JP3681158B2 - Method for producing recycled heated asphalt mixture with waste glass particles - Google Patents

Description

【００５９】
表１において廃骨材の配合率は、８０〜５０％と幅がある。これは、混合物の種類と粒度範囲により、また、アスファルト量によっても配合率が変わるためである。
また、廃ガラス粒の配合率も、５〜２０％と幅がある。廃ガラス粒の配合率は、舗装場所により様々に調整することが可能であり、例えば、一般車道用５％、駐車場用１０％、歩道用１５〜２０％等にすることができる。このように、一般的に、車両等により舗装表面の劣化の激しい箇所では廃ガラス粒の配合率を低くし、劣化の少ない箇所では高くすることができる。ただし、廃ガラス粒の配合率が高いからといって、極端に舗装面が劣化したり、剥離したりすることは無い。
【００６０】
以上図１〜図４を参照しつつ、本発明の実施の形態に係る廃ガラス粒入り再生加熱アスファルト混合物の製造方法等について説明したが、本発明はこれに限定されるものではなく、様々な変更を加えることができる。
【００６１】
【発明の効果】
以上の説明から明らかなように、本発明によれば、従来は一般廃棄物として持て余されていた廃ガラス瓶及び産業廃棄物であるところの廃アスファルトコンクリート塊を有用利用し、再び舗装等に用いることのできる。
【図面の簡単な説明】
【図１】再生アスファルト製造装置の全体構成を模式的に示す図である。
【図２】再生アスファルトを製造する工程の概略を示すブロック図である。
【図３】砂化ガラス製造プラントの全体構成を模式的に示す図である。
【図４】本発明の実施の形態に係る土壌改良剤を製造する砂化ガラス製造プラントの粉砕機の構成を示す図である。図４（Ａ）は、粉砕機の側面断面図であり、図４（Ｂ）は、図４（Ａ）のＡ−Ａ断面図である。
【符号の説明】
１０２〜１０７ ホッパ
１０９ ベルトコンベア
１１１ ドラムミキサー
１１３ バーナー
１１８ 添加剤タンク
１２０ アフターミキサー
１２４ 新アスファルトタンク
１３２ エレベータ
１３５ サイロ[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for producing a regenerated heated asphalt mixture containing waste glass particles. In particular, a method for producing a recycled heated asphalt mixture containing waste glass particles that can be used for paving, etc., by effectively using waste glass bottles that have been left over as general waste and waste asphalt concrete blocks that are industrial waste. About.
[0002]
[Prior art]
Asphalt paved roads need to be repaired because cracks and rucksets occur due to long-term use. As a repair method, there is an overlay method in which asphalt is newly paved on the existing paved asphalt. Further, when the paved road is severely damaged, a replacement method is employed in which the entire road is dug up and newly paved.
[0003]
[Problems to be solved by the invention]
Waste asphalt concrete lumps (pavement waste) dug up by such replacement work become industrial waste, which makes it difficult to treat.
[0004]
By the way, in recent years, recycling of waste glass bottles and the like is actively performed while environmental measures are screamed. Among the collected waste glass bottles, some waste glass bottles are cleaned and reused. However, most waste glass bottles are difficult to reuse and difficult to process.
[0005]
The present invention has been made in view of such problems, and has been usefully used for waste glass bottles and industrial waste waste asphalt concrete lumps that have conventionally been left as general waste, and again for paving and the like. An object of the present invention is to provide a method for producing a regenerated heated asphalt mixture containing waste glass particles that can be used.
[0006]
[Means for Solving the Problems]
In order to solve the above problems, a method for producing a recycled heated asphalt mixture containing waste glass particles of the present invention, Abandonment The glass is crushed to obtain a waste glass particle having a particle size of 2.5 mm or less, the waste asphalt concrete block is crushed to obtain a waste aggregate having a particle size of 13 mm or less to which the asphalt is adhered, and the waste glass particle and the waste aggregate are obtained. Using a drum mixer 155-175 ° C The mixture is heated and mixed for 4 to 6 minutes, and the asphalt is regenerated by adding a regenerating additive to the resulting waste glass particle / waste aggregate mixture, and then liquid new asphalt is added and further mixed. And
[0007]
A plurality of scraping blades and the like are provided in the drum mixer, and the waste aggregate is uniformly heated for 4 to 6 minutes. And since the waste aggregate and waste glass grain are mixed simultaneously in the drum mixer, the asphalt on the surface of the waste aggregate which has begun to dissolve in the drum mixer is sufficiently mixed so as to be entangled with the waste glass grain. further, 155-175 ° C The mixture is heated for 4 to 6 minutes, and the waste aggregate and the waste glass particles are sterilized by heating, so that no sanitary problem occurs.
[0008]
By injecting a regenerative additive into a mixture of waste aggregate and waste glass particles, the waste aggregate can be regenerated (resuscitation) and the asphalt can be prevented from becoming highly viscous and polymerized. Further, since the regeneration additive is supplied into the drum mixer, it is well mixed with the mixture of waste aggregate and waste glass particles, and the quality of the recycled asphalt mixture can be improved.
Moreover, the lack of asphalt components can be adjusted by mixing new asphalt into the mixture of waste aggregate and waste glass particles.
[0009]
In the method for producing the recycled heated asphalt mixture containing waste glass particles, it is preferable that the material is continuously charged and moved when the mixing is performed.
[0010]
From the process of mixing waste aggregate and waste glass particles in a drum mixer, the process from adding a regenerative additive to mixing new asphalt and completing the regenerated heated asphalt mixture in the aftermixer is a continuous process. It has become. For this reason, the temperature of the mixture does not become unstable or mixing becomes insufficient, quality control is easy, and a high-quality regenerated and heated asphalt mixture can be obtained.
[0011]
In the manufacturing method of the regenerated heated asphalt mixture containing waste glass particles, when the waste glass particles and waste aggregate are heated and mixed, hot air generated from the burner is applied to the drum mixer without applying a direct flame to the material. It is preferable to circulate inside.
[0012]
As a result, the drum mixer 155-175 ° C Therefore, the asphalt on the surface of the waste aggregate can be dissolved without substantially carbonizing the old asphalt contained in the waste aggregate.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a method for producing a recycled heated asphalt mixture containing waste glass particles (hereinafter referred to as recycled asphalt) according to an embodiment of the present invention will be described with reference to the drawings.
[0014]
First, the outline | summary of the manufacturing process which manufactures the reproduction | regeneration asphalt which concerns on embodiment of this invention is demonstrated.
FIG. 2 is a block diagram showing an outline of a process for producing recycled asphalt. The manufacturing process shown in FIG. 2 includes the following main processes.
(1) Waste asphalt crushing process 202 for crushing waste asphalt concrete block (paving waste material)
(2) Waste glass bottle crushing step 203 for crushing waste glass bottles and the like
(3) Recycled asphalt production process 204 for producing recycled asphalt by mixing waste asphalt concrete block and aggregate obtained from waste glass bottle
[0015]
In the waste asphalt concrete lump crushing step 202, the waste asphalt concrete lump is crushed using a known crusher generally called a crusher. That is, the waste asphalt concrete lump dug by construction such as replacement of a paved road is supplied to the crusher, and is crushed into particles having a particle size of 13 mm or less. Asphalt adheres to the crushed concrete particles (waste aggregate) and is used as waste aggregate when producing recycled asphalt.
[0016]
Next, the waste glass bottle crushing step 203 will be described with reference to FIGS. 3 and 4.
FIG. 3 is a diagram schematically showing the entire configuration of the sanded glass manufacturing plant used in the waste glass bottle crushing step 203.
The hopper 1 is shown in the most upstream part (right side of FIG. 3) of the sand glass manufacturing plant shown in FIG. Waste glass bottles or the like are supplied to the hopper 1 by an unillustrated shovel loader or the like. Here, the hopper 1 is usually supplied with a colorless or brown waste glass bottle that can be recycled in the form of a bottle.
[0017]
Waste glass bottles supplied to the hopper 1 are discharged from the bottom of the hopper 1 by a predetermined amount. The discharged waste glass bottle is placed on a vibration metering feeder 2 located at the lower part of the hopper 1. Below the end of the vibration metering feeder 2, a belt conveyor 10 extending in the upper left direction is disposed. At this time, the vibration metering feeder 2 always supplies a certain amount of waste glass bottles to the belt conveyor 10. A rough crusher 3 is arranged at the tip of the belt conveyor 10, and a certain amount of waste glass bottles are supplied from the belt conveyor 10 to the rough crusher 3.
[0018]
The rough crusher 3 crushes waste glass bottles, and for example, a so-called hammer crusher in which a hammer is attached to the tip of many rotating arms can be used. Waste glass pieces roughly crushed by the coarse crusher 3 (hereinafter, the roughly crushed waste glass bottles are referred to as waste glass pieces) and the like are supplied to the primary trommel 4 having a mesh screen of 12 mm × 12 mm. In the primary trommel 4, waste glass pieces and the like are classified into 12 mm or more waste glass pieces, crowns, plastics, paper pieces such as labels attached to waste glass bottles, and 12 mm or less waste glass pieces.
[0019]
A belt conveyor 11 extending downward and to the right is provided on the right side of the primary trommel 4 in the drawing. A secondary trommel 5 having a mesh screen of 12 mm × 24 mm is provided at the tip of the belt conveyor 11. The secondary trommel 5 is supplied with a piece of paper such as a label pasted on a waste glass piece, crown, plastic, waste glass bottle of 12 mm or more through the belt conveyor 11.
[0020]
On the left side of the figure of the secondary trommel 5, a chute 18 is provided that extends downward to the left. A dust box 24 is disposed at the tip of the chute 18. In the dust box 24, a crown of 24 mm or more and the like that has been sieved in the secondary trommel 5 is collected via the chute 18.
[0021]
Below the figure of the secondary trommel 5 is provided a belt conveyor 12 extending upward to the right. The tip of the belt conveyor 12 is located above the belt conveyor 10. The belt conveyor 12 is supplied with waste glass pieces or the like of 24 mm or less that have been sieved in the secondary trommel 5, and these are again supplied to the rough crusher 3 through the belt conveyor 10 and crushed.
[0022]
Below the figure of the primary trommel 4 is provided a belt conveyor 13 extending to the upper left. A crusher 6 is disposed at the tip of the belt conveyor 13. As will be described in detail later, the grinder 6 grinds waste glass pieces and the like, and for example, a so-called impact grinder that rotates a cage having pin shields arranged in several rows can be used. From the lower part of the pulverizer 6, waste glass particles pulverized by the pulverizer 6 (hereinafter, the pulverized waste glass pieces are referred to as waste glass particles) and the like are discharged.
[0023]
A sieving device 7 is provided at the lower part of the pulverizer 6 to classify the crushed waste glass particles by sieving. The sieving device 7 is mixed with crushed waste glass particles and paper pieces of 12 mm or less. In the sieving device 7, two sieves 7-1 and 7-2 having meshes with different roughnesses are provided.
[0024]
A sieve 7-1 having a coarse mesh of about 5 mm is attached to the uppermost portion of the sieving device 7 closest to the pulverizer 6 so as to be inclined obliquely. The sieve 7-1 collects waste glass particles having a particle size of 5 mm or more, paper pieces having a size of 5 mm to 12 mm, and the like. A discharge port is provided at the upper part of the end surface of the sieve 7-1 on the right side surface of the sieving device 7, and a return belt conveyor 15 extending upward is provided. The tip of the return belt conveyor 15 is connected to the pulverizer 6. Accordingly, waste glass particles of 5 mm or more and paper pieces having a size of 5 mm to 12 mm are supplied again to the pulverizer 6 via the return belt conveyor 15 and pulverized.
[0025]
A sieve 7-2 having a mesh of about 2.5 mm finer than the sieve 7-1 is obliquely attached to the lower part of the sieve 7-1 at a certain interval. The sieve 7-2 collects waste glass particles, paper pieces, and the like having a particle size of about 2.5 mm to 5 mm that are pulverized by the pulverizer 6 and pass through the sieve 7-1. A discharge port is provided at an upper part of the end face of the sieve 7-2 on the right side surface of the sieving device 7, and a discharge pipe extending obliquely downward is connected. A belt conveyor 14 extending obliquely upward to the right is disposed at the end of the discharge pipe. The tip of the belt conveyor 14 is connected to the wind power sorter 8. In the wind power sorter 8, waste glass particles having a particle size of about 2.5 mm to 5 mm and paper pieces are sorted. Below the wind power sorter 8, a belt conveyor 17 is shown. A yard 26 is disposed at the tip of the belt conveyor 17, and the collected waste glass particles having a particle size of about 2.5 mm to 5 mm are collected. Waste glass particles of this particle size can use 20 to 50% as an interlocking mixed material. The paper pieces sorted by the wind sorter 8 are collected by a dust collector 9 described later.
[0026]
A bottom surface 7-3 of the sieving device 7 is obliquely disposed at a lower portion of the sieving 7-2 with a certain interval. Waste glass particles having a particle size of 2.5 mm or less that are pulverized by the pulverizer 6 and pass through the sieve 7-2 reach the bottom surface 7-3. At the upper part of the bottom surface 7-3 on the right side surface of the sieving device 7, a discharge port is provided, and a belt conveyor 16 extending downward is connected. A yard 25 is disposed at the tip of the belt conveyor 16 and waste glass particles having a particle size of 2.5 mm or less are collected. The waste glass particles having this particle size are used as an aggregate of the recycled heated asphalt mixture containing the waste glass particles according to the embodiment of the present invention.
[0027]
The above-mentioned sanded glass manufacturing plant is provided with a suction device 27 for sucking and exhausting a piece of paper (label) attached to a waste glass bottle. The suction device 27 is provided with a dust collector 9. As the dust collector 9, for example, a dry-type device such as an electric dust collector or a bag filter can be used. In the dust collector 9, a filter 9-1 having a mesh with a roughness of about 0.03 mm is attached. A discharge port is provided on the bottom surface of the dust collector 9, and a container 23 is provided below the discharge port.
[0028]
A suction blower 9-2 is provided in the upper part of the dust collector 9. Further, an exhaust port (not shown) is provided in the upper part of the suction blower 9-2, and the air sucked into the filter 9-1 is exhausted to the outside. Since the mesh of the filter 9-1 is very fine, the air that has passed through the filter 9-1 contains almost no solid matter. Therefore, there is no problem even if this air is exhausted to the outside.
[0029]
Four ducts 19, 20, 21, and 22 are provided in the filter 9-1 portion of the dust collector 9. At the end of each duct 19, 20, 21, 22, a suction hood that is widened in a trumpet shape is provided, and connected to the rough crusher 3, the crusher 6, the wind sorter 8, and the primary trommel 4, respectively. ing. By driving the suction blower 9-2, waste glass powder having a particle size of about 0.03 to 0.15 mm existing in these devices (hereinafter referred to as what is generated from the crushed waste glass pieces and collected in the dust collector 9 is collected. This is called waste glass powder) and dust such as paper pieces that could not be collected by the wind sorter 8 is sucked into the filter 9-1 and collected in the container 23.
[0030]
In this embodiment, about 3% of the weight of the waste glass bottle as a raw material is waste glass powder.
[0031]
Next, the grinder 6 will be described in detail with reference to the drawings.
FIG. 4 is a diagram showing a configuration of a crusher of a sand glass manufacturing plant that manufactures a soil conditioner according to an embodiment of the present invention. 4A is a side cross-sectional view of the pulverizer, and FIG. 4B is a cross-sectional view taken along line AA in FIG. 4A.
[0032]
In the crusher 6 shown in FIG. 4, a large cage 71 having a plurality of pin shields and a small cage 81 are provided so as to mesh with each other. The large cage 71 and the small cage 81 are housed in housings 91 and 92.
[0033]
The large cage 71 is provided with a large disc-shaped plate 72 having a certain thickness. On the outermost peripheral portion of the left side surface of the plate 72, 24 pin shields 73 are projected evenly. The pin shield 73 is a cylindrical member made of ceramics or sintered metal, and is fixed to the plate 72 with screws (not shown). An annular pin shield fixing plate 74 having a certain thickness is provided at the tip of each pin shield 73. Sixteen pin shields 75 are projected evenly on the inner periphery of the installation location of the pin shield 73 on the left side surface of the plate 72. An annular pin shield fixing plate 76 having a certain thickness is provided at the tip of each pin shield 75.
[0034]
A central portion of the right side surface of the plate 72 is a stepped structure portion 72a, and a cylindrical shaft 78 is fitted to the central portion toward the right side of the drawing. A motor 79 for driving the large cage 71 is provided at the end of the shaft 78.
[0035]
The stepped structure portion 72a of the plate 72 is rotatably fixed to the right housing 91 via a bearing (not shown). Thus, by driving the motor 79, the large cage 71 can rotate in the housing.
[0036]
A central member 82 is disposed at the center of the small cage 81 so as to face the plate 72. The outer diameter of the center member 82 is smaller than the inner diameter of the 16 pin shields 75. The outer peripheral portion of the center member 82 has a plate shape with a certain thickness, and ten pin shields 83 are projected evenly toward the left side of the figure. An annular pin shield fixing plate 84 having a certain thickness is provided at the tip of each pin shield 83. Each pin shield 83 is fixed to the outermost peripheral portion of the pin shield fixing plate 84. On the inner peripheral portion of the pin shield fixing plate 84, 20 pin shields 85 are projected evenly toward the right side of the drawing. The 20 pin shields 85 are arranged with an interval between the 24 pin shields 73 and the 16 pin shields 75. An annular pin shield fixing plate 86 having a certain thickness is provided at the right end of each pin shield 85.
[0037]
A cylindrical shaft 88 is fitted toward the left side of the drawing at the center of the left side surface of the plate 82. A motor 89 that drives the small cage 81 is provided at the end of the shaft 88.
[0038]
The shaft 88 is rotatably fixed to the left housing 92 via a bearing (not shown). Thus, by driving the motor 89, the small cage 81 can rotate within the housing.
[0039]
A supply port 93 for supplying waste glass pieces and the like is provided upward at the upper portion of the shaft 88 on the left side surface of the left housing 92. Since the supply port 93 communicates with the central portion of the pulverizer 6, the waste glass pieces and the like can be introduced into the central portion of the pulverizer 6 by supplying the waste glass pieces and the like to the supply port 93.
[0040]
Discharge ports 91a and 92a for discharging waste glass particles and the like are provided at the lower portions of the left and right housings 91 and 92, and the waste glass particles crushed by the crusher 6 are discharged.
[0041]
The outer peripheral portions of the left and right housings 91 and 92 are flange portions 91b and 92b, and the left and right housings 91 and 92 are fixed with bolts (not shown). By removing this bolt, for example, the right housing 91 can be moved to the right. At this time, the large cage 71 and the like move to the right together with the right housing 91. By doing so, maintenance such as replacement of the pin shield can be performed.
[0042]
Then, the grinding | pulverization method in the grinder mentioned above is demonstrated.
First, waste glass pieces are supplied to the supply port 93 by a predetermined amount. The supplied waste glass piece is introduced into the center of the pulverizer 6. At that time, the motors 79 and 89 are controlled to rotate the large cage 71 and the small cage 81 in the opposite directions. In this way, the waste glass piece is crushed by being sandwiched between the large cage 71 and the pin shield of the small cage 81 and crushed. That is, the waste glass piece introduced into the central portion of the cage hits the pin shield 83 located at the innermost periphery and receives a centrifugal force, and reaches the next row of pin shields 75. At that time, the waste glass piece is crushed by being pinched between the pin shield 83 and the pin shield 75 and crushed. Subsequently, the waste glass piece hits the pin shield 75 and receives a centrifugal force, and reaches the next row of pin shields 85. At that time, the waste glass piece is crushed by being pinched between the pin shield 75 and the pin shield 85 and crushed. Further, the waste glass piece hits the pin shield 85 and receives centrifugal force, and reaches the row of pin shields 73 located on the outermost periphery. At that time, the waste glass piece is crushed by being pinched between the pin shield 85 and the pin shield 73 and being crushed. Waste glass particles hitting the pin shield 73 and receiving centrifugal force move downward along the inner surfaces of the housings 91 and 92 and are discharged from the discharge ports 91a and 92a.
[0043]
Thus, in the above-mentioned crusher, since the waste glass pieces are crushed by rotating the two cages, the shape of the crushed waste glass particles is a shape having no sharp edges and a low aspect ratio. The particle size of the waste glass particles can be adjusted by changing the number of pin shield rows and the number of cage rotations. For example, if the number of rotations of the cage is increased, waste glass particles having a small particle size can be obtained, and if the number of rotations is decreased, waste glass particles having a large particle size can be obtained. Further, even when the particle size of the waste glass pieces supplied to the pulverizer varies, it is possible to obtain waste glass particles having a stable particle size by controlling the number of rotations of the cage with an inverter.
[0044]
Next, a recycled asphalt manufacturing apparatus and manufacturing method will be described with reference to the drawings.
FIG. 1 is a diagram schematically showing the overall configuration of a recycled asphalt manufacturing apparatus.
[0045]
In the recycled asphalt manufacturing apparatus shown in FIG. 1, six hoppers 102 to 107 for temporarily storing aggregates are arranged side by side. Below each of the hoppers 102 to 107, weigh scales 102a to 107a are provided to measure the amount of aggregate discharged from each hopper. The amount of aggregate discharged from the hoppers 102 to 107 is adjusted in real time by measuring the values of the weigh scales 102a to 107a.
[0046]
In this embodiment, for example, waste aggregate with a particle size of 13 mm or less manufactured by a waste asphalt crusher (see FIG. 2) is supplied from above the hoppers 102 and 103 by a belt conveyor or an excavator loader. Further, for example, waste glass particles having a particle size of under 2.5 mm manufactured by a waste glass bottle crusher (see FIGS. 2 to 4) are supplied from above the hoppers 104 and 105 by a belt conveyor or a shovel loader.
[0047]
By the way, the waste asphalt pavement waste material, which is a source of waste aggregate, also includes sand. Therefore, in this recycled asphalt manufacturing apparatus, it is not necessary to mix sand, or even when mixing, it may be no more than about 5% at the time of manufacturing a new asphalt mixture. When mixing sand, for example, it is supplied to the hopper 106 of FIG.
[0048]
Below each hopper 102-107, the belt conveyor 109 extended in the horizontal direction of the figure is arrange | positioned. The waste aggregate discharged from the hoppers 102 and 103 and the waste glass particles discharged from the hoppers 104 and 105 are placed on the belt conveyor 109 and conveyed together here. On the left side of the belt conveyor 109 in the figure, a feeder 110 is connected upward. A drum mixer (dryer) 111 is connected to the tip of the feeder 110, and waste aggregate and waste glass particles are supplied from the feeder 110 to the drum mixer 111. At this time, the feeder 110 always supplies a certain amount of waste aggregate and waste glass particles to the drum mixer 111.
[0049]
The drum mixer 111 is, for example, a tilted cylindrical rotary type with a diameter of 1.6 m and a length of 9 m, and the residence time is about 300 seconds. The drum mixer 111 is disposed obliquely with the outlet side facing slightly downward, and is supported on the floor so as to be rotatable about its central axis. A plurality of scraping blades (not shown) are provided on the inner peripheral wall of the drum mixer 111, and when the drum mixer 111 rotates, the supplied waste aggregate can be slowly fed downward while mixing.
[0050]
A burner 113 is provided at the upper end of the drum mixer 111. Propane gas is supplied to the burner 113 from an LPG cylinder (not shown). The fire of the burner 113 is directed toward the drum mixer 111. Here, the burner 113 according to this embodiment has a structure in which only the hot air is applied to the aggregate in the drum mixer 111 without applying the direct fire of the burner 113. Thereby, since the inside of the drum mixer 111 becomes a sauna shape of about 165 ± 10 ° C., the asphalt contained in the waste aggregate can be dissolved without being substantially carbonized. Further, since a plurality of scraping blades are provided in the drum mixer 111, the waste aggregate can be uniformly heated for 4 to 6 minutes. Further, since the waste aggregate and the waste glass particles are simultaneously mixed in the drum mixer 111, the asphalt on the surface of the waste aggregate that has started to dissolve in the drum mixer 111 is sufficiently mixed so as to be entangled with the waste glass particles. . In addition, since the mixture is heated at about 165 ± 10 ° C. for 4 to 6 minutes, the waste aggregate and the waste glass particles are sterilized by heating and no sanitary problems are caused.
[0051]
A pipe 116 from an additive tank 118 that stores the additive for regeneration is connected to the tip of the drum mixer 111. The additive tank 118 has a capacity of about 15 t and is heated by a heating wire. A pulse transmission flow meter 117 is attached to the pipe 116 near the outlet of the additive tank 118, and the flow rate of the regeneration additive is controlled. The additive tank 118 stores a regenerative additive containing about 60% aromatics, and is supplied to the tip of the drum mixer 111 at a constant flow rate.
[0052]
By the way, it was confirmed that asphaltene, which is a heavy component in the asphalt composition, increases every time asphalt regeneration is repeated. As a result, the asphalt becomes highly viscous and polymerized, and mixing of the regenerated asphalt becomes somewhat difficult, and the quality of the regenerated asphalt is degraded. Therefore, by injecting a regeneration additive into the mixture of waste aggregate and waste glass particles, the asphalt on the surface of the waste aggregate can be regenerated (resuscitation), and the asphalt can be prevented from becoming highly viscous and polymerized. Further, since the regenerating additive is supplied into the drum mixer 111, it is well mixed with the mixture of waste aggregate and waste glass particles, and the quality of the regenerated asphalt mixture can be improved.
[0053]
An after mixer 120 is provided below the outlet of the drum mixer 111, and the mixture in the drum mixer 111 is supplied. The aftermixer 120 is a biaxial pug mill continuous mixer having a capacity of 40 t / h. The inside of the after mixer 120 is maintained at about 165 ± 10 ° C., similarly to the drum mixer 111, and the mixture is heated and mixed for 1 to 2 minutes.
[0054]
A pipe 122 from a new asphalt tank 124 for storing new asphalt is connected to the aftermixer 120. The new asphalt tank 124 has a capacity of about 15 tons and is heated to about 155 degrees by a heating wire. A pulse transmission flow meter 123 is attached to the pipe 122 near the outlet of the new asphalt tank 124 to control the flow rate of the new asphalt. 100% liquid new asphalt is stored in the new asphalt tank 124 and is supplied into the aftermixer 120 at a constant flow rate. Thus, the lack of asphalt components can be adjusted by mixing new asphalt into the mixture of waste aggregate and waste glass particles. A discharge port 120a is provided at the lower part of the aftermixer 120, and a certain amount of the mixture can be discharged by opening the discharge port 120a at regular intervals.
[0055]
Below the after mixer 120, an elevator 132 is provided. The elevator 132 is arranged from the lower side of the after mixer 120 toward the upper side. The elevator 132 is provided with a transport container 131, and the transport container 131 is transported from the lower side of the after mixer 120 toward the upper side. During the production of reclaimed asphalt, the transport container 131 is disposed below the aftermixer 120. When a certain amount of regenerated asphalt accumulates in the aftermixer 120, the outlet 120 a of the aftermixer 120 is opened, and the regenerated asphalt is transferred to the transport container 131. When a predetermined amount of recycled asphalt accumulates in the transport container 131, it is transported upward from the lower side of the aftermixer 120 to the side thereof.
[0056]
A hot silo 135 is provided below the upper end of the elevator 132. The silo 135 has a capacity of about 150 t, and is heated to 165 to 175 ° C. with a heating wire. The recycled asphalt transported by the transport container 131 is supplied from the upper part of the silo 135. A pipe 137 is provided near the upper part of the silo 135, and carbon dioxide for preventing oxidation of recycled asphalt is supplied into the silo 135 from an external device (not shown). At the lower part of the silo 135, a discharge port 135a sealed with an oil seal (not shown) is provided. At the time of shipment of recycled asphalt, a certain amount of recycled asphalt can be shipped by disposing a dump truck or the like below the silo 135 and opening the discharge port 135a.
[0057]
In this embodiment, as described above, the additive for regeneration is added from the middle of the process of mixing the waste aggregate and the waste glass particles in the drum mixer 111, the new asphalt is mixed, and the aftermixer 120 is mixed. The process up to the completion of recycled asphalt is a continuous process. For this reason, the temperature of the mixture does not become unstable or mixing becomes insufficient, quality control is easy, and high-quality recycled asphalt can be obtained.
[0058]
Here, the blending ratio of the regenerated asphalt manufactured by the regenerated asphalt manufacturing apparatus according to this embodiment is shown in Table 1.
[Table 1]

[0059]
In Table 1, the mixing ratio of waste aggregate has a width of 80 to 50%. This is because the compounding ratio varies depending on the type and particle size range of the mixture and also on the amount of asphalt.
Moreover, the compounding rate of waste glass particles also has a width of 5 to 20%. The mixing ratio of the waste glass particles can be adjusted in various ways depending on the pavement location. Thus, generally, the mixing ratio of the waste glass particles can be lowered at a location where the pavement surface is severely degraded by a vehicle or the like, and can be increased at a location where the degradation is small. However, just because the mixing ratio of the waste glass particles is high, the pavement surface is not extremely deteriorated or peeled off.
[0060]
While the manufacturing method of the recycled heated asphalt mixture containing waste glass particles according to the embodiment of the present invention has been described with reference to FIGS. 1 to 4 above, the present invention is not limited to this, and various You can make changes.
[0061]
【The invention's effect】
As is clear from the above description, according to the present invention, waste glass bottles that have conventionally been left as general waste and waste asphalt concrete blocks that are industrial waste are usefully used and again used for paving and the like. I can do it.
[Brief description of the drawings]
FIG. 1 is a diagram schematically showing the overall configuration of a recycled asphalt manufacturing apparatus.
FIG. 2 is a block diagram showing an outline of a process for producing recycled asphalt.
FIG. 3 is a diagram schematically showing the overall configuration of a sand glass manufacturing plant.
FIG. 4 is a diagram showing a configuration of a grinder of a sand glass manufacturing plant that manufactures a soil conditioner according to an embodiment of the present invention. 4A is a side cross-sectional view of the pulverizer, and FIG. 4B is a cross-sectional view taken along line AA in FIG. 4A.
[Explanation of symbols]
102-107 Hopper
109 Belt conveyor
111 drum mixer
113 burner
118 Additive Tank
120 Aftermixer
124 New asphalt tank
132 Elevator
135 silo

Claims (4)

Waste glass is crushed to obtain waste glass particles with a particle size of 2.5 mm or less,
Crushing the waste asphalt concrete lump to obtain waste aggregate with a particle size under 13mm with asphalt attached,
Using a drum mixer, the waste glass particles and waste aggregate are heated and mixed at 155 to 175 ° C. for 4 to 6 minutes,
Recycled heated asphalt containing waste glass particles, characterized by regenerating asphalt by adding a regenerating additive to the obtained waste glass particle / waste aggregate mixture and then adding liquid new asphalt and further mixing A method for producing a mixture.   The method for producing a recycled heated asphalt mixture containing waste glass particles according to claim 1, wherein the material is continuously charged and moved when the mixing is performed.   The hot air generated from the burner is circulated in the drum mixer without applying a direct flame to the material when the waste glass particles and waste aggregate are heated and mixed. Method for producing regenerated heated asphalt mixture with waste glass grains.   4. A method for producing a recycled heated asphalt mixture containing waste glass particles according to claim 1, wherein light oil is used as the regeneration additive.

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