RU2413814C2 - Road guide structure - Google Patents

Abstract

FIELD: construction. ^ SUBSTANCE: road guide structure for installation at the edge of road trafficways for vehicles includes front part directed towards road trafficway and fixed along edge of road trafficway. Specified front part represents guide plank, several supports arranged at the side of front part directed away from road trafficway, joined with front part and resting against foundation. Supports are separated from each other, and at least one tension anchor passing through supports separated from each other. At the same time specified tension anchors are reinforcement rods, and system comprising supports and at least one tension anchor is free from tension in normal condition. Reinforcement rods are equipped with continuous external thread, and neighbouring tension anchors are connected to each other by means of tension nuts to form transverse reinforcement elements joined to each other at large distances in road guide structure. ^ EFFECT: prevention of vehicle moving off the trafficway, reduced damage of motor vehicle and less injuries to passengers in it in case of emergency. ^ 8 cl, 11 dwg

Description

The invention relates to a road guide structure for installation on the edge of a roadway for vehicles.

Road guiding structures are known in various forms of execution. They are especially important on bridges, as they serve to prevent a vehicle from dropping off a roadway from falling off a bridge. Therefore, first of all, road guides in the form of concrete barriers are used on bridges, which, although they usually prevent the vehicle from falling off the bridge, but often because of its stiffness, cause significant damage to the vehicle and its passengers.

The objective of the invention is the creation of a road guide structure, overcoming the disadvantages of the latest level of technology.

This problem is solved by the features of paragraph 1 of the claims. The essence of the invention lies in the fact that in the road guiding structure with vertical supports separated from each other, horizontal tension anchors are used to increase rigidity in the longitudinal direction.

Further advantages of the invention are presented in the dependent claims.

Additional features and details are explained in the description of seven examples of execution based on the drawings. The drawings show:

Figure 1 - road guide structure in accordance with the first embodiment,

Figure 2 is a cross section of a road guide structure in accordance with figure 1,

Figure 3 is an enlarged fragment of the mounting anchor of the road guide structure in accordance with figure 1,

Figure 4 is an enlarged fragment of the foundation plate of the road guide structure in accordance with figure 1,

5 is a road guide structure in accordance with a second embodiment,

6 is a road guide structure in accordance with a third embodiment,

7 is a road guide structure in accordance with a fourth embodiment,

Fig.8 is a road guide structure in accordance with a fifth exemplary embodiment,

Fig.9 is a road guide structure in accordance with a sixth embodiment,

Figure 10 - connection of anchors in accordance with a sixth embodiment,

11 is a road guide structure in accordance with a seventh embodiment.

Below with reference to figures 1-4 describes the first example of execution. The road guiding structure 1 is installed on the edge of the carriageway 49 in order to prevent the vehicle from getting off the carriageway and getting beyond the edge of the carriageway 2. This is especially important on bridges, especially on highway bridges. Building 1 is installed along the direction of the carriageway 3 and has basically the same cross-section along direction 3 (see FIG. 2), except for connection points 42. Construction 1 has a lateral 4 along the horizontal, transverse to the direction of the carriageway 3, facing the edge carriageway 2 front section 5, the middle section 6 connected to it, and also the section 7 connected to it.

The front section 5 has horizontally extending, located along the direction of the carriageway 3, the foundation slab 9 is fixed on the foundation 8. The foundation 8 is in the first embodiment, asphalt or concrete. The second example of execution describes fixing in ordinary soil. The front plate 10 is connected to the foundation plate 9, which extends substantially vertically and lies along one part of the entire height H _{G of the} structure 1. The front plate 10 has a height H _v . The ratio is: H _v / H _G ≥0.5, ≥0.6, preferably about 0.75. An inclined plate 11 inclined at an angle b in the direction 4 is connected to the front plate, preferably b≈45 °.

A cover plate 12 connected to the middle portion 6 is connected to the inclined plate 11. The plates 9, 10, 11 and 12 are made integrally with each other and consist of one metal sheet, mainly a steel sheet. These four slabs are called together the front part 13. In the region of the middle portion 6, under the covering slab 12, a square block 14 of porous concrete, aerated concrete or other similar compressible mineral material is provided. Block 14 has a height of about H _G and a thickness of D _p , while D _p / H _G ≥0.15, preferably equal to 0.25. The block 14 is supported by the bottom side 15 on the foundation 8. The block 14 is fixed to the rear part 16 made entirely of metal. The rear part 16 consists of a cover plate 17 which extends horizontally and is superimposed on the upper part 18 of block 14. A vertically extending plate 17 is connected to the cover plate 17 superimposed on the block 14, the rear plate 19, with which in turn is connected horizontally, resting on the foundation 8 foundation plate 20. The base plate 20 protrudes along the lateral direction 4 behind the rear plate 19 at the rear. Plates 17, 19 and 20 are made integrally with each other and consist mainly of a solid steel sheet. Block 14 has a beveled section 44 in the upper right edge of FIG. 2, i.e., a rectangular edge is made in this section. Section 44 extends substantially parallel to the inclined plate 11 located at a distance from it. Block 14 is secured with the mounting anchors 21 described in detail below at the rear 16. They pass through horizontal drill holes formed in the rear plate 19. For stabilization as part of the rear 16 are welded, shown in FIG. 2, as right-angled triangles of the support 23, which are welded with their long side to the rear plate 19, and the short side to the foundation plate 20. These supports are arranged at regular intervals s direction of the roadway 3, for example every meter. It is also possible to make the back plate 20 along the direction of the carriageway 3 incompletely, and only provide for the corresponding segments in the region of the supports 23. It is also possible to use supports that do not taper upward in the shape of a triangle, but only in the lateral view have a rectangular cross section. The next possibility is the use of finished T-beams or double T-beams as supports. Drill holes 24 are provided in the foundation of the plate 20, through which the foundation plate 20 is fastened with anchors 21 to the foundation 8. The base plate 20, as well as the supports 23, belong to the rear section 7. The covering plate 17, as well as the back plate 19 and block 14, relate to the middle portion 6. The front part 13 and the rear part 16 through the drill holes 25, which vertically in the middle pass through the cover plate 12, the cover plate 17 and the block 14, are connected to each other by fixing anchors 21.

The front plate 10, the inclined plate 11, the front side of the block 14, as well as the foundation 8 cover the deformation space 27, which in this embodiment is not filled, but can be filled with appropriate compressible materials, such as synthetic foam, glass wool, etc. In the front plate 9, numerous recesses in the form of a key well are located next to each other, which consist of an annular section 29 of diameter D _K and an immediately adjacent elongated section 30 of width B _L. B _{L is} less than D _K , wherein D _K corresponds mainly to the outer diameter of the mounting anchor 21 at that location. Thus, in the case of the recess 28, we are talking about a tapering elongated hole in which a narrow section faces the edge of the carriageway 2. It is acceptable that the recesses 28 have other shapes. It is also possible, in principle, to make an elongated hole of the same thickness. It is still possible to choose an oblong hole shape in which the width gradually decreases. The base plate 9 is fixed through the recesses 28 with mounting anchors 21 on the foundation 8.

Figure 3 shows in more detail the structure of the mounting anchor 21. It is known from patent DE 10 2005 007 721.8 of 02/18/2005. As for a more accurate structure, here is a link to this application. The content of this application is taken into account in this application. Anchor 21 has a cylindrical rod 31 with a thread 32 located from the end of the input against the direction of screwing, which has cutting elements 33 in the front section. In the rear section, the anchor has an external thread 34 that is open to the outside, and the inner polyhedron 35 for screwing the anchor 21 at its bottom The rod 31 has an upwardly extending collar 36 at the outer end. To secure the anchor 21, a drill hole 37 is first drilled, which is partially filled with a binder mass of dispersion hardening 38, and then the rod 31 is screwed they are pulled with an impact screwdriver into the drill hole 37 to such an extent that the collar 36 is not on a straight line with the foundation 8. After that, a fixed object, for example, a foundation plate 9 is installed by a recess 28 on the internal thread 34. Then, a screw with a metal external thread 39 with a sealing the washer 40 and the rounded polyhedral head 41 are screwed through the recess 28 into the internal thread 34, and the object, for example, the foundation plate 9 is fixed to the foundation 8. An advantage of the anchor 21 is that the rod 31 with the thread 32 is not standing However - only on the screw - it is under tensile force, since the head 41 ultimately rests on the collar 36. Thanks to the binder mass 38, a particularly good fixing is ensured in the base, which is especially favorable for porous materials such as asphalt or concrete.

In principle, conventional screws, for example concrete screws, can be used instead of the fixing anchor 21.

The following describes the installation of the road guide structure 1 and then its condition in a collision. Two different parts are delivered to the respective construction site, namely the front parts 13 and the rear parts 16 separately from each other. The front parts 13 can be stacked on top of each other to save space. The same applies in principle to the rear parts 16. They block 14 is already screwed to the rear plate 19, therefore, is mounted. At appropriate positions, drill holes 27 are drilled in a foundation, that is, in concrete or asphalt. After that, the base plates 9 and 20 of the mounting anchors 21 are connected to the foundation 8.

The front parts 13 have longitudinally protruding connecting segments 42 at the ends of the longitudinal sides, which in the longitudinal direction extend beyond the ends of the longitudinal sides of the rear parts 16. They have numerous drill holes 43. The connecting segments 42 of two adjacent front parts 13 are superimposed upon mounting and screwed together each other with numerous connections with screws and nuts. Due to this, an endless road guiding structure 1 is formed along the direction of the carriageway 3. From above, the anchoring anchors 21 are screwed into the block 14 through the covering plates 12 and 17, and all three parts are thus connected to each other.

In a collision, the vehicle moving off the roadway 49 first falls on the front section 5, which is deformed due to this. In this case, the front plate 10 approaches the block 14, and the deformation space 27 is reduced. As a result of the deformation of the front section 5, the shock energy is gradually accumulated. The edge between the front plate 10 and the inclined plate 11 stabilizes the front part 13, so that in a collision a greater amount of impact energy is converted into heat. In addition, in a collision, the foundation plate 9 moves along the lateral direction 4. In this case, the fixing anchor 21 expands the recess 28, and therefore, energy is also absorbed in a controlled manner. The design of the rounded head 41 has the advantage that the wheels passing through it do not make holes. In a weaker collision, only the front section 5 is deformed.

If the collision is more energetic, this leads to the fact that the front plate 10 lies on the block 14, which consists of porous concrete. As a result of the collision, it contracts, in connection with this, more energy is absorbed. The rear portion 7 is generally rigid in order to prevent a breakdown of the road guide structure 1. In an energetic collision, the road guide structure 1 thereby has a large energy absorption potential at a given total depth T _G along the direction of the sides 4. In a small collision, only the front part 13 needs to be replaced. The consequences of a collision for a hit car are smaller than with a concrete barrier, since in a collision with the corresponding road guide structure 1, a larger amount of collision energy as a result of deformation of the road guide structure 1 turns into heat.

A second embodiment of the invention is described below with reference to FIG. Identical parts have the same designations as in the first embodiment described above. Structurally different, but functionally similar parts have the same designation with the addition of the letter “a”. The second example of execution relates to the case when the road guide 1a is not installed on concrete or asphalt, but on the ground. In this case, it is not possible to fasten using fixing anchors 21. For this, alternatively, in the block 14, vertical drill holes 45 are located one after another, through which rod-shaped anchors 46 with radially protruding heads 47 are driven into the foundation 8a. The advantage of deformability of the front portion 5 is retained in this embodiment. The same goes for simple installation on a construction site. Only energy absorption in the recesses 28 is excluded.

Below, with reference to FIG. 6, a third embodiment of the invention is described. Identical parts have the same designations as in the first embodiment described above. Structurally different, but functionally similar parts have the same designation with the addition of the letter “b”. A third embodiment relates to the case where the road guide 1b is not located on the outer edge of the carriageway 49, but between two roadways, so that a collision with the road guide 1b can occur on both sides. The structure can most easily be explained in this way: the half of the first embodiment is located to the right of the central longitudinal level 48 in FIG. 2 and is mirrored at level 48 so that a basically mirror-symmetrical structure is formed. This means that the block 14 is located in the middle, and the front part 13 is located on the sides of the block 14, and also in the mirror image to the level 48 - the second front part 13b. Parts 13 and 13b are connected by fixing anchors 21 to the foundation 8, i.e., to asphalt and concrete. The parts 13 and 13b are connected to each other by means of anchors 21, which are screwed through the cover plate 12, immediately below the cover plate 12b and the block 14. Due to the symmetrical construction on both sides of the block 14, there is a deformation space 27 and 27b. The positive deformation qualities described in the first embodiment are in the third embodiment, both in a collision with the left side of FIG. 6 and the right side of FIG. 6. First, the front portion 5 would deform and then block 14. For example, in a collision with the right side of FIG. 6, part 13b would adopt the support function of the rear, and vice versa.

A fourth embodiment of the invention is described below with reference to FIG. Identical parts have the same designations as in the first embodiment described above. Structurally different, but functionally similar parts have the same designation with the addition of the letter “c”. The fourth example of execution has basically the same structure as the third example of execution. So it is designed to be placed between two carriageways. As in the second example of execution, fixing on the foundation does not occur with fixing anchors 21, but with the help of anchors 46 with heads 47, which are driven into the ground through block 14. In the case of foundation 8c, it is thus not a question of concrete or asphalt, but of soil. Otherwise, everything really said about the second and third examples of execution.

A fifth embodiment of the invention is described below with reference to FIG. Identical parts have the same designations as in the first embodiment described above. Structurally different, but functionally similar parts have the same designation with the addition of the letter “d”.

The front section 5 is constructed in the same way as in the first embodiment, which means that the foundation plate 9, the front plate 10, the inclined plate 11 and the covering plate 12 are made in the form of an integral structural part. On the cover plate 12 is fixed L-shaped in cross section. It has a cover plate 17d screwed to the cover plate 12, from which the rear 16d extends vertically downward. Unlike the first embodiment, the rear part 16d does not extend to the foundation, but along a small part of the total height, which is necessary for securing the vertical supports 23d on it with screws 21d. Supports 23d are designed as T-beams. It is also possible to use double T-beams or supports in accordance with the first embodiment. Supports 23d are fixed to respective foundation plates 20d, and are predominantly rigidly welded. These foundation plates 20d are screwed through the mounting anchors 21d to the foundation 8. The supports 23d are positioned so that their cross section 50 is screwed to the back 16d by surface 50 with screws 21d. Leg segment 51 projects vertically from transverse segment 50 along direction 4.

To stabilize the supports 23d relative to each other and in general in all leg sections 51, drill holes 52 are located at the same height through which a tension anchor 53, which is also called a tension bar, is passed. Most preferred are known anchors called, in special terminology, Dywidag-tensioning beams. They have a large external thread 54 extending over their surface onto which nuts 55 can be screwed. To stabilize the support 23d, two nuts 55 are placed on the tension anchor 53 to the left and right of the drill hole 52 and are tightened relative to the leg section 51. Thus, the support 23d in a collision on the tension anchor does not move. Neighboring tension anchors 53 can be connected to each other using sleeve-shaped threadedly cooperating nuts 54 or threaded couplings so that transverse reinforcing joints are formed at long distances in the rail 1d. It is also possible to place several tension anchors 53 one above the other. In this case, several drill holes 52 are respectively distributed in each leg section 51. Then, the tension anchors 53 expediently run parallel to each other. With an inclined, that is, not horizontal passage of the tension anchors 53, an additional interference may be formed.

When a vehicle collides with a road guiding structure 1d, the energy acting along the direction of the roadway 3 is absorbed not only by the supports 23d, which are directly affected by the collision, but also the energy generated is distributed through the tension anchors 53 to a large number of supports 23d. First of all, the stability of the road guiding structure 1d along the direction of the carriageway 3 is significantly increased by the tension anchors 53. Speaking of the tension anchors 53, we are talking about inexpensive reinforcing bars - reinforcing bars that are widely available on the market. To avoid corrosion, tension anchors can be galvanized at least. An advantage in the use of tension anchors is that it is possible to stabilize the supports 23d with respect to each other without having to support the supports, for example, with cables, against each other. Thus, the system is in normal condition without tension.

Below, with reference to FIG. 9 and FIG. 10, a sixth embodiment of the invention is described. The main difference compared to the fifth embodiment is that the guide bars 57 themselves, which form the front portion 13 e, are standard guide bars.

Two guide rails 57 are arranged one above the other. The upper guide bar 57 is screwed with the help of a screw 58 and with the help of an L-shaped support element 59 with a support 23e having a cross section U shape. The lower guide bar 57 is also attached with a screw 58 to the generally cylindrical hollow damping element 60. On the opposite side, it is screwed to the support 23e with two screws 58.

Two support anchors 53 located one above the other pass through the supports 23. Moreover, the sides 61 of the U-shaped cross-section support 23e have two drill holes 52 one after another, through each of which a tension anchor 53 is passed. Talking about tension anchors 53, we are talking about standard tension anchors, such as those available on the market, among all others, DYWIDAG brand anchors. The tension anchors 53 have a large external thread 54, and on the opposite side they have a flange so that the tension anchor 53 can be caught by tools and primarily rotate. The tension anchor 53 in the area of the support 23e with nuts 55 screwed on it is rigidly connected to the supports 23e. One after the other, tension anchors 53 are connected to each other by means of a connecting nut 56, also called a sleeve, which covers the ends of two adjacent tension anchors 53.

To reduce the gap between the connecting nut 56 and the tension anchors 53, the nut 56 has a drill hole 63 extending radially outward in the middle 63. After the nut 56 is screwed onto both tension anchors 53, a hardening adhesive mass 67 is injected through the drill hole 63, which fills the remaining internal space 64 mainly area 5 between the external thread 54 of the tension anchor 53 and the internal thread of the nut 56, as shown in Fig.10. Suitable hardening adhesives 67 are, for example, epoxy. After the adhesive mass has hardened, the nut 56 is firmly attached to the tension anchors 53 and there is no longer any gap between them both. This is of great importance for the stability of the road guiding structure 1e.

Even a small gap between the tension anchors 53 along direction 3 leads to a relatively large instability along the lateral direction 4. Thanks to the use of tension anchors 53 in the road guiding structure 1e, its stability is significantly increased, and only minor additional costs are required. If tension anchors 53 are not taken into account, then the road guide structure 1e is a standard road guide structure.

A seventh embodiment of the invention is described below with reference to FIG. Identical parts have the same designations as in the first embodiment described above. Structurally different, but functionally similar parts have the same designation with the addition of the letter “f”. The main difference compared to the sixth embodiment is the fixing of the tension anchors 53 to the supports. The rest, and especially the arrangement of the guide rails 57, is identical. Each support 23f has a U-shaped fastening bracket 66 which protrudes against the 4 direction and is screwed to it with nuts 65. Two tensioning anchors 53 located one above the other are passed through it. Using nuts 65, the mounting brackets 66 can be pressed onto the tensioning anchor 53 so that so that the brackets 66 cut into the thread 54 and thereby fix the tension anchors 53 along the direction 3. The two tension anchors 53 are connected to each other, as shown in Fig. 10. An advantage of securing the tension anchors 53 in accordance with FIG. 11 is that they do not have to pass through the drill holes 52, which would be difficult with an existing and mounted road guide structure. In addition, the supports 23f are not loosened due to the drill holes 52. The fastening of the tension anchors 53 in accordance with FIG. 11 thereby makes it easy to equip and stabilize an existing road guide structure.

In general, it must be pointed out that the special characteristics of individual embodiments can easily be combined with each other. For example, recesses 28 of the first embodiment may be provided in all embodiments. Fixing anchors 21 of the first embodiment can also be used if necessary. In all examples of execution, if desired, a block 14 of a porous compressible material can be used. If the foundation consists of soil, then in all cases the fastening of the road guide structure can be carried out using the appropriate driven anchors. All variants of implementation can also, with their corresponding adaptation, be performed as middle guide strips, as shown in Fig. 6. Tension anchors can also be used in almost all examples of execution, and especially in conventional systems of guide strips.

Speaking of a tension anchor, also called a threaded beam, we are talking generally about a standard tension anchor, such as, among other commercially available, the Dywidag brand anchor. The tension anchor has a generally annular cross section. The tension anchor is made of solid material, mainly steel. The tension anchor is advantageously not only a steel sheet or a steel tube. The tension anchor has a diameter of from 10 to 60 mm, mainly 20 to 40 mm, mainly 25 to 32 mm. On the outside there is a large external thread, mainly flared. Preferably, the external thread extends along the entire length of the tension anchor. Flats are provided on the opposite side so that the tension anchor can be caught by the tools and rotated. The tension anchor has great intrinsic rigidity, so not only the tensile force, but also the lateral components of the traction force can be transmitted along the longitudinal direction of the tension anchor. Thus, the tension anchor differs significantly from the steel cable. In addition, the tension anchor, unlike a steel cable, has no sagging problem and there is no need for the cable to be pulled. The tension anchor has a characteristic tensile strength of about 500-600 N / mm. Preferably, the strength is selected for the anchor to obtain the best combination of tensile load and pressure and bending. Higher strengths above 900 N / mm can lead to an rupture of the tension anchor under unexpected impact, without plastic deformation due to narrowing. Nevertheless, the use of higher strength in some cases is possible. The tensile strength of tension anchors is between 100 kN and 1200 kN, mainly from 150 kN to 630 kN. In accordance with individual diameters, the breaking load is as follows: with a diameter of 50 mm - 1080 kN, with a diameter of 40 mm - 631 kN, with a diameter of 32 mm - 442 kN, with a diameter of 28 mm - 336 kN and with a diameter of 16 mm - 111 kN. This digital data is for reference only. In principle, it is also possible to use tension anchors with a different cross section, preferably with a rectangular cross section. Nonetheless, tension anchors are generally preferred with a generally circular or oval cross-section. The adjacent tension anchors are connected in endless engagement using unsealed connecting nuts or couplings with an internal thread suitable for the external thread. Regarding the connection of adjacent tension anchors, DE 10 2006 001 980.6 of 01/13/2006 is indicated here, in particular in FIGS. 2 and 3, with a corresponding description.

Claims (8)

1. Road guiding structure for installation on the edge (2) of carriageways (49) for vehicles, including:
a) the front part (13e; 13f) directed towards the carriageway (49) and fixed along the edge (2) of the carriageway (49), said front part (13e; 13f) being a guide bar (57),
b) several supports (23e; 23f) located on the side of the front (13e; 13f), directed from the carriageway (49), connected to the front (13e; 13f) and resting on the foundation (8), while the supports (23e; 23f) are separated from each other, and
c) at least one tension anchor (53) passing through separate supports (23e; 23f), wherein
d) reinforcing bars are used as said tension anchors (53), and
e) a system containing supports (23e; 23f) and at least one tension anchor (53), in normal condition, is free of tension, characterized in that
f) said reinforcing bars are provided with a continuous external thread (54), and
g) the tension anchors (53) adjacent to each other are connected to each other by the tension nuts (56) to form transverse reinforcing elements in the road guide structure that are connected to each other at great distances. 2. Road guide structure according to claim 1, characterized in that the supports (23e; 23f) are fixed with at least one tension anchor (53). 3. A road guide structure according to any one of claims 1 or 2, characterized in that the tension anchors are passed generally horizontally. 4. Road guide structure according to any one of claims 1 to 3, characterized in that several tension anchors (53) are located one above the other. 5. Road guide structure according to any one of claims 1 to 4, characterized in that at least a portion of the tension anchors (53) extend obliquely to the horizontal. 6. Road guide structure according to any one of claims 1 to 5, characterized in that the supports (23e; 23f) are in the form of the letter T, double T or U. 7. Road guide structure according to claim 1, characterized in that the supports (23f) comprise outwardly protruding fastening brackets (66) connected to the supports (23f) for connecting tension anchors (53) to the supports (23f). 8. Road guiding structure according to claim 4, characterized in that the free space between the outer side of the tension anchors (53) and the inner side of the connecting nut (56) is at least partially filled with hardening adhesive material.

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