RU2578450C1 - Amphibious aircraft for evacuation of injured people in emergency situations at regional scale - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to air-cushion vehicles. Amphibious vehicle for evacuation of injured people in emergencies contains fuselage, cargo cabin with transport-lifting equipment room for placement of evacuated in emergencies in upper part of which there is acoustic ceiling. Acoustic ceiling has attached single sound dampers, each of which is composed of trihedral pyramidal structure.

EFFECT: lower noise is achieved.

1 cl, 5 dwg

Description

The invention relates to air-cushion vehicles and can be used year-round in conditions of complete impassability, in river basins, including rivers that do not have guaranteed ship depths, for regular transport work for delivering large technical cargo to consumers from the port, as a passenger and freight ferry, for the destruction of large ice fields by the dynamic method during the period of freezing in the lower Siberian rivers, when there is a threat of “freezing” of river vessels or the formation of ice jams on rivers during ice drift, as a vehicle in extinguishing forest fires for the delivery of special equipment and large volumes of water, in the aftermath of floods, in rescue operations in the tundra, on rivers and at sea, as well as to eliminate the consequences of other emergencies (Emergency).

The closest technical solution to the technical nature and the achieved result is an amphibious transport device according to the patent of the Russian Federation No. 135297 (prototype), containing a fuselage including a navigator’s cabin located in a superstructure on top of the fuselage’s nose, a cockpit and a flight engineer installed in the engine control panel cabin, instruments for monitoring the operation of engines and on-board systems, apparatus control, flight and navigation instruments and equipment, radio equipment, on-board electrical equipment, cargo cab Well, with transport and lifting equipment, a cargo hatch and a ramp located at the bottom of the tail, the right and left landing gear gondolas located on the sides of the fuselage, the main landing gear with brake wheels retractable into the gondolas, the front landing gear retractable into the fuselage, a two-wing wing vertical tail, consisting of keels with rudders and trim tabs, tail horizontal stabilizer with elevator and trim tab, two marching turboprop engines installed in wing nacelles variable-pitch coaxial propellers rotating in different directions, an auxiliary power unit located in the left nacelle of the chassis, fuel system, centralized fueling system, portable and stationary automatic fire fighting systems of marching engines, a system for pressurizing fuel tanks with neutral gas, a hydraulic system, a pneumatic system, elevons are installed on wing instead of flaps, wing fairings with navigation lights, mast mounted behind the superstructure with a radio surveillance antenna ator, on the left and right sides in the upper part of the fuselage of the lodgement attachment points for transported long loads, a platform attached to the fuselage from below, consisting of the right and left side sections, the right and left pontoons with pressurized neutral gas system, pressurized storage compartments, the front box with by air-thermal heating of the front toe, transom with tail end deviated together with the ramp, air-heat heated stem, attached to the platform perimeter peripheral flexible an airy pillow fencing, including a flexible receiver - monolith and flexible nozzle segments, attached directly to the bottom of the fuselage, a longitudinal flexible two-tier sectioned keel, an air-cushion pressurization system consisting of right and left airplane type nacelles, each of which has a dual-circuit turbofan engine with high bypass ratio, fuel system, automatic fire-fighting dual-mode system, air-to-air heating system for intake air intake engine compartment mounted at the outlet of the lifting motors of the outlet diffusers with airbag boost control units.

A disadvantage of the known device is the relatively low reliability during an emergency landing on an uneven surface due to the relatively low strength of fastening the fuselage of the apparatus with a platform consisting of right and left side sections, right and left pontoons with a pressurized neutral gas system, as well as relatively low noise comfort indicators that may affect the well-being of those evacuated during emergency response.

A technically achievable result is an increase in the reliability and comfort of the apparatus during operations to eliminate emergency situations on a regional scale.

This is achieved by the fact that in an amphibious transport device for evacuating victims in a regional emergency, containing the fuselage, including the navigator’s cockpit, the cockpit of the pilots and flight engineer installed in the cockpit on top of the nose of the fuselage, engine control panels, engine and onboard systems monitoring devices , apparatus control, flight and navigation instruments and equipment, radio equipment, on-board electrical equipment, cargo compartment with handling equipment, sn from the tail end of the cargo hatch and ramp located on the sides of the fuselage the right and left chassis nacelles, the main landing gear with brake wheels retractable into the nacelles, the front landing gear retractable into the fuselage, the wing with soft fuel tanks placed inside, two-keel vertical tail unit, consisting of keels with rudders and trim tabs, tail horizontal stabilizer with elevator and trim tab, two marching turboprop engines mounted in wing nacelles with rotationally aligned coaxial air variable pitch propellers, auxiliary power unit located in the left nacelle of the landing gear, fuel system, centralized fueling system, portable and stationary automatic fire engines for main engines, pressurized fuel tanks with a neutral gas system, hydraulic system, air system, with elevons installed on the wing instead of flaps, wing fairings with navigation lights, mast installed behind the superstructure with a panoramic radar antenna, on the left and right Orts in the upper part of the fuselage lodgement attachment points for transporting long loads, a platform attached to the fuselage from below, consisting of the right and left side sections, the right and left pontoons with pressurized neutral gas system, hermetic storage compartments, the front box with air-heat heating of the front toe , transom with tail part deviated together with the ramp, air-heat heated stem, fixed peripheral flexible two-tier fence around the platform perimeter an ear cushion, including a flexible receiver-monolith and flexible nozzle segments, attached directly to the bottom of the fuselage, a longitudinal flexible two-tier sectioned keel, an air-cushion pressurization system consisting of right and left airplane type nacelles, each of which has a high-power turbofan engine dual-circuit, fuel system, automatic fire-fighting dual-mode system, air-heat heating system of the intake air intake of the engine, installed On the output of the outlet motors of the outlet diffusers with airbag pressurization control units, there is an additional spatial elastic-damping frame structure connecting the fuselage with a platform consisting of the right and left side sections, the right and left pontoons, the transom, the front caisson and the stem, and consisting from the upper elastic frame, tightly and rigidly surrounding the fuselage, and the lower elastic frame, tightly and rigidly surrounding the platform, along its outer contour facing the fuselage, while the elastic frames are connected They are interconnected by means of elastic-damped screeds pivotally hinged to the elastic frames, consisting of two rigid parts connected in the middle by a damping element, and there is also an additional comfortable passenger room with an acoustic ceiling and piece sound absorbers.

In FIG. 1 shows a diagram of an amphibious transport apparatus in working condition, in a perspective view, top view; in FIG. 2 is a diagram of an amphibious transport apparatus in a perspective view, bottom view, in FIG. 3 is a diagram of comfortable rooms for accommodating evacuated in emergencies, in FIG. 4 - acoustic ceiling for comfortable rooms, in FIG. 5 - piece sound absorber for comfortable rooms.

The amphibious transport device for evacuating victims of regional emergencies (Fig. 1) contains the fuselage 1, which houses aeronautical and navigation equipment, control the aerodynamic control surfaces of the device, control devices for on-board systems, radio equipment and other equipment similar to the prototype equipment. In the forward part of the fuselage, the navigator’s cabin 2 is located, in the superstructure 3 on top of the fuselage is the cockpit and flight engineer, behind which there is a 600 cubic meter cargo compartment. m and a size of 4.3 × 4.3 × 33 (m) with transport and lifting equipment, including a crane-beam, two winches, mooring nets and belts. In the rear of the fuselage below there is a large cargo hatch 4 and a ramp 5 for loading and unloading of self-propelled vehicles. On the outside of the main wing of the cargo hatch there are guides 6 (Fig. 2) for the movement of the crane beam with the cargo hatch open. At the top in the middle part of the fuselage is a wing 7 with elevons 8, which is the center section of the wing of a prototype aircraft, at the ends of which wing fairings 9 with navigation lights 10, similar to winged aeronautical lights of an airplane, are mounted. On the lower side of the wing, the right 11 and left 12 engine nacelles of the marching engines are installed.

Marching engines - single-shaft turboprop engines (TVD) with rotating in opposite directions coaxial propellers 13 of variable pitch with a diameter of six meters each. A horizontal stabilizer 14 with an elevator 15 is mounted on top of the tail of the fuselage. The elevator is equipped with trimmers 16. The vertical tail of the apparatus is two-keel and consists of keels 17 with rudders 18. The rudders are also equipped with trimmers 19. There are fairings 20 on the upper end of the keels. in which the blocks of radio equipment are mounted. On both sides from the outside of the fuselage above the construction horizontal (GFS), there are mounted 21 attachment points for removable lodgements for transporting long, non-demountable goods weighing up to 10 tons. Behind the superstructure on top of the nose of the fuselage on the mast 22, an antenna 23 of the surveillance radar and an antenna 24 of the long-distance radio are installed. In front of the antenna mast of the locator on top of the superstructure there is an upper emergency hatch 25 for the crew to exit in emergency situations. The wheeled chassis of the device is similar to the chassis of the prototype aircraft and consists of the main chassis installed behind the center of mass of the device and the front chassis mounted in the nose of the fuselage.

The main chassis consists of six separate struts 26 with pneumatic-hydraulic shock absorber each and a pair of wheels. Racks are installed in a train of three on each side of the fuselage symmetrically with respect to the plane of symmetry of the fuselage. All wheels of the main chassis are brake diameter 1750 mm. The racks are retracted in flight into the nacelles of the chassis 27, located along the sides of the fuselage in separate niches, which are closed by two wings 28, kinematically connected with the landing gear. The front chassis 29 is a one-post with a pneumatic-hydraulic shock absorber and a pair of wheels remotely controlled relative to the vertical axis. The strut is retracted in flight into a niche in the fuselage, which is closed by wings 30.

A platform is attached to the bottom of the fuselage, consisting of the right and left side sections 31, right and left pontoons 32, transom 33, front box 34 and stem 35. The side sections are a continuation of the chassis nacelles for the entire length of the cylindrical part of the fuselage, the bow and stern of which from the outside they end with fairings 36 and 37, respectively. On the outer side of the section have a flange joint for connection with the pontoons. By design, the side sections are similar to the chassis gondolas and are thin-walled riveted structures consisting of frames and reinforced with a longitudinal set of casing. The frames of the airborne sections are riveted through the thiokol tape to the fuselage in the area of its frames. The cladding of sections in the bottom area is riveted through asbestos-soaked impregnated with lead minium. Section cavities have internal sealing. From the bottom of the apparatus, the joints of the airborne sections with the pontoon and the gondola of the chassis are closed by the front 38 and rear 39 fairings.

Pontoons of a trapezoidal cross-section of a rectangular shape in plan in the front are joined with a caisson, along the sides - with the side sections, and in the stern they are connected to the transom. Pontoons are technologically divided into several sections, consisting of sealed tank compartments. Tank compartments are included in the fuel system of the apparatus, are constantly inflated from the onboard neutral gas system and can be used both to increase the buoyancy margin and as additional fuel tanks. The front caisson is a transverse power element of the platform. Structurally, it is a part of the OCHK (detachable part of the wing) of the prototype aircraft docked along the plane of symmetry of the apparatus, including the inter-spar part and the heated sock. The caisson is attached directly to the fuselage, has a cutout for a niche of the front chassis, in front of the junction of the caisson with the fuselage it is closed by a runway turning into a stem. The transom is a transverse caisson. The tail of the transom can deviate along with the ramp, with which it is kinematically connected.

The nozzle type airbag is used on the device. Flexible enclosure of the air cushion consists of external - peripheral and internal.

External GO - two-tier, consisting of a flexible monolith receiver 40 and removable flexible nozzle segments 41. The internal guard consists of a flexible longitudinal keel 42. The keel - a two-tier non-expendable one has longitudinal and transverse sectioning. The keel sections are inflated regardless of the collector attached to the receiver. The keel is attached to the longitudinal beams riveted directly to the bottom of the fuselage. The ejector-type air-cushion pressurization system consists of 2 identical systems - the right and left systems, working on a common monolith receiver. Each system consists of a turbofan engine with a high degree of bypass installed in the engine nacelle 43 with internal mixing of the flows of the first and second circuits. An output diffuser 44 with a supercharger control unit 45 is installed at the output of each engine nacelle.

To increase the strength of the structure, it is additionally equipped with a spatial elastic-damping frame structure (Fig. 1) connecting the fuselage with a platform consisting of the right and left side sections 31, the right and left pontoons 32, transom 33, the front box 34 and the stem 35, and consisting of an upper elastic frame 46, tightly and rigidly surrounding the fuselage, and a lower elastic frame 48, tightly and rigidly surrounding the platform, along its outer contour facing the fuselage, while the elastic frames 46 and 48 are interconnected by hinged closure captured to the elastic frames 46 and 48 (not shown) of elastically damped screeds 47, consisting of two rigid parts connected in the middle by a damping element (not shown).

A comfortable room for accommodating evacuated in emergencies can be made as a single room or as separate rooms of an amphibious aircraft (Fig. 3), each of which is a metal die-welded frame 53, consisting of supporting profile structures (not shown), inside which are installed packages soundproofing elements 57, each of which includes layers of vibration damping material on a bitumen basis and at least one layer of porous sound-absorbing material and perforated hydrochloric decorative panel, wherein an air gap (not shown) is formed between the panel and a layer of porous sound absorbing material. Inside the cabin, piece sound absorbers (not shown) are attached to the ceiling and walls. The cabin frame is connected to the supporting structures 58 of the vessel by means of a vibration isolating system consisting of an upper suspension, including at least two rubber vibration isolators 49 and 50 of the upper suspension of the cabin and at least two vibration isolators 51 and 52 of the lower suspension of the cabin, made in the form of cylindrical or conical coil springs. Inside the cabin there is a table 54, a chair 55 and a bed 56 for personnel serving the vessel, and the fastening of these objects to the frame 53 of the cabin can be carried out rigidly or through vibration damping pads (not shown). The cabin is equipped with a suspended acoustic ceiling (not shown).

Packages of acoustic insulation elements 57 can be either solid or consisting of elements (not shown in the drawing) inscribed in the outline of the cabin frame 53 and consisting of a front with slotted perforation and a rear wall made of stainless steel or galvanized sheet 0.7 mm thick with a protective and decorative polymer coating of the Pural type with a thickness of 50 microns or Polyester with a thickness of 25 microns, or an aluminum sheet with a thickness of 1.0 mm and a coating thickness of 25 microns. In this case, the front and rear walls of the packages can be made of structural materials, with a layer of soft vibration-damping material, for example, VD-17 mastic or Gerlen-D type material, applied on its surface from one or two sides, and the ratio between the thickness of the lining and vibration-damping coating lies in the optimal range of values - 1: (2.5 ... 3.5).

The sound-absorbing material of the acoustic insulation elements is made in the form of a plate made of rockwool basalt mineral wool or URSA mineral wool or P-75 basalt wool or glass wool lined with glass wool or foamed polymer, such as polyethylene or polypropylene, moreover, the sound-absorbing element over its entire surface is lined with an acoustically transparent material, for example, fiberglass type EZ-100 or polymer type "Poviden." Sound-absorbing material can also be made of rigid porous sound-absorbing material, for example, foam aluminum or cermets, or metal foam, or a shell rock with a degree of porosity in the range of optimal values: 30 ... 45% (not shown). Sound-absorbing material 6 can be made in the form of crumbs from solid vibration-damping materials, for example elastomer, polyurethane, or plastic compound such as Agate, Anti-Vibrate, Shvim, and the size of the fractions of the crumb lies in the optimal range of values: 0.3 ... 2, 5 mm (not shown).

Amphibious transport apparatus for the evacuation of victims in emergencies of a regional scale works as follows.

Before starting the engines, the device stands on chassis 26, 29. On the control panel in the cockpit and flight engineer, the control levers for the mid-flight and lift engines (ORE) are on the stop, the propellers 13 "are removed from the intermediate stop".

The shutter of the supercharger control unit air cushion 45 is in the "open" position. On the engine control panel, the “air bleed” toggle switch is in the “closed” position, the “turbo-cooler” toggle switch is in the “off” position. The order of starting the engines when starting from a solid screen is not essential for the apparatus to operate, but to save fuel at starting the engines, it is advisable to start the lifting engines first, which must be fully warmed up before moving, and the main engines after starting should be warmed up when taxiing. Starting of lifting engines is carried out in accordance with the "Instructions for the operation of the engine on an airplane."

In the process of engine spin-up and exit to the temperature regime of exhaust gases from the nozzle of the primary circuit, the turbofan engine can reach more than 700 ° C, which is 400-450 ° C higher than in steady-state conditions. Moreover, the fan performance of the second circuit of the engine, due to low revolutions, is insufficient to ensure that the gas-air mixture formed at the engine outlet is cooled to an acceptable temperature (under normal ACI conditions — about 80 ° C) and compress it to the pressure required to form under platform air cushion device. In addition, droplets of kerosene and oil may accumulate in the gas jets exiting the engine, which accumulate while the apparatus is stationary in the combustion chamber and in the jet nozzle of the primary circuit due to leaks in the units of the turbofan engine. Therefore, when starting and heating the lifting engines, the gas-air mixture is discharged by the supercharging control unit 45 into the atmosphere.

In order for the apparatus to "stand up" on the air cushion, the throttle thrust of both hoisting engines is transferred to the position corresponding to the nominal speed. After that, from the engine control panel, the shutter drives of the supercharger control unit “on opening” are turned on, and the air-gas mixture flow opens to the entrance to the diffuser 44, at the same time the air flow exit is blocked (in Fig. 1, the shutters 45 are shown in the “open” position) and the air-bag pressurization system comes into operation in its main mode.

The gas-air mixture leaving the engine enters the outlet diffuser 44. In the diffuser, the full pressure of the gas stream is restored to the required static pressure in the receiver 40 and the lifting force of the air cushion is formed. The actual value of the excess static pressure of the gas-air mixture at the outlet of the diffuser 44 at a temperature of less than 80 ° C under normal MSA external conditions is about 8 kPa. According to the layout of the lifting system, a shortened diffuser with a constant pressure gradient is used on the apparatus. From the receiver 40, the gas-air mixture, flowing through the nozzles 41, enters under the platform of the apparatus. After warming up the lifting engines, the marching engines are started in accordance with the "Instructions for the Use of Engines" on the prototype. After starting, the marching engines operate in the "small earth gas" mode, therefore the thrust of the propellers 13 is less than that necessary to overcome the braking power of the chassis wheels in any state of the surface of the launch pad. To start the movement of the apparatus, the air-cushion pressurization system is put into operation in its main mode, then the throttle thrusters of the main engines are moved from the stop to the side of increasing fuel supply.

When the apparatus moves over a solid surface with a taxiing speed (significantly less than cruising), the apparatus can be controlled at the heading by marching engines — the operation of the engines "in a mess", together with aerodynamic rudders 18, which are blown by the air stream behind the propellers 13, as well as by turning the wheels the front chassis 29. At high speeds (above 30 km / h) - purely aerodynamic, the simultaneous action of rudders 18. When accelerating the apparatus over open water, course control is carried out analogously adic - engine operation "in torn" together with the aerodynamic control surfaces 18, whose effectiveness is considerably higher because of the more intensive blowing, because engines to overcome the "hump of resistance" operate at an increased mode, close to take-off.

When the apparatus moves, the fuselage 1 with the wing wing 7 with the elevons 8 deflected by 15 degrees and the tail horizontal stabilizer 14 with the elevator 15 create an additional controlled aerodynamic lifting force, the proportion of which at maximum speed, taking into account the blowing of the wing part 7 by the propellers 13, can reach up to 15 -20% of its total flight weight. Due to the aerodynamic unloading of the apparatus, the elevation of the apparatus, as well as its stability and controllability, due to the good aerodynamic shape of the apparatus, increases simultaneously with the increase in speed. Longitudinal balancing in a wide range of machine alignments and displacements of the VP pressure center is carried out by deflecting the elevator 15, which is controlled manually or by autopilot. Rapid fluctuations in the pitch of small amplitude are damped by horizontal feathering 14. Transverse stability (stability) at low roll angles is ensured by the differentiated deviation of the elevons 8, and also due to the restoring moment of the air cushion due to its sectioning on the right and left sections by a longitudinal flexible keel 42. Wheel chassis 26 , 29 when moving over a solid screen, it may be in the “retracted” position or in the “released” position, depending on the conditions on the traffic path. When moving above water, the chassis is in the "retracted" position. The compartments of the nacelles of the main and nasal landing gears in the “retracted” position are closed by the shutters 28 and 30, respectively, and are pressurized by gas supplied from the flexible receiver 40 through special channels in the pontoons 32.

The device is braked by reducing the mode of marching engines, and in emergency cases due to the reverse of the propeller thrust 13, braking by the wheels of the chassis, which is especially effective when moving or landing the device on a hard underlying layer, deflecting elevons 8 by an angle of 35 degrees.

In an emergency, for example, in case of failure of the lifting motors or the destruction of most of the flexible fence 41, an emergency landing is carried out when moving above a hard screen on an airplane - on chassis 26 and 29, and when moving above water, marshy soil or a snowy screen - on the bottom of the device landing gear, while elastically connecting the fuselage to the platform, the frame structure, due to pivotally attached, to the elastic frames 46 and 48 of elastically damped couplers 47, due to their damping elements will prevent damage to the fusel and with rooms for evacuees.

In an emergency, for example, when the air bag crashes, the supporting structure is in the form of a spatial elastic-damping frame structure (Fig. 2), connecting the platform-bottom of the housing 1 and the buoyancy units 2, on which two elastic plates 13 are rigidly fixed, coupled elastically - damped couplers 14 with hull 1, will prevent damage to hull 1 and the comfortable passenger compartment (cabins or cabins) located in it for those evacuated during emergency response.

A comfortable room for placing evacuated in emergency situations (Fig. 3) works as follows.

Packages of sound insulation elements 57 reduce the structural and reverberation components of noise. Polyurethane foam gaskets effectively dampen high-frequency air vibrations, the source of which is the sound pressure flow energy. Polyurethane foam is at the same time a reliable heat insulator due to its high porosity, insulated on both sides by a thin melted polyurethane foam film. Decorative perforated fiberboard is a good vibration damper. The transition of sound energy into thermal energy (dissipation, energy dissipation) occurs in the pores of a sound absorber, which are the Helmholtz resonator model, where energy losses occur due to friction of the mass of air in the resonator neck oscillating with the frequency of excitation on the neck wall, which has the form of a branched sound absorber pore network. To prevent the eruption of a soft sound absorber, a fiberglass fabric, for example, type EZ-100, is located between the sound absorber and the perforated wall.

The acoustic ceiling (Fig. 4) for a comfortable passenger room consists of a rigid frame 59 made in the form of a rectangular parallelepiped with the dimensions of the sides in the plan a × b, the ratio of which lies in the optimal range of values a: b = 1: 1 ... 2: 1, suspended from the ceiling of an industrial building by means of hangers 62, mounted on a rod 60, rigidly connected by means of brackets 61 to the frame 59. The frame is fixed to the ceiling using dowels (not shown). A perforated sheet 65 is attached to the frame, on which a layer of sound-absorbing material 63 is located through the layer of transparent transparent material 64, and fixtures 67 are installed in the frame. When installing an acoustic ceiling, the optimum size ratios must be observed: d - from the point of suspension of the frame to any of its sides and c is the thickness of the layer of sound-absorbing material, and the ratio of these sizes should be in the optimal range of values: c: d = 0.1 ... 0.5. Perforated sheet 65 has the following perforation parameters: hole diameter 66 - 3 ... 7 mm, perforation percentage 10% ... 15%, and the shape of the hole can be made in the form of holes of a round, triangular, square, rectangular or diamond-shaped profile (shown in the drawing are round holes). In the case of non-circular holes, the maximum diameter of a circle inscribed in a polygon should be considered as a conditional diameter.

The layer of sound-absorbing material 63 can be made on the basis of aluminum-containing alloys, followed by filling them with titanium hydride or air with a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength in the range of 5 ... 10 MPa, strength bending within 10 ... 20 MPa, or from a soft foamed porous sound-absorbing material, for example, foamed polyurethane foam or polyethylene foam, or from a rigid porous sound-absorbing material, such as foam aluminum, and the implementation of the sound absorber from n combustible materials makes the design fireproof.

Suspension of the suspended acoustic ceiling is carried out on suspensions 63, which are attached to the ceiling with dowels, and the other end is fixed to the frame 59 through the rod 60 and the bracket 61.

The piece sound absorber (Fig. 5) for a comfortable passenger room consists of a rigid frame made in the form of at least a trihedral pyramidal structure, consisting of three perforated inclined faces 69 connected to form the top by fasteners 74. A ship bulkhead is used as the base of the trihedral pyramid 68, to which, through vibration damping elements 72 by means of fasteners 71 and elastic ties 73, perforated inclined faces 69 are attached. In this case, the elastic ties and 73 are located inside the frame in a plane perpendicular to the ship bulkhead 68. One end of the couplers is attached to hooks fixed to the bulkhead 68, and the other to the fasteners.

On the inside of the carcass, a sound-absorbing non-combustible material 70 (for example, vinipore, fiberglass) wrapped in an acoustically transparent material, for example fiberglass, is attached to the perforated inclined faces 69. There is an air cavity 75 between the layers of sound-absorbing material 70 inside the frame, and there is an air gap 76 between the perforated inclined faces 69 and the sound-absorbing non-combustible material 70, which serves to suppress noise in the low-frequency range.

The pyramidal design of a piece of sound absorber, consisting of inclined faces 69 connected to form a vertex, is surrounded on the outside with an air gap 77 by a sound-absorbing conical surface 78, fixed by a base to the bulkhead 68, and lined with an acoustic transparent material 79. As a sound-absorbing material of the conical surface 78, rockwool-type basalt mineral wool, or URSA-type mineral wool, or P-75 basalt wool, or glass wool with a face can be used glass fiber, or foamed polymer, such as polyethylene or polypropylene. Moreover, the sound-absorbing material over its entire surface is lined with an acoustically transparent material, for example, EZ-100 fiberglass or a “visible” polymer, or the surface of the fibrous sound absorbers is treated with special porous paints that allow air to pass through (for example, Acutex Τ) or coated with breathable fabrics or non-woven materials, e.g. Lutrasil. In addition, as the sound-absorbing material of layers 2 and 4, a porous sound-absorbing material, for example, foam aluminum, or cermets, or a shell rock with a degree of porosity in the range of optimal values: 30–45%, or metal foam, or a material in the form of pressed crumbs from solid vibration-damping materials, for example elastomer, polyurethane, or plastic compound like “Agate”, “Anti-vibration”, “Shvim”, and the size of the crumbs fractions lies in the optimal range of values: 0.3 ... 2.5 mm, and they could also porous mineral piece materials were used, for example, pumice, vermiculite, kaolin, slag with cement or other binder, or synthetic fibers, while the surface of the fibrous absorbers is treated with special porous paints that allow air to pass through, such as Acutex Τ or coated with breathable fabrics or non-woven materials e.g. Lutrasil.

Piece sound absorber works as follows. Sound waves propagating in a room interact with sound-absorbing material 70. Sound absorption at low and medium frequencies occurs due to the acoustic effect constructed on the principle of Helmholtz resonators formed by air cavities 75. Different volumes of resonant cavities serve to suppress sound vibrations in the required sound frequency range As a rule, large volumes for noise suppression in the low-frequency range, and small - in the medium and high frequencies. The air gap 77 between the inclined faces 69 and the conical sound-absorbing surface 78, lined externally with an acoustically transparent material 79, allows to increase the efficiency at low frequencies by introducing an additional volume of air participating in the Helmholtz resonator effect.

Claims (1)

An amphibious transport device for evacuating victims of emergency situations on a regional scale, containing the fuselage, a cargo compartment with transport and lifting equipment, a room for placing evacuated in emergency situations which is designed as a single room, or as separate cabins of an amphibious aircraft, each of which is metal die-welded frame, consisting of supporting profile structures, inside of which are installed packages of sound and heat insulation elements, each of sound and vibration insulation elements includes layers of vibration-damping material on a bitumen basis and at least one layer of porous sound-absorbing material and a perforated decorative panel, and an air gap is formed between the panel and the layer of porous sound-absorbing material, while the cabin frame is connected to the supporting structures of the vessel by means of a vibration-isolating system consisting of an upper isolation system a suspension comprising at least two rubber vibration isolators of the upper suspension of the cabin and at least two vibration isolators of the lower cabin cabinets made in the form of cylindrical or conical coil springs, and the packages of soundproofing elements can be made either whole or consisting of elements inscribed in the outline of the cabin frame, and the sound-absorbing material of soundproofing elements is made in the form of a basalt mineral wool slab and It is lined with acoustically transparent material over its entire surface, and the unit sound absorber is made in the form of a rigid frame fixed to the hook ceiling on the cabin ceiling. or on ropes, and containing elements with sound-absorbing material wrapped in an acoustically transparent material and placed on a perforated surface, and as sound-absorbing material, slabs made of rockwool basalt based mineral wool or URSA or basalt mineral wool are used Wools of type P-75, or glass wool lined with glass wool, or foamed polymer, for example polyethylene or polypropylene, and as an acoustically transparent material, for example fiberglass type EZ-100 or polymer t PA "Visible", and in the upper part of the comfortable passenger compartment there is an acoustic ceiling, characterized in that piece sound absorbers are attached to the acoustic ceiling, each of which is made in the form of at least a trihedral pyramidal structure consisting of inclined faces connected to form the top by fixing elements, and the pyramidal design of a piece sound absorber, consisting of inclined faces interconnected to form a peak, surrounds the sound box with an air gap outside an absorbing conical surface fixed by a base to the ship’s bulkhead and lined with an acoustically transparent material on the outside, while rockwool mineral wool or URSA mineral wool was used as sound-absorbing material on the conical surface, sound-absorbing material is lined over its entire surface with an acoustically transparent material, for example, fiberglass type EZ-100 or a polymer of the “poviden” type, or the surface of fibrous sound absorbers is specially treated and porous air-permeable paints, for example Acutex T, or coated with breathable fabrics or non-woven materials, such as Lutrasil, or used porous mineral piece materials, such as pumice, vermiculite, kaolin, slag with cement or another binder, or synthetic fibers, with the surface fibrous sound absorbers are treated with special porous air-permeable paints, such as Acutex T, or coated with breathable fabrics or non-woven materials, such as Loutra silt.

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