EP4033028A1

EP4033028A1 - Method for applying a top layer comprising onto a substrate

Info

Publication number: EP4033028A1
Application number: EP21153581.0A
Authority: EP
Inventors: Gerrit Gijsbertus Van Bochove; Martinus Johannes Adrianus Maria VAN SANTVOORT
Original assignee: Heijmans NV
Current assignee: Heijmans NV
Priority date: 2021-01-26
Filing date: 2021-01-26
Publication date: 2022-07-27
Also published as: EP4033029A1

Abstract

The present invention relates to a method for applying a top layer comprising bitumen and chippings onto a substrate. Furthermore, the present invention relates to a top layer comprising bitumen and chippings applied onto a substrate, and to a runway for aircraft which is provided with such a top layer.

Description

The present invention relates to a method for applying a top layer comprising bitumen and chippings onto a substrate. Furthermore, the present invention relates to a top layer comprising bitumen and chippings applied onto a substrate and to a runway for aircraft which is provided with such a top layer.
Top layers based on bitumen and chippings are known per se. A known example is the European patent EP 3 103 921 granted to the present applicant. The aforementioned European patent discloses a method for treating an asphalt construction with a liquid agent, in particular an asphalt construction which comprises a top layer of very porous asphalt concrete (ZOAB), in which a liquid binder is sprayed onto the top layer of the asphalt construction so that the liquid binder penetrates the top layer and forms a binder sealing layer in the top layer in an area at the location of the bottom side of the top layer.
Porous or open layers, such as ZOAB (Very Porous Asphalt Concrete), have been used as a top layer or upper layers of a road surface for years. The advantages thereof are known and provide significant advantages both for the road user and the environment. Rainwater is absorbed into the porous layer, so that no water splashes or sprays are created when it rains which could hamper the view of the road user. In addition, the porosity absorbs and reduces the driving noise of vehicles, so that there is less noise pollution as a result of road traffic in the vicinity of the road. A two-layer very porous asphalt concrete is a particular form of a porous road surface. In this case, two layers of porous asphalt on top of each other are used; the bottom layer is a coarse-grained layer with large pores which allows for satisfactory water flow in and through the layer and, on top thereof, a relatively thin fine-grained top layer is provided which is optimized to reduce traffic noise.
Runways for aircraft have particular requirements. Not only is it essential that the functional properties are retained, including skid resistance and texture depth, but the costs and the operational opportunities and risks have to be considered, including the availability of runways. By coating a runway with a so-called antiskid top layer, it becomes so skid-resistant that a landing aircraft can use the rapid-exit taxiway more often. In addition, the runway also remains skid-resistant in severe weather conditions due to the high drainage content, the reduced risk of hydroplaning and the intended surface condition 'dry when wet'. The skid-resistant top layer increases the directional stability and results in an aircraft having a shorter braking distance. As a result thereof, an aircraft can use the rapid-exit taxiway much more often. Thus, the runway is used more efficiently and more flight movements are possible. Even if an aircraft is relatively heavy, it is still able to land safely in adverse weather conditions.
European application EP 2 357 280 discloses a top layer for roads provided with a water-permeable road surface, consisting of a water-draining binder layer between a road bed and the road surface, wherein the road surface is composed of a porous supporting structure made of aggregate materials and bitumen or polymer bitumen as binder and a reaction resin surface with open pores which reinforces the porous supporting structure and is filled in with sand and/or coarse aggregate materials having different properties, wherein fibres, in particular cellulose fibres or rubber fibres, are added to the bitumen or polymer bitumen. In order to adjust the desired viscosity during processing, the reaction resin preferably has a filler content of 0 to 70 % by mass, preferably 0 to 10 % by mass, with barium sulphate, calcium carbonate, sheet silicates (such as talcum or mica), silica, aluminium oxide, diatomaceous earth, magnesium silicate or organic and inorganic fibres being mentioned as suitable fillers for the reaction resin.
American publication US 6 491 472 discloses a runway which is composed of a gradation layer and a surface layer which is paved onto the gradation layer and is composed of concrete or reinforced concrete.
It is an object of the present invention to provide a method for applying a top layer comprising bitumen and chippings (road metal, stone chippings) onto a substrate, wherein it is possible to obtain the desired physical properties of the top layer which has been applied in this way.
It is another object of the present invention to provide a method for applying a top layer comprising bitumen and chippings onto a substrate, wherein the top layer is suitable to be used for a runway.
It is yet another object of the present invention to provide a method for applying a top layer comprising bitumen and chippings onto a substrate, wherein the application may be performed under a wide range of weather conditions.
It is yet another object of the present invention to provide a method for applying a top layer comprising bitumen and chippings onto a substrate, wherein the resultant construction is immediately fully operational after opening.
The present invention thus relates to a method for applying a top layer comprising bitumen and chippings onto a substrate, which method comprises the following steps:

i) providing a composition comprising bitumen and chippings,
ii) heating the composition from i),
iii) applying the heated composition from ii) onto the substrate and compacting it,
iv) allowing the composition applied onto the substrate to cool,
v) water-jetting the cooled composition applied onto the substrate from iv).

By applying such a method, one or more objectives are achieved. The inventors have found that the water-jetting technique, i.e. step v), is a suitable technique for removing the bitumen skin in a controlled manner, that is up to the desired depth and to the desired degree, in which case the water pressure to be used and the speed of travel of the water jet play a part. It is desirable for these parameters to be adjustable and monitorable.
The inventors have thus found that it is desirable to remove a sufficient degree of the bitumen skin. This is understood to mean that some amount of bitumen may remain behind on the surface, but this remaining amount of bitumen has to be so little that no more bitumen film is formed. This is of particular importance because the bitumen becomes hot to such a degree that it becomes liquid due to the heat generated by the friction of the aircraft tyres and due to the cavities between the pebbles at the surface being opened further. The desired degree of removal of bitumen skin is, in particular, determined by the speed of travel and water pressure of the equipment which is used for water-jetting. The depth up to which the bitumen skin is removed is influenced by the angle of the water-jetting. A water pressure of 1500 bar and a speed of travel of 7 m¹ per minute/420 m¹ per hour may be mentioned as a suitable base setting for the equipment which is used for water-jetting. The indication "m¹" relates to "per linear metre". It is possible that one or more settings may be adjusted on the basis of a visual assessment and the measured texture depth after a first operation of the water-jetting has been performed. Thereafter, a second operation of the water-jetting may be desirable, for example using a water pressure of 1500 bar and a speed of travel of 400 m per hour, but other settings are also possible.
The invention is thus aimed in particular at an asphalt cover or top layer which is designed, after an aftertreatment, to function as the surface of a runway for aircraft. The asphalt cover or top layer obtained by the present invention is understood to be non-water-permeable, porous and draining, but with water-discharging and (limited) water-retaining properties due to the texture of the asphalt. In contrast to the very porous asphalt concrete explained previously in the present application, the cavities between the pebbles in the asphalt cover or top layer obtained by the present method are not connected to each other. The water-draining capacity of the asphalt cover or top layer obtained by the present method is influenced by the cross-sectional profile of the runway according to a specific standard (in particular EASA, European Union Aviation Safety Agency) and additional requirements.
In a particular embodiment of the invention, an additional step vi) is performed after water-jetting the cooled composition applied onto the substrate (step v)), i.e. a step vi) in which the texture depth of the top layer applied in this manner is measured. The texture depth provides information about the water-retaining capacity of the pavement surface. The texture depth is an indication of the skid resistance of the top layer when it rains.
In one embodiment of the invention, the texture depth measured in step vi) is compared to a reference value, with the water-jetting of the cooled composition applied onto the substrate being repeated (step v)) if the texture depth measured in step vi) is less than the reference value. It is desirable for the water-jetting of the cooled composition applied onto the substrate (step v)) to be terminated the moment the texture depth measured in step vi) is equal to or larger than the reference value.
In one embodiment of the invention, it is desirable for the composition applied onto the substrate to be cooled down to a temperature of at most 20°C before water-jetting of the cooled composition applied onto the substrate (step v)) is performed. The present inventors have found that after the composition, also referred to as the cover layer, has been applied and compacted, the entirety has to cool down and the bitumen of the composition has to harden. This is also referred to as "setting" which involves a certain waiting time. If the water-jetting (step v)) is started too soon, the mastic of the composition is still too soft, as a result of which the water-jetting will not be effective or may even be counterproductive, because the bitumen layer on the surface is not removed, but is pushed into the cavities between the pebbles of the composition. This does not result in the desired degree of skid resistance.
In one embodiment of the invention, the time between allowing the compacted composition which has been applied onto the substrate (step iii)) to cool down to a temperature of at most 20°C and subsequently water-jetting the composition applied onto the substrate and cooled in this way (step v)) is at least 36 hours, in particular at least 42 hours, preferably at least 48 hours.
According to an embodiment of the invention, the ASFT skid resistance of the cooled composition which has been applied onto the substrate is measured both before and after the water-jetting of the composition applied onto the substrate and cooled in this way (step v)).
According to an embodiment of the invention, the composition mentioned in step i) furthermore comprises one or more constituents selected from the group comprising sand, polymers and limestone. The term polymers is also understood to include fibres, in particular natural and synthetic fibres.
According to an embodiment of the invention, the heating of the composition from i) also comprises mixing the constituents homogenously, so that a composition in which the constituents have been mixed homogenously is used in step iii) for applying the heated composition from ii) onto the substrate and compacting it.
It is therefore desirable for the texture depth to be measured before and after water-jetting, for example using the sand patch method and/or a digital texture depth meter. Measuring the texture depth before water-jetting indicates the starting situation and the measurement results after water-jetting are used to determine if the surface meets the requirements for the texture depth or if additional water-jetting is required to get the texture depth to the desired level. It is preferred to measure the texture depth using a digital texture depth meter, as will be explained below.
The present inventors have found that the surface of the applied top layer does not yet have the intended texture depth after applying and compacting, i.e. step iii). Therefore, an additional step, that is to say step v), is required to remove the bitumen skin from the surface by means of water-jetting. Any bitumen skin which is still present may, for example, have an adverse effect on the skid resistance when heat is generated, in particular due to the tyres of aircraft during landing or take-off, or extreme heat during warm periods, such as the summer.
The sand patch method (RAW test 76) is a method for measuring the texture depth. One protocol for determining the texture depth is as follows. The texture depth is tested on a dry, tack-free substrate which has been brushed clean beforehand. Fill a cylinder with a volume of 23,800 (± 100) mm³ and an internal diameter of 20 (± 1) mm entirely with fire-dried round-grain sand with a grain size of between 0.125 and 0.250 mm. Skim off any excess of sand by using a flat slat. Then pour the measured amount of sand onto the spot on the pavement surface where the measurement will take place. If necessary, take precautions during the trial run to prevent the sand from being blow away. Distribute the sand over the surface using a flat brass disc having a diameter of 65 (± 2) mm and coated with a hard rubber disc with a thickness of 1.5 (± 0,5) mm on the bottom side and provided with a handle on the top side. Distribute the sand by rotating the brass disc which should in this case be held horizontally. Rubbing should result in a circular sand patch, with the depths in the surface being filled up to the highest points. Then measure, to an accuracy of 1 mm, the diameter of the sand patch in four directions at an angle of 45 degrees with respect to each other. Calculate the texture depth, to an accuracy of 0.1 mm, using the formula:
TD= 484800 / (D1+D2+D3+D4)², in which: TD is the texture depth in mm, Di is the measured diameter of the sand patch in mm. The texture depth is determined in at least 5 different spots.
Another method for determining the texture depth comprises using a digital meter. A digital meter uses a laser sensor to measure the depth at one location. The sensor has a specific diameter, for example 150 millimetres, with a circle having a certain circumference being measured, for example 400 millimetres. The associated circle is measured in its entirety, following which the mean value is determined for the average.
The digital meter has some advantages over the sand patch method, namely i) the speed of the measurement, ii) the objectivity of the measurement, iii) less susceptible to weather conditions (wind and water) and, iv) the digital meter has a GPS signal by means of which the measurements can be visualised later by means of a GIS environment and can thus be stored in a database. The rotating high-resolution laser of the laser-controlled texture depth meter scans the road surface at a high resolution. A commercially available laser-controlled texture depth meter is ELAtextur (brand name) which is used to determine the macrotexture of road surfaces according to the directives of EN ISO 13473-1 and ASTM E1845-09.
It is possible to perform the texture depth measurements after the water-jetting according to the so-called Hammersley method. The Hammersley method uses a semi-arbitrary sequence which is repeated every 500x60 metres. Every 500x60 metres across the length of a substrate, 180 measurements are performed in order to arrive at a margin of error of less than 1 percent. If this is done, for example, across a length of a substrate of 3800 metres, the total number of measurements is 1368.
It is also desirable to measure the ASFT skid resistance before and after water-jetting. The results before the water-jetting give an insight into the initial skid resistance, that is to say the initial situation in which the bitumen skin is still present. The skid resistance after water-jetting gives an insight into whether the skid resistance of the surface of the top layer meets the specified requirements, i.e. ASFT ≥ 0.70, preferably ASFT ≥ 0.74. A method for measuring ASFT is known, for example, from American publication US 2014 202230 , which document, in particular the measuring method described therein, is deemed to be incorporated herein by reference.
The present invention also relates to a top layer comprising bitumen and chippings, which top layer is applied onto a substrate, wherein the top layer has a texture depth ≥10 mm, in particular ≥1.1 mm, preferably ≥ 1.2 mm, particularly preferably >= 1.3 mm. In this case, the texture depth is measured according to a sand patch method which is described in more detail in the present description and/or by means of a digital texture depth meter, preferably a digital texture depth meter.
A top layer according to the present invention is characterized by a negative texture, to be understood as hollow spaces in the surface and hollow spaces which extend downwards in the surface. The top layers which are currently commercially available and used are described as top layers having a positive texture, to be understood as gravel which protrudes from the surface. The present texture which, in the context of the invention, is to be seen as a negative texture, ensures that the surface of the top layer is less susceptible to decreasing skid resistance and texture depth during its operational life.
The present invention also relates to a runway for aircraft which is provided with a top layer obtained according to a method as described above or which is provided with a top layer as described above.
Thus, the present invention relates to a runway for aircraft in which an ASFT skid resistance for the runway applies which is at least greater than 0.70, preferably greater than 0.74.
The present invention is explained in more detail by means of an example, but it should be noted that the invention is by no means limited to such an example.

Example 1

A composition consisting of 11 % by weight of fine sand, 76 % by weight of Quarz Grauwacke 8/11, 7 % by weight of modified bitumen, 0.5 % by weight of polyacrylonitrile polymer, 5.5 % by weight of average limestone filler was heated, applied onto a solid substrate and compacted using an asphalt spreader. Compacting usually takes place by means of a roller. After a substrate had been applied, the asphalt layer which had thus been applied was first cooled down to at least 20°C. Furthermore, the asphalt layer had to set for at least 48 hours. In the period between 24 and 48 hours, the temperature on the surface of the asphalt was measured at least twice. During this 48-hour period, the asphalt temperature was found to be below 20°C, so that the water-jetting was started after the 48-hour period had passed, with a water pressure of 1500 bar and a speed of travel of 7 m¹ per minute/420 m¹ per hour being used. After the water-jetting, the texture depth was found to have a mean value of 1.4 mm. The ASFT skid resistance of the asphalt layer had a value of 0.8. The texture depth was measured using the commercially available laser-controlled texture depth meter ELAtextur (brand name) according to the directives of EN ISO 13473-1 and ASTM E1845-09.

Example 2

The same composition and equipment as in Example 1 were used, except that the water-jetting was performed in two separate steps. After a first stage of water-jetting, the texture depth was 1.27 mm, which value was increased, after a second stage of water-jetting, to a mean value of 1.5 mm. The texture depth was measured using a commercially available laser-controlled texture depth meter ELAtextur (brand name) according to the directives of EN ISO 13473-1 and ASTM E1845-09.
It should be noted that if, in the aforementioned period of 48 hours, the asphalt temperature does not drop below 20°C, water-jetting has to be delayed until measurements show that the temperature of the asphalt has dropped below 20°C. Only at that moment may water-jetting be performed. If the temperature of the asphalt has not dropped below 20°C after 2 x 48 hours, the asphalt pavement has to be cooled down with water to a temperature below 20°C just before water-jetting.

Claims

Method for applying a top layer comprising bitumen and chippings onto a substrate, comprising the following steps:
i) providing a composition comprising bitumen and chippings,

ii) heating the composition from i),

iii) applying the heated composition from ii) onto the substrate and compacting it,

iv) allowing the composition applied onto the substrate to cool,

v) water-jetting the cooled composition applied onto the substrate from iv).
Method according to Claim 1, characterized in that an additional step vi) is performed after step v), that is to say:
vi) measuring the texture depth of the top layer applied in this manner.
Method according to Claim 2, characterized in that the texture depth measured in step vi) is compared to a reference value, wherein step v) is repeated if the texture depth measured in step vi) is less than the reference value, wherein step v) is terminated if the texture depth measured in step vi) is equal to or greater than the reference value.
Method according to one or more of the preceding claims, characterized in that the composition applied onto the substrate is cooled down to a temperature of less than 20°C before step v) is performed.
Method according to one or more of the preceding claims, characterized in that, before step v) is performed, the time between step iii) and step v) is at least 36 hours, in particular at least 42 hours, preferably at least 48 hours.
Method according to one or more of the preceding claims, characterized in that the ASFT skid resistance of the cooled composition applied onto the substrate is measured before step v) is performed.
Method according to one or more of the preceding claims, characterized in that the ASFT skid resistance of the composition subjected to water-jetting and applied onto the substrate is measured after step v) has been performed.
Method according to one or more of the preceding claims, characterized in that the composition mentioned in step i) furthermore comprises one or more constituents selected from the group comprising sand, polymers and limestone.
Top layer comprising bitumen and chippings applied onto a substrate, wherein the top layer has a texture depth ≥10 mm, in particular ≥1.1 mm, preferably ≥ 1.2 mm, particularly preferably >= 1.3 mm, wherein the texture depth is measured according to the sand patch method mentioned in the description and/or by means of a digital texture depth meter.
Runway for aircraft provided with a top layer obtained according to a method as described in one or more of Claims 1-8, or provided with a top layer according to Claim 9.
Runway for aircraft according to Claim 10, characterized in that the ASFT skid resistance is at least greater than 0.70, preferably greater than 0.74, wherein the ASFT skid resistance is measured according to the measuring method mentioned in the description.