SK7021Y1 - Reinforced ditch or influent stream - Google Patents

Abstract

Reinforced ditch or gutter trough is formed by a system of pre-cast concrete or reinforced concrete fittings. Subject-matter of the utility model is that the fittings (1) are provided with two arms (2) arranged in V-shape, whereby the arms (2) form side walls of the ditch or gutter.

Description

The technical solution relates to the field of construction, in particular reinforced ditches or springs, e.g. ditches, drainage ditches, etc., which drain irregular amounts of water depending on rainfall or spring water.

BACKGROUND OF THE INVENTION

Road trenches or drainage ditches, e.g. between land, fields, etc. they prevent swamp formation and divert tidal or spring water when heating snow into larger troughs. Irregular filling of water and especially its steep slope burden the trough and cause its bleaching, clogging and damage. As a result, the water cannot continuously flow out and spills out of the trough, so that the soil in the surroundings is drenched or local floods occur. Road trenches risk undermining roads and seriously damaging them, posing serious safety risks and traffic complications.

In order to avoid these phenomena, the troughs of road ditches, drainage ditches and other springs are being strengthened. Normally, the bottom of the ditch is reinforced by stacked flat stones, embedded in concrete. The sides of the ditch are also reinforced with stacked stones, which do not necessarily have to be poured with concrete. The disadvantage of this solution is its laboriousness and time demands. In the worst-case areas, it is difficult to transport both trenches and trenches. Concrete pouring is also difficult in places with a steep gradient, which limits the use of this solution.

Another solution is gutter fittings, which stack up the bottom of the ditch or troughs, so that the water has the ability to drain quickly, the dirt does not catch on the grass, which grows at the bottom of the ditch, so there is no clogging and water spill around. The disadvantage of this solution is that these fittings cannot be anchored sufficiently firmly to the bottom of the trough, so that the steep water quickly undermines and entrains them in places with a larger gradient. It is therefore necessary to constantly maintain these channels, which is very expensive.

In areas with a steep gradient, the strengthening of troughs, ditches or springs is solved by cascading geogrids, filled with gravel crumbs or soil. Grass can overgrow the geogrid, which makes the gravel or soil partially solidified. Nonetheless, gravel and soil from geogrids are bleached, thereby degrading the bed.

The disadvantages of existing solutions are mainly that they do not sufficiently respect the characteristics of the natural environment where they are planted and therefore are easily susceptible to damage, which entails increased maintenance costs, which are particularly difficult in the spring months because the soil is soaked after snow heating and maintenance material is difficult to transport.

The essence of the technical solution

This task is solved by providing a reinforced ditch or trough of a jar according to this technical solution. The essence of the invention is that the fittings are provided with two V-shaped arms, the arms forming the side walls of the ditch or the spring. The shape of the ditch or jar does not need to be specially modified. The fitting adheres to the walls of the ditch or spring thanks to its V-shape.

In a preferred embodiment, the top V of the arms is formed by a foot with a base surface for mounting on the bottom of a ditch or spring. The foot is embedded in a concrete bed which is formed at the bottom of the ditch or the spring, thereby anchoring the fitting and preventing it from sliding along the bottom of the ditch.

The fittings are arranged in a ditch or step in a staircase corresponding to the gradient of the ditch or step. In this embodiment, the fittings are supported one on the other, so that they are anchored twice, both in the concrete bed and on the other, which is particularly advantageous in terrain with steep slopes. In the case of heavy rains, a large amount of water flows through the ditch, which could otherwise collapse the system of fittings in another way of paving the bottom of the ditch or spring.

In the case of steep gradients, it is furthermore advantageous that the fittings are connected to one another by anchors, which pass through the mounting and connecting holes through the fittings arms. The anchor is preferably formed by a steel wire or rope and is anchored at its anchoring end in the concrete bed of the above-mentioned fitting. The anchor extending through the mounting and connection aperture located at the top of the arm also extends through the mounting and connection aperture located at the bottom of the arm of the above-mounted fitting. The anchoring end is knuckled behind the above fitting and connects the two fittings together. However, it is possible to extend the anchor so that its anchoring end passes through the fitting and remains anchored in the concrete bed of another higher fitting. The system of fittings placed in the ditch or trough of the spring is thus reinforced and secured against damage due to weathering, in particular flowing water and alternating between positive and negative temperatures.

SK 7021 Υ1

In a preferred embodiment, the ditch or trough is terminated with a mouthpiece adjacent to the last fitting. The inlet forms a solid support for the system of fittings forming the bottom of the ditch or spring and effectively prevents the fittings from slipping due to the slope slope as well as the impact of rain water or melting snow water in the spring.

It is preferred that the arms of the at least one fitting in the upper portions are provided with opposing shoulder for receiving the footbridge. Thus, if necessary, it is possible to easily form a footbridge through a ditch by simply placing a plate whose length corresponds to the spacing of the fitting arms. The pedestrian anti-displacement plate is effectively provided by the shoulder in the upper parts of the arms, and it is advantageous that the guide shoulder is formed by opposing half-grooves forming a prismatic guide, which is a very simple solution for producing the fitting as well as pedestrian boards. A prismatic fit prevents the spreader from spontaneously raising in the case of high water and the spreader.

It is also advantageous that a drainage opening is formed in at least one arm of the at least one fitting. Water from slopes or ditches can thus leak into the system of fittings and be discharged to the inlet or ditch. The drainage holes prevent the ditches or the spring from waterlogging the slopes below the fitting assembly, which could cause damage to it, eg. grinding of the concrete bed and upset of the adjacent fittings. In a preferred embodiment, the drainage openings are formed in adjacent fittings each on the opposite side of the trench or spring. More openings could make the fitting more fragile and more susceptible to damage.

It is further preferred that the foot of the at least one fitting is housed in a concrete bed so that the fitting system is anchored in the ditch.

Finally, it is preferred that the arms of the at least one fitting are housed in a concrete bed. This solution can be applied especially in heavily waterlogged terrain, where the bottom of the ditch or spring cannot be dried and it would not be possible to ensure sufficient hardening of the concrete bed or access of the technique.

The advantages of the reinforced ditch or trough are that it consists of a set of prefabricated fittings which deny each other to form a solid anchorage. Thus, the fittings are not rinsed out of their beds, which makes the maintenance of trenches or springs so much easier and cheaper.

BRIEF DESCRIPTION OF THE DRAWINGS

The technical solution will be explained in more detail by means of the drawings, in which FIG. 1 shows a side section of the horizontally arranged fittings in the down-stream ditch, FIG. in a slightly sloping terrain with inlet, Figure 5 side section of stair-shaped fittings with inlet, Figure 6 perspective view of stepped stair-shaped fittings with inlet, Figure 7 side section of stair-shaped fittings in steep incline and anchors, Figure 8 9 shows a perspective view of the ladder fittings; FIG. 10 shows a side section of the ladder fittings; and FIG. 11 shows a cross-section of the ladder fittings and the arms embedded in a concrete bed.

EXAMPLES

It is to be understood that the described and illustrated specific examples of embodiments of the invention are presented by way of illustration, not as a limitation of the embodiments of the invention to the aforementioned cases. Those skilled in the art will find or will be able to find, using routine experimentation, more or less equivalents to specific embodiments of the invention specifically described herein. These equivalents will also be included within the scope of the following protection claims.

A simple concrete bed 9 made of plain concrete is formed at the bottom of the reclamation ditch. The entire V-shaped prefabricated fittings 1 can be directly mounted on the bed 9. The fittings 1 are formed by arms 2 and a foot.

3. Prefabricated fittings 1 are concrete or reinforced concrete. In the upper parts of the arms 2, guide shoulders 4 are formed opposite to each other, forming approximately L-shaped rebates. Drain holes 7 are provided in the arms 2 to drain water from the sides of the ditch into the fitting 1 and thereby prevent erosion of the ditch or trough. At least one drainage hole 7 is provided in each fitting 1. Several drainage holes may be provided in the fitting 1, e.g. one in each arm 2. The location of the drainage holes 7 in the fittings 1 seated in the ditch is diagonal. The drainage holes 7 are formed horizontally towards the ditch slope. The arms 2 are further provided with mounting and connecting holes 11 for fastening the fittings 1 to each other. Anchors 12 made as steel bars or ropes, whose anchoring ends are designed as hooks, extend through the mounting holes 11. The anchors 12 can be used to reinforce the trough of a ditch or spring, the slope of which is very steep. In this case, it is not possible to use the pressure of the above-mentioned fitting

Thus, the fittings 1 are reinforced with each other by anchors 12 connecting the fittings 1 to each other.

In the first exemplary embodiment shown in Figure 1, the fitting reinforced with fittings 1 opens into another down-stream trench 8. In this embodiment, only the last fitting 1 leading to the down-stream trench 8 is supported by the concrete bed 9.

Figures 2 and 3 show a second embodiment of the invention when the fittings 1 are stairly arranged and are connected to a down-stream trench 8. Each of the fittings J is housed in its own concrete bed 9. The concrete bed 9 of the last two fittings 1 opening into the down-stream ditch 8 is embedded deepest as it anchors the entire descending set of fittings 1.

A third embodiment is shown in Figures 4 to 6. The bottom of the ditch is filled with a concrete bed 9 and the base fitting 1 is supported by the upper inlet W. Further fittings 1 are stacked one after the other so that each subsequent fitting 1 is positioned higher than the previous The fitting 1 thus rests against one another, thus preventing them from being plucked and torn off in the case of large water.

Figures 7 and 8 show the anchoring of the fittings 1 in a ditch with a steep slope. The fittings 1 are stairly embedded in the concrete bed 9. Anchors 12 pass through the mounting and connecting holes 11. fittings

1. The anchor 12 extending through the mounting and connecting hole 11 located in the upper part of the arms 2 of the below-shaped fitting 1 passes through its anchoring end 15 through the mounting hole 11 arranged in the lower part of the arm 2 of the higher bearing fitting 1. reinforced against erosion.

The concrete bed 9 need not be formed only on the bottom of the ditch. It can also be applied to the sides of the ditch. Such a solution is particularly advantageous in cases where the trench bottom is permanently standing water or an unbearable subsoil and it would be difficult and lengthy to reinforce or drain the standing water. This embodiment is shown in Figure 11. In this case, the shoe 3 of the fitting 1 does not reach the bottom of the trench. The fitting 1 is anchored on the sides of the trench by its arms 2.

The shaped pieces 1 may have shoulder 4 on the upper edge of the arms 2 for receiving the footbridge 5. The shoulder pieces 4 have an L-shaped open rebate inclined to the vertical axis of the shaped piece 1 so as to form a prismatic guide. The steps 4 for supporting the footbridge 5 may also be formed as a recess in the upper edge of the arms 2 and the footbridge 5 may be formed as a flat or slightly arched plate embedded in the recess and anchored by an overlap 13 extending over the edge of the arms 2 as shown in Figure 10.

Industrial usability

The reinforced ditch or trough according to the technical solution can be used in mountain areas and wherever the drainage ditches and troughs of permanent or temporary springs have a larger gradient and there is a danger of the existing strengthening systems being washed out. On the other hand, the second way of use is in places with a small slope of amelioration ditches, where a small longitudinal slope and overgrowth of the troughs make it impossible to efficiently drain the water.

Claims (11)

A reinforced ditch or trough formed by a set of prefabricated concrete or reinforced concrete fittings, characterized in that the fittings (1) are provided with two V-shaped arms (2), the arms (2) forming the side walls of the ditch or the trough. A reinforced ditch or trough according to claim 1, characterized in that the apex V formed by the arms (2) is formed by a foot (3) with a base surface for mounting on the bottom (14) of the ditch or trough. A reinforced ditch or trough according to claim 1 and 2, characterized in that the fittings (1) are arranged in a staircase in the ditch or the staircase in a gradient corresponding to the slope of the ditch or the ditch. Reinforced ditch or trough according to at least one of claims 1 to 3, characterized in that the fittings (1) are connected to one another by anchors (12) which pass through the mounting and connecting holes (11) through the arms (2) of the fittings (2). A reinforced ditch or trough according to claims 1 to 3, characterized in that it is terminated by an inlet (10) adjoining the last fitting (1). SK 7021 Υ1 Reinforced ditch or trough according to at least one of Claims 1 to 5, characterized in that the arms (2) of the at least one fitting (1) are provided in opposite parts with opposing shoulder (4) for receiving the footbridge (5). Reinforced ditch or trough according to at least one of Claims 1 to 6, characterized in that the guide shoulder (4) is designed as an open L-shaped rebate. Reinforced ditch or trough according to at least one of claims 1 to 7, characterized in that a drainage opening (7) is formed in at least one arm (2) of the at least one fitting (1). Reinforced ditch or trough according to claim 8, characterized in that the drainage holes (7) are formed in adjacent fittings (1) on the opposite side of the ditch or trough. A reinforced ditch or trough according to at least one of claims 1 to 9, characterized in that the foot (3) of the at least one shaped piece (1) is embedded in the concrete bed (9). A reinforced ditch or trough according to at least one of claims 1 to 10, characterized in that the arms (2) of the at least one shaped piece (1) are mounted in a concrete bed (9).