RU2574086C2 - Modular plate and system of modular surfaces - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to modular building boards. The board can be butt jointed to the second removable modular board with the channel passing from the hole in the top surface to the hole in end face surface and/or the channel passing from the hole in end face surface in the board. The channel in the first board can be matched either with the channel in the second board in such a way that the extended channel passing through both boards is formed the access to which is possible through the holes in the top surfaces of all boards and where the first joining fixture for mutual joining of two boards, or with the channel in the second board can be detachably installed is formed in such a way that the extended channel is formed which passes through end faces of both boards and ending inside the second board, the access to which is possible only through the hole in the top surface of the first named board and in which the second connecting fixture for connection of two boards among themselves can be detachably installed.

EFFECT: method of series joining of four building boards and the joining fixtures for mutual joining of boards are offered.

14 cl, 16 dwg

Description

The invention relates to slabs used in the construction industry, in particular to modular building slabs, to a system of modular surfaces consisting of such slabs, and also to a method for connecting building slabs.

It is widely known that slabs, in particular concrete or concrete, are used in the construction industry as building elements. Such slabs are used as flooring for buildings, highways, etc. When connecting two or more of these plates together, an internal bonding means is usually used, which extends internally along the length and / or width of the plates.

The disadvantage of the system consisting of such plates and their fastening means is that after connecting the plates with internal fastening means, if it becomes necessary to adjust, straighten or move the plate or fastening means, the only way to access the fastening means is to disconnect the corresponding plates by at least partial destruction of the plate or means of bonding. This is expensive and long, since any part that has been at least partially destroyed usually has to be replaced, as a result of which the system is disabled for the period of repair work.

In this regard, it would be desirable to develop an improved slab for use in the construction industry, as well as an improved method for joining slabs that would be devoid of the aforementioned disadvantages that currently exist.

According to a first aspect of the invention, there is provided a removable modular plate for use in the construction industry, having an upper surface, an opposing lower surface thereof, and a first and second opposing end surfaces located between the upper and lower surfaces substantially perpendicular to them, and comprising a channel extending from the hole in the upper surface to the hole in the end surface, and the plate is made with the possibility of connecting end-to-end with a second removable modular plate, and marking the upper surface, the opposite lower surface, and the first and second opposite opposite surfaces located between the upper and lower surfaces essentially perpendicular to them, and containing a channel extending from the hole in the upper surface of the plate to the hole in its end surface, and / or the channel entering the plate from the hole in its end surface, while either the channel in the first plate is aligned with the channel in the second plate with the formation of an elongated channel passing through the ends of the two it, access to which is possible through openings in the upper surface of each plate and in which the first fastening means for connecting the two plates to each other is removably mounted, or the channel in the first plate is combined with the channel in the second plate with the formation of an elongated channel passing through the ends of the two plates and ending inside the second plate, and access to this elongated channel is possible only from the side of the hole in the upper surface of the first plate, and in this elongated channel, a second fastening means for connecting two plates between each other.

Also according to a first aspect of the invention, there is provided a corresponding second removable modular plate for use in the construction industry together with the aforementioned removable modular plate, which has an upper surface opposite its lower surface, as well as first and second opposite opposite surfaces located between the upper and lower surfaces essentially perpendicular to them, and containing a channel extending into the plate from the hole in its end surface, the second plate being made can be joined end-to-end with the above-described plate, so that the channel is aligned with the channel in the plate according to claim 1 with the formation of an elongated channel passing through the ends of two plates and ending inside the second plate, while access to the elongated channel is possible only from the side of the hole in the second surface of the above-described plate and in this elongated channel is removably mounted a second mounting means for connecting the two plates together.

A removable modular slab of this type is convenient to use, because, firstly, modularity means that the slabs are reproducible and predictable in size, and that they can be easily and precisely aligned. Secondly, the plates can be quickly installed both at the initial installation and during subsequent replacements, and it is also easy to adjust with minimal inconvenience and cost. For this, the upper surface of the plate is preferably open, i.e. easily accessible, as well as the holes in it.

Preferably, at least one, first or second, opposed end surface is profiled so that it is possible to create a joint connection with the profiled end surface of another plate when they are connected end-to-end to each other.

Preferably, the profile of the end surface of one plate includes a protrusion, and the profile of the end surface of another plate includes a corresponding recess, therefore, when the end surface of one plate and the end surface of the other plate are joined end-to-end, the surfaces and profiles are combined in such a way that a tight connection is formed. An elongated channel or elongated cavity may pass through such a connection, as well as the first or second connecting means for connecting two plates.

In addition, the protrusion and recess are preferably shaped so that the end surface of each of them (i.e., the surface that will be flush with the rest of the end surface of the plate, if the protrusion is straightened or the recess is aligned) is at an angle of 45 ° or less to the vertical plane, preferably less than 25 °, more preferably less than 15 °, most preferably in the range of 1-5 °.

The profile of the end surface of one plate can pass along the entire length of the end surface of this plate, as well as, respectively, for another plate. Meanwhile, it is not necessary that the mating surfaces have such a length. The profile of the end surface can only partially extend along the length of the end surface of both plates; the profile may be located in the center of the width of the end surface of the plates or may extend at one end of the end surface.

A removable modular plate according to the invention can have two end surfaces with the same profiles. Such a slab will be called a Type A slab. Another modular slab, to which a Type A slab is connected end-to-end, can also have two end surfaces with the same profiles that are different from and mating with the type A slab profiles. Such a plate will be called a type B plate. A type plate may have, for example, two end surfaces, each of which has a recess, and a type B plate may have, for example, two end surfaces, each of which has a protrusion; recesses and protrusions have a complementary and mating shape. Similar type A and type B boards can form a series of several boards in the following sequence -A-B-A-B-A-B- (etc.).

Alternatively, the removable modular plate according to the invention may have two different end surfaces. In this case, such a plate will be called a type C plate. The profile of one of the end surfaces of a type C plate can mate with the profile of the other end surface, whereby one type C plate can be butt-joined to another type C plate. For example, on one of the end surfaces Type C slabs may have a recess, and a protrusion may be present on the other end surface. Such type C boards can form a series of several boards in the following sequence —C — C — C — C — C — C (etc.).

The removable modular slab described above can be pre-cast or pre-molded from a structural material that can be any suitable known material, however, it is preferable to use concrete or a derivative thereof, for example fiberglass reinforced concrete (GFRC), or fiberglass reinforced plastic material ( GFRP), or a plastic material, due to the inherent strength of such materials, resistance to corrosion and electrical insulation properties.

Preferably, the modular slab has one or more voids located therein, preferably longitudinal, to reduce its weight compared to a full-bodied slab without reducing strength. Such voids may remain unfilled or may be filled with a light weight aggregate such as porous / foam rubber. Preferably, such a filler can also dampen vibrations if or when the board is exposed to vibration loads.

In addition, the modular plate may contain one or more recesses on its first surface, which can be used for drainage and / or for the placement of cables, such as electrical cables. In addition, along with one or more recesses, there may be longitudinal ducts for accommodating cables and / or so that water can flow from the surface into them. In addition, the longitudinal ducts inside the slab can be crossed by transverse ducts.

According to a second aspect of the present invention, there is provided a system of modular surfaces for use in the construction industry, consisting of two modular plates, each of which has a channel extending from an opening in its upper surface to an opening in its end surface, as discussed above, and a first connecting means for connecting two plates to each other, and the first connecting means can be removably mounted in an elongated channel.

In practice, any number of modular plates can be interconnected in a similar way, and are connected either linearly, forming an elongated surface, or multidirectionally, forming a larger surface area.

Preferably, the first connecting means may be removably mounted in an elongated channel. In addition, the first connecting means can be installed in an elongated channel with the possibility of adjustment. In both cases, the ease of access to the first connecting means due to the layout of the channels in the slabs means that the adjustment, alignment or replacement of the modular slab in such a system of modular surfaces is quick, easy and low cost.

Preferably, the elongated channel has an arcuate or parabolic shape; the channel is open at both ends on the upper surfaces of two adjacent modular plates and can arcuate between the adjacent end surfaces of the plates. Accordingly, the first connecting means may be curved and be either a tension cable or flexible connection, or a flexible connecting rod. Since the cable is placed in an elongated passage through the upper surfaces in two adjacent modular plates, a tensile force can act on the lower part of the cable, while a compressive force can act on the upper part of the cable. Thus, when a force is applied to the joint between two plates, the distribution of forces within the cable ensures that the plates are aligned. As a result, the plates together act as a single structure.

The first connecting means can preferably be tensioned and attached to the upper surfaces of each plate, which provides easy access to it if it is necessary to align or replace one or more plates.

According to a second aspect of the present invention, there is also provided a system of modular surfaces for use in the construction industry, consisting of two modular plates, one of which has a channel extending from an opening in its upper surface to an opening in its end surface, and the other has a channel entering the inside of the plate from the hole in its end surface, as described above, as well as the second connecting means for connecting two plates to each other, which can be removably installed in an elongated channel.

In the same way, any number of modular plates can be interconnected in a similar way, moreover, they are connected linearly, forming an elongated surface, or in different directions, forming a larger surface area.

Preferably, the second connecting means is removably mounted in the elongated channel. In addition, the second connecting means can be installed in an elongated channel with the possibility of adjustment. In both cases, the ease of access to the second connecting means due to the layout of the mating walkways and cavities in the slabs means that adjusting, leveling or replacing the modular slab in such a system of modular surfaces is quick, easy and at a low cost.

Preferably, the elongated channel has an arcuate, parabolic or linear shape; the channel is open only from one end in the upper surface of one of the adjacent modular plates and ends in the body of the other plate. Accordingly, the second connecting means may be curved and constitute a tension cable, a flexible connection or a flexible connecting rod.

The second connecting means is preferably anchored at the end of the elongated channel inside one plate and can be tensioned at the upper surface of the other plate, which provides easy access to it if you need to align or replace one or more plates.

As noted above, modular plates can be of three types: type A, type B and type C. The system of modular surfaces according to the invention can consist of conjugated modular plates of two types: types A and B. Alternatively, the system can consist of plates of only one type : type C.

The modular surface system according to the invention can be widely used in the construction industry. Meanwhile, it, in particular, can be used as a support for railway rails or rails of public transport. Typically, a railway consists of a base or subgrade on top of which a ballast layer is laid. The ballast layer creates an aligned substrate for laying the sleepers, to which the railway tracks are then directly attached. The disadvantage of such a device is that under the influence of external factors the ballast layer and sleepers are destroyed, i.e. water, snow and ice can penetrate into them, which leads to unbalanced paths. Re-alignment of such tracks is often an expensive and lengthy procedure and leads to significant delays in the movement of trains, thereby reducing the availability and throughput of tracks.

The use of a modular surface system as a support for railway rails minimizes such shortcomings by replacing the sleepers with modular slabs. The rail can rest on the first surface (usually the top) of the modular slabs, which, in turn, can be laid directly on the existing ballast layer, which serves as the base. Alternatively, the base may be in the form of processed or hydraulically stabilized gravel, or ordinary soil may be used instead. The ballast layer will be predominantly closed and protected from external factors by means of plates, as well as improved connecting means between the plates, thus creating a continuous structure.

Alternatively, urban transport rails may be laid on the first surface (usually top) of the slabs.

In practice, many modular slabs can be connected by connecting means, forming a single support for the rails of the railway or city transport without the use of additional concrete providing strength, and used as a long-term solution and as an alternative to railway tracks with gravel. This may be particularly preferred in tunnels, overpasses and switches, railway crossings, and also in places with weak soil; as well as for the light metro in the city (for example, on the Docklands light rail), where quick installation is critical to minimize traffic disruptions.

Of course, other areas of application of modular plates and a system of modular surfaces according to the invention are possible, including, but not only, as flooring in buildings, on highways, at airports (for example, on the runway), as well as in ports or on cargo terminals (for arrangement of parking with a hard coating). In addition, the invention can be used for non-horizontal (or at least non-floor) applications, for example, in the walls of fastening structures, as well as in the construction of temporary or rescue structures.

According to a third aspect of the present invention, there is provided a method for releasably joining two building boards, each of which has an upper surface, an opposing lower surface thereof, a first and second opposing end surfaces located between the upper and lower surfaces substantially perpendicular to them, and a channel extending from holes in the upper surface to the hole in the end surface. The method involves butt jointing of two plates so that the channel in one of the plates can be aligned with the channel in the other plate, forming an elongated channel passing through the ends of the two plates, as well as installing a removable first connecting means in the elongated channel so that to each end The first connecting means was accessible through the top surface of each plate.

According to a third aspect of the present invention, there is also provided an appropriate method for releasably joining two building boards, each of which has an upper surface, an opposing lower surface thereof, a first and second opposing end surfaces located between the upper and lower surfaces substantially perpendicular to them, wherein one of the plates has a channel extending from the hole in its upper surface to the hole in its end surface, and the other plate has a channel extending from the hole in its end surface inside the plate. The method involves butt jointing of two plates in such a way that the channel in one of the plates can be combined with the channel in the other plate, forming an elongated channel passing through the ends of the two plates, as well as installing a removable second connecting means in the elongated channel ending in the other plate in this way so that access to the second connecting means is possible only through the upper surface of the first plate.

This joining method can be used for modular plates according to the first aspect of the invention, as well as for a system of modular surfaces according to the second aspect of the invention. Meanwhile, it is also applicable to other plates, which simplifies access to the connecting means through their upper surfaces, which in the case of retaining structures or rescue structures can be external vertical or essentially vertical surfaces.

The method also includes the steps of subsequent anchoring / fastening and tensioning of the connecting means, which eliminates the need to use connecting materials that are cured or vulcanizable before the operation of the structure of the plates.

The invention will be more apparent from the following detailed description of an example of its implementation and with reference to the accompanying (schematic) drawings.

1 shows a modular plate according to the invention, a perspective view;

figure 2 is the same, end view;

figure 3 shows an alternative modular plate according to the invention, a perspective view;

figure 4 is the same end view;

figure 5 shows the end surfaces of two modular plates according to the invention (shown in figures 1-4), a perspective view;

figure 6 shows several modular plates according to the invention (shown in figures 1-5), a side view in longitudinal section;

in Fig.7 shows another modular plate, an alternative to the plate shown in Fig.1-4, a perspective view;

on Fig shows several modular plates according to the invention (shown in Fig.7), a side view in longitudinal section;

figure 9 shows a system of modular surfaces according to the invention, a side view in longitudinal section;

figure 10 shows a modular plate according to the invention, a view in cross section;

figure 11 shows an alternative modular plate according to the invention, a view in cross section;

on Fig shows several modular plates according to the invention, a perspective view;

FIG. 13 shows a modular plate of the form, an alternative form of the modular plate of FIG. 1, a perspective view;

Fig.14 is the same end view;

on Fig shows a variant of the system of modular surfaces shown in Fig.9, a side view in longitudinal section;

on Fig shows another alternative modular plate according to the invention, a view in cross section.

1 and 2, a modular plate 10 is shown having a first surface in the form of an upper surface 11, a second surface in the form of a lower surface 12, and also two opposite end surfaces 13. The plate 10 is elongated in the direction between two end surfaces 13. Each of the end surfaces surfaces 13 of the plate is profiled and forms a recess 16. This profile partially extends along the length of the end surface 13 and is located in the center of it. Inside the recess 16 there are four holes 14 corresponding to the other four holes 15 located on the upper surface 11 of the plate 10 adjacent to the end surface 13. Between each pair of holes passes a channel 19 (shown by a dashed line), connecting them.

The plate 10 also contains longitudinal voids 17 (shown by dashed lines), which can be filled with foam rubber both to reduce the total weight of the plate 10 (compared to a similar plate without cavities), and to damp any vibrations arising in it, without reducing its strength . In addition, along the longitudinal axis of the plate, a central elongated channel 18 passes with drainage outlets 18a along it to drain surface water, which otherwise might stagnate on the upper surface 11 of the plate. Two longitudinal ducts 18b, as well as optional transverse ducts 18c, can be formed on each side of the channel 18, inside the plate body 10.

FIGS. 3 and 4 show a modular plate 20 similar to the modular plate 10 in FIGS. 1 and 2, since it also has a first surface in the form of an upper surface 21, a second surface in the form of a lower surface 22, and also two opposite end surfaces 23. The plate 20 is elongated in the direction between the two end surfaces 23. The plate 20 also contains longitudinal voids 27 (shown by dashed lines), which can be filled with foamed rubber both to reduce the total weight of the plate 20 (compared to a similar plate without cavities), and for g solving any vibrations arising in it, without reducing its strength. In addition, along the longitudinal axis of the plate, there is a central elongated channel 28 with drainage outlets 28a along it to drain surface water, which otherwise might stagnate on the upper surface 21 of the plate. Two longitudinal ducts 28b, as well as optional transverse ducts 28c, can be formed on each side of the channel 28, inside the plate body 20.

The plate 20 differs from the plate 10 in that each end surface of the plate 20 is profiled and forms a protrusion 26. This profile partially extends along the length of the end surface 23 and is located in the center of it. In the protrusion 26 there are four holes 24, which correspond to the other four holes 25 located on the upper surface 21 of the plate 20 adjacent to the end surface 23. Between each pair of holes passes a channel 29 (shown by a dashed line), connecting them.

In order to avoid discrepancies, although only four channels were shown on slabs 10 and 20, if necessary, any number of channels can be used to fasten two slabs together. The channels can be of different diameters and can differ from each other, depending on the degree of tension applied to the connecting means (tension cable).

Figure 5 shows two modular plates 10, 20 and, in particular, how these plates can be joined end-to-end. Plate 10 is similar to the plate shown in FIGS. 1 and 2, and plate 20 is similar to the plate shown in FIGS. 3 and 4. When plates 10 and 20 are in contact “butt-to-butt”, the protrusion 26 fits snugly into the recess 16 forming a strong connection. In such a connection, the channels (not shown) passing between the holes 14, 24 in the end surfaces 13, 23 and the holes 15, 25 in the upper surfaces 11, 21 of each of the plates 10, 20 are joined and aligned so that an elongated channel is formed ( not shown) extending from the upper surface 11 of the plate 10 to the upper surface 21 of the plate 20.

Figure 6 shows how several plates 10 are connected to several plates 20, forming a continuous single surface. It is clear that if it is necessary to remove one of the plates 10 from the system, then it can simply be lifted up without destroying it. Plates 10 and 20 may be a pair consisting of an A-type plate having identically profiled protrusions on its end surfaces, and a B-type plate having identically profiled recesses on its end surfaces. The advantage of this arrangement is that, if necessary, the B-type plate can be removed from the system outward, away from adjacent A-type plates. Alternatively, both plates 10 and 20 may be C-type plates in which protrusions are formed on one of the end surfaces, and recesses are formed on the opposite end surface. In addition, although it was indicated that only two end surfaces are profiled on the plates 10, 20, one or both longitudinal surfaces can also be profiled in such a way that the joints can be formed on all four sides.

7 shows an alternative plate 30, which is largely similar to plates 10, 20 in that it also has a first surface in the form of an upper surface 31, a second surface in the form of a lower surface 32, as well as two opposite end surfaces 33a and 33b located between the first and second surfaces essentially perpendicular to them. The plate 30 is elongated in the direction between the two end surfaces 33a and 33b. In this case, the end surface 33a of the plate 30 is profiled so that it forms a protrusion 36a. This profile extends along the entire length of the end surface 33a. The end surface 33b is profiled so that it forms a recess 36b, which also extends along the entire length of the surface 33b. On the end surface of the protrusion 36 there are four holes 34, which correspond to the other four holes 35, located on the upper surface 31 of the plate 30 adjacent to the end surface 33. Between each pair of holes passes a channel 39 (shown by a dashed line), connecting them.

In addition, the plate 30 has a central elongated channel 38 extending along the longitudinal axis of the plate 30, with drainage outlets 38a along it. Transverse ducts 38c may also be formed in the plate body 30. Plate 30 can be attributed to a C-type plate, in which a protrusion is formed on one of the end surfaces, and a recess is formed on the opposite end surface.

If the plate 30 is joined end-to-end with another plate, then such another plate must be profiled so that it forms a recess extending along the entire length of its end surface, in which there are correspondingly arranged openings and passages, whereby a modular system -C is formed -C-C-C- (etc.) of the type as shown in FIG.

Figure 9 shows a system 40 of modular surfaces, consisting in this case of two plates 10 and 20 of the type discussed above. The plates 10 and 20 abut against each other, forming a joint connection 43 so that the individual channels 19 and 29 in each of the plates are joined and connected, forming an elongated channel 44 passing between the two plates 10 and 20. Through the channel 44 the first connecting means 42 in the form of a flexible steel cable, which can pass along an arcuate path. At each end of the connecting means 42 is a fastening and tensioning means 45, designed to fix the plates 10 and 20 in place, as well as to ensure the strength of the connection 43.

Joint connection 43 is profiled so that the end surfaces 13 and 23, forming a recess 16 and a protrusion 26, respectively, are located at an angle of 5-10 ° relative to the vertical plane (indicated in the drawing by the angle θ). It is believed that due to the location of the connection surfaces in a similar manner, the two plates 10 and 20 are easier to align when laying the system 40.

Any number of two or more plates 10 and 20 can be connected in the following sequence:

- preparing the surface, for example, the underlying layer (not shown) and the upper ballast layer (not shown) by aligning them;

- laying two plates 10 and 20, abutting against each other, so that their profiled surfaces 13 and 23 are joined and many elongated channels 44 are formed between them;

- placing the connecting means, for example the cable 42, in each elongated channel 44 by threading it through the hole in the upper surface 11 of the plate 10 until it comes out through the corresponding hole 25 in the upper surface 21 of the plate 20;

- installation of fastening and tensioning means 45 at each free end of each cable 42 to fix them in place and subsequent tension, resulting in a bonding of the connection 43 between the two plates 10 and 20.

This method is equally suitable for laying and joining two or more plates 30.

Figure 10 shows the plate 10, presented in figures 1 and 2, used as a support for railway rails. Plate 10 is laid on the base surface (not shown), and rail rails 50 and fasteners 51 are placed on it for fastening the rails 50 to the top surface 11 of plate 10. Instead of using concrete reinforced with fiberglass (GFRP), a reinforcing bar 52 is installed inside the plate 10 , which in this case is located next to the bottom surface 12 of the plate and extends upward along the side wall of the plate. The rod 52 may extend around the ducts 18b and be located adjacent to the top surface 11 of the plate, forming a reinforcing loop. As an additional safety feature, the plate 10 has an optional raised portion 54, which extends longitudinally downward from each side of the upper surface 11 and is located outside the rails 50. If the train going along the rails 50 goes off the rails, the raised portion 54 will not allow the aforementioned the train roll over and get off the rail, which further enhances railway safety.

11 also shows a plate 10, shown in figures 1 and 2, used as a support for railway rails. On the plate 10, there are also railway rails 50 and fasteners 51, however, the upper surface 11 of the plate contains a raised profiled section 101, that is, as seen in cross section, the plate in the center has an increased height compared to its outer edges and the height of the plate decreases from the center to outer edges. In addition, on the upper surface 11, there are two longitudinal recesses 102 in which the rails 50 and fastening components 51 are placed. Due to this, the rails 50 can actually be laid in the plate 10, which can be especially convenient if the rails need to be deepened to increase the clearance when laying in tunnels or under bridges or at level crossings and in locomotive depots, which allows for repair work using conventional road equipment.

12 shows a system 60 of boards that are connected to form a wider surface area than with a simple joint butt-to-joint connection. In the system shown in FIG. 12, different types of plates are used, the end and / or side surfaces of which are profiled as necessary to provide appropriate connections to adjacent plates. In particular, FIG. 12 shows that:

- plate 61 has profiles in the form of a pair of protrusions 62 on one of the end surfaces 63, as well as on one of the side surfaces 64;

- plate 65 has profiles in the form of a pair of recesses 66 formed on both end surfaces 67, as well as on one of the side surfaces;

- plate 68 has profiles in the form of a pair of protrusions 69 formed on both end surfaces 70, as well as on both side surfaces.

Holes 71 and channels 72 are arranged appropriately so that when the various plates abut end-to-end, elongated channels are formed allowing the said plates to be joined in two directions (i.e., in the X direction and in the Y direction), thereby forming a mosaic of the plates. As for the system 60, the slabs may be more square than elongated.

Figures 13 and 14 show a modular plate 10 ', which is similar to the modular plate 10 shown in Figs. 1 and 2. The plates are so similar that the similar features in Figs. 13 and 14 are indicated by similar reference numbers, but with a prime (') . The difference between the plate 10 'and the plate 10 is the difference in the profile of the plates along the edges, due to the profile of the channel 18' in the plate 10 'and the channel 18 in the plate 10. In Fig.13 and 14 it is clearly seen that the height of the profile along the longitudinal edges forming the channel 18 ', through which the longitudinal ducts 18b' pass, more.

On Fig shows a system 40 'of modular surfaces, which is an alternative to the system 40 of modular surfaces shown in Fig.9. Similar features in FIG. 15 are indicated by similar reference numerals, but with a dash (') or two dashes ("). The main difference between the systems shown in Figs. 9 and 15 is the second connecting means 42' and the corresponding alternative plate shape 10".

The plate 10 "has a channel 70 extending from an opening (not shown) in the end surface 13" into the body of the plate 10 ", in which the fixed metal anchor tip 71 is located. The plates 10" and 20 abut against each other, forming a joint 43 ' so that the channels 70 and 29 of each plate are joined and connected, forming an elongated channel 72, which extends between the two plates 10 "and 20. In the channel 72 is placed the second connecting means 42 'in the form of a flexible steel cable or a curved rod of fiberglass reinforced plastic (G FRP), which can go along an arcuate path.The first end of the cable / bent bar 42 'is screwed into the tip 71 to fix the cable in place, and the other end of the cable / bent bar 42' is equipped with fastening and tensioning means 45 'for fixing the plates 10 "and 20 in place and to give strength to the connection 43 '.

The joint 43 'is likewise profiled so that the end surfaces 13 ", 23 forming the recess 16" and the protrusion 26, respectively, are located at an angle of 5-10 ° relative to the vertical plane (indicated by the angle θ in the drawing). It is believed that by arranging the connection surfaces in a similar manner, the two plates 10 "and 20 are easier to align when laying the system 40 '.

Fig. 16 shows a modular plate 10 ″, which is similar to the modular plate 10 shown in FIG. 11. The plates are so similar that the similar features in FIG. 16 are denoted by similar reference numerals, but with three strokes (“″). The difference between the 10 ”″ plate and the 10 plate is the difference in the profile of the plates at the edges. FIG. 16 shows the 10 ″ ″ plate used as a plate for urban light rail systems. The rails / fastening element 50 ″ and the fasteners 51 ″ ″ are likewise installed on the plate 10 ″, but the upper surface 11 ″ ″ is modified and contains two raised external profiled sections 10 ″, that is, in a sectional view of the edge of the plate 10 "'' have an increased thickness compared to the center of the plate, which allows it to be laid on less deep sections of the road surface (not shown). In addition, on the upper surface 11 ″ there are two longitudinal recesses 102 ″, in which the rails 50 ″ and the fastener elements 51 ″ are placed. Due to this, the rails can actually be recessed in a 10 ”″ plate, which can be especially convenient when used for public transport rails passing along motorways or city streets. A 10 ″ modular plate can have many 17 ″ ″ passages for cables connected with a city transport system, as well as a 102 "recess with drainage outlets 103, 104, 105 for collecting, draining or draining water accumulating on or below the surface.

Claims (14)

1. A set of four plates connected in series, each of which is a removable modular plate for use in the construction industry, having an upper surface, an opposing lower surface thereof, and also a first and second opposing end surfaces located between the upper and lower surfaces along essentially perpendicular to them, and the plates are connected sequentially, and at each connection between two series-connected plates there is a channel from the hole in the top the surface of one plate to the hole in the end surface of this plate, and the second plate contains one or both channels:
(i) a channel extending from an opening in the upper surface of the plate to an opening in its end surface, wherein the channel in said first plate is aligned with the channel in the second plate to form an elongated channel passing through the ends of the two plates, which can be accessed through openings in the upper surface of each plate and in which the first fastening means for connecting the two plates together,
(ii) a channel extending into the second plate from an opening in its end surface, the channel in the first plate being aligned with the channel in the second plate to form an elongated channel passing through the ends of the two plates and ending inside the second plate, while accessing the elongated channel it is possible only from the side of the hole in the upper surface of the first mentioned plate and in this elongated channel a second fastening means for connecting the two plates together,
at the same time, in each connection between two series-connected plates, the profile of the end surface of one plate includes a protrusion, and the profile of the end surface of the other plate includes a corresponding recess, so that when connecting the butt plates with each other, a joint connection is formed, and when each fastener is removed means one of the two middle plates can be removed without destruction, while the other plates remain in place. 2. The kit according to claim 1, in which the channel in the second plate is aligned with the channel in the first plate with the formation of an elongated channel passing through the ends of the two plates and ending inside the second plate, while access to the elongated channel is possible only from the side of the hole in the upper surface the first plate and in this elongated channel, a second fastening means for connecting the two plates together. 3. The kit according to claim 1 or 2, in which the protrusion and the recess are shaped so that the end surface of each of them is at an angle of 45 ° or less to the vertical plane, preferably less than 25 °, more preferably less than 15 ° and in the range 5 to 10 °. 4. The kit according to claim 3, in which the profile of the end surface extends along the entire length of the end surface of each plate or partially extends along the length of the end surface of each plate. 5. The kit according to claim 3, in which a plate having two end surfaces with identical profiles, called a type A plate, is connected end-to-end with a second plate called a type B plate and having two end surfaces with identical profiles different from those of a type A plate but mating with them. 6. The kit according to claim 3, in which the plate, called a type C plate and having two end surfaces with different profiles, while the profile of one end surface is compatible with the profile of the other surface, is connected end to end with another type C plate. 7. The kit according to claim 1 or 2, in which the plate is pre-cast or pre-molded from a structural material, which is preferably fiber reinforced concrete, reinforced concrete or plastic mass. 8. The kit according to claim 1, in which both series-connected adjacent plates have a channel extending from an opening in their upper surfaces to an opening in their end surfaces, as well as a first fixing means connecting the two plates together, passing through an elongated channel with the possibility removal. 9. The kit according to claim 8, in which the first fastening means is removable and / or adjustable mounted in an elongated channel, preferably having an arcuate or parabolic shape, the first fastening means preferably being a curved tension cable or a flexible connecting rod and configured to tension and fastening at the upper surfaces of each of the two plates. 10. The kit according to claim 2, in which the second fastening means is removable and / or adjustable mounted in an elongated channel having preferably an arcuate, parabolic or linear shape, wherein the second fastening means is preferably a curved tension cable or a flexible connecting rod and anchored at the end of an elongated channel inside one plate and stretched at the top surface of another plate. 11. The set according to claim 1, which is a support for railway rails or rails of urban transport, while preferably the railway rails rest on the first surface of the modular plates, the rails of urban transport are recessed into the first surface of the modular plates, and many of the modular plates are connected using the first or second fastening means for forming a single support for railway rails or urban transport rails. 12. The kit of claim 11, wherein each plate has a raised portion that extends longitudinally downward from each side of the upper surface of each plate and which is optionally at least as high as or above a railway rail resting on each plate him. 13. A method of sequentially connecting four building boards, each of which has an upper surface, an opposite lower surface, a first and second opposite end surfaces located between the upper and lower surfaces substantially perpendicular to them, and a channel extending from an opening in the upper surface to the hole in the end surface, while the profile of the end surface of one plate includes a protrusion, and the profile of the end surface of another plate includes the corresponding angle hardening, so that when connecting the butt of two plates with each other, a joint connection is formed, while the plates are connected by:
- butt joint of two plates so that the protrusion of one plate is placed in the recess of the next plate and the channel in one plate is combined with the channel in another plate with the formation of an elongated channel passing through the ends of the two plates,
- removable installation of the first fixing means in an elongated channel so as to provide access to each end of the first fixing means through the upper surface of each plate,
repeating the steps until four plates are connected in series, the method comprising removing fastening means connecting one middle plate to series connected adjacent plates, and removing the middle plate without destroying the adjacent plates remaining in place. 14. A method of sequentially connecting four building boards, each of which has an upper surface, an opposite lower surface, first and second opposite surfaces facing each other, located between the upper and lower surfaces essentially perpendicular to them, while one of the plates has a channel passing from the hole in its upper surface to the hole in its end surface, and the adjacent plate has a channel extending from the hole in its end surface into the plate, with the profile of the end face rhnosti one plate includes a projection, and the profile surface of the other end plate includes a corresponding recess, so that a joint compound when connecting two plates end to end with each other, wherein the plates are connected by means of:
- butt joint of two plates in such a way that the protrusion of one plate is placed in the recess of the next plate and the channel in one plate is combined with the channel in the other plate with the formation of an elongated channel passing through the ends of the two plates;
- removable installation of the second fixing means in an elongated channel ending in another plate, so as to provide access to the second fixing means only through the upper surface of the first plate;
repeating the steps until four plates are connected in series, the method comprising removing fastening means connecting one middle plate to series connected adjacent plates, and removing the middle plate without destroying the adjacent plates remaining in place.

Images