 416. When the landing of the aircraft carrier needs to be met, the intelligent integrated controller 414 instructs the parking aid 413 to extend backwards along the track slot 417, if the length of the parking aid 413 is 120 meters, according to a common practice, the aircraft carrier will land at the middle section of the parking aid 413 and extend out of the tail hook to hook the guiding device arranged at the middle section, then the inertial impulsive force of the aircraft carrier will drive the whole parking aid 413 to move towards the elevator 403, and at this time, the parking aid 413 will immediately deploy two tasks: firstly, the accumulator arranged below the deck stores power, and the inertia impulsive force of the carrier-based aircraft is quickly digested. Secondly, the clamping devices 416 are close to the middle of the two sides of the docking assistant 413, and the positions of the carrier-based aircraft are corrected, so that each carrier-based aircraft can accurately slide to the elevator 403 or the elevator 404 every time. When the ship-based aircraft is not lifted and landed but needs to be fully loaded, the intelligent integrated controller 414 also instructs the parking aid 413 to extend backwards, then the rotating pieces 418 and 419 near the track groove 417 are lifted up through the lifting device to be equal to other guiding devices in height, and as the rotating pieces 418 and 419 can respectively enable the ship-based aircraft staying on the rotating pieces to move towards the transverse direction or the longitudinal direction, the ship-based aircraft can be uniformly distributed at each appropriate position, including the ship-based aircraft after being popped up, and then the ship-based aircraft is positioned through a positioning device such as a sucker device to deal with high wind and high waves. If the pilot can not safely control the aircraft due to the injury, a power switch which requests the remote control of the ship-based aircraft can be turned on, and the landing work is handed over to the ship-based island staff to be completed. If the carrier-based aircraft is on fire, the tail hook hooks the guiding device on the parking aid 413 instantly when the carrier-based aircraft lands, the intelligent integrated controller 414 instructs the fire extinguishing device 433 to be unfolded and operated at the first time, and when the parking aid 413 is to be stopped stably, the carrier-based aircraft is instructed to stretch, straighten and retract the tail hook, so that the carrier-based aircraft rapidly slides over the elevators 403 and 404 from the parking aid 413 to the rescue deck 434 by using the residual force of inertial impulsive force, and is positioned by the stopping piece 435 and the clamping device 436, so that the rescue device 437 can continuously complete emergency tasks such as fire extinguishing, rescue, medical care and the like. The damaged carrier-based aircraft is quickly moved to the rescue deck 434 to receive emergency rescue, and the normal take-off and landing of other carrier-based aircraft cannot be influenced.

The elevator 401 is able to transport the carrier aircraft to the thrusters 421, 422 through the transition deck 420. Since the flat flame deflector 423 is provided with the guide 424 and the top end of the booster is provided with the rotating member 425, the carrier-based aircraft can also reach the catapult position of the booster 422 from the lift 402 through the rolling guide of the guide 406, 426, 424, 425 and can also reach the catapult position of the booster 421 if transmitted through the steering of the guide 427. In the same way, the carrier aircraft staying behind the island 430 can also be transported to the launch position of the thrusters 422 by the guiding devices 429, 428, 426, 424, 425. The tips of the thrusters 421 and 422 are provided with flight assist slopes 431 and 432, respectively. The boosters 421 and 422 can launch one carrier at a time or two carriers at the same time to take off the carrier-based aircraft as required. Through the control of the intelligent integrated controller 414, all guiding devices on the deck can be lowered to be as high as the deck surface, the work of the fire fighting truck and the take-off and landing of the helicopter are not influenced, the configuration and the use of the tractor can be avoided, even the tires can be omitted by the fire fighting truck in cooperation with the use of the guiding devices and the accurate and rapid control of the controller, and the complicated work on the deck is mechanized, intelligent and unmanned as much as possible.

As shown in fig. 8 and 9, a steel plate 502 is connected to the upper end surface of the parking aid 501, a roller 503 is connected to the upper end of the steel plate 502, a steel plate 504 is covered on the roller 503, a steel plate 505 is connected to the upper surface of the steel plate 504, a barrier rod 506 is connected to the upper end of the steel plate 505, a high-temperature-resistant and friction-resistant protective layer is wrapped on the barrier rod 506, and a guide device with a double-layer elastic shock absorption structure is arranged on the parking aid 501. When the missile 507 is closed, the chemical energy impeller and the initiation fuse fall to the position above the stopping aid 501, the tail hook 508 laid down can hook the arresting rod 509, and the missile 507 can gradually lose inertia power through the actions of the stopping aid 501 and the accumulator 510 arranged in the runway groove 513, so that the missile can land safely and stop stably. The missile 507 is provided with folding wings 511, and when landing, the missile can land in a folding and folding manner as shown in fig. 8, and can land in an unfolding and gliding manner as shown in fig. 9. The tail rudder 512 of the missile 507 can also be rotated to fold as shown in fig. 8 or erected to work as shown in fig. 9. The front end of the missile 507 is provided with a protective cover 514 to protect the missile nose from being impacted by common external force and not exploding. Reserve fuel tanks 515, 516 are provided on both sides of missile 507 to increase its cruise radius or extend its cruise time. Missile 507 performs its mission on the fly, opens protective shield 514, and after launching a bullet or projectile of somewhat smaller size, it can either return to the ground with fuel tanks 515, 516 or directly attack the target in a self-destructive manner. One side of the missile 507 used for landing is provided with a crawler belt device 517, the side provided with the wear-resistant layer is downwards rotated to cope with landing sliding friction, and the other side provided with the stealth coating is downwards rotated to help stealth.

Claims (7)

1. Facilities or devices required for the taxiing take-off and landing of aircraft without landing gear or tires or brakes, characterized in that:

the runway is provided with facilities or devices which can replace the functions of landing gears or tires or braking members on the aircraft or can assist the taking off and landing of the aircraft, and the facilities or devices at least comprise runway grooves or track grooves or raft vehicles or assisted parking devices or boosted devices or accumulators or controllers or detectors or forks or guide devices;

the accumulator is provided with a pneumatic or hydraulic part or an elastic substance;

the guide device comprises a rotating part or a wear-resistant part or a track groove or a track groove or a tubular object or a magnet or a magnetic suspension device or a buffer device or a positioning device or a clamping device or a steam driving device or an electric driving device;

the main components in the buffer device comprise a wheel, a flywheel, a tire, a gear, a rack, a track, a chain, a liquid filling piece, an inflating piece, an air pressing piece, a hydraulic piece, an air pressing piece, an anti-collision piece, a blocking piece, a braking piece or an elastic shock absorption device, and the elastic shock absorption device is composed of two or more layers;

the rotating part comprises a wheel or a flywheel or a ratchet wheel or a gear or a tire or a bearing or a roller or a conveyor belt or a crawler belt; the rotation of the rotating piece is controlled by a steam driving device, an electric driving device, a speed changer or a braking piece;

the arresting piece comprises an arresting cable, an arresting rod, an arresting column, an arresting block, an arresting plate, an arresting wall, an arresting net or an arresting sleeve;

the controller comprises a manual controller, a remote controller, an intelligent controller or an intelligent integrated controller;

the main components in the positioning device comprise a magnet piece, a sucker piece, a bolt piece, a buckle piece, a spiral piece, an expansion piece, a binding piece, a hook piece, a hanging piece, a sleeve piece, a clamping piece or a surrounding piece;

on the runway or in the runway groove or the track groove, or a liquid or guiding device or an accumulator or a steam ejector or an electromagnetic ejector is arranged;

the carrier of the runway is the deck of a ground or liquid or surface ship.

2. A facility or apparatus as claimed in claim 1, wherein:

the runway or the parking aid, the booster or the raft vehicle is provided with a power accumulator or a steam type catapult or an electromagnetic type catapult or a controller or a detector or a lifter;

the parking aid, the booster or the raft vehicle is parallel to or connected with or combined with the elevator into a whole;

a hooking device or a guiding device or a lifting device or a fire fighting device or an emergency device or a medical device or a flying assisting slope or a ladder or a slide or a manned escalator or a freight elevator is arranged on the parking aid or the booster or the raft vehicle or the lifter or on the road surface of the runway; the guiding device can be used as a hooking device;

a boosting part is arranged on the booster, and a rotating part is arranged at the upper end of the boosting part; the booster or the raft vehicle or the runway or the deck is provided with a flame baffle plate, and the flame baffle plate is provided with a rotating part; a guide device is arranged on or on the flying assisting slope;

the upper end face of the stop aid or the booster or the raft vehicle is as high as or almost as high as the road surface of the runway;

or when the raft vehicle stays on the stopping aid or the booster, the upper end surface of the raft vehicle is equal to or almost equal to the road surface of the runway;

the stop aid is combined with the booster into a whole.

3. A facility or apparatus according to claim 1 or 2, wherein:

and a booster or a stopping aid or an accumulator or a chemical energy pusher or a steam type ejector or an electromagnetic type ejector is arranged on the raft vehicle.

4. A facility or apparatus according to claim 1 or 2, wherein:

the stopping aid or the booster is of a double-layer or three-layer structure or is in a step shape, the stopping aid or the booster in the step shape is at least provided with a first step and a second step, the upper end surface of the second step is equal to or almost equal to the road surface of the runway in height, and the upper end surface of the second step is provided with a guide device;

when the raft vehicle stays on the first-stage step of the parking aid or the booster, the upper end face of the raft vehicle is equal to or almost equal to the upper end face of the second-stage step.

5. A facility or apparatus according to claim 1 or 2, wherein:

the guiding device can be a clamping type leading-in and leading-out device or an arched or frame-shaped supporting device;

the leading-in and leading-out device is in a lying type, one end of the leading-in and leading-out device can lead in a landing aircraft or lead out an aircraft needing to take off, two sides of the leading-in and leading-out device or the position of the leading-in and leading-out device can be moved, and the space between the two sides can be narrowed or widened; the controller can move the position of the lead-in and lead-out device or adjust the width of the space according to the real-time position of landing or takeoff of the aircraft;

the supporting device is in a vertical or inclined type, two sides of the supporting device are erected on a runway or a stop aid or a booster or a raft vehicle, the two sides can be bent, rotated or stretched, the two sides can keep a vertical or inclined state or an arc shape through elastic force, the two sides are formed by combining superposed elastic sheets, and the two sides are connected into a frame shape through a rotating piece or a blocking rod; the barrier rod is provided with a buffer device; the supporting device can be arranged or combined by two or more pieces;

the top surface of the supporting device is provided with a plate-shaped object or a strip-shaped object or a block, and the plate-shaped object or the strip-shaped object or the block is provided with a buffer device.

6. A facility or apparatus as claimed in claim 1, wherein:

the aircraft is provided with a tail hook or a telescopic piece or a detector or a controller or is provided with a power switch which allows or does not allow the ground command center to remotely control the aircraft to take off and land;

the tail hook or the telescopic piece is provided with a rotating piece;

the telescopic piece is in a plate shape, a block shape, a tubular shape, a strip shape or a column shape, and a groove, a convex object or a corner is arranged on or arranged on the telescopic piece; the turning piece or the corner can act as a tail hook;

the number of the tail hooks or the telescopic pieces is two or more, the tail hooks can be straightened or folded, and the straightened state, the folded state or the hooked state of the tail hooks is controlled by a pneumatic or hydraulic piece, a pulley or a pulley block, a spring or a gear or a chain or a spiral device; the aircraft is connected with the tail hook through a rod-shaped object, a strip-shaped object or a block-shaped object, and the connection position of the rod-shaped object, the strip-shaped object or the block-shaped object and the tail hook can be rotated or is provided with a joint or is provided with a spring, a hydraulic piece, a pneumatic piece or a spiral device; the cross section of the rod-shaped object or the strip-shaped object or the block-shaped object can be in any geometric shape; the strip comprises a rope; the number of the rods, the strips or the blocks is two or more; the shaft or block may be bifurcated or may be flexible or resilient.

7. A facility or apparatus according to claim 1 or 6, wherein:

a convex part or a groove or a rotating shaft or a transmission part or a guiding device is arranged on one surface of the aircraft, which faces the runway and is used for landing;

the convex part or the groove or the rotating shaft or the transmission part or the guide device is magnetic or provided with a stealth coating;

the cross section of the rotating shaft is a regular or irregular semicircle or trapezoid; the rotating shafts can be arranged together by two or more than two.

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