EA047190B1 - ROAD ENERGY ABSORBING UNIT AND ROAD FRONT GUARD - Google Patents

Description

Field of technology

The invention relates to the field of road construction, in particular to road frontal barriers that provide stopping or redirection (adjustment) of the trajectory of a vehicle when driving at the maximum permissible speed for a given category of road, ensuring safety for road users, as well as the safety of road construction elements, in front of which road frontal barriers are installed.

Prior Art

A front-side road fence is known (utility model patent No. RU 169181, publ. 03/09/2017), containing a longitudinal beam mounted on vertical supports that are installed in the base soil, and a frontal impact buffer, which is installed at the end of the beam. Along the beam there are oblong holes for bolted connections with the support consoles, in the initial section the supports are located in sleeves that are installed in the foundation soil and fixed in them with shear bolts, in the consoles there are holes through which the cable is pulled along the beam, while at the initial section of the fence, the end of the cable is attached to the base soil by an anchor connection, and the other end of the cable is fixed in the tensioner, which is located in the working section of the fence. The front impact buffer is made in the form of a vertical plate, which is attached perpendicularly to the end of the first beam in the initial section and is connected by a guide to the outer support of the initial section of the fence. During the translational movement of the beam, the bolts connecting the beams to the consoles of the vertical posts cut the jumpers between the longitudinal holes in the beams, resulting in the work of elastoplastic deformation of the beam material, which gradually dissipates the kinetic energy of the vehicle impact.

The main disadvantage of this device is the instability of the operation of this design, in particular, if with a direct frontal impact the device will work stably, then with an angular (at a small angle) frontal impact, for example, 15 degrees, the device will not work due to the loss of its guide functions both under the influence of the transverse component of the impact force, and as a result of the separation of the first post (and then immediately the second) from the support sleeve (sleeves) with a shear bolt (bolts), as a result of which, under the action of the transverse component of the impact force, the beam bends in the initial section, which will eliminate further longitudinal movement of the beam along the working supports. In addition, the disadvantage of this device is that the longitudinal grooves in the beam 6, being non-working areas, greatly lengthen the braking distance and, accordingly, the length of the road front fence.

A known shock attenuator for vehicles (RU 2576674, publ. March 10, 2016) includes an energy-absorbing device for slowing forces, containing a housing, at least two pins located in the housing, which are located parallel to each other in the housing, and also a metallic elongated pull member that may be positioned in the housing so that it extends between and in contact with the pins. The pins and the pulling element are arranged in such a way that a change in direction occurs at the pulling element as each pin passes, thus, as the pulling element and the housing move relative to each other, the movement is slowed down due to the deformation of the pulling element as each pin passes.

The main disadvantage of this solution is that the value of the deformation energy of the metal element remains constant, i.e. At the beginning of the vehicle braking, the braking energy is insufficient, and at the end of the braking it is in excess, which does not allow reducing the length of the device while maintaining a low value of overload for the person in the vehicle. The disadvantages of this device also include the increased complexity of the design due to the presence of an energy-absorbing device with several pins, increased dimensions, increased labor intensity of maintenance, which is associated with the high complexity of filling and removing the deformable steel strip inside the hollow guide and energy-absorbing device, increased waste of metal (steel) , due to the fact that after a vehicle collides with this device, the entire pulling element in the form of a steel strip has to be removed for recycling, even if this steel strip is partially (not completely) used, and the increased labor intensity and cost of manufacturing the pulling element in the form of a variable steel strip thickness and width.

The closest analogue is the terminal terminal for a road barrier (EP 3660219, published 06/03/2020), which includes a guide, which is connected at its ends to a ground anchor and a protective fence, respectively, and includes a collision catcher, which is movably mounted on the guide. The collision catcher is equipped with a sliding block with a hole through which passes a guide, which has a square or rectangular cross-section. At least two deforming elements are provided in the hole on the sliding block. The guide has an initial depressed part in which one or more protruding deforming elements are located.

The disadvantage of this solution is the inability to regulate directions in any area

- 1 047190 energy expended on deformation, which in turn does not allow achieving high efficiency of the final terminal and limits the possibility of reducing the length of the device while simultaneously requiring to obtain the required values of dynamic overloads of a person in the vehicle. The disadvantages of this device also include the increased labor intensity of maintenance, which is associated with the high labor intensity of replacing the guide after a collision with a vehicle, increased metal (steel) waste, and low structural reliability at the junctions of the guide sections.

The technical problem is the lack of effectiveness of analogues and increased danger for people in the vehicle.

Brief description of the invention

The problem to which the invention is aimed is to increase the efficiency of the road front guard and increase safety for people in the vehicle.

The technical result when using the invention is the ability to change the braking force of the vehicle, which makes it possible to reduce the length of the front guard and reduce the value of the generalized inertial overload index or ASI for people in the vehicle.

The above technical result is achieved due to the fact that the road energy-absorbing unit contains a guide on which a pusher is mounted with the possibility of longitudinal movement, while the guide is equipped with sequentially located energy-absorbing elements protruding relative to the outer surface of the guide, and the pusher is installed on the guide using a carriage that is made with the possibility of influencing protruding energy-absorbing elements during longitudinal movement.

The guide of the energy-absorbing unit can be made of at least one profile.

The guide of the energy-absorbing unit can be made of at least two interconnected channels or tees.

Protruding energy-absorbing elements of the energy-absorbing unit can be located on the wall and/or shelves of the profile or profiles.

The protruding energy-absorbing elements of the energy-absorbing unit may be part of the guide.

The protruding energy-absorbing elements of the energy-absorbing unit can be fixed to the guide.

Protruding energy-absorbing elements in different sections of the guide can be made of different materials.

The protruding energy-absorbing elements can be made in the form of plates with protruding and fastening ends, while the protruding energy-absorbing elements are secured to the guide with fastening ends.

The energy-absorbing elements can be fixed to the guide by means of a common base.

Protruding energy-absorbing elements may be part of the common base.

Protruding energy-absorbing elements can be secured to a common base.

Protruding energy-absorbing elements can be attached to the outer surface of the guide.

The guide may include openings, and the protruding energy-absorbing elements may be secured to the inside of the guide and project outward through corresponding holes in the guide.

Protruding energy-absorbing elements can be located at an angle to the guide.

Protruding energy-absorbing elements may have different angles of inclination to the guide in different sections of the guide.

The protruding energy-absorbing elements may have different thicknesses and/or widths in different sections of the guide.

The pusher can be configured to act on protruding energy-absorbing elements.

The carriage can be equipped with end attachments, which are designed to act on protruding energy-absorbing elements.

The end attachments on the carriage can be made rotary.

Protruding energy-absorbing elements may be located along at least one of the guide surfaces.

According to the invention, the road front fence contains an energy-absorbing unit mounted on at least one rack, and is configured to be connected to a barrier fence or a vehicle.

- 2 047190

Brief description of the drawings.

The invention is illustrated by drawings, in which:

fig. 1 - side view of the road front fence;

fig. 2 - top view of the road front fence;

fig. 3 - general view of the energy-absorbing unit;

fig. 4, 7 - top view of a fragment of a guide with a fixed energy-absorbing element;

fig. 5, 8 - side view of a fragment of a guide with a fixed energy-absorbing element;

fig. 6, 9 - side view of the energy-absorbing element;

fig. 10 is a top view of a fragment of a guide with fixed energy-absorbing elements on a common base;

fig. 11 is a side view of a fragment of a guide with fixed energy-absorbing elements on a common base;

fig. 12 - general view of energy-absorbing elements on a common base;

fig. 13, 14, 15 - top views of a fragment of a guide with an energy-absorbing element;

fig. 16, 17, 18 - side views of a fragment of a guide with an energy-absorbing element;

fig. 19, 20 - ASI graphs at a constant value of strain energy.

Disclosure of the Invention

As shown in FIG. 1, 2, the road front fence is designed to be connected to the barrier fence (5) and contains an energy-absorbing unit, including a pusher (3), at least one post (6) and a guide (1) installed on at least one stand (6). The guide (1) is made of at least one profile, in particular, but not limited to these examples, it can be made of: a bent profile, and/or an H-shaped profile (for example, an I-beam), and/or at least two connected channels between each other, and/or at least two interconnected brands. Making the guide (1) from profiles makes it possible to increase the rigidity of the guide (1) during a lateral collision of a vehicle, while the profile must be made with a shelf and/or wall sufficient to accommodate energy-absorbing elements. Making the guide (1) from 2 or more components makes it possible to further increase the value of absorbed energy. The position of the guide (1) can be either at an angle relative to the base (road surface), as shown in Fig. 2, and parallel to it.

As shown in FIG. 3, the guide (1) is equipped with energy-absorbing elements (4) protruding relative to the outer surface of the guide, and the pusher (3) is installed on the guide (1) using a carriage (2), which can act on the energy-absorbing elements (4). The carriage (2) is supplemented with rotating end attachments (7), which can act on energy-absorbing elements (4). The use of energy-absorbing elements (4) protruding relative to the outer surface of the guide allows one to change the braking force of the vehicle, which makes it possible to reduce the length of the front fence, as well as reduce the overload values for people in the vehicle, both during a frontal and lateral collision. A generalized measure of inertial overload at the center of mass of a vehicle is the Safety Index (Injury Severity Index) or ASI. Methods for calculating the safety index or ASI are disclosed in the relevant standards: GOST R 52721-2007 or DIN EN 1317-1:2011-01.

Energy-absorbing elements (4) can be part of the guide (1) and located on the wall and/or flanges of the profile or profiles from which the guide (1) is made. Installation of the pusher (3) on the guide (1) using a carriage supplemented with rotary end attachments (7) allows you to stabilize the movement of the pusher (3) during a frontal collision of the vehicle at an angle relative to the axis of installation of the road front guardrail. The end attachments (7) of the carriage can be made in the form of cylindrical elements with the possibility of rotation when the pusher (3) moves.

As shown in FIG. 4-9, energy-absorbing elements (4) can be made in the form of plates with protruding ends (4a) and fastening ends (4b), while the protruding ends (4a) are located at an angle to the fastening end (4b), and can be located on the wall or shelves of the profile or profiles from which the guide (1) is made.

As shown in FIG. 10-12 energy-absorbing elements (4) can be made on a common base (9). In this case, the energy-absorbing elements (4) can be part of the common base (9), forming protruding ends (4a), or can be fixed to the common base (9).

As shown in FIG. 7-9, energy-absorbing elements (4), both individually and in the embodiment with a single base (9), can be attached to the inner surface of the guide (1). In this case, the guide (1) contains holes (8), and the energy-absorbing elements (4) protrude through the corresponding holes (8) on the guide (1).

The energy-absorbing elements (4) can be made of various materials, in particular various metals such as steel or aluminum, composite materials, rubbers and plastics.

The shape of the energy-absorbing elements (4) and/or protruding ends (4a) can be different, for example triangular, rectangular, trapezoidal, etc., including with rounded corners.

- 3 047190

As shown in FIG. 13-18, the energy-absorbing elements (4) may have different characteristics of inclination angle (a), which can be in the range from 0 to 180 degrees with respect to the surface of the guide (1), thickness (A), and width (B). The energy-absorbing elements (4) may have different values of the angle (a) of inclination to the guide (1) in different sections of the guide (1). The thickness (A) of the energy-absorbing elements (4) may have different values in different sections of the guide (1). The width (B) of the energy-absorbing elements (4) can have different values in different sections of the guide (1). Changing the parameters of the angle of inclination (a), thickness (A), and width (B) of the energy-absorbing elements (4) allows you to more accurately regulate the energy absorption values, thereby creating the opportunity to more smoothly reduce the speed of the vehicle hitting the fence and minimize damage to the perpetrator collision with a vehicle, and accordingly reduce the value of the generalized inertial load index, or ASI, for the occupants of the vehicle.

When using a guide (1) consisting of two or more profiles, you can use profiles with different wall thicknesses to simplify the adjustment of the thickness (A) of the energy-absorbing element (4).

The guide (1) may contain at least one surface for the location of protruding energy-absorbing elements (4), and the energy-absorbing elements (4) may be located along at least one of these surfaces. In particular, energy-absorbing elements can be located on the side and/or top surfaces of the guide (1), if it has a generally quadrangular shape in cross-section.

The guide (1) is designed to be connected to a barrier or vehicle.

The energy-absorbing elements (4) can be located on a wide flange of the profile or profiles to provide greater possibilities for adjusting the width (B) of the energy-absorbing elements (4).

The greatest optimization of the braking process is achieved by different combinations of the angle of inclination (a), thickness (A), and width (B) of the energy-absorbing elements (4).

As implementation examples, FIGS. 19-20 show graphs of the dependence of ASI on time (t) in seconds for 2 cases when the energy-absorbing elements have the same combinations of parameters of the angle of inclination (a), thickness (A), and width (B) (Fig. 19) and different combinations of parameters of angle of inclination (a), thickness (A), and width (B) (Fig. 20). As can be seen from the graph, at the moment the vehicle collides, the overload is maximum and as the vehicle slows down and its kinetic energy decreases, the braking time is 0.45 s, which characterizes the short length of the device achieved. In turn, the graph (Fig. 20) shows a vehicle collision when the energy-absorbing elements have different parameters of the angle of inclination (a), thickness (A), and width (B), which allows you to stop the car in 0.3 seconds, while peak ASI values are lower than in the first case.

The device works as follows.

At the moment of a frontal collision of a vehicle with a road frontal barrier, the kinetic energy of a moving object is transferred through the pusher (3), the carriage (2) and the end attachments (7) to the energy-absorbing elements (4) located on the guide (1), during deformation (crushing) of which it fades out smoothly. The process is a sequential operation of energy-absorbing elements (4). After the passenger car begins to contact the pusher, the speed is reduced in such a way that the safety condition for the driver and passengers of the car is met, namely the ASI value <1.4.

At the moment of a frontal collision of a vehicle with a road frontal barrier at an angle relative to the axis of installation of the device on the road frontal barrier, the kinetic energy of a moving object is transferred through the pusher (3), the carriage (2) and the end attachments (7) to the energy-absorbing elements (4) located on the guide ( 1), during deformation (crushing) of which it is smoothly extinguished, while the movement of the pusher (3) along the guide (2) is stabilized by the rotary end attachments (7) of the carriage (2). The process is a sequential operation of energy-absorbing elements (4).

When a vehicle collides sideways with a road front fence, it is adjusted due to the rigidity of the guide (1) installed on at least one post (6), which, when deformed, allows you to set a safe trajectory.

Claims (21)

1. A road energy-absorbing unit containing a guide on which a pusher is mounted with the possibility of longitudinal movement, characterized in that the guide is equipped with sequentially arranged energy-absorbing elements protruding relative to the outer surface of the guide, while the pusher is installed on the guide using a carriage, which is designed to act on protruding energy-absorbing elements during longitudinal movement. 2. The unit according to claim 1, characterized in that the guide is made of at least one profile. 3. The unit according to claim 2, characterized in that the guide is made of at least two interconnected channels or tees. 4. The unit according to claim 2, characterized in that the protruding energy-absorbing elements are located on the wall and/or shelves of the profile or profiles. 5. The unit according to claim 1, characterized in that the protruding energy-absorbing elements are part of the guide. 6. The unit according to claim 1, characterized in that the protruding energy-absorbing elements are fixed to the guide. 7. The unit according to claim 6, characterized in that the protruding energy-absorbing elements in different sections of the guide are made of different materials. 8. The unit according to claim 6, characterized in that the protruding energy-absorbing elements are made in the form of plates with protruding and fastening ends, while the protruding energy-absorbing elements are fixed to the guide with fastening ends. 9. The unit according to claim 6, characterized in that the energy-absorbing elements are fixed to the guide by means of a common base. 10. The unit according to claim 9, characterized in that the protruding energy-absorbing elements are part of a common base. 11. The unit according to claim 9, characterized in that the protruding energy-absorbing elements are fixed on a common base. 12. The unit according to claim 6, characterized in that the protruding energy-absorbing elements are fixed on the outer surface of the guide. 13. The unit according to claim 6, characterized in that the guide contains holes, and the protruding energy-absorbing elements are fixed on the inside of the guide and protrude out through the corresponding holes in the guide. 14. The unit according to claim 1, characterized in that the protruding energy-absorbing elements are located at an angle to the guide. 15. The unit according to claim 14, characterized in that the protruding energy-absorbing elements have different angles of inclination to the guide in different sections of the guide. 16. The unit according to claim 1, characterized in that the protruding energy-absorbing elements have different thicknesses and/or widths in different sections of the guide. 17. The unit according to claim 1, characterized in that the pusher is designed to act on protruding energy-absorbing elements. 18. The unit according to claim 1, characterized in that the carriage is equipped with end attachments, which are designed to act on protruding energy-absorbing elements. 19. The unit according to claim 18, characterized in that the end attachments on the carriage are rotary. 20. The unit according to claim 1, characterized in that the protruding energy-absorbing elements are located along at least one of the surfaces of the guide. 21. A road front fence containing an energy-absorbing unit according to any one of claims 120, mounted on at least one rack, configured to be connected to a barrier fence or a vehicle.