NL1039661C2 - ROAD CONSTRUCTION. - Google Patents

Description

Road construction

BACKGROUND OF THE INVENTION

The invention relates to a road construction with a road surface, in particular paved road surface, and a roadside adjoining it.

5 Rainwater falling on a paved road flows down the sideways slope to the verge. It can penetrate the natural soil there, for example via water-permeable (poured in situ) concrete strips or via so-called growth blocks and grass concrete blocks that have been laid in the roadside to stabilize them. However, the rainwater running off takes contaminants present on the road surface during the run-off, so that these can also get into the soil and damage the groundwater and the soil material. Especially after a period of drought the load of the running water is high. These contaminants originate in particular from motor vehicles and include mineral oils and heavy metals such as lead. 15 Furthermore, crash barriers release zinc.

Dutch patent 1033155 provides a solution for this in the form of incorporating into the roadside construction a filtering material comprising broken shells, shell lime and / or zeolite. This granular material can be placed in the holes of the growth blocks placed in the roadside and / or in a layer directly below. The growth blocks are provided with profiled edges to engage with each other so that they stay securely in place. The growth blocks are placed on a geotextile that forms a filter cloth and in one embodiment directly supports the growth blocks, in another embodiment indirectly through the layer of granular material.

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SUMMARY OF THE INVENTION

An object of the invention is to provide a road construction of the type mentioned in the preamble with which it can be prevented in a far-reaching manner that mineral oils, PAHs and / or heavy metals can get into the soil and / or groundwater.

An object of the invention is to provide a road construction of the type mentioned in the preamble which prevents the penetration of mineral oils, PAHs and / or heavy metals into the soil and groundwater and which is easy to apply.

An object of the invention is to provide a road construction of the type mentioned in the preamble which prevents the penetration of mineral oils, PAHs and / or heavy metals into the soil and groundwater and which can be effective for a long period of time.

To achieve at least one of these objects, the invention provides a road construction with a road surface and a roadside adjoining it, wherein the roadside comprises an upper layer of air- and water-permeable concrete 10, below which concrete layer a layer of granular material is arranged, which layer granular material is applied to a first water-permeable filter cloth (woven or non-woven), which has mineral oil-absorbing and degrading properties.

Filter cloths for the first filter cloth, whether or not composed or multi-layered, are known per se and are commercially available (for example from Drain Products Europe BV, Amsterdam), inter alia under the name Permafilter ®. This filter cloth is a non-woven, needle punched geotextile with a surface-enlarging structure, made from a mixture of plastic fibers with hydrophilic and hydrophobic properties, respectively. The geotextile 20 of the filter cloth may comprise an upper layer of hydrophobic fibers and a lower layer of hydrophilic fibers. The retained hydrocarbons (mineral oils and PAHs) are broken down (biodegradation) by natural and / or added microorganisms, which may be present in the form of a biofilm supported by the hydrophilic material. Reference can also be made to the underlying patent application, WO 2006/021756.

After leaving the concrete layer, the water supplying the contaminants first comes into contact with the granular material and only then with the said first filter cloth. The layer of granular material thus provides a first cleaning stage in which at least some of the contaminants, in particular also other then mineral oils, such as heavy metals, can be collected and / or recorded and possibly broken down. A second cleaning step follows in the first filter cloth, focusing on the mineral oils. As a result, the first filter cloth will be less susceptible to clogging up, which may otherwise result in the water flowing sideways over the upper surface of that filter cloth and that water with the impurities contained therein end up in the soil next to the verge. Furthermore, due to the lower location of the first filter cloth, the chance of the filter cloth drying out in 3 periods that no rainwater falls falls considerably. Dehydration would have a strong negative influence on the functioning of that filter cloth, in particular on the microorganisms therein.

In a further development of the road construction according to the invention, the layer of granular material comprises olivine sand and broken shells, the broken shells forming the largest volume part (preferably about 1/3 to 2/3) of the granular material to form a load-bearing skeleton in the roadside. This allows heavy metals to be collected and recorded. The olivine sand can fix heavy metals such as lead and zinc and also copper in carbonate form by adsorption. The phosphates present in the rainwater can react with the iron and magnesium released from the olivine sand. The combination of olivine sand with shell material is advantageous because the lime of the shell material causes an increase in the pH value, which promotes the adsorption of heavy metals to olivine. In itself, the olivine may, due to weathering, cause some pH value increase, but that is for the long duration. The broken shells form a skeleton containing shell lime and, because of the cup-shaped spaces, specific to shells, offer space for the olivine sand, which is thereby presented to the water falling down through the shell skeleton. The cup-shaped spaces moreover increase the residence time of the water to be cleaned, which moves downwards as if in a messy cascade. The shell skeleton provides sufficient open spaces for both the downward moving water and for air needed for the proper functioning of the first filter cloth.

The crushed shells preferably originate from shells with a relatively strong curvature, in particular native North Sea shells such as half-shelled beach shell, large beach shell, cockle, nub, saw, venus shell and beach gaper.

In a further development, the granular material may further comprise shell powder or grit (ground shells), which preferably substantially passes through a sieve size of 63 µm. That material can also take place in the cup-shaped spaces of the shells.

The material of broken shells can have dimensions such that, in a state prior to incorporation in the work, they remain substantially at a screen size of 3 mm. The olivine sand has dimensions in the order of magnitude of sand, in particular the fraction that is commercially available and has dimensions such that it substantially passes through a screen size of 3 mm.

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With their small sizes, the olivine sand and the shell powder have a relatively large specific surface area and can therefore jointly have a high degree of effectiveness.

A suitable mixture of granular material with olive sand and 5 shells and shell powder is RONA® Biogrit, type RB (Cleansing Berm) available from Altena Groep, 't Harde.

The thickness of the layer of granular material can be in the range of about 1 to about 10 cm.

In a more extensive embodiment, the first filter cloth is applied to a bottom layer of granular material applied in situ, in particular with a thickness of one or more dm, preferably at most 3 dm. This creates a storage room under the roadside. If the bottom layer of granular material comprises olivine and shell material, the water can be further purified during storage.

A second, water-permeable filter cloth can be arranged between the concrete layer and the layer of granular material. For stability of the roadside construction, the second filter cloth can have a tensile strength in two perpendicular directions (in particular chain and weft) of at least 90 kN / m (meter edge length). Such a strength requirement can usually be imposed on geotextiles that are incorporated in a roadside construction. This filter cloth can be, for example, HP 90/90, available from Altena Groep, 't Harde.

In one embodiment the concrete layer is formed by concrete blocks provided with through holes, such as the said growth blocks. These preferably have an open space of more than 8% per m2 of surface covering. A suitable concrete block is the RONA® Verge dressing block (30% open space due to the holes, not permeable to water outside) available from Altena Groep, 't Harde. These concrete blocks are provided with profiled edges with receiving spaces and corresponding projections for mutual engagement. The holes promote the entry of air into the filter cloth. Partly in accordance with the teachings of NL patent 1033155, in order to promote cleaning, the holes can be at least partly filled with granular material comprising olivine and / or broken shells.

In an alternative or additional embodiment, the concrete of the concrete blocks themselves is air and water permeable, such as the RONA® Drain bonding block 35 (approximately 20% open space based on concrete surface and further through holes), available from Altena Groep, 't Harde.

In another alternative embodiment, the concrete layer is formed by a strip of water and air permeable concrete poured in situ.

The aspects and measures described in this description and claims of the application and / or shown in the drawings of this application can, where possible, also be applied separately from each other. These individual aspects can be the subject of split-off patent applications that are aimed at this. This applies in particular to the measures and aspects that are described per se in the subclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

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The invention will be elucidated on the basis of an exemplary embodiment shown in the accompanying drawings. Shown is:

Figure 1 shows a schematic section through an exemplary embodiment of a road construction according to the invention.

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DETAILED DESCRIPTION OF THE DRAWINGS

The road construction 1 is mainly shown in Figure 1 with regard to the roadside area. A paving construction 2 comprises an upper layer 3 of asphalt concrete, which is under slope 20, a foundation 4 of crushed stone below it and an earth track 5, surrounded / supplemented with soil / earth 6. Alongside the longitudinal edges 7 of the layers 3,4, a roadside paving 8 is placed. , composed of a series of concrete growth blocks or grass concrete blocks 9 with through holes 10.

The concrete blocks 9 can be RONA® Verge dressing blocks, aforementioned, with dimensions I x W x H of 40 x 40 x 12 and 20 x 40 x 12 [cm], associated with, in the direction of travel, successively two blocks 40 x 40 and a block 20 x 40, a block 40 x 40 and a block 20 x 40. At the longitudinal edge 7, they have a stretched edge, on mutually facing edges or protrusions and recesses, for hollow / mad fit. The blocks 9 can be made of concrete B45 or C45 / 55 and have vertically continuous holes 11 which define an open space of 8% or more. The aforementioned RONA® Verge dressing blocks can have an open space defined by the through vertical holes of approximately 30%.

The blocks can also be made of water-permeable concrete material. The aforementioned RONA®Drain dressing blocks can have an open space defined by the continuous vertical holes of approximately 30% of the surface of the entire concrete covering itself with an additional hollow space in the concrete material itself of approximately 20% (based on the concrete material surface adjacent to the through holes).

The blocks 9 are cold laid on (second) filter cloth 11, represented in this example in a thickened form, and for example formed by the aforementioned HP 90/90.

The filter cloth 11 rests on an applied layer 12 of granular material, for example a 7.5 cm thick layer, in this example of olivine, broken shell and shell powder material, mixed together, for example available under the name RONA® Biogrit, type RB, at Altena Groep, 't Harde. The material of layer 12 can also be provided in the holes 11 of the blocks 9. The layer 12 comprises, for example, for 1 volume part of shell powder (smaller than 63 µm) 2 volume parts of broken shells (larger than about 3 mm) and 1 volume part of olivine sand (smaller then about 3 mm).

The layer 12 is applied to a (first) filter cloth 13 laid on the ground / earth 6, which has been selected for collection and biodegradation of mineral oils and PAHs, such as Permafilter ®, as described above. The filter cloth 13 is laid up next to the layer 12 , with peripheral area 13a. The filter cloth 13 will not dry out quickly due to the contact with the ground 6 and / or the somewhat lower location if there is a drought period, so that it can properly retain its effect.

In an alternative embodiment, the excavation height is greater if a layer of water-storing foundation material 25 is provided under filter cloth 13, for example sand, coarse sand, with olivine sand and / or shell material.

As shown in Figure 1, precipitation P flows sideways in direction B to the verge, entrained with mineral oils, polycyclic aromatic hydrocarbons (PAHs) and heavy metals. The water 30 contaminated therewith flows / seeps in the direction C through the holes 10, whether or not filled with the material of layer 12, and after passing through filter cloth 11 ends up in the layer 12 granular material and seeps down there, direction D, where it comes into contact with the olivine sand and shell powder in the bowls of the broken shells. As a result, the water is effectively purified on, in particular, heavy metals such as zinc and lead, and also on copper. Through the shell lime of the shells, the pH is raised, possibly greater than 7, so that any acids present are neutralized. The broken shells 7 also release lime in the long term, but still essentially retain their cup shape, so that the above-mentioned cup action is also retained in the longer term. The bowls further provide a surface on which formed heavy metal carbonates can deposit.

The water then ends up in (first) filter cloth 13, where at least the mineral oils are collected and degraded by anaerobic manner by microorganisms. The water purified therefrom then enters the soil 6 (arrows E),

The above description is included to illustrate the operation of preferred embodiments of the invention, and not to limit the scope of the invention. Starting from the above explanation, many variations will be apparent to those skilled in the art that fall within the spirit and scope of the present invention.

1039661

Claims (14)

A road construction with a road surface and an adjacent shoulder, wherein the shoulder comprises an upper layer of air and water-permeable concrete, under which concrete layer a layer of granular material is applied, which layer of granular material is applied to a first, water-permeable filter cloth 5 (woven or non-woven), which has mineral oil-absorbing and degrading properties. Road construction as claimed in claim 1, wherein the layer of granular material comprises olivine and broken shells, the broken shells forming the largest volume part (preferably about 1/3 to 2/3 of the granular material to form a load-bearing skeleton in the roadside. The road construction of claim 2, wherein the layer of granular material further comprises shell powder. 4. Road construction as claimed in any of the foregoing claims, wherein the thickness of the layer of granular material is in the range of approximately 1 to approximately 10 cm. Road construction as claimed in any of the foregoing claims, wherein a second, water-permeable filter cloth is arranged between the concrete layer and the layer of granular material which preferably has a tensile strength in two perpendicular directions of at least approximately 90 kN / m. Road construction as claimed in any of the foregoing claims, wherein the first filter cloth is applied to a bottom layer of granular material, in particular with a thickness of one or more dm, preferably at most 3 dm. 7. Road construction according to claim 6, wherein the bottom layer of granular material comprises olivine and shell material. Road construction as claimed in any of the foregoing claims, wherein the concrete layer is composed of concrete blocks which are provided with through holes. 9. Road construction as claimed in claim 8, wherein the holes are at least partially filled with granular material which comprises olivine and / or broken shells. Road construction as claimed in claim 8 or 9, wherein the concrete of the concrete blocks itself is air and water permeable. 1039661 11. Road construction as claimed in claim 8, 9 or 10, wherein the concrete blocks are provided with profiled edges with receiving spaces and corresponding protrusions for mutual engagement. 12. Road construction as claimed in any of the claims 1-7, wherein the concrete layer is formed by a strip of water and air-permeable concrete poured in situ. 13. Road construction provided with one or more of the characterizing measures described in the attached description and / or shown in the attached drawings. 14. Method provided with one or more of the characterizing measures described in the attached description and / or shown in the attached drawings. -o-o-o-o-o-o-o-1039661