[0001] The invention relates to a method for recycling asphalt, used asphalt being broken
into pieces which in the main are smaller than 5 cm, the said pieces being separated
into at least two fractions, if necessary.
[0002] It is known, when recycling asphalt, to break asphalt into pieces and, with heating,
mixing it with fresh raw materials. It is likewise known to reuse used asphalt without
employing freshly added raw materials. The problem is then often encountered that,
because of an unfavourable composition of the asphalt to be reused, the physical properties
of the recycled asphalt, particularly with respect to the stiffness modulus and the
resistance to deformation, leave something to be desired.
[0003] Moreover the known methods for the warm processing of tar-containing asphalt, for
example when this is applied to a road surface, and therefore also the reprocessing
of warm tar-containing asphalt give rise to a relatively high emission of polycyclic
aromatic compounds. Consequently, tar-containing asphalt is generally cold-processed
into low-value materials. Subsequent recycling of the said low-value product by means
of the known techniques is not readily possible in these cases.
[0004] The object of the present invention is to provide a method which avoids these problems.
[0005] To this end, the method according to the invention is characterized in that the fractions
of old asphalt are separately heated in respective proportioning units, whereupon
the fractions, in a weight ratio changed with respect to the original asphalt, are
combined in a mixing apparatus. Preferably the fractions are mixed, in the mixing
apparatus, with a binder. The remixing of the various fractions of the asphalt to
be recycled, which has been broken into pieces, allows for a considerable improvement
in the properties in terms of stability, processibility and durability of the recycled
product. To obtain high-quality recycled asphalt, the lumps of asphalt are formed
into a first fraction containing particles having a size of between about 4 and 50
millimetres, and a second fraction containing particles which are smaller than about
4 millimetres. The different fractions contain different gradations of minerals. The
fine fraction contains virtually exclusively sand, filler and bitumen. The coarser
fractions contain relatively large amounts of gravel or stone. The fine fraction contains
more binder, such as bitumen, than the coarse fraction. Remixing the fractions together
in a weight ratio to be chosen between 20/80 and 80/20 produces a very advantageous
product in terms of stability, density and degree of filling.
[0006] Preferably, no more than 3% of bitumen are added to the fractions formed. It was
found that as a result of the different fractions being separated and being back-mixed
at the changed weight ratios, relatively little bitumen (in the form of an emulsion
or foamed bitumen), from a process point of view, need be added to obtain a sufficiently
processible mixture which can be readily conveyed and mixed within the system.
[0007] Preferably, during recycling, heating takes place by the virtually exclusive supply
of steam to the proportioning units, in which the filling level and temperature are
such that all of the steam condenses. The proportioning units are constructed in such
a way and the steam injection takes place in such a way that no steam leaves the proportioning
unit. This is advantageous, in particular, in recycling tar-containing asphalt and
results in the emission of polycyclic aromatic compounds being reduced to an acceptable
level without special provisions such as filters and afterburners being necessary.
Heating of the asphalt to be recycled, which involves complete or virtually complete
condensation of the steam, can likewise be employed advantageously if the asphalt
to be reused is not separated in terms of weight fractions. Tar-containing asphalt
which, during recycling, has been heated in the abovementioned manner can be applied,
for example, to a road surface without significant emission of noxious substances
such as naphthalene. It is assumed that as a result of the condensation of steam the
polycyclic aromatic compounds in particular are dissolved in the condensate and are
therefore unable, while the asphalt is being processed, to escape into the atmosphere
as vapour.
[0008] Preferably, the temperature in the proportioning units is between 80° and 100°C,
preferably between 90 and 95°C, which is relatively high compared with heating to
about 65°C via, for example, a known system such as the "turbo-steam unit", in which
fuel such as oil is burnt under water in a high-pressure vessel. In the case of the
known heating method the gas mixture of steam and combustion gases is injected in
its entirety into the proportioning hoppers. The energy efficiency of this known process
is relatively low, since large amounts of steam disappear into the air, entraining
polycyclic aromatic compounds. If steam is employed virtually exclusively for heating,
using the method according to the invention, the temperature rises to 90 to 95°C.
This is very important in order to convert even pure, previously used old asphalt
into a processible compound without, for example, bitumen emulsion being added. Because
emulsion is present in limited amounts, a lubricating effect does not occur, so that
this high temperature is necessary to make it possible to process and to densify the
asphalt to be recycled. Moreover, in the case of the novel method, virtually all the
steam condenses in the proportioning units, so that the emission from the proportioning
units is virtually nil.
[0009] Preferably asphalt is recycled with the addition of minimal amounts of other and
fresh raw materials. If the addition of extra material is necessary, this material
is first heated in the proportioning unit, before the heated fractions of old asphalt
are fed into the mixing apparatus, and is then, together with a binder, fed to the
mixing apparatus. This mixture, which for example comprises hardcore and/or sand and
bitumen, is then homogenized. The homogenized mixture is then admixed with the first
and the second fraction of the old asphalt in the correct weight ratios. The previous
homogenization of the unused material ensures that the added emulsion comes into effective
contact with the fresh materials, very homogeneous and beneficial mixing being obtained
as a result.
[0010] It is also possible to add cement or lime to the asphalt fractions in the mixing
apparatus. The stiffening rate of the recycled asphalt and the ultimate stiffness
can thus be increased.
[0011] A few embodiments of the method according to the invention will be explained in more
detail with reference to the accompanying drawing, in which:
Figure 1 shows a schematic representation of a method according to the invention,
in which the weight fractions of the asphalt to be recycled are formed by screening,
and
Figure 2 shows a method in which the weight fractions are formed by various ground
processes.
[0012] Figure 1 schematically shows how used asphalt is crushed, in a crushing apparatus
1, into fragments having a size of at most 5 centimetres. Via a conveyor these fragments
are fed to a screening apparatus 3, two fractions being formed in the process.
[0013] Alternatively it is possible, however, to obtain two fractions of asphalt particles
of different sizes by employing various processes for grinding used asphalt, followed
by screening. In this case the maximum size of the particles, about 5 cm, can essentially
be formed by, for example, the old asphalt being broken up by rotary cutting, after
which the cut asphalt is screened. When old asphalt is broken up into so-called clods,
these clods need to be broken into particles smaller than 5 cm with the aid, for example,
of a breaker, followed by screening. The separated fractions obtained from the various
crushing processes and/or screening processes, which may be at a distance from the
proportioning units 5 and 7, are then separately fed or conveyed to the proportioning
units 5 and 7.
[0014] The fraction of particles having a size smaller than 4 millimetres is then fed to
the proportioning units 5, 7 by means of, for example, a shovel. The fraction of larger
particles having a size of between 4 and 50 millimetres, which remains behind on the
screening apparatus 3, is fed to a proportioning unit 7, the weight fraction of the
small particles fed to the proportioning unit 5 being between 10 and 90% of the total
weight of the broken-up asphalt fed to the screening apparatus 3.
[0015] Via a steam source 9, steam is introduced into the centre of the proportioning units
5, 7, at a temperature of about 110° or higher. The steam is introduced at a point
at the bottom of the proportioning units 5 and 7. At the bottom of the proportioning
units 5 and 7, whose bottom end is funnel shaped, the molten asphalt forms a plug
through which the steam introduced at the bottom is passed upwards, heating the cold
asphalt. At regular intervals, such as every 2 to 3 min, heated material is drawn
off from the proportioning units 5, 7 via closing devices 11, 13, for example from
2 to 4 metric tonnes of asphalt being discharged, and the proportioning units are
replenished with fresh, cold material. If the shut-off valves 11, 13 are dimensioned
correctly, the shut-off valves, for example, being designed to have different respective
through-flow diameters or having a different open-close cycle, different weight ratios
of materials are fed to a mixing apparatus 15 from the proportioning units 5 and 7.
The purpose of determining the weight fractions and feeding to the mixing apparatus
is preferably served by a belt weigher, as shown in Figure 2. The mixing apparatus
15 is supplied, from a container 17, with a binder such as bitumen emulsion which
is preferably sprayed over the introduced asphalt via a nozzle situated within the
mixing apparatus 15. Up to 2 wt% of cement can be supplied to the mixing apparatus
15 from a container 21. Via a discharge valve 19, the asphalt mixed with the binder
from the container 17 is discharged from the mixing apparatus 15.
[0016] The fractions from the proportioning units 5 and 7 are preferably each supplied separately
to the mixing apparatus 15. If a first fraction consists of fresh material and has
been placed into the mixing apparatus 15, the required amount of bitumen emulsion
is supplied from the container 17. Instead of bitumen emulsion it is also possible
to use foamed bitumen. A method and apparatus for producing and applying foamed bitumen
has been described in the Canadian Patent No. 1261183. The one weight fraction is
then blended with the binder into a homogeneous mass. Then the mixed weight fraction
is fed in from the proportioning units 5 or 7 and is blended with the bitumen present
in the mixing apparatus 15 and with the first weight fraction. If necessary, a further
amount of emulsion can be fed in at this time from the container 17.
[0017] Using the apparatus according to the invention, 2-6 metric tonnes of asphalt can
be recycled per batch, with a process time of from 2 to 3 minutes per batch. The steam
injection into the mixing apparatus allows effective prevention of the emission of
noxious substances and volatile vapours.
[0018] Figure 2 shows an alternative embodiment of an apparatus according to the present
invention. In the apparatus shown in Figure 2, the two fractions of asphalt to be
recycled are formed by used asphalt being broken up, in separate breaking and screening
installations 23, 25, into a fraction of lumps having a size of between 4 mm and 5
cm, and a fraction of particles having a size smaller than about 4 mm. The asphalt
particles formed and separated in the breaking and screening apparatuses 23, 25 are
stored in an intermediate store 27, 29, for example on a heap. In this situation the
breaking and screening apparatuses may be at different locations, at a relatively
large distance from the proportioning units. With the aid of a shovel the particles
are then dumped into the proportioning units 31, 33 from the intermediate store 27,
29. Via a steam source 30, steam having a temperature of at least about 110°C is injected
into the proportioning units 31, 33. From the respective proportioning unit 31 or
33, the heated fractions are fed, one by one, via an automatically operated valve
34, 36, to a conveyor belt 35. The conveyor belt 35 comprises a weighing device (not
shown) for determining the weight of heated material dumped on the conveyor belt.
The conveyor belt 35 feeds a weighed amount to a mixing apparatus 37. In the mixing
apparatus 37 the fractions coming from the proportioning units 31, 33 are mixed together
by means of mixing paddles 41, and a bitumen emulsion is fed in via a line 39 and
a nozzle. From the mixing apparatus 37 the mixed fractions can be dumped, for example,
into a lorry and the recycled asphalt can be transported to a site in order to be
applied once more as a road surface.
[0019] It was found that when the above-described process was used, even without the weight
fractions of the asphalt to be used here being adjusted, heating with complete steam
condensation results in a very low emission of polycyclic aromatic compounds when
asphalt recycled according to the invention is applied once more.
1. Method for recycling asphalt, used asphalt being broken into pieces which in the main
are smaller than 5 cm, the said pieces being separated into at least two fractions,
characterized in that the fractions are separately heated in respective proportioning
units, whereupon the fractions, in a weight ratio changed with respect to the original
asphalt, are combined in a mixing apparatus.
2. Method according to Claim 1, characterized in that a first fraction comprises particles
having a size of between 4 and 50 mm, for example of between 4 and 20 mm, and a second
fraction comprises particles smaller than 4 mm, the weight ratio of the first and
the second fraction being between 80/20 and 20/80, and the weight ratio, during mixing,
of the first and the second fraction being between 20/80 and 80/20.
3. Method according to Claim 1 or 2, characterized in that the fractions are mixed, in
the mixing apparatus, with a binder.
4. Method according to Claim 1 or 2, characterized in that the fractions are admixed
in the mixing apparatus with not more than 3 wt% of bitumen and/or not more than 2
wt% of cement.
5. Method according to any one of the preceding claims, characterized in that heating
takes place by the virtually exclusive supply of steam to the proportioning units,
in which the temperature is such that virtually all of the steam condenses.
6. Method for recycling tar-containing asphalt, used asphalt being broken into pieces
which in the main are smaller than 5 cm, the said pieces being heated in a proportioning
unit, characterized in that heating takes place by the virtually exclusive supply
of steam to the proportioning units, in which the temperature is such that virtually
all of the steam condenses.
7. Method according to Claim 5 or 6, characterized in that the temperature in the proportioning
units is between 80 and 100°C, preferably between 90 and 95°C.
8. Method according to any one of the preceding claims, characterized in that initially
a first heated fraction such as unused material or asphalt and a binder are fed to
the mixing apparatus, and the mixture formed is then homogenized therein, the heated
second fraction and/or a further first fraction being introduced into the mixing apparatus
after the homogenization and being mixed with the previously homogenized contents.
9. Method according to Claim 6, wherein the binder includes bitumen.
10. Method according to Claim 6, characterized in that the mixing apparatus is supplied
with cement and/or lime.
11. Method according to any one of the preceding claims, characterized in that the separation
of the fractions takes place by screens having different mesh sizes.