JP3612030B2 - Recyclable asphalt composite manufacturing method - Google Patents

Description

【００３５】
表１に示される如く、粒径の大きいＲＳ−５，ＲＳ−１３，ＲＳ−２０については、油分含有量が非常に少なく（３％未満）、ピッチ被膜が充分に除去されているが、０〜２．５ｍｍの成分（ＲＳ−２．５）は油分含有量が比較的多く（３％以上）、ピッチ被膜の除去が充分ではないことが分かる。
また、表乾比重については全ての粒径成分で、吸水率についてはＲＳ−２．５を除く成分において、日本工業規格（ＪＩＳ Ａ５００１）の規格値（表乾比重２．４５以上、吸水量３．０％以下）を満たしていた。また、ＲＳ−２．５、ＲＳ−５，ＲＳ−１３，ＲＳ−２０の各成分はいずれもＪＩＳに規定された粒度分布を満たしていた。
【００３６】
（実施例２）
実施例１において、スーパーサンダーに代えて研磨設備（ドラムリクレーマー）を使用した以外は同じ工程にて処理し、その結果得られた再生単粒度砕石について、アスファルト含有量、粒度分布、比重、吸水率を測定した。
測定結果を表２に示す。
【表２】

【００３７】
表２に示される如く、粒径の大きいＲＳ−５，ＲＳ−１３，ＲＳ−２０については、油分含有量が非常に少なく（３％未満）、ピッチ被膜が充分に除去されていたが、０〜２．５ｍｍの成分（ＲＳ−２．５）は油分含有量が比較的多く（３％以上）、ピッチ被膜の除去が充分ではなかった。
また、表乾比重については全ての粒径成分で、吸水率についてはＲＳ−２．５を除く成分において、日本工業規格（ＪＩＳ Ａ５００１）の規格値（表乾比重２．４５以上、吸水量３．０％以下）を満たしていた。また、ＲＳ−２．５、ＲＳ−５，ＲＳ−１３，ＲＳ−２０の各成分はいずれもＪＩＳに規定された粒度分布を満たしていた。
【００３８】
（実施例３）
現場より搬入されたアスファルト廃材を図３に示す工程（３次破砕設備（２０）としてスーパーサンダーを使用）に従って処理し、その結果得られた再生単粒度砕石のうち、ＲＳ−１３，ＲＳ−５．ＲＳ−２．５について、アスファルト含有量、粒度分布を測定した。
測定結果を表３に示す。
【表３】

【００３９】
表３に示される如く、粒径の大きいＲＳ−５，ＲＳ−１３については、油分含有量が少なく（３％未満）、ピッチ被膜が充分に除去されているが、０〜２．５ｍｍの成分（ＲＳ−２．５）は油分含有量が比較的多く（３％以上）、ピッチ被膜の除去が充分ではないことが分かる。また、ＲＳ−２．５、ＲＳ−５，ＲＳ−１３はいずれもＪＩＳに規定された粒度分布を満たしていた。
【００４０】
上記した如く、本発明に係る方法の一例による前半工程によって得られた再生単粒度砕石のうち、ＲＳ−５，ＲＳ−１３，ＲＳ−２０については油分含有量が少なく新骨材と同等の高い品質を有しているが、ＲＳ−２．５については油分含有量が比較的多いという結果が得られた。
そこで、本発明に係る方法の後半工程においては上述した如く、油分含有量の少ないＲＳ−５，ＲＳ−１３，ＲＳ−２０については直接加熱方式により加熱し、油分含有量の多いＲＳ−２．５については間接加熱方式により加熱するという方法を採用し、これによって油分燃焼による粒度分布の変化や過熱劣化を最小限に抑えつつ優れた熱効率が得られるようになった。
【００４１】
【発明の効果】
以上説明したように、本発明に係る循環型アスファルト合材製造法によれば、アスファルト廃材の表面に付着したピッチ被膜を打撃衝突作用を利用して破砕を行う破砕設備にて、もしくは磨鉱作用を利用して研磨を行なう研磨設備にて強制的に剥奪除去することで、油分含有量の少ない新骨材と同等の品質を有する再生単粒度砕石を回収することができ、この回収された再生単粒度砕石を使用して再生アスファルト合材を製造するに際して、油分含有量が３％以上の成分については間接加熱し、残りの成分については直接加熱することにより、油分の燃焼による粒度分布の変化や過熱劣化を最小限に抑えることができ、しかも加熱時の熱効率においても優れたものとなり、結果としてアスファルト廃材の占める割合が１００％に近い極めて高い再生資源利用率が少ないエネルギー消費で得られ、廃材の大部分を再生材として循環利用することができて、省資源化及び地球環境保全に対する貢献度が非常に高く、更には新材と同等の施工性及び仕上がりを得ることが可能な再生アスファルト合材、即ち循環型アスファルト合材の製造方法となる。
【図面の簡単な説明】
【図１】本発明に係る方法の前半工程の一例を示すフローシートである。
【図２】本発明に係る方法の前半工程において使用される研磨設備の一例を示す断面図である。
【図３】本発明に係る方法の前半工程の別の例を示すフローシートである。
【図４】本発明に係る方法の前半工程の別の例を示すフローシートである。
【図５】本発明に係る方法の前半工程の別の例を示すフローシートである。
【図６】本発明に係る方法の後半工程を示すフローシートである。
【図７】従来の方法により得られた再生骨材の問題点を示す説明図である。
【符号の説明】
１ 原料受入設備（ホッパー）
２，３ 切り出し設備
１３ １次ふるい設備
６ １次破砕設備
９ １次ふるい設備
１１ ２次破砕設備
１８ ２次ふるい設備
２０ ３次破砕設備（研磨設備）
３０ 間接加熱式ドライヤー
３８ 直接加熱式ドライヤー
４５ 混合装置（ミキサー）[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for producing a recycle type asphalt composite material, the purpose of which is to obtain a reclaimed asphalt composite material with an extremely high recycled resource utilization rate that is nearly 100% of the asphalt waste material. An object of the present invention is to provide a method for producing a recycled asphalt mixture that can be recycled.
[0002]
[Prior art]
The amount of asphalt waste generated by repairing paved roads is an enormous amount, reaching about 36 million tons per year. However, in recent years, the recycling law (the law on the promotion of the use of recycled resources) has been observed. Due to efforts to promote reuse of construction by-products, the reuse rate is increasing year by year, and about 80% of these waste materials are reused in some form.
However, of the generated asphalt waste material, the ratio of recycled asphalt mixture, that is, the recycled resource utilization rate is as low as about 30%, and most of it is reused for other uses such as roadbed materials. It is a fact.
This is because in the conventional method of obtaining recycled aggregate by crushing asphalt waste, most of the pitch coating (B) adhering to the surface of the asphalt waste remains on the surface of the recycled aggregate (A) without being removed. It is because it ends up. That is, when such recycled aggregate is used in the production of asphalt composites, as shown in FIG. 7, the particle size distribution is in an appropriate range because the particle size of the aggregate is greatly reduced by the combustion of oil mixed in the coating. It was difficult to increase the proportion of recycled aggregate to 30% or more because it was not suitable for the project and it had an adverse effect on the asphalt mixture plant.
Moreover, the recycled aggregate obtained by the conventional method has a large amount of residual oil from the waste material, so the temperature of the recycled asphalt mixture cannot be raised so much, so the workability at the site deteriorates and the finish is good. It was difficult to get.
[0003]
In view of such circumstances, one of the inventors of the present application, in Japanese Patent Application Laid-Open No. 9-141243, recovered a recycled aggregate having a small pitch from asphalt waste, and used this recycled aggregate to produce a recycled asphalt composite. is suggesting.
Since this method can remove most of the pitch coating adhering to the surface of the asphalt waste material, it is a very excellent technology that can obtain a recycled asphalt mixture in which the asphalt waste material occupies most of the raw material. there were.
However, even with this method, a component with a small particle size (0 to 2.5 mm) in the recycled aggregate contains a relatively large amount of oil, and the recycled aggregate containing this component is directly put into a drum mixer. If heated directly, there is a risk of burning oil or causing overheating, so it was necessary to use a new aggregate containing no oil and mixed with recycled aggregate.
[0004]
[Problems to be solved by the invention]
The present invention solves the problem of the oil remaining in the recycled aggregate obtained from the above-mentioned asphalt waste material, thereby obtaining an extremely high recycled resource utilization rate in which the proportion of the asphalt waste material is close to 100%. Recycled recycled asphalt compound that can be recycled as recycled material, has a very high contribution to resource saving and global environmental conservation, and can achieve the same workability and finish as new materials The manufacturing method is to be provided.
[0005]
[Means for Solving the Problems]
The present invention relates to a grinding facility for grinding a raw material made of asphalt waste material using at least one crushing step and a sieving step, and then crushing using a striking impact action or grinding using a grinding ore action To remove the pitch portion coated on the crushed material, and to supply to the sieving equipment to separate and recover the regenerated single-grain crushed stone composed of a plurality of components having different particle size ranges, and at least of these recovered components Ingredients with oil content of 3% or more are heated indirectly, the remaining ingredients are heated directly, and both of these heated ingredients are fed to the mixing device together with additives, asphalt and stone powder and mixed to regenerate asphalt The present invention has succeeded in solving the above problems by providing a method for producing a recycled asphalt composite material characterized by obtaining a composite material.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of a method for producing a circulating asphalt composite according to the present invention will be described with reference to the drawings.
FIG. 1 is a flow sheet showing a part of the steps of the method according to the present invention. First, the step of recovering recycled single-grain crushed stone from asphalt waste material, which is the first half step of the method according to the present invention, will be described based on this drawing. .
First, the asphalt waste material used as a raw material (29) is accommodated in a hopper (1). A cutting facility (2) is provided at the lower end discharge port of the hopper (1). For example, a reciprocating feeder is used as the cutting facility (2), and the raw material is continuously cut out by a predetermined amount. The raw material cut out from the cutting equipment (2) is further sent to the next cutting equipment (3). As this cutting equipment (3), for example, a grizzly feeder is used, and the raw material cut out from the cutting equipment (2) is continuously cut out by a predetermined amount.
In addition, when the asphalt waste material brought in is small, it is also possible to omit the cutting equipment (2).
[0007]
The raw material having a predetermined particle size or less cut out from the cutting equipment (3) is supplied to the primary sieving equipment (13) comprising a vibrating screen through the conveying device (4). In addition, the magnitude | size of the raw material cut out from the cutting equipment (3) is not specifically limited, It can change suitably according to the kind of asphalt waste material brought in as a raw material, and the performance of the primary crushing equipment (6).
[0008]
In addition, in the illustrated flow sheet, the case where the size of the raw material cut out from the cutting equipment (3) is 50 mm or less is shown as an example, and the following explanation will be made along this flow sheet. When the size of the raw material to be cut out is changed, it is needless to say that the particle size shown in the subsequent process can be changed, and this is the same for the other flow sheets.
[0009]
Although a belt conveyor etc. are used as a conveying apparatus (4), it does not specifically limit, This is the same also about all the conveying apparatuses used at the following processes. In addition, a magnetic separator (5) is provided on the upper part of the conveying device (4) to remove metal foreign matter (14) such as iron scrap.
[0010]
On the other hand, the raw material of a size (for example, 50 mm or more) that could not pass through the cutting equipment (3) is supplied to the primary crushing equipment (6) and crushed. A compression crusher such as a jaw crusher is used as the primary crushing equipment (6).
The crushed material crushed by the primary crushing equipment (6) is supplied to the primary sieving equipment (9) comprising a vibrating screen through the transport device (7). In addition, the magnetic separation apparatus (8) is provided also in the upper part of a conveying apparatus (7), and metal foreign materials (14), such as iron scrap, are removed.
[0011]
In the primary sieving equipment (9) (13), the crushed material is separated into, for example, those exceeding 30 mm and those below 30 mm. Of these, those exceeding 30 mm are supplied to the secondary crushing equipment (11) by the transport device (10). As the secondary crushing equipment (11), a crusher that performs crushing using an impact collision action such as an impeller breaker (trade name: manufactured by Kawasaki Heavy Industries) is preferably used.
[0012]
The crushed material crushed by the secondary crushing facility (11) is sent again to the conveying device (7) via the conveying device (12) and supplied to the primary sieving facility (9).
In the primary sieving equipment (9), as described above, the crushed material is separated into a crushed material exceeding 30 mm and a crushed material of 30 mm or less, and the crushed material exceeding 30 mm is secondarily passed through the conveying device (10). Supply to crushing equipment (11). That is, the said process is repeated until the crushed material exceeding 30 mm sorted by the primary sieve equipment (9) becomes a size of 30 mm or less.
[0013]
The crushed material of 30 mm or less sorted by the primary sieving equipment (9) is divided into one sent to the transport device (16) and one sent to the transport device (17) by the quantitative switching device (15).
The crushed material sent to the conveying device (16) is recovered as it is as a regenerated crusher run (RC-30) of 0 to 30 mm. On the other hand, the crushed material sent to the conveying device (17) is supplied to the secondary sieving equipment (18), and is separated into a crushed material of less than 10 mm and a crushed material of 10 to 30 mm, and the crushed material of less than 10 mm is regenerated. It is recovered as a crusher run (RC-10), and the crushed material of 10 to 30 mm is supplied to the tertiary crushing facility (20) via the transport device (19).
[0014]
The tertiary crushing equipment (20) is used to crush a crushed material exceeding 20 mm into fine pieces by crushing using a hitting collision action to make it 20 mm or less and remove the pitch (asphalt) coated on the crushed material. For example, a super sander (trade name: manufactured by Kawasaki Heavy Industries, Ltd.) used as a sandmaking machine, a new dick (trade name: manufactured by Lhasa Kogyo Co., Ltd.) used as a particle size adjuster, or the like is preferably used.
[0015]
In this invention, it can replace with the above-mentioned tertiary crushing equipment (20), and the structure which uses a grinding equipment can also be employ | adopted preferably.
As the polishing equipment, one having the structure shown in FIG. 2 is preferably used.
In the polishing equipment shown in FIG. 2, two rotating shafts rotating in opposite directions are horizontally arranged on the same axis at a predetermined interval, and the raw material is charged at an upper position near the base end of one rotating shaft (60). In addition, an inlet chute (61) is provided, and a supply rotor (62) having a diameter that is tapered toward the front end of the rotary shaft so as to communicate with the lower end portion of the inlet chute (61) is opened to the rotary shaft ( 60) and a cylindrical shape that opens toward the supply rotor (62) at the tip of the other rotating shaft (63) and has a larger diameter than the tip opening of the supply rotor (62). A discharge rotor (64) is attached, and the other rotating shaft (63) is configured to be telescopic.
As a polishing equipment having such a configuration, there is a drum reclaimer (trade name: manufactured by Kawasaki Heavy Industries, Ltd.).
[0016]
According to this polishing equipment, the raw material charged from the inlet chute (61) is discharged along the taper of the supply rotor (62) by the action of the centrifugal force generated with the rotation of the rotating shaft (60). ) And is pressed against the peripheral portion of the discharge rotor (64) by the action of centrifugal force generated by the rotation of the rotating shaft (63), and discharged from the gap between the supply rotor (62). The In this series of operations, the feed rotor (62) and the discharge rotor (64) rotate in directions opposite to each other, so that the raw material has a pitch (asphalt) coated on the crushed material by a grinding action in which the surfaces are rubbed together. ) Is removed.
In this equipment, the gap between the supply rotor (62) and the discharge rotor (64) can be changed by expanding and contracting the other rotating shaft (63), thereby facilitating the residence time of the raw material in the rotor. Can be adjusted to.
By using such polishing equipment instead of the tertiary crushing equipment (20), cracking of the raw material can be prevented and the actual volume ratio can be improved.
[0017]
The portion of the pitch removed from the crushed material by the tertiary crushing facility (20) or the polishing facility is collected by the dust collector (24). An air separator or the like is used as the dust collector (24). Moreover, the crushed material which came out of the tertiary crushing equipment (20) is supplied to the tertiary sieve equipment (22) which consists of a vibration sieve by a conveying apparatus (21).
[0018]
In the tertiary sieving equipment (22), the supplied crushed material or polished material is first separated into a component exceeding 20 mm and a component not exceeding 20 mm, and the component exceeding 20 mm is separated again by the crushing equipment (23) 20) Or supply to polishing equipment.
And the component of 20 mm or less is further classified into a component exceeding 13 mm (13 to 20 mm) and a component of 13 mm or less, and the component of 13 mm or less is further separated into a component of 5 to 13 mm and a component of less than 5 mm, and less than 5 mm. These components are further separated into components of 2.5 to 5 mm and components of less than 2.5 mm.
The fractionated crushed material (25) having a particle size of 13 to 20 mm is No. 5 regenerated single particle crushed stone (RS-20), and the crushed material (26) having a particle size of 5 to 13 mm is No. 6 regenerated single particle crushed stone (RS-13). ), The crushed material (27) of 2.5 to 5 mm is recovered as No. 7 regenerated single particle crushed stone (RS-5), and these regenerated single particle crushed stones are the regenerated single particle crushed stone (0 to 2.5 mm) ( 28) together with the post-process shown in FIG.
In addition, the above-described separation of the particle size range shows a preferable example to the last,
If blending can be made so as to satisfy the required particle size distribution in the asphalt compound to be manufactured in the subsequent process, it is possible to change the classification of the particle size range obtained in the previous process by changing the sieve mesh etc. is there.
[0019]
Moreover, in the above-mentioned process, the crushed material is separated into those exceeding 40 mm and those not exceeding 40 mm by the primary sieving equipment (9) (13). In addition to being supplied to the secondary crushing equipment (11), the secondary sieving equipment (18) separates the crushed material of less than 10 mm and the crushed material of 10 to 40 mm, and the crushed material of less than 10 mm is used as recycled crusher run (RC-10). It is good also as a structure which collect | recovers and supplies a 10-40 mm crushed material to a tertiary crushing installation (20) or a grinding | polishing installation via a conveying apparatus (19).
[0020]
Recycled single-grain crushed stones of Nos. 5 to 7 obtained by the processes described above are subjected to a crushing process over the third order, or a crushing process over the second order and one polishing process, as shown in the examples described later. The oil content is low because most of the pitch adhering to the surface is removed.
[0021]
Moreover, it is also possible to employ | adopt the process shown, for example in FIG. 3 thru | or FIG. 5 instead of the said process as a process of collect | recovering recycled single-grain crushed stone from the asphalt waste material which is the first half process of the method which concerns on this invention.
In the process shown in FIG. 3, the secondary sieving equipment (18) in the process shown in FIG. 1 is omitted, and the components of 30 mm or less screened by the primary sieving equipment (9) are directly passed to the tertiary crushing equipment (20). The other steps are the same as those shown in FIG. In the process of FIG. 3, the grinding equipment shown in FIG. 2 may be used in place of the crushing equipment (20), and the smashed material exceeds 40 mm in the primary sieving equipment (9) (13). And 40 mm or less.
[0022]
The process shown in FIG. 4 omits the primary crushing equipment (6) in the process shown in FIG. 1, and directly supplies the raw material having a size exceeding 40 mm cut out from the cutting equipment (3) in the process shown in FIG. The impeller breaker (trade name: manufactured by Kawasaki Heavy Industries, Ltd.) used as the next crushing equipment is used to supply to the crusher (11) that crushes using the impact collision action. This is substantially the same as the process shown in FIG. In the process of FIG. 4, the grinding equipment shown in FIG. 2 may be used in place of the crushing equipment (20), and the smashed material exceeds 5 mm or less than 5 mm in the secondary sieving equipment (18). You may make it classify into a thing.
[0023]
In the process shown in FIG. 5, the secondary sieving equipment (18) in the process shown in FIG. 4 is omitted, and the components of 20 mm or less screened by the primary sieving equipment (9) are crushed as they are using the impact collision action. It is configured to be supplied to crushing equipment (20) such as Super Sander (trade name: manufactured by Kawasaki Heavy Industries, Ltd.) and New Dick (trade name: manufactured by Rasa Industrial Co., Ltd.). The process is substantially the same. Also in the process of FIG. 5, the polishing equipment shown in FIG. 2 may be used instead of the crushing equipment (20).
[0024]
FIG. 6 is a second half step of the method according to the present invention, which is a step of producing a recycled asphalt mixture (recycled asphalt mixture) using the recycled single grain crushed stone obtained in the first half step described above. .
The 13 to 20 mm component (25), 5 to 13 mm component (26), and 2.5 to 5 mm component (27) collected in the first half step described above are separately accommodated in the hopper (31), The remaining 0-2.5 mm component (28) is housed in a hopper (32) located elsewhere.
The components accommodated in the hopper (31) are components supplied to the direct heating dryer (38) described later, and the components accommodated in the hopper (32) are supplied to the indirect heating dryer (30). It is an ingredient.
Here, part or all of the component (27) of 2.5 to 5 mm may be accommodated in the hopper (32), and the small-diameter component (for example, 0) screened by the secondary sieving equipment (18). ˜5 mm) may also be accommodated in the hopper (32).
However, for the sake of convenience, the text following paragraph (0026) describes the case where only the component (28) of 0 to 2.5 mm is accommodated in the hopper (32).
[0025]
In the present invention, what is contained in the hopper (32) is a component containing 3% or more of an oil component, and such a component with a large amount of oil inevitably appears as a component with a small particle size. (For example, 0 to 2.5 mm or 0 to 5 mm) is accommodated in the hopper (32).
Here, the component (27) of 2.5 to 5 mm described above that may be accommodated in the hopper (32) may have an oil content of 3% or more and less than 3%. Of these, those with an oil content of 3% or more are always stored in the hopper (32).
On the other hand, the oil content of less than 3% may be accommodated in either the hopper (31) or the hopper (32), and only the amount less than 3% is accommodated in the hopper (32). For example, when the capacity of the indirectly heated dryer (30) is sufficiently large, all or most of the oil content less than 3% may be accommodated in the hopper (32). When the capacity of the indirectly heated dryer (30) is small, all or most of the oil content less than 3% may be accommodated in the hopper (31).
[0026]
The small diameter component (for example, 0 to 2.5 mm) (28) accommodated in the hopper (32) is supplied into the indirectly heated dryer (30) via the belt conveyor (29) and the elevator (40).
The indirectly heated dryer (30) has a structure in which a combustion device (33) equipped with a burner and a drying section (34) are separately provided and connected by a connecting pipe (35). The component supplied in the inside is not directly heated by the flame of the burner, but is indirectly heated by the hot air introduced from the combustion device (33) through the connecting pipe (35) into the drying section (34). The
A dust collector (36) made of a cyclone is connected to the upper part of the indirectly heated dryer (30), and the exhaust gas that has passed through the dust collector (36) is fed into the combustion device (33) by a circulation fan (37). It is sent.
[0027]
On the other hand, each component accommodated in the hopper (31), for example, the component (25) of 13 to 20 mm, the component (26) of 5 to 13 mm, the component (27) of 2.5 to 5 mm, the belt conveyor (53), etc. Is fed directly into the heated dryer (38). The direct heating dryer (38) directly heats the components supplied to the inside by a flame of a burner, and a bag filter (39) is connected to the upper part thereof. The exhaust gas that has passed through is discharged from the chimney (41) by the blower (40). In the figure, reference numeral (51) denotes a fuel tank for storing the burner fuel.
[0028]
The present invention is characterized in that indirect heating and direct heating are used in combination when heating the recycled aggregate used as a raw material for asphalt composite as described above, and the reason why this combined method is adopted will be described below. .
First, for components having a large particle size, for example, components of 2.5 to 5 mm, 5 to 13 mm, and 13 to 20 mm (recycled single-grain crushed stone), the pitch coating is sufficiently removed by the above-described first half step. As shown in the examples, the oil content is very low (about 0.2 to 3%).
In the present invention, such a component having a low oil content is directly heated because it is difficult to cause deterioration due to combustion or overheating of the oil even if it is directly heated. And according to direct heating, since it can raise temperature in a short time also about the component with a large particle size which is hard to raise temperature by indirect heating, it becomes the thing excellent in thermal efficiency.
[0029]
On the other hand, for small diameter components, for example, components of 0 to 2.5 mm, the pitch film cannot be sufficiently removed because the particle size is small, and the oil content is relatively high (about Therefore, if it is directly heated with direct fire, it may cause deterioration due to combustion of oil or overheating.
In the present invention, such a component having a relatively large oil content is indirectly heated to prevent deterioration due to oil combustion or overheating. Since the entire temperature can be easily raised in a short time by heating, there is almost no loss due to the use of indirect heating in terms of thermal efficiency.
[0030]
As described above, in the method according to the present invention, by using indirect heating and direct heating in combination, combustion and deterioration of the oil can be prevented, and the thermal efficiency at the time of heating is excellent. Thus, the recycled resource rate can be dramatically increased.
[0031]
Small-diameter components heated by the indirect heating dryer (30), for example, components of 0 to 2.5 mm are put into the surge pins (42), and each component heated by the direct heating dryer (38), for example, 13 to 20 mm. The component, the component of 5 to 13 mm, and the component of 2.5 to 5 mm are input to the hot pin (44) through the hot elevator (43).
The components in the surge pin (42) and the hot pin (44) are asphalt stored in the asphalt tank (47), stone powder stored in the filler tank (48), and in the additive tank (49). Then, it is fed into the mixer (45) together with the additive stored in (1) and mixed. The additive used here is for restoring the changed properties of asphalt and is generally called a regenerative additive or softener.
In the figure, (46) is a measuring device for measuring the supply amount of the components screened in the hot pin (44) to the mixer (45), (48) is an asphalt measuring device, (50) is It is a filler elevator.
[0032]
The mixture obtained by mixing by the mixer (45) is loaded into the hot mix silo (52) as a recycled asphalt mixture (circulated asphalt mixture) and reused.
[0033]
The recycled asphalt mixture (circulated asphalt mixture) obtained through the above-described steps is a raw material from which about 97% of the raw material is obtained from asphalt waste, excluding the amount of added stone powder (about 3%). As a result, the recycle resource utilization rate is dramatically higher than that of the conventional method.
[0034]
【Example】
Hereinafter, the effect of the present invention will be clarified by showing examples of the method according to the present invention. However, the present invention is not limited to the following examples.
Example 1
The asphalt waste material brought in from the site is treated according to the process shown in Fig. 1 (using a super sander as the tertiary crushing equipment (20)). The water absorption was measured.
The measurement results are shown in Table 1.
[Table 1]

[0035]
As shown in Table 1, for RS-5, RS-13, and RS-20 having a large particle size, the oil content is very small (less than 3%), and the pitch coating is sufficiently removed. It can be seen that the component of ~ 2.5 mm (RS-2.5) has a relatively high oil content (3% or more) and the removal of the pitch film is not sufficient.
In addition, with respect to the surface dry specific gravity, all the particle size components, and with respect to the water absorption rate, the components other than RS-2.5 are standard values of the Japanese Industrial Standard (JIS A5001) (surface dry specific gravity of 2.45 or more, water absorption of 3 0.0% or less). Moreover, each component of RS-2.5, RS-5, RS-13, and RS-20 satisfy | filled the particle size distribution prescribed | regulated to JIS.
[0036]
(Example 2)
In Example 1, it processed in the same process except having used polishing equipment (drum reclaimer) instead of the super sander, and about the regenerated single grain crushed stone obtained as a result, asphalt content, particle size distribution, specific gravity, water absorption The rate was measured.
The measurement results are shown in Table 2.
[Table 2]

[0037]
As shown in Table 2, for RS-5, RS-13, and RS-20 having a large particle size, the oil content was very low (less than 3%), and the pitch film was sufficiently removed. The component (RS-2.5) of ˜2.5 mm had a relatively high oil content (3% or more), and the pitch film was not sufficiently removed.
In addition, with respect to the surface dry specific gravity, all the particle size components, and with respect to the water absorption rate, except for RS-2.5, the standard values of the Japanese Industrial Standard (JIS A5001) (surface dry specific gravity of 2.45 or more, water absorption of 3 0.0% or less). Moreover, each component of RS-2.5, RS-5, RS-13, and RS-20 satisfy | filled the particle size distribution prescribed | regulated to JIS.
[0038]
(Example 3)
The asphalt waste material carried from the site is processed according to the process shown in FIG. 3 (using a super sander as the tertiary crushing equipment (20)), and among the regenerated single-grain crushed stones obtained as a result, RS-13, RS-5 . Asphalt content and particle size distribution were measured for RS-2.5.
Table 3 shows the measurement results.
[Table 3]

[0039]
As shown in Table 3, for RS-5 and RS-13 having a large particle size, the oil content is small (less than 3%), and the pitch coating is sufficiently removed, but the component is 0 to 2.5 mm. It can be seen that (RS-2.5) has a relatively high oil content (3% or more), and removal of the pitch film is not sufficient. RS-2.5, RS-5, and RS-13 all satisfied the particle size distribution defined in JIS.
[0040]
As described above, among the regenerated single-grain crushed stone obtained by the first half step according to an example of the method according to the present invention, RS-5, RS-13, and RS-20 have a low oil content and are as high as new aggregates. Although it has quality, RS-2.5 has a relatively high oil content.
Therefore, in the latter half of the method according to the present invention, as described above, RS-5, RS-13, and RS-20 having a low oil content are heated by the direct heating method, and RS-2. As for No. 5, a method of heating by an indirect heating method was adopted, whereby excellent thermal efficiency can be obtained while minimizing changes in particle size distribution and overheat deterioration due to oil combustion.
[0041]
【The invention's effect】
As described above, according to the circulating asphalt composite material manufacturing method according to the present invention, the pitch coating adhered to the surface of the asphalt waste material is crushed using a crushing action using the impact collision action, or the grinding action Forcibly stripped and removed with a polishing facility that performs polishing, it is possible to recover recycled single-grain crushed stone having the same quality as new aggregate with low oil content, and this recovered regeneration When producing recycled asphalt composites using single-grain crushed stone, the components with an oil content of 3% or more are indirectly heated, and the remaining components are directly heated to change the particle size distribution due to combustion of the oil. And overheating degradation can be minimized, and the thermal efficiency during heating is excellent, and as a result, the proportion of asphalt waste is extremely high, close to 100%. Recycled resources can be obtained with low energy consumption, and most of the waste can be recycled as recycled materials, contributing greatly to resource conservation and global environmental conservation, and equivalent to new materials. It becomes the manufacturing method of the reproduction | regeneration asphalt compound material which can obtain workability | operativity and a finish, ie, a circulation type asphalt compound material.
[Brief description of the drawings]
FIG. 1 is a flow sheet showing an example of the first half of a method according to the present invention.
FIG. 2 is a cross-sectional view showing an example of a polishing equipment used in the first half of the method according to the present invention.
FIG. 3 is a flow sheet showing another example of the first half of the method according to the present invention.
FIG. 4 is a flow sheet showing another example of the first half of the method according to the present invention.
FIG. 5 is a flow sheet showing another example of the first half of the method according to the present invention.
FIG. 6 is a flow sheet showing the latter half of the method according to the present invention.
FIG. 7 is an explanatory view showing a problem of a recycled aggregate obtained by a conventional method.
[Explanation of symbols]
1 Raw material receiving equipment (hopper)
2,3 Cutting equipment
13 Primary sieve equipment
6 Primary crushing equipment
9 Primary sieve equipment
11 Secondary crushing equipment
18 Secondary sieve equipment
20 Third crushing equipment (polishing equipment)
30 Indirect heating dryer
38 Direct heating dryer
45 Mixer

Claims (1)

Supply raw materials consisting of asphalt waste materials to at least one crushing step and sieving step, and then supply them to crushing equipment that crushes using the impact collision action or polishing equipment that uses the grinding action After removing the pitch component coated on the crushed material, it is supplied to a sieving facility to separate and recover the regenerated single-grain crushed stone composed of a plurality of components having different particle size ranges. At least 3% of the recovered component is oil. The above components are heated indirectly, the remaining components are heated directly, and both the heated components are supplied to the mixing device together with additives, asphalt and stone powder and mixed to obtain a regenerated asphalt mixture. A circulating asphalt composite manufacturing method characterized by the above.

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