RU2278034C1 - Passenger car energy-absorbing buffer - Google Patents

Abstract

FIELD: transport engineering.

SUBSTANCE: invention relates to collision protective devices and it can be used as front and rear bumpers of different passenger cars, minibuses and other vehicles. proposed buffer to be connected to bearing structure of car has common outer sheathing and central and side sections whose support surfaces are connected to each other through connecting energy-absorbing devices with leaf springs. Main energy-absorbing devices are connected to support surfaces of sections being uniformly spaced and including definite number of interconnected absorbing mirror-like members. Each energy-absorbing member is made integral from section of round metal bar and provided with base, bridge and brace arranged in relatively perpendicular planes. Braces of main energy-absorbing devices are arranged horizontally, being connected to plates of movable bases made integral with leaf springs. Braces of main energy-absorbing devices of left-hand and right-hand parts of buffer are pointed to different sides, respectively, in directions from middle to edges of buffer. Buffer is furnished additionally with energy-absorbing devices made in similar manner, connected to bearing structure of car and interacting through braces with rear surface of corresponding side section of buffer.

EFFECT: high energy absorbing capacity and stability of shock absorbing characteristics with possibility of repeated use.

3 cl, 8 dwg

Description

The present invention relates to means of passive safety of vehicles in collisions, protective equipment that have a high energy absorption capacity, and may find application as front and rear bumpers of cars of various classes, minibuses and other vehicles.

Numerous designs of energy-absorbing bumpers are known [1, 2, 3, etc.], including rigid supporting surfaces, outer skin, and shock absorbing devices and elements of various types located between them; however, they do not have a high energy absorption capacity and do not have the possibility of reusable use after performing certain repair operations.

The closest in the set of features to the analogues are the designs of energy-absorbing buffers for cars [5, 6, 7], and the “Energy-absorbing buffer of a passenger car" [6] is a prototype of the proposed design. This device includes an outer skin, a U-shaped bumper attached to the supporting structure of the car, energy-absorbing devices located between them and evenly spaced along the length of the bumper from each other, attached to the outer surface of the bumper, and other auxiliary elements. Each energy-absorbing device includes a certain number of energy-absorbing elements adjacent to each other, each of which is a mirror image of an adjacent one, made in one piece from a round segment made, in particular, of a material having the effect of “shape memory”, a metal rod, sections of which are sequentially bent in mutually perpendicular planes, and accordingly includes a base, a jumper and a brace, and the bases of all energy absorbing elements of each energy the absorption device along its entire length is connected to the outer surface of the bumper, the jumpers are respectively aligned with each other and interact with their lateral surface with the outer surface of the bumper, and the adjacent braces are located in the same plane, are interconnected along their entire length and are directed outward relative to bumpers, and two central energy-absorbing devices, each of which is a mirror image of the other, are adjacent to each other, the bases and braces of all energies the absorbing elements are arranged horizontally, the jumpers of all the energy absorbing elements are arranged vertically, and the braces of all the energy absorbing devices of the left half of the buffer and the braces of all the energy absorbing devices of the right half of the buffer are turned at different angles, respectively, in the directions from the middle to the edges of the buffer, with each energy absorbing device equipped with a movable base in the form of a rigid plate, made in one piece with the side protrusions, and leaf springs, attached nienny to the back surface of the movable base and made, in particular, of a material having the effect of "shape memory".

This device is distinguished by its simplicity of design, high energy intensity, stability of depreciation characteristics and the possibility of reusable use, respectively, after performing simple repair operations and replacing the outer skin and a number of other elements.

The disadvantages of this device include the low efficiency of energy absorption in a collision, when all the collision energy falls only in the left or right edge of the buffer, which includes only two or three extreme energy absorbing devices.

The task to which the proposed design is directed is to provide protection for a passenger car in a collision with an obstacle or other passenger car, moreover, a protection possessing high energy absorbing ability and stability of amortization characteristics even when all the impact energy acts only in the left or right edge portion of the buffer.

The technical result consists in the fact that a significant increase in energy absorption and depreciation is ensured in the event of impact loads in one or another side section of the buffer and the possibility of reusable use of the energy-absorbing buffer design and full restoration of the specified characteristics after deformation due to impact loads and, accordingly, after simple repair operations and replacement of the outer skin.

These technical results are achieved in that the energy-absorbing buffer of a passenger car, including the outer skin, provided with individual sections of the metal strip attached to its inner vertical surface, a support surface in the form of a U-shaped profile attached to the supporting structure of the car, and located between the skin and the support surface and evenly spaced along the profile length of the U-shaped section at a distance from each other, the main energy-absorbing devices, with connected to the outer surface of the profile of the U-shaped section and including each specific number of adjacent energy-absorbing elements, each of which is a mirror image of the adjacent one, made in one piece from a round segment made, in particular, of a material having the shape memory effect ", a metal rod, sections of which are successively bent in mutually perpendicular planes, and accordingly includes a base, a jumper and a brace, and the bases of all energy the absorbing elements of each main energy-absorbing device along their entire length are attached to the outer surface of the profile of the U-shaped section, the jumpers are respectively aligned with each other and interact with their lateral surface with the outer surface of the profile of the U-shaped section, and the adjacent braces are located in the same plane are interconnected along their entire length and directed outward relative to the supporting surface, with two central main energy-absorbing devices, each e of which is a mirror image of the other, are adjacent to each other, the bases and braces of all the energy-absorbing elements of each main energy-absorbing device are horizontal, the jumpers of the energy-absorbing elements are respectively vertical, and the braces of all the main energy-absorbing devices of the left half of the buffer and the braces of all the main energy-absorbing devices of the right half buffers face each at a given angle in different directions, respectively, in the directions from the middle to buffer, each main energy-absorbing device provided with a movable base in the form of a rigid plate made in one piece with two side protrusions, and including leaf springs made, in particular, of a material having the effect of "shape memory", and connected with one of its own end to the outer surface of the U-shaped profile of the supporting surface, additionally made as follows: the supporting surface of the buffer includes a Central and two side sections, which are located end to end to each other and interconnected through connecting energy-absorbing devices, including each specific number of adjacent energy-absorbing elements, each of which is a mirror image of the neighboring one, made in one piece from a round segment made, in particular, of a material having the effect of “shape memory”, a metal rod, sections of which are successively bent in mutually perpendicular planes, and accordingly includes a horizontal base, a vertical bridge and additional horizontal base, and the horizontal base and additional horizontal base are directed respectively in opposite directions and horizontal bases are respectively attached along their entire length to the rear surface of the U-shaped profile of the Central section, and additional horizontal bases along their entire length are attached to the rear surface of the U-shaped profile of the side section, with vertical jumpers interacting with their side surface with the back surface П U-shaped profile of the central section and are flush with its lateral edges, while the horizontal shelves of the supporting surfaces of the central and lateral sections at the joints are made with oblique cutouts, the supporting surface of the buffer is provided, in particular, made of a material having the shape memory effect ", leaf springs, which are respectively coaxial to the connecting energy-absorbing devices and each connected at one end to the rear surface of the Central section, and the other its their end to the rear surface of the side section of the supporting surface of the buffer; in addition, the energy-absorbing buffer of a passenger car can be equipped with two additional energy-absorbing devices attached to the side of the car supporting structure, including each specific number of energy-absorbing elements, each of which is a mirror image of the neighboring one, made in one piece from a round segment made, in particular, from a material having the effect of "shape memory", a metal rod, sections of which are successively bent into a mutually perpendicular planes, and accordingly includes a base, a jumper and a brace, with the bases of all the energy absorbing elements of each additional energy absorbing device located horizontally and along their entire length attached laterally to the supporting structure of the car, the jumpers are respectively vertically and coaxially to each other and interact with their lateral surface with the outer the surface of the vehicle’s load-bearing structure, and the braces are horizontal and in the same plane, connected by a jumper and directed respectively to the side sections of the supporting surface of the buffer, with each additional energy-absorbing device provided with a movable base plate made in one piece with a leaf spring, which is attached to the side of the vehicle supporting structure, and the braces along their entire length are attached to the movable base plate and interact respectively with the back surface of the side sections of the supporting surface of the buffer; in addition, the energy-absorbing buffer of a passenger car can be made as follows: the U-shaped profile of the supporting surface of the buffer is equipped with plate overlays located at the joints of the central and side sections, respectively, above and below the horizontal shelves of the U-shaped profile and attached to the horizontal shelves of the U-shaped the profile of the central section, while the plates of the movable bases of the main energy-absorbing devices are made in one piece with leaf springs, and I absorb energy The main elements of the energy absorbing devices are equipped with an additional jumper connecting all their braces to each other.

The essence of the proposed design is illustrated by drawings, where Fig. 1 shows a longitudinal section of an energy-absorbing buffer, a top view, and on the left side of the drawing shows a simplified version that can be used independently as a rear buffer, as well as for light vehicles, and on the right side of the drawing - The main option, intended for use as a front buffer and for medium and heavy vehicles; figure 2 shows an enlarged image, a section of a connecting energy-absorbing device located at the junction of the sections of the buffer, and the direction of rotation of the side section and, accordingly, the twisting of the torsion bars when exposed to shock load is conventionally shown by an arrow; figure 3 shows an enlarged image of a connecting energy-absorbing device, an external view (respectively, a view of the rear surface of the buffer); figure 4 presents an enlarged image of a set of energy-absorbing elements of the main energy-absorbing device, front view; figure 5 shows an enlarged image - a cross section of the main energy-absorbing device in the original - view a and partially deformed - view b state, and the possible impact directions of the shock load are conditionally shown by arrows; figure 6 shows an enlarged image, a section of the movable base of the main energy-absorbing device; Fig.7 shows an enlarged image, a section of an additional energy-absorbing device that interacts with the side section of the buffer, and the rotation directions of the braces of the energy-absorbing device and side section of the buffer due to the impact of the load are conventionally shown by arrows; and Fig. 8 shows an enlarged image, a side view of an additional energy-absorbing device.

The design of the energy-absorbing buffer attached to the supporting structure 1 of the car contains (see Fig. 1) a supporting surface in the form of a rigid metal profile of a U-shaped section, including a central section 2 and two side sections 3, which are located in one line. Moreover, the vertical wall of the U-shaped profile of the supporting surface of sections 2 and 3 of the buffer (in accordance with the design of the prototype [6]) to increase its strength and stiffness at minimum mass cost can be performed (see figure 5) in one piece intersecting stiffeners located on its back surface, for example waffle. The central 2 and lateral 3 sections of the supporting surface of the buffer are located butt to each other and, at the joints and interconnections, are provided with plate overlays 4 located (see Figs. 2, 3), respectively, attached to the top and bottom of the horizontal shelves of the U-shaped profile, for example, by welding - a one-sided seam with penetration, to the horizontal shelves of the U-shaped profile of the central section 2 and interacting with the horizontal shelves of the U-shaped profile of the side 3 sections, while the horizontal shelves of the U-shaped Ophelia of the central 2 and lateral 3 sections at the joints of the sections are made with oblique cutouts facing the supporting structure 1 of the car (see figure 2, 7, where these cuts are clearly visible against the background of the bottom plate 4).

The central section 2 of the buffer is connected to the supporting structure 1 of the car, and the side sections 3 of the buffer are connected to the central section through connecting energy-absorbing devices 5, each of which (see Figs. 1, 2, 3) a certain number, namely four adjacent to each other energy-absorbing element 6, each of which is a mirror image of the neighboring one, is made in one piece from a round segment made, in particular, of a material with the effect of "shape memory", a metal rod, sections of which consequently bent in mutually perpendicular planes, respectively, and includes a horizontal base portion 7, the vertical bridge 8 and the additional horizontal base 9, which lever. The horizontal base 7 and the additional horizontal base 9 of each energy-absorbing element 6 are directed respectively in opposite directions and the horizontal bases 7 are connected along their entire length to the back surface of the U-shaped profile 2 of the central section by means of welds 10, and additional horizontal bases 9 of both energy-absorbing devices 5 along their entire length, respectively, are connected by welding seams 10 to the back surface of the U-shaped profile 3 of each side section buffers. In this case, the vertical jumpers 8, which are torsions, interact with their lateral surface with the back surface of the U-shaped profile 2 of the central section and are flush with its lateral edges. The supporting surface of the buffer structure is also provided with leaf springs 11 made, in particular, of a material having a "shape memory" effect, arranged respectively coaxially with the energy absorbing devices 5 and each connected at one end thereof to the rear surface of the U-shaped profile 2 of the central section, and its other end - to the back surface of the U-shaped profile of 3 side sections.

On the outer surface of all sections 2 and 3 of the supporting surface of the buffer (in full accordance with the design of the prototype [6]), the main energy-absorbing devices 12 are uniformly spaced from each other, with two central main energy-absorbing devices 12 of the central section 2 of the buffer structure, each of which is a mirror image of another, adjacent to each other.

Each energy-absorbing device 12 includes (see FIGS. 4, 5, 6) a certain number, namely four energy-absorbing elements 13 located in a certain predetermined manner and closely adjacent to each other, each of which is a mirror image of the neighboring one, made in one piece from a round piece made, in particular, of a material having the effect of “shape memory” [8], a metal rod, sections of which are successively bent in mutually perpendicular planes, and accordingly includes a horizontal ontal base 14, vertical jumper 15 and horizontal brace 16; in this case, as a part of each device 12, all braces 16 are interconnected by an additional jumper 17, which, in particular, can be made integrally with two extreme energy-absorbing elements 13 and attached to the central braces 16 by means of welding seams 10. Each brace 16 located at a given angle φ _{about the} base 14 and is a lever that provides twisting of the jumper 15, which is a plastic torsion, relative to the fixed base 14 when exposed to shock load. As part of each energy-absorbing device 12, vertical jumpers 15 of all energy-absorbing elements 13 are aligned with each other, horizontal bases 14 (see FIG. 4) are connected along their entire length by welding seams 10 to the outer surface of the U-shaped profile, and adjacent to each other the bases 14 are also interconnected by means of a weld 10. In this case, the end sections of the braces 16 (in full accordance with the design of the prototype [6]) can, if necessary, be made hollow curved, i.e. rounded towards the outer surface of the U-shaped profile of each section of the buffer; this provides an increase in the surface area of the movable bases and, to a certain extent, expands the possibilities of operation of energy-absorbing devices 12 in cases of impact loading in collisions of the buffer structure with objects of various sizes and shapes and at different angles.

The design of each main energy-absorbing device 12 also includes (see FIGS. 1, 5, 6) a movable base 18 made in the form of a rigid plate equipped with two horizontal lateral protrusions that have a width corresponding to the diameter of the brace 16 and face the outer surface U-shaped profile, and the plate of the movable base 18 is made in one piece with a leaf spring 19, which is attached at its end to the outer surface of the U-shaped profile 2 or 3, respectively. In this case, the plate of the movable base 18 is rigidly connected to the braces 16 of all energy-absorbing elements 13 (along their entire length) by means of welding seams 10, and the adjacent braces 16 are also interconnected by a welding seam 10.

It should be noted that in the structure of the energy-absorbing buffer, all energy-absorbing devices 12 are located and respectively oriented in such a way that they are divided into four groups: two groups of devices 12, the braces of which are facing respectively in different directions and directed towards the edges of the buffer, each located in the side sections of the buffer , and the other two groups of devices 12 are left and right, the braces of which are respectively facing in different directions and also directed towards the edges of the buffer, are located in the central section, which redelyaet said groups can work energy absorbing device 12 when exposed to an impact load separately or jointly.

In addition, the design of the energy-absorbing buffer also includes two additional ones - left and right energy-absorbing devices 20, each attached to the side to the supporting structure 1 of the car (see figures 1, 7, 8). Each additional energy-absorbing device 20 includes two energy-absorbing elements 21, each of which is a mirror image of the neighboring one, made in one piece from a round segment made, in particular, of a material having the effect of “shape memory”, a metal rod, the sections of which are sequentially bent into mutually perpendicular planes, and accordingly includes a base 22, a jumper 23 and a brace 24, and the base 22 of all energy-absorbing elements 21 are located horizontally and throughout their lengths are laterally connected to the vehicle supporting structure 1 by means of welding seams 10, the jumpers 23 are arranged vertically and coaxially with each other and interact with their lateral surface with the outer surface of the vehicle supporting structure 1, and the braces 24 are horizontally and in the same plane, connected by a jumper 25 made with them in one piece, and directed to the corresponding side sections 3 of the supporting surface of the buffer, and the initial position of the braces 24 is initially set by the angle φ _∂ . In addition, each additional energy-absorbing device 20 is provided with a plate of the movable base 26 made, in particular, of a material having a "shape memory" effect, integrally with side protrusions and a leaf spring 27, which is attached laterally to the vehicle supporting structure 1, and the braces 24 are adjacent to the lateral protrusions of the plate of the movable base 26, are attached to it along its entire length by means of welding seams 10, and together with the plate of the movable base 26 interact with the rear NOSTA respective side sections 3 of the supporting surface of the buffer. In addition, each side section 3 of the buffer structure (see Figs. 1, 7) can be equipped with a limiter for moving the movable base 26 of the corresponding additional energy-absorbing device 20, which is made in the form of a hard stop 28 attached to the back surface of the U-shaped profile 3 supporting the surface of the energy-absorbing buffer, and which at the same time is a rotation limiter for each side section 3 of the buffer structure in the event of the impact of intense shock load in it.

The design of the energy-absorbing buffer also includes an outer casing 29, made in the form of a U-shaped profile with rear ends rounded back, covering the energy-absorbing devices 12 and attached using detachable joints to the supporting surface 2 of the buffer or to the supporting structure 1 of the car. In this case, the outer skin 29 is provided (see FIG. 1 and view II) attached to its vertical inner surface, for example, by means of adhesive bonding to individual sections of the metal strip 30, which are located with a gap relative to each other. Two of them are located in the left and right parts of the central section 2 of the buffer structure, respectively opposite to two groups of energy-absorbing devices 12, the braces and movable bases of which are facing (see Fig. 1) in different directions, respectively, in the directions from the middle to the edges of the buffer, and the other two sections 30 of the metal strip are respectively located in the side sections 3 of the buffer structure. The use of individual sections of the metal strip 30, the width of which in the limit can be equal to the height of the plates 18 of the movable bases of the energy-absorbing devices 12, on the one hand, provides increased strength and stiffness of certain sections of the outer skin, located respectively opposite the groups of energy-absorbing devices 12, which will work together when impact of shock loads, and on the other hand, causes the destruction of the outer skin 29 precisely at the place of the gaps between the sections 30 of the metal strip, t .e. at the joints of the central 2 and lateral 3 sections and in the middle of the central section 2 of the buffer.

The manufacture and assembly of the proposed design is very simple and performed by conventional known methods. Most structural elements are made of ordinary steels and alloys; by conventional methods, leaf springs, movable bases, the supporting surface of the sections in the form of a U-shaped profile and the outer skin in the form of a U-shaped profile with back ends rounded back, including sections of a metal strip attached to its rear surface, are performed. And only to the manufacture of energy-absorbing elements of any energy-absorbing device, which, in particular, can be made of various steels - Art. 20, Art. 40X and others, as well as to simplify and speed up repair work from a material having the effect of "shape memory" [8], such as titanium nickelide, are subject to certain requirements. Each piece of metal rod of the workpiece of the energy-absorbing element or the entire set of elements (see Figs. 3, 4, 7) of this energy-absorbing device, having correspondingly given dimensions and a certain diameter, is sequentially bent in mutually perpendicular planes, respectively, at predetermined angles, and in the case of manufacturing an energy-absorbing element of a material having the effect of "shape memory", the bending of the rod is carried out at a temperature setting "shape memory". In the latter case, leaf springs 11, 19 and 27, the last of which are made in one piece with movable bases, it is also advisable to perform from a material having the effect of "shape memory", and the formation of the springs, respectively, is carried out at a temperature setting "shape memory". The manufactured energy-absorbing elements are connected to each other at the place of contact of their bases and braces with the help of welds, and then attached to the back surface of the plates of the movable bases also with welds located respectively along the entire length of their braces. Next, partially assembled energy-absorbing devices 5 and 12 with welds are attached in place to the outer and back surfaces of the U-shaped profile, and energy-absorbing devices 20 are connected in place to the outer surface of the supporting structure 1 of the car, and the bases of all energy-absorbing elements are welded along their entire length , including their end sections. Then, by conventional methods, leaf springs are attached in place, and lastly, outer casing 29 is put on and attached using detachable joints to the supporting surface of the buffer or the supporting structure of the vehicle.

In the case of a head-on collision, when the impact of the shock falls on the central section 3, the buffer structure (see Figs. 1, 5) works as follows. First of all, the outer skin 29 is destroyed in its weakest sections, namely, at the place of the gaps between the sections of the metal strip 30 and, respectively, in the center and sides of the central section 2 (see Fig. 1 and type II). Then there is a deformation of two groups of energy-absorbing devices 12 of the left and right halves of the Central section, deforming, respectively, in different directions. The impact of the load, the magnitude of which exceeds the torsion resistance of the vertical jumpers 15, which are plastic torsions, and the stiffness of the leaf springs 19 on the outer surface of the movable bases 18 cause them to turn (see FIG. 5, view b) to the outer surface of the U-shaped profile 2 and, respectively the rotation of the braces 16 connected to them, which leads to plastic twisting of the coaxial vertical jumpers 15 of the energy-absorbing devices 12 and, accordingly, the absorption of energy by the acting load. At the same time, deformation of leaf springs 19 of these energy-absorbing devices 12 having a predetermined stiffness also occurs. The total energy absorption of each main energy-absorbing device 12 and all buffer energy-absorbing devices 12, which directly had a collision, respectively, consists of the energy absorption values provided by the aforementioned leaf springs and torsion bars during deformation. The rotation of the movable bases 18 of the energy-absorbing devices 12 occurs either until the shock load ceases, and then the energy-absorbing devices 12 remain in some intermediate deformed position (see Fig. 5, view b), due to the magnitude of the acting load, or continues until the stroke depreciation and energy absorption capacity of these devices 12 will not be exhausted. In the latter case, the plates of the movable bases 18 will be rotated in the limit by an angle of φ _о , respectively, the plastic torsion bars - vertical jumpers 15 of energy-absorbing devices 12 will be twisted to the same angle, and the braces 16 with their back surface will abut against the outer surface of the U-shaped profile 2. When it should be noted that simultaneously with the indicated two groups of energy-absorbing devices 12 of the central section 2, others adjacent to them can enter the work on the perception of frontal shock load (see figure 1) -rotating device 12, but disposed on one or both side sections 3 and deforms in the same manner.

In the event of a collision along the normal or at an angle, but when the impact of the impact falls on one or the other side section 3, the buffer structure (see Figs. 1, 2, 7) works as described above, except that in this case it is described energy-absorbing devices 12 of this side section are located above the deformation, located in the same way. At the same time, the following is possible. In the event of intense shock loading, deformation of the connecting energy-absorbing device 5 or joint deformation of the connecting energy-absorbing device 5 and additional energy-absorbing device 20, which are deformed in a similar way, will additionally occur.

The impact of the load, the value of which exceeds the force of torsion resistance (see Figs. 1, 2, 3) of the vertical jumpers 8, which are plastic torsions of the energy-absorbing device 5, and the stiffness of the leaf spring 11 cause a rotation (the direction of rotation is conventionally shown by an arrow) of the buffer supporting surface 3 and additional bases 9 of the energy-absorbing device 5 connected to it, which leads to plastic twisting of the torsion-bridges 8 and, accordingly, the absorption of energy of the acting load. At the same time, deformation of the leaf spring 11 having a predetermined stiffness also occurs. The total energy absorption of each energy-absorbing device 5 is respectively composed of the energy absorption provided by the indicated torsions and the spring during deformation, moreover, the type of energy-absorbing device 5 and the presence of plate plates 4 located at the junction of the central 2 and side 3 sections of the buffer, connected respectively to the top and bottom to the horizontal shelves of the U-shaped profile 2 of the central section and interacting with the horizontal shelves of the U-shaped profile 3 more oic sections together provide exactly horizontal rotation of the side sections 3 buffer torsions around the jumper 8-energy-absorbing device 5. The maximum angle of rotation of the side section 3, and respectively limiting the angle of twisting torsions energy-absorbing device 5 may be defined by the angle φ _with - the angle between the edges of the oblique notches, which are made in the horizontal shelves of the U-shaped profile 2 of the central section and the U-shaped profile 3 of the side section, and the edges of these cutouts can be additionally supported with latches.

In the event that the buffer design is equipped with two additional energy-absorbing devices 20, which is suitable for heavy class cars and minibuses, they work in parallel with the energy-absorbing devices 5 and provide a significant increase in energy absorption in the event of an impact load in one of the side sections of the buffer structure. Each additional energy-absorbing device 20 is attached laterally to the supporting structure 1 of the car (see Figs. 1, 7, 8) and interacts with its braces 24 together with the plate of the movable base 26 with the back surface of the U-shaped profile 3 of the corresponding side section of the buffer, and the initial position braces 24 is given by the angle φ _∂ . In the event of an impact load, the magnitude of which exceeds the resistance of the vertical jumpers-torsion 23 to twisting and the stiffness of the leaf spring 27, on the end section of the plate of the movable base 26, interacting with the rear surface of the side section 3, the plate of the movable base 26 rotates, the end section of the plate moves the movable base 26 towards the edge of the buffer and simultaneously rotate the side section 3 relative to the central section 2 (the direction of rotation is conventionally shown fir 7) securable to the vehicle body. At the same time, there is a twisting of the vertical jumpers-torsion 23 and the deformation of the leaf spring 27, providing the absorption of energy of the acting load. The rotation of the plate of the movable base 26, the movement of the end portion of the plate of the movable base 26 towards the edge of the buffer and the rotation of the side section 3 relative to the central section 2 occurs either until the load ceases and then these elements remain in some intermediate deformed position due to the magnitude of the acting load , or continues until the end portion of the plate of the movable base 26 abuts against the movement limiter 28, made in the form of a hard stop a, attached to the back surface of the U-shaped profile of this side section 3, after which the depreciation progress will be exhausted. It should be noted that in the case of combined use of energy-absorbing devices 5 and 20 in the structure of the buffer, the angle φ _с is equal to the limiting value of the change (or increment) of the angle φ _∂ , which is respectively set by the value of the possible movement of the plate of the movable base 26 towards the edge of the buffer to the limiter 28, and in this case, the edges of the cutouts in the horizontal shelves of the U-shaped profiles 2 and 3 also abut against each other, which together will provide a certain rigidity of the deformed buffer structure.

It should be noted that in certain cases of collisions, along with the energy-absorbing devices 12 of this section of the buffer, the energy-absorbing devices 12 of one or two adjacent sections, for example, the lateral and central ones, when colliding at an angle or the central and two side sections in a head-on collision, can also be deformed. moreover, energy-absorbing devices 12 can begin to deform simultaneously or sequentially, in particular, in the case of a “sliding” shock load, and sections of 30 allicheskoy strip and connected thereto cladding portions 29 thus may break, wrinkle, and move together with the movable base plate of the groups 12 of energy absorbing devices.

It should be noted that energy-absorbing devices 5, 12, and 20 have high energy intensity and stability of depreciation characteristics that are inherent in shock-absorbing devices, including plastic torsion bars [4, 5, etc.], which are subjected to torsion, and even more so, torsion bars supported by deformable elastic or plastic ones simultaneously leaf springs with a given stiffness. Moreover, the energy-absorbing elements and leaf springs can be, in particular, made of a material having the effect of "shape memory", in which case they are plastic shock-absorbing elements that are irreversibly deformed under the influence of the load. In the case when the above shock-absorbing elements of energy-absorbing devices 5, 12 and 20 are made of ordinary steels and alloys, jumpers (torsion bars) are also plastic shock-absorbing elements, and leaf springs can be both elastic and plastic shock-absorbing elements, and in all of the above In the above cases, the stiffness of leaf springs can be set less than the force of resistance of plastic torsion torsion equal to it or vice versa, respectively, in the same way as in the known analogues [4, 5 , 6, etc.].

It should be emphasized that the total amount of energy absorption and the course of amortization of each energy-absorbing device can be set over a wide range by increasing or decreasing the corresponding angle φ between the braces and the bases, which determines the limiting value of the twisting of jumpers-torsion bars of energy-absorbing elements, by setting certain sizes and length ratio and diameters of jumpers-torsion bars of energy-absorbing elements, as well as the length of the braces, which are levers, and thereby setting times personal values of the efforts of their resistance to deformation, as well as by setting certain combinations of characteristics of energy-absorbing elements and leaf springs in each energy-absorbing device.

The energy-absorbing devices 5, 12 and 20 of this design also have another positive quality, namely that a partially or fully deformed device can be restored to its original position repeatedly and repeatedly, and its energy-absorbing ability is restored, which is ensured by certain repairs, moreover without replacing any items.

In the case when the energy-absorbing elements and plate springs of energy-absorbing devices are made of a material having the effect of “shape memory” [8], for example, titanium nickelide, for this it is enough to simultaneously heat these elements with a heating device, for example a blowtorch, to the recovery temperature of the “shape memory” ", after which these elements themselves will return to their original given shape, the elements connected to them will also return to their original position, and the design of the device and its energy-absorbing ability will be fully restored.

In the case when the energy-absorbing elements and plate springs of energy-absorbing devices are made of ordinary steels and alloys, it is necessary (in full accordance with the prototype design) to use power devices, for example, hydraulic cylinders with a sliding rod or jacks, attached to the corresponding elements (for example, to section П -shaped profile and the plate of the movable base, to the supporting structure and the plate of the movable base or to the section of the U-shaped profile) of individual energy-absorbing devices and among Twomey impact load generated by subjecting them data elements slow involuntary deformation in the opposite direction. The aforementioned set of repair operations can be carried out without disconnecting the buffer structure from the supporting structure of the vehicle, and the number of cycles "deformation under the influence of shock loading - reverse forced deformation" is at least several hundred cycles depending on the material from which the energy-absorbing elements and leaf springs are made energy-absorbing devices, and the ratio of sizes - lengths and diameters of jumpers-torsion bars of energy-absorbing elements. After all previously deformed energy-absorbing devices are brought to their original position, they put on and attach a new outer casing and the buffer design is again ready to absorb shock loads, and its energy-absorbing ability is restored.

Thus, we can conclude that this design of the energy-absorbing buffer, which has a high energy-absorbing ability and stability of the amortization characteristics, provides effective protection for a passenger car in various types of collisions, which is due to the use and type of execution of various energy-absorbing devices and a certain specified location of energy-absorbing devices in the structure buffers. At the same time, a significant increase in energy absorption and the course of depreciation in the case of impact loads only in the surface of the side section is provided and the possibility of independent deformation of various sections of the buffer, namely those directly impacted, and the possibility of multiple restoration of the buffer structure and its energy-absorbing ability after deformation are ensured under the influence of shock, and without replacing the main elements. This energy-absorbing buffer is characterized by simplicity of design, ease of manufacture and repair work, as well as low weight characteristics; the design of each of the energy-absorbing devices allows you to broadly set the total energy intensity and the course of depreciation by setting specific angles between the bases and braces of the energy-absorbing elements, setting certain sizes and aspect ratios - the lengths and diameters of their torsions, and also by setting certain combinations of energy-absorbing characteristics elements and leaf springs as part of an energy-absorbing device and setting various characteristics corresponding to different ergopogloschayuschim devices consisting of a buffer structure.

The design of the energy-absorbing buffer can be used as front and rear bumpers of cars of various classes, minibuses and other vehicles and significantly increase their protection in collisions.

LITERATURE

1. US patent No. 4787658 "Bumper for a car", 60 R 19/20, publ. 88.11.29., No. 1096 No. 5.

2. Japanese application No. 63-23944 "Shock-absorbing bumper", 60 R 19/22, publ. 05/05/18. No. 2-599.

3. UK application No. 1493315 "Bumper for a vehicle", 60 R 19/08, publ. 11/7/30. No. 4627.

4. AC USSR No. 854751 of July 27, 1979, "Multilayer depreciation panel", 32 V 3/08.

5. RF patent No. 2207261 dated 12/13/2001, "Energy-absorbing buffer of a truck", 60 R 19/56.

6. RF patent for application No. 2003119280/11 dated 06.25.2003, “Energy-absorbing buffer of a passenger car”, 60 R 19/18.

7. RF patent for application No. 2003124320/11 of 08/04/2003, "Lateral energy-absorbing buffer of a car", В 60 R 19/42.

8. Tikhonov A.S. and others. "The use of the shape memory effect in modern engineering" M., Mechanical Engineering, 1981

Claims (3)

1. The energy-absorbing buffer of a passenger car, including the outer casing, equipped with individual sections of the metal strip attached to its inner vertical surface, a supporting surface in the form of a U-shaped profile attached to the supporting structure of the car, and located between the casing and the supporting surface and evenly spaced the length of the profile of the U-shaped section at a distance from each other, the main energy-absorbing devices attached to the outer surface of the profile U-shaped section and including each specific number of adjacent energy-absorbing elements, each of which is a mirror image of the neighboring one, is made in one piece from a round segment made, in particular, of a material with the effect of “shape memory”, a metal rod, portions of which sequentially bent in mutually perpendicular planes, and accordingly includes a base, a jumper and a brace, and the bases of all energy-absorbing elements of each main energy absorption along their entire length are connected to the outer surface of the profile of the U-shaped section, the jumpers are respectively aligned with each other and interact with their lateral surface with the outer surface of the profile of the U-shaped section, and the adjacent braces are located in the same plane, interconnected along its entire length and directed outward relative to the supporting surface, with two central main energy-absorbing devices, each of which is a mirror image of another oh, they are adjacent to each other, the bases and braces of all the energy absorbing elements of each main energy-absorbing device are horizontal, the jumpers of the energy-absorbing elements are respectively vertical, and the braces of all the main energy-absorbing devices of the left half of the buffer and the braces of all the main energy-absorbing devices of the right half of the buffer are facing each at a given angle in different directions, respectively, in directions from the middle to the edges of the buffer, with each main energy absorbing its device is equipped with a movable base in the form of a rigid plate made in one piece with two side protrusions, and including leaf springs made, in particular, of a material having the effect of "shape memory", and attached at one end to the outer surface of the U-shaped profile of the supporting surface, characterized in that the supporting surface of the buffer includes a Central and two side sections, which are located end-to-end to each other and interconnected via connecting energy-absorbing devices, including each certain number of energy-absorbing elements adjacent to each other, each of which is a mirror image of the neighboring one, made in one piece from a round segment made, in particular, of a material having the effect of “shape memory”, a metal rod, the sections of which are successively bent into mutually perpendicular planes, and accordingly includes a horizontal base, a vertical jumper and an additional horizontal base, and the horizontal base and the additional horizontal base is directed respectively in opposite directions and the horizontal bases are respectively attached along their entire length to the rear surface of the U-shaped profile of the central section, and the additional horizontal bases along their entire length are attached to the rear surface of the U-shaped profile of the side section, vertical jumpers interact its lateral surface with the back surface of the U-shaped profile of the central section and are flush with its lateral with rhombs, while the horizontal shelves of the supporting surfaces of the central and side sections at the joints are made with oblique cutouts, the supporting surface of the buffer is provided, in particular, with plate springs made, in particular, of a material having the effect of “shape memory”, which are respectively aligned with the energy-absorbing connecting devices and each attached at one end to the rear surface of the central section, and at the other end to the rear surface of the side section of the buffer supporting surface, chrome of this, the energy-absorbing buffer is equipped with two additional energy-absorbing devices attached to the side of the car supporting structure, including each specific number of energy-absorbing elements, each of which is a mirror image of the neighboring one, made in one piece from a round segment made, in particular, of a material having the effect "shape memory" of a metal rod, sections of which are successively bent in mutually perpendicular planes, and accordingly include it has a base, a jumper and a brace, the bases of all the energy-absorbing elements of each additional energy-absorbing device are horizontally and laterally attached to the vehicle supporting structure, the jumpers are respectively vertically and aligned with each other and interact with their lateral surface with the outer surface of the vehicle supporting structure, and the braces are horizontal and in the same plane, interconnected by a jumper and directed respectively to the side sections of the supporting surface of the buffer, with each additional energy-absorbing device provided, made, in particular, of a material having the effect of "shape memory", a plate of a movable base, made in one piece with a leaf spring, which is attached laterally to the supporting structure of the car, and braces along its entire length are attached to a plate of a movable base, together with which they interact with the back surface of the corresponding side section of the supporting surface of the buffer. 2. The energy-absorbing buffer of a car according to claim 1, characterized in that the U-shaped profile of the supporting surface of the buffer is provided with plate overlays located at the joints of the central and side sections, respectively, above and below the horizontal shelves of the U-shaped profile, attached to the horizontal shelves P -shaped profile of the central section and interacting with the horizontal shelves of the U-shaped profile of each side section, while the U-shaped profile of the supporting surface of each side section of the buffer with is equipped with a movement limiter of the movable base of an additional energy-absorbing device, made in the form of a hard stop attached to its rear surface. 3. The energy-absorbing buffer of a passenger car according to claim 1, characterized in that the plates of the movable bases of the main energy-absorbing devices are made integrally with leaf springs, and the energy-absorbing elements of the main energy-absorbing devices are equipped with an additional jumper connecting all their braces.

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