RU2668935C1 - Method of displacement of the self-propulsion vehicle that provides its high performance, increased stability on water, and the device for its implementation - Google Patents

Abstract

FIELD: transportation.SUBSTANCE: invention relates to a device providing additional means of transportability and buoyancy for vehicles. Above the self-propelled vehicle are floating vessels and are held by the mechanism of their movement. Movement on deep places of reservoirs is carried out by swimming, leaning on floating capacities. Before moving to deep water reservoirs, floating vessels are moved to the lower position along the sides of the self-propelled vehicle by means of a movement mechanism. Movement along the shoals, marshes and when entering the reservoir is made by walking. Walking is carried out by lifting and moving the self-propelled vehicle with respect to the floating vessels along the direction of travel, then lifting and moving the floating tanks with the support of the vehicle on their wheels, tracks or body elements.EFFECT: increase in the passability of the vehicle, increased stability on the water is achieved.3 cl, 6 dwg

Description

The invention relates to a method and device that provide conventional vehicles moving on wheels or tracks for additional cross-country ability and buoyancy.

A similar analogue is known - US patent No. 6840825, January 11, 2005, which describes a method of moving an amphibious car, in which movement on a rigid surface is carried out on wheels, similar to the movement of a car, while the pontoons are moved in a state pressed to the car body to provide a small width of a car, movement in deep places of water bodies is carried out by swimming, relying on pontoons, before moving in deep places of water bodies, pontoons are turned manually relative to the hinge axis so that they increase the width Well car, providing better stability of an amphibious car on water.

The device described in the above patent contains a central and side pontoons, a captain’s bridge with a cabin above the central pontoon, wheels for moving on the ground, an articulated mechanism that allows the side pontoons to be placed above the central one when moving on land and fixed below the central one for moving on water.

The disadvantage of the analogue is the need for manual manipulations by the user, necessary to secure additional structural elements or to dismantle them, which reduces the usability of an amphibian vehicle and makes it ineffective in operating mode with a frequent change of land-water environment.

A number of analogues are known from the patents RU46722, US5315950, JP2000301922, US4691657. All of them provide methods for moving an amphibious car, in which the movement on a rigid surface is carried out on wheels, similar to the movement of the car, while the pontoons are moved in the transport position, usually at the top of the car, the movement through the deep places of the water bodies is carried out by swimming, relying on the pontoons, before moving along pontoons are lowered into the deep places of water bodies by various mechanisms in the working position in the lower zone of the car or under it.

Analog devices contain floating tanks, placed when moving on land on the roof of a car, and a device for fastening and moving floating tanks from the transport position to the working one and vice versa.

All the differences between the given analogues are in the construction of floating tanks and in the devices and methods of their fastening and moving. The main disadvantage of these analogues is that they realize their advantage of giving the car the ability to swim on water only after the car has driven deep into the water so that it is possible to lower the floating containers so that the wheels come off the bottom. To carry out the method of movement described in the analogues is possible only in the case of a flat shore, and a car equipped with the devices described in the analogues can move into the water or go ashore only in those places where the bottom is fairly flat. As a rule, the banks of water bodies are little adapted for the movement of cars. To approach the water, enter the water and leave the water, as well as move through difficult to overcome terrain, increased passability is required, however, the devices described in the analogues do not increase, but worsen, this characteristic due to the increase in weight and dimensions.

A known analogue is the patent for the invention of the Russian Federation No. 2460662, 08/08/2010, which describes a method of moving through swamps, in which movement along the shallows and swamps is carried out by pacing, and the pacing is carried out by an automatic movement by cyclic alternately supporting the marsh at first one supporting pontoon, while moving the second pontoon along the direction of movement, then to the second pontoon, moving the first along the direction of movement.

The device described in the above patent is an assembly for collecting oil and oil products from the contaminated surface of swamps, including a walking swamp, consisting of a housing connected to parallel mounted pontoons, a mechanism for alternately moving the pontoons, characterized in that the housing is a chassis mounted on the central and side pontoons, in which telescopic blocks are hermetically enclosed; mechanisms for removing loads from the cantilever ends of the elements of the telescopic blocks when they are open; unit rotation mechanism; oil gathering drum with a system for pumping collected oil; guards - pontoon skis hung on an oil gathering drum; boom booms, workplace of operators - installers of boom booms located on the chassis of the marsh walker, a container for transporting boom booms and accumulation of collected oil, attached to the stern of the chassis of the marsh walker and flexibly connected to the pumping system of the collected oil. Another analogue in which the same method of movement is implemented is known from the RF patent for utility model No. 30701.

In the two listed analogs, the method of “walking” of floating tanks - pontoons for the movement of a vehicle was used. These analogs are much better suited for overcoming off-road areas of shallow water, where it is still impossible to sail, but it is already impossible to move on wheels. Their disadvantage is the lack of the ability to quickly and maneuverably navigate on land. In such vehicles there are no wheels for movement on a flat surface and a means that would ensure the movement of floating tanks in the transport position.

A known analogue is US patent No. 8454399, January 4, 2013, adopted as a prototype of the proposed method, in which the movement on a rigid surface is carried out similarly to the movement of a car with a wheel drive, and when moving on a hard surface, pontoons are placed on top of the self-propelled vehicle, the pontoons are held in by the mechanism of their automatic movement, the movement along the deep places of the water bodies is carried out by swimming, relying on the pontoons, while the self-propelled vehicle relative to the pontoon The s are held by the mechanism of their automatic movement, before moving through the deep places of the reservoirs, the pontoons are moved to the lower position on the sides of the self-propelled vehicle using the automatic movement mechanism.

The device described in the above patent is adopted as a prototype of the proposed device. It is made in the form of an amphibious vehicle containing floating tanks, a mechanism for automatically moving floating tanks from a position above a self-propelled vehicle to a position on the sides of a self-propelled vehicle, and a mechanism for automatically moving floating tanks and a self-propelled vehicle relative to each other in the vertical direction.

The prototype method increases the convenience and speed of movement, as it eliminates the need for manual manipulation by the user, necessary to secure additional structural elements or their dismantling, and the movement of the pontoons is carried out automatically. An amphibious prototype vehicle allows you to move on land and on water and transfer from land to water and from water to land without dismantling the structural elements and without the need for manual manipulations by the user, necessary to secure additional structural elements or dismantle them.

The first disadvantage of the prototype is the low cross-country ability on heavy sections of the road and in shallow areas where it is still impossible to sail, but it is already impossible to move on wheels. The second disadvantage of the prototype method and device is low stability on water due to the dependence of the longitudinal trim of the car, which is at that moment a swimming means, on the distribution of cargo on the car. The third disadvantage of the prototype, which applies to previous analogues, is the inability to use without significant modifications a conventional car, widely manufactured by the industry.

An object of the invention is to provide a method and device that improves the patency of a conventional vehicle widely manufactured by industry by land, by water and when entering water.

The technical result of the invention consists in the creation of a method and device for the mutual movement of floating tanks and a self-propelled vehicle, which increase the permeability of the vehicle when moving from land to water and back, when moving through difficult terrain, and when overcoming water barriers, without serious modification vehicle.

The solution to the technical problem in the method of moving a self-propelled vehicle, providing it with high cross-country ability, increased stability on water, in which the movement on a rigid surface is carried out similarly to the movement of a vehicle driven by wheels or tracks, and when moving on a hard surface on top of a self-propelled vehicle are floating tanks, while floating tanks are kept by the mechanism of their movement, movement in deep places of water bodies is carried out by swimming, supported by to floating vessels, while the self-propelled vehicle relative to the floating tanks is held by the mechanism of their movement, before moving through the deep places of the reservoirs, the floating tanks are moved to the lower position on the sides of the self-propelled vehicle by the movement mechanism, which is achieved by the movement on the shallows, swamps and when entering the pond, they are stepping, and the stepping is carried out by a moving mechanism by cyclic alternately supporting first of all the self-propelled transport medium floating vessels with the raising and moving of the self-propelled vehicle relative to the floating tanks along the direction of movement, then lifting the floating tanks with the self-propelled vehicle resting on its wheels, tracks or hull elements with lifting and moving the floating tanks along the direction of movement, and in order to ensure longitudinal stability during movement by floating carry out the movement of a self-propelled vehicle relative to floating tanks by the same movement mechanism, which They carry out the movement by striding.

The solution to the technical problem in a device that provides high cross-country ability and increased stability on water to a self-propelled vehicle containing floating tanks, a mechanism for moving floating containers from a position above the self-propelled vehicle to a position on the sides of the self-propelled vehicle and a mechanism for the vertical movement of the self-propelled vehicle and floating tanks relative to another, made with the possibility of transferring the weight of the vehicle to floating containers, achievable It consists in that it contains an element that secures the device to self-propelled vehicles, including those commercially available by the industry, a mechanism for the longitudinal movement of the self-propelled vehicle and floating tanks relative to each other, and the mechanisms of vertical and longitudinal relative movements of the self-propelled vehicle and floating tanks each other form a stepping movement mechanism, ensuring the alternate support of first of all one vehicle to floating tanks with the raising and moving of a self-propelled vehicle relative to floating tanks along the direction of travel, then raising the floating tanks with the self-propelled vehicle resting on its wheels, tracks or hull elements with the raising and transfer of floating tanks along the direction of movement.

Floating tanks can be fixed with the possibility of quick replacement to platforms that are part of the walking mechanism, floating containers can be inflatable nacelles, an element that secures the device to self-propelled vehicles can be mounted with the vehicle frame, the mechanism for moving floating containers from the position above the self-propelled vehicle to the position on the sides of the self-propelled vehicle and the vertical movement mechanism of the self-propelled vehicle of the vehicle and floating containers relative to each other can have common links and contain vertical guides placed on each side in front and rear of the self-propelled vehicle, to which carriages are fixed with the possibility of vertical movement, two on each side of the self-propelled vehicle, each carriage can be rotated relative to the longitudinal axis of the self-propelled vehicle with its first end attached to a lever having a hinge on the second end, the rotation of which is perpendicular to the longitudinal axis of the self-propelled vehicle, the lever couplings are fixed to the hinges of each pair of levers located on one side of the self-propelled vehicle, into which the front and rear ends are inserted so that the beam can rotate around its longitudinal axis, and the beam is fixed to the rear lever clutch without the possibility of longitudinal sliding, and to the front lever clutch with the possibility of longitudinal sliding relative to the front lever, and also contain power drives for place carriages, turn levers and rotate the beam, the mechanism of the longitudinal movement of the self-propelled vehicle and floating containers relative to each other contains platforms on each side of the self-propelled vehicle, corresponding to the length of the self-propelled vehicle, with fixed floating containers attached to them, and each platform is fixedly mounted longitudinal guides to which beam couplings are fixed with the possibility of longitudinal sliding, which are fixedly fixed next to Independent user and rear ends of each beam, and also comprises an actuator mounted movably on each platform with respect to its beam.

Figure 1 shows a rear view of a self-propelled vehicle with a device that provides it with high traffic.

Figure 2 shows a side view of a self-propelled vehicle with a device that provides it with high traffic.

Figure 3 shows the movement of floating containers from the transport position to its original position when moving in steps.

Figure 4 shows the initial phase of one step of a self-propelled vehicle in the mode of moving in steps.

Figure 5 shows the final phase of one step of a self-propelled vehicle in the step-by-step mode.

Figure 6 shows the initial and final position of one step of a self-propelled vehicle in the mode of moving in steps.

A device providing high cross-country ability to a self-propelled vehicle, shown in Figure 1, contains floating tanks 1 in the form of gondolas, which are fastened with the possibility of quick replacement to platforms 13, which is part of the walking movement mechanism. The length of the platforms 13 is approximately equal to the length of the entire vehicle 3. The device is fixed to the frame 2 of a self-propelled vehicle 3, which is a car. The mechanism for moving floating containers 1 from a position above the self-propelled vehicle 3 to the position on the sides of the self-propelled vehicle 3 and the vertical movement mechanism for the self-propelled vehicle 3 and floating tanks 1 relative to each other have common links and contain vertical guides 4 located on each side in front and the rear parts of the self-propelled vehicle 3, to which the carriages 5 are mounted vertically, two on each side of the self-propelled vehicle orthogonal means 3, to each carriage 5 with the possibility of rotation relative to the longitudinal axis of the self-propelled vehicle 3, a lever 6 is attached with its first end having a hinge 7 at the second end, as shown in Figure 2, the axis of rotation of which is perpendicular to the longitudinal axis of the self-propelled vehicle 3, to couplings 8 of levers 6 are mounted to the hinges 7 of each pair of levers 6 located on one side of the self-propelled vehicle, into which the front and rear ends are inserted with the possibility of rotation around their longitudinal axis 9, and the beam 9 is fixed to the clutch 8 of the rear lever 6 without the possibility of longitudinal sliding, and to the clutch 8 of the front lever 6 with the possibility of longitudinal sliding relative to the front lever 6. There is a power drive 10 for moving the carriages 5, a power drive 11 for turning the levers 6 , a power drive 12 for rotating the beam 9. The mechanism for the longitudinal movement of the self-propelled vehicle 3 and the floating tanks 1 relative to each other contains platforms 13 located on each side of the self-propelled vehicle 3, with floating containers 1 to them, moreover, longitudinal rails 14 are fixedly fixed to each platform 13, to which, with the possibility of longitudinal sliding, clutches 15 of beams 9 are fixed, which are fixedly fixed to each beam 9 near its front and rear ends. To move each platform 13 relative to its beam 9 there is a power drive 16.

Consider an example of a specific implementation of a device that provides high maneuverability to a self-propelled vehicle. As a self-propelled vehicle 3, a KAMAZ-4310 car with a KUNG-type body is used to accommodate people. Floating tanks 1 are made in the form of inflatable nacelles, which are inflated immediately before the start of swimming or moving through difficult terrain. This achieves a decrease in the size of the vehicle 3 when driving on ordinary roads. Swing arms 6 are made in the form of a frame assembled by welding from pipes of rectangular cross section. The frame has a triangular shape, which provides maximum rigidity. Each pair of vertical guides 4 is an element of a rigid frame assembled by welding from pipes of rectangular cross section and fixed to the frame 2 of the vehicle 3. Four such frames are fixed to the vehicle 3, two on each side, and two of them are fixed between the wheel axles closer to vehicle cab 3, the other two behind the rear axle. The carriages 5 have surfaces sliding along the guides 4. To move the carriage 5 along its vertical guides 4, a power drive 10 is used, consisting of a hydraulic motor with a gearbox and a chain drive. The hydraulic motor of the power drive 10 is located below, under the frame 2 of the vehicle 3 to reduce the center of gravity of the entire structure. On each carriage 5, a rotary drive 11 is fixed, made in the form of a hydraulic motor with a gearbox, the drive axis of which is connected to the beam of the rotary lever 6 with the possibility of rotation. Hinges 7 are fixed to the top of the triangle, which is each pivoting arm 6, into which couplings 8 are installed, into which longitudinal beams 9 are threaded.

So that when placing the platforms 13 on the sides of the car 3, the front and rear levers 6 can be located at different heights (the beam 9 with the platforms 13 is not located parallel to the car, but at an angle to the horizontal), it is necessary that both ends of the beam 9 are pivotally mounted with the possibility of rotation around the transverse axis of the vehicle 3 and the attachment point of the beam 9 to at least one lever 6 slid relative to it, since the distance between the attachment points of the beam 9 will change. Therefore, the rear of the beam 9 is threaded into the coupling 8 of the rear lever 6, and the front of the beam 9 is threaded into the coupling 8 of the front lever 6 with rotation and longitudinal sliding. Longitudinal beams 9 have a circular cross section and are made of thick-walled pipes. On the rear rotary levers 6 are mounted rotary drives 12 for rotating the beam 9, each of which is a hydraulic motor with a gearbox. On each beam 9 two couplings 15 are rigidly fixed, one in front, closer to the vehicle cabin 3, and one behind, closer to the rear wheel axle of the vehicle 3. Couplings 15 are fixed by crimping the beam 9. Couplings 15 with longitudinal guides 14 are sliding pairs . Longitudinal guides 14 are made of steel profile. To ensure the sliding of the longitudinal rails 14 relative to the clutches 15, the sliding surface of the clutch 15 is made of polyamide, and the surface of the rail 14 is steel, and in the clutch 15 there is a lubrication system. For linear movement of the longitudinal guides 14 relative to the couplings 15, drives are used made in the form of a hydraulic motor with a gear 16 and a chain gear with a chain 17, a drive sprocket 18 and a driven sprocket 19. Platforms 13 are fixed to the longitudinal guides 14 with bolts, the length of which is approximately equal to the length of the vehicle made of polymer material. The floating containers 1 are attached to the platforms 13 by a quick-detachable lock, to ensure quick replacement or repair of the floating tanks 1. The couplings 8 of the levers 6 are mounted through hinges 7 to provide an additional degree of freedom when attaching the beam 9, for the possibility of its fastening to two rotary levers 6.

Consider an example of the implementation of the method of moving a self-propelled vehicle, providing it with high traffic. When driving on ordinary roads, there is no air in the nacelles 1 and they are compactly laid. The carriages 5 are in a position above the self-propelled vehicle of the vehicle 3, the pivoting levers 6 are in a vertical position, providing the upper position of the platforms 13 with the attached nacelles 1, as shown in Figure 2. In this case, the self-propelled vehicle moves as usual on wheels. Before driving off-road or through water, the levers 6 are turned by means of power drives 11 so that the platform 13 goes into horizontal position, while the nacelles 1 are located on top of the platforms 13, as shown in Figure 3 a. Gondolas 1 are filled with air and they acquire the form required for swimming and off-road movement. After that, the beam 9 is rotated using the power drive 12, as shown in Figure 3 b, after which the nacelles 1 are at the bottom of the platforms 13, as shown in Figure 4 a. For off-road movement, the platform 13 with the nacelles 1 is moved forward using the drive 16 and the chain gear 17, as shown in Figure 4 b. The carriages 5 using power drives 10 are moved along the guides 4 to the lower position, while the nacelles 1 abut against the surface of the earth, and the vehicle 3 rises above the surface of the earth, as shown in Figure 4 c. Then, using the drive 16 and chain transmission 17, the vehicle 3 is moved forward, as shown in Figure 5 a. Then the carriages 5 are lifted, as a result of which the platforms 13 with the gondolas 1 rise relative to the vehicle 3, and the vehicle 3 itself falls to the ground, as shown in Figure 5 b. When the carriages 5 reach the upper position, the vehicle 3 stands on the surface, and the nacelles 1 are raised at a certain height above the ground, as shown in figures 5 b, c. In this way, a step is carried out. Further movements are repeated in a cycle, thereby moving the vehicle 3 off-road in steps. Figure 6 shows the initial and final position of one step of a self-propelled vehicle in the step-by-step mode. Such movement is effective on rough terrain, swamps, at the entrance to the reservoir, when the movement on wheels is impossible. When in the water, the vehicle 3 is moved along the longitudinal axis relative to the nacelles 1, while ensuring the correct placement of the center of gravity to eliminate the trim caused by the uneven placement of the load on the vehicle 3.

The achievement of the technical result by the proposed method of moving a self-propelled vehicle, providing it with high cross-country ability, increased stability on water, is achieved by moving in steps, in which the vehicle itself is one of the supports, and the kinematics of walking movements is formed by simple movements - vertical and horizontal relative movements of the vehicle and floating tanks. This allows you to increase the permeability of the vehicle when moving from land to water and vice versa, when moving through difficult to overcome terrain, while overcoming water barriers and does not require serious refinement of the vehicle itself. This method allows you to switch from driving mode on wheels or tracks to walking mode quickly and without lengthy preparatory operations. The achievement of the technical result in the method is also due to the ability to change the longitudinal trim in the mode of movement by swimming by longitudinally moving relative to each other floating containers and the vehicle, which is also used when moving in steps. This ensures the stability of the vehicle on the water when moving by swimming.

The achievement of the technical result in a device that provides high traffic and increased stability on the water of a self-propelled vehicle is achieved due to the presence of simple mechanisms of longitudinal and vertical relative movements of the self-propelled vehicle and floating tanks.

Claims (3)

1. A method of moving a self-propelled vehicle, providing it with high cross-country ability, increased stability on water, in which the movement on a rigid surface is carried out similarly to the movement of a vehicle driven by wheels or tracks, and when moving on a hard surface, floating containers are placed on top of the self-propelled vehicle, at the same time, floating containers are held by the mechanism of their movement, movement in deep places of water bodies is carried out by swimming, relying on floating containers, at the volume of the self-propelled vehicle relative to the floating containers is held by the mechanism of their movement, before moving to the deep places of the reservoirs, the floating tanks are moved to the lower position on the sides of the self-propelled vehicle using the movement mechanism, characterized in that the movement on the shallows, swamps and when entering the reservoir is carried out by walking moreover, the pacing is carried out by a movement mechanism by cyclic alternately supporting first the entire self-propelled vehicle to floating tanks with by lifting and moving the self-propelled vehicle relative to the floating tanks along the direction of travel, then raising the floating tanks with the self-propelled vehicle resting on its wheels, tracks or body elements with the lifting and moving of the floating tanks along the direction of movement, and to ensure longitudinal stability during movement, they carry out swimming movement of a self-propelled vehicle relative to floating tanks by the same movement mechanism by which ganiy. 2. A device that provides high maneuverability and increased water resistance to a self-propelled vehicle, containing floating tanks, a mechanism for moving floating containers from a position above the self-propelled vehicle to a position on the sides of the self-propelled vehicle and a mechanism for the vertical movement of the self-propelled vehicle and floating tanks relative to each other made with the possibility of transferring the weight of the vehicle to floating containers, characterized in that it contains NT, which secures the device to self-propelled vehicles, including those commercially available by industry, a mechanism for the longitudinal movement of a self-propelled vehicle and floating tanks relative to each other, and the mechanisms of vertical and longitudinal relative movements of the self-propelled vehicle and floating tanks relative to each other together form a moving mechanism paced, made with the provision of alternating support first of all self-propelled vehicles Twas on the floating container with lifting and moving the self-propelled vehicle with respect to the floating containers along the direction of travel, then raise the floating tanks journalled self-propelled vehicle on its wheels, tracks, or members of the body to lift and transport containers floating along the direction of motion. 3. A device that provides high cross-country ability and increased water resistance to a self-propelled vehicle according to claim 2, characterized in that the floating containers are fixed with the possibility of quick replacement to platforms that are part of the walking mechanism, floating containers are inflatable nacelles, an element providing fastening the device to self-propelled vehicles, made with the possibility of fastening to the car frame, the mechanism for moving floating tanks from a position above the self-propelled vehicle by means of the device to the position on the sides of the self-propelled vehicle and the mechanism for the vertical movement of the self-propelled vehicle and floating tanks relative to each other have common links and contain vertical guides placed on each side in the front and rear parts of the self-propelled vehicle, to which are mounted with the possibility of vertical movement carriages, two on each side of the self-propelled vehicle, to each carriage with the possibility of rotation relative to the longitudinal axis a self-propelled vehicle, a lever having a hinge at its second end, the axis of rotation of which is perpendicular to the longitudinal axis of the self-propelled vehicle, is attached to its hinges on each pair of levers located on one side of the self-propelled vehicle, lever couplings are inserted into which the front and rear ends are inserted with the possibility rotation around its longitudinal axis of the beam, and the beam is fixed to the rear lever clutch without the possibility of longitudinal sliding, and to the front lever clutch with the possibility of longitudinal sliding relative to the front lever, and also contain power drives for moving the carriages, turning the levers and rotating the beam, the mechanism for the longitudinal movement of the self-propelled vehicle and floating containers relative to each other contains platforms located on each side of the self-propelled vehicle, corresponding to the length of the self-propelled vehicle, with floating tanks fixed to them, with longitudinal guides fixed to each platform, to which With the possibility of longitudinal sliding, beam couplings are fixed, which are fixedly mounted next to the front and rear ends of each beam, and also contains a power drive fixed with the possibility of moving each platform relative to its beam.

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