RU2047681C1 - Plate for sectional roadway covering - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: plate has polygonal structure of connected to one another through their thickness upper and lower side parts. Side faces of each part of the plate are made in the form of alternating projections and recesses. The projections and recesses of basic upper part of the plate are placed respectively over recesses and projections of lower part of the plate. Angles between lateral sides of the projections and recesses of the lateral faces of each part on the one hand and the plane passing through vertical corner edge of this lateral face in points where they intersect on the other hand are larger than 0 and smaller than half of least angle formed with planes passing through vertical corner faces of adjoined lateral faces of this part of the plate. The plate may have at least one additional part rigidly connected to one of the basic parts of the plate. Lateral faces of this additional part are made in the form of alternating projections and recesses placed respectively under recesses and projections of lower basic part or over projections and recesses of upper basic part. Angle between lateral sides of the projections and recesses on each face of additional part on the one hand and the plane passing through vertical corner edges of this lateral face of the plate in points where they intersect on the other hand is larger than appropriate angle between lateral sides of the projections and recesses of the basic part of the plate related to them. Lateral faces with alternating projections and recesses has the same number of projections and recesses in each part. Shape of the projections and recesses is similar in each part of the plate. Lateral sides with alternating projections and recesses may have not less than two projections and recesses in each part of the plate. Bevels may be made along the perimeter of alternating projections and recesses of lower row of the plate. EFFECT: easy handle and use. 6 cl, 9 dwg

Description

 The invention relates to construction and can be used for paving roads, airfields, sidewalks, sites for various purposes and fortifications from prefabricated elements.

Known plate for prefabricated coatings, in particular the elastic base of roads with a base plate of reinforced concrete of a quadrangular, mainly square shape, and the base plate is located on the bottom plate and both plates are integrally connected to each other in thickness. The bottom plate relative to the horizontal projection of the base plate comprises alternating projections and depressions having a common vertical plane directed at an angle to the edge 45 ^of the base plate. The upper plane of the protrusion and the lower plane of the cavity are located at an acute angle to the horizontal and mutually complement each other, while the head segments of the protrusion of the base and the end segments of the cavity are parallel to the edge of the base plate and have the same length [1]
The disadvantages of the known design are the relatively low bearing capacity of the coating and the durability of the butt joint, which does not absorb bending moment under the action of the load on the upper working surface of the plate, and the practically impact loading of the cross section of the butt joint by the transport load with a straight outline of the seam increases the dynamism of its impact.

The closest technical solution for the combination of essential features and the achieved result is the implementation of a prefabricated cover plate in the form of a supporting polygonal structure of rigidly interconnected by thickness of the upper and lower main parts, in which the side faces of the upper part are made in the form of alternating protrusions and corresponding in shape troughs [2]
The disadvantages of the known design are the lack of strength and durability of the coating when exposed to significant dynamic loads during operation under heavy traffic and adverse climatic conditions (waterlogging of the base, frosty rise of the base).

 The objective of the invention is to increase the strength and durability of the coating structure, as well as its operational reliability in the case of coating on weak soils prone to heaving and significant dynamic loads.

This problem is solved due to the fact that each part of the plate is made with lateral faces having the form of alternating protrusions and depressions, while the protrusions and depressions of the upper main part of the plate are located respectively above the depressions and protrusions of the lower main part, and the angles between the sides of the protrusions and depressions the lateral face of each of the parts and the plane passing through the vertical angular ribs of this lateral face of the plate at the points of their intersection are more than 0 ^about and less than half of the smallest angle formed by the planes, passing through the vertical angular ribs of adjacent side faces of this part of the plate, while it can be made with an additional part rigidly connected to one of the main parts of the plate, and the side faces of this additional part are in the form of alternating protrusions and depressions with their placement respectively under the protrusions and hollows of the lower main part or above the protrusions and hollows of the upper main part, the angle between the sides of the protrusions and troughs of each side face of the additional part and the plane passing through without vertical angular ribs of this lateral face of the plate at the points of their intersection, greater than the corresponding angle between the sides of the protrusions and troughs of the main part of the plate connected to it, or it can be made with additional parts rigidly connected to the upper and lower main parts of the plate, and the side the faces of the additional parts are in the form of alternating protrusions and depressions with the placement of the protrusions and depressions of one additional part under the protrusions and depressions of the lower main part of the plate, and the protrusions and depressions of another additional part above the protrusions and depressions of the upper main part of the plate, while the angles between the sides of the protrusions and depressions of each side face of the additional parts of the plate and the plane passing through the vertical angular ribs of this side edge of the plate at their intersections are larger than the corresponding angles between the sides of the protrusions and depressions associated with them the main parts of the plate, and the side faces with alternating protrusions and depressions in each part contain the same number of protrusions and depressions, the shape of which in each Asti plate is the same, but at least two projections and two recesses in each side plate, wherein at the perimeter of alternating projections and recesses of the lower row plates can be formed chamfer.

 The solution to the above problem of increasing the strength and durability of the coating slab is ensured by the technical effect, namely, when connecting to adjacent plates parts of the slab, the side faces of each of which are formed by alternating protrusions and depressions with their sides directed at an acute angle to the plane passing through vertical angular ribs of the plate form a butt joint, in the work of which its entire area is involved. Such a butt joint provides the coating for bending and lateral loading both when exposed to a transport load on the surface of the coating and when the base can be lifted as a result of frost heaving. In addition, the butt joint has a broken outline on the surface of the coating, as a result of which the wheel load of vehicles from the vehicles at the plate edges is varied at the same time, which reduces the dynamic impact of the load on the butt joint and increases its durability.

In a prefabricated coating, each plate works as a plate lying on an elastic base and resting on a contour on adjacent plates, which increases the bearing capacity and coatings as a whole. The angle between the sides of the projections and depressions each of the portions and a plane passing through the vertical corner rib plates due to the fact that the angle of ⁰ ° is formed a butt joint, and at an angle of more than half of the angle formed by planes passing through the vertical corner edges plate adjacent lateral faces, it is impossible to carry out installation of prefabricated cover in the area.

 Figure 1 presents a General view of a two-row version of the plate with protrusions and depressions in the form of a segment; figure 2 option plate with protrusions and depressions in the form of a segment with an additional lower part, General view; figure 3 option plate with protrusions and depressions in the form of a segment with an additional upper part, General view; figure 4 option plate with protrusions and depressions in the form of a segment with additional upper and lower parts, General view; in FIG. 5 schemes for laying plates in the coating; in Fig.6 scheme of the butt connection of a variant of the plate in Fig; 1; Fig.7 scheme of the butt connection of a variant of the plates in Fig; 2; on Fig work diagram of the butt joint option plate in figure 3; in Fig.9 the operation diagram of the butt joint of the variant of the plates in Fig.4.

 Plate 1 prefabricated coating includes a supporting polygonal structure of interconnected by thickness parts 2-5 (Fig.1-4). The lateral faces of the lower main part of the plate 2 (Fig. 1) are made in the form of alternating protrusions 6 and depressions 7, the sides of which 8 and 9 are directed at an acute angle β to the plane passing through the vertical angular ribs of this edge of the plate 10, at their intersections . The lateral faces of the upper part of the plate 3 are also made in the form of alternating protrusions 11 and depressions 12, the sides of which 13 and 14 are directed at an acute angle α to the plane passing through the vertical angular ribs of this edge of the plate 10, at their intersections. In this case, the protrusions 11 and depressions 12 of the upper main part of the plate are respectively located above the depressions 7 and protrusions 6 of the lower main part of the plate 2. The plate 1 can be provided with an additional part 4 (Fig. 2), rigidly connected with the lower main part 2, and (or ) additional part 5, rigidly connected with the upper main part 3 (figure 3, 4). The lateral faces of the additional part 4 are made in the form of alternating protrusions 15 and depressions 16, the lateral sides of which 17 and 18 are directed at an acute angle θ to the plane passing through the vertical angular ribs of this edge of the plate 10 at the points of their intersection, and the angle θ is greater than the angle β. The protrusions 15 and depressions 16 of the additional part 4 are located respectively under the protrusions 6 and depressions 7 of the lower main part of the plate 2. The lateral faces of the additional part 5 are also made in the form of alternating protrusions 19 and depressions 20, the sides of which 21 and 22 are directed at an acute angle φ to the plane passing through the vertical angular ribs of this face of the plate 10 at the points of their intersection, and the angle φ is greater than the angle α. The protrusions 19 and depressions 20 of the additional part 5 are located respectively above the protrusions 11 and depressions 12 of the upper part of the plate 3.

 The shape of the protrusions 6, 11, 15, 19 and depressions 7, 12, 16, 20 in the plan may be different. In particular, they can be made in the form of a triangle, a trapezoid, a segment, or another convex and concave shape. From the point of view of ensuring sufficient strength, as well as simplifying the manufacturing technology of tooling for the production of plates, the preferred form of the protrusions 6, 11, 15, 19 and troughs 7, 12, 16, 20 in the form of a segment (Fig.1-5).

 The depth of the protrusion and trough in each part of the plate is determined by calculation depending on the magnitude of the current load, material, size and shape of the plate, base material. However, taking into account the possible deviations of the geometric dimensions of the plate elements during their manufacture, the possible movement of the plates as a result of the temperature effect, the depth of the protrusion and the depression should be such that the length of the interaction area between adjacent plates at any level of the plate is at least 1 cm.

 The number of protrusions 6, 11, 15, 19 and depressions 7, 12, 16, 20 in each of the parts 2, 3, 4, 5 of the plate 1 on one of its lateral faces should be the same and contain at least two protrusions and two depressions. In this case, it is possible to stack the slabs apart, i.e. with the displacement of the butt joints in adjacent rows of plates (figure 5), resulting in increased distribution ability and durability of the coating.

 The overall shape of the slab is a polygon formed by planes passing through the vertical angular edges of the faces of the slab 10. The general shape of the slab can be in the form of a square, rectangle, rhombus, triangle, hexagon, trapezoid, parallelogram.

 Installation of prefabricated coatings is carried out on a prepared base according to known technology in the following sequence.

 The same slab 1 precast coating (figure 5) is laid on the base, orienting them in a given direction. Next to the first laid plate 1, in accordance with the selected scheme, lay the next plate and move it along the base, joining with the previously laid plate 1 so that the protrusions 6, 11, 15, 19 and the depressions 7, 12, 16, 20 of the laid plate 1 coincide respectively, with depressions 7, 12, 16, 20 and protrusions 6, 11, 15, 19 of the previously laid plate 1.

Installation of plates can be carried out in a coating only if the angles α, β, θ or φ formed by the sides of the largest projections and depressions with a plane passing through the vertical corner edges of one face of the plate are less than half the angle γ formed planes passing through the vertical corner edges of the slab of adjacent side faces. For example, for plates having a general plan shape in the form of a rectangle or square, the largest of the angles α, β, θ or φ is less than 45 ^° , for plates having a general shape of an equilateral triangle, the largest of the angles α, β, θ or φ is less than 30 ^about , etc.

 Before joining the plates, their joints can be treated with waterproofing materials, for example, bitumen mastic, etc. materials, which allows to ensure the watertightness of the butt joint, to eliminate the gaps in it necessary for the free installation of plates in the coating and, in addition, to reduce the dynamic effect of the transport load on the butt joint. The butt joint can be filled after laying the plates by known methods. In this case, bitumen mastic, sand-cement mixture, dry sifted sand and other similar materials can be used as filler.

 To reduce the complexity of installation and to prevent movement of unreinforced base material when laying the plates around the perimeter of the lower parts 2 or 4 of the plate 1, chamfers can be made.

 To this end, the interacting upper and lower surfaces of the protrusions and depressions can be made with a slope not exceeding 1:20 (Fig. 1-4).

 The plate of the prefabricated coating, when it is declared to be connected to adjacent plates under the influence of the transport load, acts as a plate lying on an elastic base and interacting along the contour with its protrusions and depressions with adjacent plates, and therefore, the bearing capacity of the plate and coating as a whole increases significantly using the invention.

 In the work of the butt joint, its entire thickness is involved in total. Depending on the embodiment of the plate, the work of the butt joint has its own characteristics.

 With the mutual connection of the plates 1, made according to the variant shown in figure 1, the protrusions 11 of the upper main part 3 of the plate 1 with its lower surface together with the surface of the depressions 7 below the lower main part 2 of the plate 1 interact with the upper surface of the protrusions 6 of the lower part 2 plate 1, working in conjunction with the lower surface of the located above the cavity 12 of the upper part 3 of the plate 1 (Fig.1 and 6).

When exposed to a load on the coating surface, the protrusions of the upper main part 3 of the plate 1 work on bending and a transverse load along an inclined section of thickness h ₃ . At the same time, the protrusions of the lower main part 2 of the plate 1 work mainly on a transverse load along an inclined section of thickness h ₂ . When exposed to a load from below as a result of a possible frosty rise of the base, the bending moment and the transverse force from the external load are perceived by an inclined section of thickness h ₂ . The upper part of the plate at the same time works mainly on a transverse load with a section thickness.

 With the mutual connection of the plates 1, made according to the variant shown in figure 2, the protrusions 11 of the upper main part 3 of the plate 1 with its lower surface, together with the upper surface of the depressions 7 of the 2 part of the plate 1, as well as the depression 7 of the part 2 of the plate 1 its lower surface, formed due to the depression 16 of part 4 of the plate 1, interact respectively with the upper surface of the protrusions 6 of part 2 of the plate 1, working in conjunction with the lower surface of the depressions 12 of part 3 of the plate 1 and the upper surface of the protrusions of 15 parts 4 1 plates bounded by projections 6 parts 2 plate 1 (Figures 2 and 7).

In this case, an additional platform appears in the butt joint, through which the external load is transferred from one plate to another. So, when exposed to a load on the surface of the coating, the protrusions 11 of part 3 of the plate 1 and the trough 7 of part 2 of the plate 1 work on bending and transverse load along inclined sections of thickness h ₃ and h ₃ -h ₂ . In this case, the protrusions 6 of part 2 of the plate 1 over an area supplemented by depressions 12, and the protrusions 15 of part 4 of the plate 1 along their upper surface work mainly on the transverse load along inclined sections of thickness h ₂ -h ₄ and h ₄ . A similar nature of the work of the butt joint occurs with the mutual connection of plates made according to the option presented in figure 3 and 8.

 The appearance in the butt joint of an additional site leads to a redistribution of forces in it under the action of an external load, as a result of which the unit load per unit area of the calculated cross section of the butt joint decreases, and its strength and durability increase.

 With the mutual connection of the plates 1, made according to the variant shown in figure 4, two additional platforms are formed in the butt connection, through which the external load is transferred from one plate to another (figures 4, 9), i.e. the bending moment and the transverse force from the external load during the execution of the plate 1 with additional parts 4 and 5 is redistributed in three levels of the section of the plate along the broken outline of the butt joint formed by the protrusions 6, 11, 15, 19 and depressions 7, 12, 16, 20, in As a result, additional inclined sections appear, perceiving a bending moment and a transverse force from an external load, i.e. the unit load per unit area of the design cross section of the butt joint is significantly reduced.

 Thus, the strength and durability of the butt joint and coating generally increases. Due to the fact that the butt joint has a broken shape not only in plan but also in cross section (Figs. 1–9), during operation of the coating laid on an unstressed base, a possible splash of the base material is prevented, which usually takes place when waterlogging the base in the billing period. As a result of this, there is no weakening of the base (formation of voids) in the joint zone and the durability of the coating increases.

Claims (6)

1. COVERING PLATE, comprising a supporting polygonal structure made of rigidly interconnected by thickness of the upper and lower main parts, in which the side faces of the upper part are made in the form of alternating protrusions and their corresponding hollows, characterized in that each part of the plate is made with lateral faces in the form of alternating protrusions and depressions, while the protrusions and depressions of the upper main part of the plate are respectively located above the depressions and protrusions of the lower main part, and the angles between the lateral The defenses of the protrusions and depressions of the lateral face of each of the parts and the plane passing through the vertical angular ribs of this lateral edge of the plate at the points of their intersection are more than 0 ^o and less than half of the smallest angle formed by the planes passing through the vertical angular edges of the adjacent side faces of the plate.  2. The plate according to claim 1, characterized in that it is made with an additional part rigidly connected to one of the main parts of the plate, the side faces of the additional part are in the form of alternating protrusions and depressions with their placement respectively under the protrusions and depressions of the lower main part or above protrusions and depressions of the upper main part, and the angle between the lateral sides of the protrusions and depressions of each side face of the additional part and the plane passing through the vertical angular ribs of this side face of the plate at their intersections I, more than the corresponding angle between the sides of the protrusions and depressions of the main part of the plate connected with it.  3. The plate according to claim 1, characterized in that it is made with additional parts rigidly connected to the upper and lower main parts of the plate, the side faces of the additional parts are in the form of alternating protrusions and depressions with the placement of the protrusions and depressions of one additional part under the protrusions and depressions the lower main part of the plate, and the protrusions and depressions of the other additional part above the protrusions and depressions of the upper main part of the plate, while the angles between the sides of the protrusions and depressions of each side face of the additional parts of the plates s and the plane passing through the vertical angular ribs of this side face of the plate at the points of their intersection are larger than the corresponding angles between the sides of the protrusions and troughs of the main parts of the plate connected with them.  4. The plate according to claims 1 to 3, characterized in that the side faces with alternating protrusions and depressions contain in each part the same number of protrusions and depressions, the shape of which is the same in each part of the plate.  5. The plate according to claims 1 to 3, characterized in that the side faces with alternating protrusions and depressions contain at least two protrusions and depressions in each part of the plate.  6. The plate according to claims 1 to 3, characterized in that bevels are made along the perimeter of the alternating protrusions and depressions of the lower row of the plate.

Images