Ferrari

All-wheel drive all-terrain vehicle with a breakable bobby frame. All-wheel drive karakat “Little Imp” Homemade pneumatic vehicle with a breakable frame

Today there are a large number of people who are experimenting and trying to create their own vehicles from what they have on hand. Naturally, this is an incredibly difficult task that not everyone can do, but if you have the appropriate skills, you can afford something like this. The only question is, what exactly would you like to design? After all, there are various common vehicles that people very often choose first. For example, it is popular to convert a motorcycle into a tricycle. However, in this article we will talk about another type of transport, namely caracats with a breaking frame. You will learn what it is and also get some useful tips on exactly how to create it.

What is a karakat?

Many people who hear about caracats with a breaking frame for the first time are very surprised - it is difficult to imagine what it is if you have never seen this type of transport. In fact, everything is not as scary as it might seem. The fact is that a karakat is a vehicle that does not have a solid frame; it has the ability to bend, since it consists of two parts. This is what allows the carakat to overcome a wide variety of obstacles without any problems - that is why it is called an all-terrain vehicle. It can be used for entertainment, as it can overcome any obstacles, and do it extremely effectively. However, you should definitely pay attention to the fact that this type of transport can also be used to solve more serious problems, since it can overcome snow, stones, and many other obstacles that cars with a solid frame cannot do. Naturally, you are unlikely to find such a design in a store, so if you are interested in caracats with a breaking frame, then you will have to think about making them yourself.

Basic design

So, if you are thinking about what it will take to make caracats with a breaking frame available to you, then you definitely need to decide what exactly your design will be, as well as what you will make it from. The first thing you will need to do is frames, or rather half-frames, since each of them will represent half of a full frame. By the way, it is worth paying attention to the fact that the breaking frame is actually called articulated, but this is the official name, which is not so easy to pronounce, which is why people call it breaking - for the unusual property that it has. Accordingly, you will need to weld the half-frames either from scratch, or based on some frame that you have in stock. But at the same time, pay attention to the fact that in the future you will not have problems with the placement of all the necessary elements, including wheels. If you make the frame with your own hands, then you will need to prepare a drawing in advance, so that you can then carry out everything in accordance with it. It is also recommended to consult with other people who also understand the issue so that they can point out any shortcomings that you may have missed. Remember that it is extremely difficult to do, so you will have to try hard to get something useful.

Half frames

If you create, you are expected to do everything the way you want, but this is not always the best way. Sometimes it can be useful to take advantage of the work of people who have already done something similar. For example, you shouldn’t reinvent the wheel, at least when it comes to creating semi-frames. Traditionally, the front frame bears the main functional load - it houses the driver’s seat, steering wheel, and engine compartment. Why is this so? In an all-frame car, you can choose exactly where the engine will be located, what kind of drive the car will have, and so on. Here the frame is divided into two parts, and in the end it turns out that the front part will not be able to move normally if all the functional load is located at the rear. Accordingly, the rear half-frame is usually used as an addition - space for cargo can be made on it. Moreover, in this matter, the simpler everything is, the better, so don’t come up with any incredible shapes, shifting the center of gravity, and so on. A homemade karakat with a breaking frame is, first of all, a functional device. And only if it functions perfectly on its own, can you think about cosmetic and other improvements.

Rounded fist

Well, it's time to talk about one of the most important moments that a karakat has - breaking the frame. It occurs constantly as your vehicle turns from side to side, descends lower or rises higher, and also encounters obstacles. Accordingly, you need to ensure that your steering knuckle is attached to the half-frames as securely as possible, and is also durable and functional in itself. To do this, sheets of metal need to be welded to the end of the half-frames - it is to them that the fist will be attached, so they must also be as strong as possible. It doesn’t matter whether you are making a karakat from a motorcycle or from a car, in any case you will have to take proper care of the wheel drive chain, as this is extremely important.

Wheel drive chain

Naturally, when it comes to homemade caracats, you will have to think carefully about how you will set the wheels of your all-terrain vehicle in motion. The most reliable way is to install a pulley on the engine, from which chains and belts are put on the wheels. There will be no problems with the front ones, but you will have to try hard with the rear ones, since you will need to take into account the breaking frame - it can become an obstacle for you. However, this is not to say that this is the most difficult obstacle possible.

Transmission

Also do not forget that your vehicle will need which, naturally, should be brought to the same place as the steering wheel. As for choosing a specific gearbox, it all depends on your taste: you can leave the box that was installed on the vehicle that you use as the basis for your karat, or you can choose something more up-to-date.

Driver's seat

Well, it's time to figure out what the place where the driver will be will look like. You need to choose the most comfortable chair that will also be securely fastened, since you will be traveling in conditions that are not the most comfortable, so it is extremely important that you yourself feel comfortable and safe in the chair. But don’t forget that you should leave space right under the seat to install the battery. The steering wheel should be left the same or choose one that is more suitable for extreme off-road driving.

Cabin

Naturally, if you don’t want to, then you don’t need to make a cabin as such - here we mean everything that you can find in the driver’s cabin, that is, the pedal assembly, which you should also take from the car that best suits you. Also, do not forget to design the dashboard, which should include everything necessary, for example, the mechanism responsible for turning the headlights on and off, the horn button, switching the mass, as well as the rest of the functionality that your karakat will be equipped with.

The article is compiled based on materials - link to source

The all-terrain vehicle "Bobik" is made according to the "perelomka" design, that is, it consists of two independent semi-frames that can independently rotate both in the horizontal and vertical planes. This design virtually eliminates the wheels hanging out on uneven surfaces and almost always all four wheels have contact with the ground. This increases the cross-country ability of the all-terrain vehicle, turning is carried out by turning the semi-frames, that is, the wheels themselves do not turn, they turn due to the skew of the semi-frames. Load capacity on land is about 300 kg, on water 200 kg. The curb weight of the all-terrain vehicle is 780 kg, the maximum speed is 25 km/h.

The frame is made of a profile pipe, the size of the front half-frame is length 165cm, width 80cm, height 26cm. The motor is located in front, which takes up 75 cm. For the frame, profiles with dimensions 40*40*2mm 40*20*1.5mm 40*25*2mm were used. The rear semi-frame is trapezoidal. Height 20cm, base width 81cm, side edges 90cm long, half frame height 26cm.

The outer skin is made of painted smooth sheet, which is attached to the frame with aluminum rivets. The all-terrain vehicle is small in size and capacity, the design was designed for minimally comfortable dimensions, and for an economical low-power engine, so the weight was reduced as much as possible without compromising the reliability and strength of the frame and transmission.

The base of the all-terrain vehicle is 183 cm; to attach the semi-frames, reinforced plates 10 mm thick are welded to their ends, through which the turning point is attached. The fracture unit is based on the steering knuckle of the UAZ front axle. The driver's seat (from the passenger Gazelle) is located on the rear edge of the front half-frame, one might say that it is almost in the center of gravity of the all-terrain vehicle. A full-fledged car battery is installed under the seat, the driver's seating position is high, conducive to overcoming off-road conditions and uneven terrain.

The transmission looks like this:
From the engine, torque is transmitted by four belts to the gearbox. The pulley on the engine has a diameter of 9.5 cm, the pulley on the box is 26 cm, it is installed on the support shaft to relieve the load on the box shaft, and rotates in a double-row bearing from the front wheel of the VAZ-2108. A splined bushing from the VAZ clutch disc is welded to the end of the driven pulley support shaft; this bushing includes the input shaft of the VAZ-2106 gearbox. The belts are tensioned by a roller on two springs, this roller also acts as a clutch, the length of the belts is 125cm. The generator drive is taken from the drive pulley on the engine by the fifth belt; the generator belt is from the D-240 diesel engine and almost all of its modifications.

Four belts in the drive were used to extend their life. In general, it would be possible to install one belt, but it would quickly wear out. The motor power is 9 kW, and for these belts the load should be 2 kW, just enough for four belts.

The output shaft of the box is cut off at the beginning of the splines, and the splines are fitted onto the VAZ cardan flange, while the cardan pipe is cut to the required size. The second end of the cardan is screwed by the cardan flange to the shaft of the chain gearbox, on which a sprocket Z=13 is welded, pitch 19.05 mm. The gearbox is made on the basis of the VAZ front hub and is attached to a metal plate, which in turn is screwed to the frame and can be shifted to tension the chain. From the intermediate shaft, the chain drive goes to the steering knuckle, on which a 41-tooth sprocket is installed, and from the knuckle the drive is distributed by cardans to the front and rear axles.

Driver's seat and controls. The brake pedal presses the brake cylinder through the rod (a UAZ clutch cylinder is installed). The clutch pedal is driven by a cable to the tension roller of the engine drive belts; by squeezing, the roller is pulled back and the belts begin to slip. The gas pedal controls the carburetor through a cable. The steering wheel and upper crosspiece are from a VAZ2106, the lower crosspiece is from an M-2141, the crosspieces are connected using a 20*20mm profile. The rake is also from M-2141. Under the steering wheel on the right is the carburetor damper drive, and there is also a headlight switch, a horn button and a battery mass switch.

The cross-country ability of the all-terrain vehicle is good, although there may be a lack of differential locking, but this will significantly complicate the design and add weight. And so, in terms of cross-country ability, you can drive anywhere, even on water, the all-terrain vehicle floats, but a uniform draft is achieved if the rear part is loaded or there is a passenger, and there is a large roll on the front since both the engine and the driver are in front. The engine is rather weak, but it is enough for leisurely driving, and most importantly it is economical. But if the snow is more than 40 cm deep and loose, then the engine has a hard time. The belt clutch performed well, the main thing is that the belts are of high quality, the fake ones don’t last long, but with good belts the season definitely lasts.

In my spare time I enjoy building all-terrain vehicles. I built the first such car in the summer of 2011. And now I present, in my opinion, one of my most successful developments - an all-wheel drive all-terrain vehicle with a “breakable” frame - “Bobik”.

The frame is articulated (“breakable”), consists of two box-type semi-frames, welded from profile pipes with sections 40x40x2 mm, 40x20x1.5 mm and 40x25x2 mm. The places where the bridges are attached to them are reinforced with linings made of a rectangular pipe of 40x25x2 mm.

The frames of the cabin, hood, wings and body are made of square pipes 20x20x1.5 mm and 15x15x1.5 mm.

Main dimensions of all-terrain vehicle semi-frames: A – side view; B – top view

Dimensions of the front half-frame (length x width x height) – 1650x800x260 mm. The engine compartment occupies 750 mm (in length), the rest of the space is reserved for the driver's seat. This half-frame was conceived as universal - for several types of engines. Therefore, the dimensions of the engine compartment were made for the VAZ-1111 Oka engine. Most of the other suitable engines are smaller in size. For example, for an engine like the Lifan 182FD, the length of the engine compartment can be reduced by 100 - 150 mm.

The rear semi-frame is trapezoidal in plan (narrower in front than in the rear), so that the turning radius is smaller. The width of the “top” is 200 mm, the base is 810 mm, the sides are 900 mm long. The height of the “box” of the semi-frames is 260 mm. To increase the volume of the body, I made a rectangular rear semi-frame.

1 – axis of the tension roller lever (homemade); 2 – tension roller lever (homemade, inside bearings 180204, 2 pcs.); 3 – drive pulley (5 grooves of profile “A”); 4 – tension roller axis (homemade); 5 – belt clutch tension roller (homemade, inside bearings 180203.2 pcs.); 6 – engine (“Lifan” or equivalent); 7 – driven pulley (Ø250, 4 grooves of profile “A”); 8 – driven pulley shaft (homemade); 9 – driven pulley support housing (homemade, inside bearings 180109, 2 pcs.); 10 – VAZ-2101 – 2107 gearbox (clutch removed, casing cut off); 11 – flange of the secondary shaft of the gearbox (flange of the primary shaft of the rear axle VAZ-2101-2107; 12 – driveshaft (from VAZ-2121, shortened); 13 – primary shaft of the chain drive; 14 – drive sprocket of the chain drive (z=13, pitch 19.05); 15 – bearing housing of the input shaft of the chain drive (rear hub of the VAZ-2108 assembled with bearings); 16 – movable plate of the chain drive (s10); 17 – brake disc (from the front wheel of the VAZ-2101-2107); 18 – driven sprocket of the chain drive (z=43, pitch 19.05); 19 – transfer shaft (block) of the rotary unit (UAZ-469 CV joint shaft, converted); 20 – bearing housing of the transfer shaft (homemade, inside bearings 180106, 2 pcs.); 21 – fixed plate of the steering knuckle ball joint (s10); 22 – steering knuckle ball joint (from UAZ, internally machined for bearing 1000906-2118); 23 – CV joint (from UAZ); 24 – steering knuckle housing (from UAZ); 25 – steering knuckle axle (from UAZ); 26 – steering knuckle hub (from UAZ, inside bearings 127509, 2 pcs.); 27 – CV joint bearing housing (from UAZ, modified, inside bearing 1000908-2RS); 28 – rear axle drive flange; 29 – driveshaft (from VAZ-2121, shortened); 30 – rear axle (from VAZ-2101-2107); 31 – front axle (rear axle from VAZ-2101 - 2107); 32 – VAZ-2121 driveshaft (short); 33 – adapter washer (homemade)

1 – gearbox; 2 – cardan shaft; 3 – drive sprocket of the chain drive (chain gear); 4 – support bearing assembly of the drive sprocket; 5 – chain; 6 – support bearing assembly of the driven sprocket; 7 – driven sprocket; 8 – transmission brake disc caliper; 9 – driveshaft of the front axle (under the frame tube); 10 – front axle; 11 – articulating (fracture) unit of semi-frames; 12 – rear axle driveshaft; 13 – rear axle; 14 – rear semi-frame; 15 – front half frame

A power unit with a 5-ribbed V-belt drive pulley on the output shaft (4 belts for the power transmission and 1 belt for driving a generator or power steering) and a 4-ribbed driven pulley. The connecting spline assembly of the driven pulley shaft and the gearbox input shaft are located in the housing (in the foreground)

1 – fracture site; 2 – bipod; 3 – hinge; 4 – traction; (the chain on the driven sprocket and behind them the transmission brake caliper are clearly visible)

Steel plates of 10 mm thickness are welded to the internal crossbars of the semi-frames, to the sides facing each other, for attaching the articulating joint (fracture unit). The distance from the internal “ends” of the semi-frames to the middle of the bridges is 790 mm. Thus, the base of the all-terrain vehicle is 1830 mm.

The design of the turning point is based on the steering knuckle from the front axle of the UAZ-469. Inside, in two bearings 180106, one bearing 180208 and two bushings, the CV joint from the UAZ rotates.

Of course, the articulating (fracture) unit is a rather complex mechanism, and it is worthy of a detailed description. I made it according to the method of Omsk resident Yuri Shashkin - from a steering knuckle from a UAZ-469, making only a few changes. Yuri uses a CV joint from a VAZ-2121 (or VAZ-2108). There are other differences: Yuri has a ball joint for the steering knuckle machined for the bearings, while I have a separate housing for them.

1 – support for the steering column frame and instrument panel; 2 – instrument panel; 3 – steering wheel; 4 – steering shaft in the column; 5 – steering column; 6 – cardan steering shaft; 7 – steering rack; 8 – front steering rack mount; 9 – adapter from the steering rack to the tie rod end; 10 – steering tip (2 pcs.); 11 – lock nut M18x1.5 (2 pcs.); 12 - steering rod; 13 – rear steering rack mount; 14 – hinged tip; 15 - bipod; 16 – “turning point” node; 17 – lock nut

In general, only on converting the UAZ knuckle into a turning unit can you write a multi-page separate article. But I didn’t make my own drawings, and giving someone else’s is unethical.

A home-made flange is mounted in the middle of the front half-frame, into which a shaft with a block of a driven sprocket of a chain gearbox, a brake disc and a driveshaft fork of the front axle drive is inserted. The disc is equipped with a VAZ-2106 caliper screwed to the frame with cylinders and pads.

A flange from the main drive of the UAZ axle is attached to the rear semi-frame plate, through which the shaft passes. breaking point with rear drive driveshaft fork.

TRANSMISSION

A drive pulley with a diameter of 95 mm is installed on the output shaft of the engine (Lifan 182FD or similar). The pulley has five grooves of profile “A”. Four of them are intended for clutch drive belts and one (outmost) is for driving a generator or hydraulic pump. The shafts on different engines are not the same size and have different keyway widths, so you have to be careful here.

The length of the “A” profile belts (generator from the D-240 diesel engine) is 1250 mm. The belts are tensioned by a roller with two springs. The roller rotates in two bearings 180203. Its axis, for convenience, fits into the bearings using a “sliding” fit, that is, quite freely (by hand). When the axle nut is tightened, the inner races of the bearings are clamped between the spacers and do not rotate.

A driven pulley with a diameter of 260 mm is mounted on a support shaft, which rotates in a double-row bearing from the front wheel of a VAZ-2108 car. A splined bushing from the Zhiguli clutch disc is welded to the end of the support shaft. This bushing includes the input shaft of the gearbox (gearbox) from the VAZ-2106.

The holes in the pulley for attaching it to the shaft are drilled for the flange of the “Zhiguli” propeller shaft. This was done for the versatility of using this pulley. It is not necessary to repeat this at all; you can place the holes on the pulley and shaft flange at an angle of 90°.

The gearbox output shaft is cut to the beginning of the splines. The flange of the Zhiguli driveshaft is mounted on the splines. The shaft pipe is cut to the required length. The second cardan flange is screwed to the input shaft of the chain gearbox, to which the sprocket is welded (z=13, pitch 19.05 mm). The input shaft itself rotates in tapered bearings from the front hub of the Zhiguli, which, in turn, is screwed to a movable plate. By changing the position of the plate, you can adjust the chain tension.

A driven sprocket with a number of teeth z=41 is installed on the transfer shaft of the rotary unit. The transfer shaft drives the main axle gears (from the VAZ-2106) via cardan shafts (shortened from the VAZ-2121 Niva). The drive axles (both front and rear) are from the VAZ-2106. The tires on the wheels were both homemade (“torn off”) and industrially produced. I didn't notice much difference in driving performance.

DRIVER'S CABIN

The driver's seat is located behind the engine compartment and is separated from it by a partition made of duralumin sheet on a frame made of pipes with a cross-section of 20x20 mm. The driver's cabin is semi-closed (without doors or rear wall). The seat is from a passenger Gazelle. There is a 60 Ah battery under the seat. The steering column was converted from a Zhiguli one (VAZ-2106), and the upper part of the steering propeller shaft was taken from there. Its lower part is made of a 20x20x2 mm profile pipe, the crosspiece is from the M-2141 Moskvich car. The steering mechanism (“rack”) was also borrowed from the M-2141.

Pedal units are from Zhiguli. Their location is the same as on a car. The clutch pedal is connected to the tension roller of the clutch belt via a cable. The brakes are transmission, the disc is mounted on the driven sprocket shaft. The pedal is connected by a rod to the main brake cylinder (from the UAZ clutch), which drives the brake caliper cylinders (from the VAZ-2108). The gas pedal is homemade, connected to the carburetor with a Bowden cable.

Under the steering wheel there is a panel on which there is a toggle switch for turning on the headlights, a cable handle for the carburetor air damper, a horn button and a ground switch.

The all-terrain vehicle "Bobik" has been modernized several times, and even has several similar copies, which were distributed to different owners. Therefore, some drawings may differ in some ways from the images in the photographs.

BASIC DATA OF THE ALL-TERRAIN VEHICLE “BOBIK”

Engine – Lifan 182FD, 11 hp, four-stroke, forced air cooling, made in China.

The gearbox is from a VAZ-2106, four-speed.

Bridges are from VAZ-2106, gear ratio 3.9.

Tires – VI-3 (from KRAZ-255B), lightweight (“torn”), actual size 1250×520-533 mm.

The wheels are non-separable (for beading), with the tires secured with bolts.

Overall dimensions (lengthxwidthxheight) – 3300x1950x2300 mm.

Loading capacity on land/water -300/200 kg.

Curb weight – 780 kg.

Maximum speed – 25 km/h.

P. Semenov, Medvedkovo village, Tver region

Articulated frame for UAZ.
Review of designs of "breaking" frames.

For the average person, the phrase "frame failure" is associated with severe breakdown of a truck or SUV.

However, there are engineering solutions that are specifically designed for this ability to “break” the frame without consequences :).
This is done to increase the cross-country ability and maneuverability of the vehicle.

Back in 1919 Italian engineer Pavesi designed the Fiat-Pavesi P4 all-terrain tractor-trailer with very large wheels. To turn the car, the principle of a “breaking” frame was implemented. (source - patriot4x4.ru)

In our country, in 1961, on instructions from the government, it was developed Tractor K-700 with a breaking frame. The goal of the project was to create the first domestic wheeled tractor of the fifth traction class. The photo shows the tractor K-701

The semi-frame of the K-700 tractor has impressive dimensions

Assembly drawing of the connecting joint of the K-700 tractor

Who doesn’t remember the city articulated bus Ikarus-280?

The unique properties of cars with a breakable frame have prompted many designers to implement such a solution in various types of all-terrain vehicles. Moreover, both individual homemade ones and on an industrial scale.
Here, at least remember the Swedish tracked swamp vehicle Elk, which has many imitators.
But there is also something to see in the ranks of wheeled vehicles:

Snow and swamp-going vehicles SKU

Snow and swamp-going vehicles SKU, which were produced by the Severodvinsk company Diphthong, have two sections connected to each other by a rotary coupling device, which allows the links to fold relative to each other in a horizontal plane.
Snow and swamp-going vehicles are described in the Autoreview magazine for 2006

Photo of the swivel joint

Photo demonstrating that it is necessary to install a turn limiter

Tractor "Sibiryak"

The Sibiryak has an articulated frame

The most interesting is the central hinge unit.
It consists of a power housing, which is the rear part of the front half-frame, a constant velocity joint (CV joint), transmitting torque to the rear axle, and a ball housing, hinged and powered.
The ball shank is inserted into a special housing of the rear semi-frame and has the ability to rotate in it when the relative position of the semi-frames changes. The special housing is connected to the rear semi-frame by two 20 mm plates.

Power housing welded from sheets 20 mm thick. perceives loads acting on the machine in a vertical plane, and a ball bearing fixed in the tapered bearings of the housing serves to rotate the semi-frames relative to each other in the horizontal plane.
This movement is carried out by a hydraulic cylinder installed between the front half-frame and the ball joint bracket.

The basis for the central unit was parts from the steering knuckle of the front wheel of the ZIL-131 car, identical in design to the GAZ-66 car, but different in size.
The shank of the ball body and the shanks of the axle shafts of the drive and driven CV joint shafts have been modified.
The bearings in the axial joint are bronze bushings, and the traction (longitudinal) forces are absorbed by a thrust ball bearing. The joint cavities are sealed with oil seals and filled with grease.

Central hinge:
1 - bearing 60212; 2- stud M10 (6 pcs.): 3, 10 - thrust rings (steel 45, s2). 4 - kingpin; 5 - cuff (from the standard unit); 6 - spring ring; 7 -- cuff (1-115x145); 8 - liners (bronze): 9 - spacer; 11 - thrust nut; 12 - bearing 8212; 13 - locking nut; 14 - special housing; 15 - body of the central ball-joint assembly; 16 - ring; 17 - driven shaft; 18 - ball body; 19 - drive shaft; 20, 26 - bearing housings (steel 45). 21 - flange (cram. 45) 22 - M32 nut; 23 - M5 pin (6 pcs.); 24 tapered bearing (standard); 25 - bearing cover: 27 - sealing ring (rubber); 28 - cuff (1-85x110); 29 - steering hydraulic cylinder.

Often, the steering unit for all-terrain vehicles is made from the steering knuckle of the front wheel of an all-wheel drive vehicle, for example, from the steering knuckle of a UAZ

UAZ-Camper with a rolling frame

Using the technology that was developed at the Corporals, UAZs with a torsional frame were made. This is a camper based on the Krasnodar auto club "Kuban" and a truck at the base UAZ-39095

In fig. 1 shows a plan view of the vehicle; in fig. 2 the same, side view; in fig. 3 diagram of bearing unloading.
An articulated vehicle 1 with all-wheel drive contains two independent semi-frames A and B, interconnected with the possibility of relative movement. A main hinge 2 is installed between the half-frames, having an internal diameter 3 sufficient for the free passage of the cardan shaft 4 through it.
On half-frame B, a movable element 6 is installed coaxially with bearing 2 on brackets 5 (element 6 can be used, for example, a shaft mounted in bearings, or a ball joint, or a ball connector), rotating around axis 7. Element 6 is permanently attached beams 8 and 9. The second ends of 10 beams are detachably attached to the connecting elements 11 of half-frame A. The ends of 10 beams are spaced apart from the longitudinal axis of the car 7.

The vehicle works as follows.
When driving off-road, half-frames A and B can move around the horizontal longitudinal axis relative to each other at an angle of up to 23°. The possibility of mutual movement is provided by the hinge 2 connecting the half-frames A, the rods 8 and 9, rotating on element 6 and tracking the movement of one half-frame relative to the other, unload the hinge 2 and increase its service area (see Fig. 3). The arising longitudinal force loads between half-frames A and B are perceived primarily by connectors 8 and 9, since they are connected rigidly (without backlash), are partially damped due to their own elasticity, and then transferred to hinge 2.

When driving on public roads, the power frame works in the same way as when driving off-road, absorbing maximum loads and unloading hinge 2.

In the non-working position, the hinge is fixed with pins on both sides, which allows the car to move comfortably on public roads. (in the photo the pins are taken out)