KR101296529B1 - Manufacturing system for reclaiming aggregate - Google Patents

Abstract

The present invention relates to a circulating aggregate manufacturing system for crushing the waste asphalt pavement paved on the road with a crusher, and more particularly, a selection unit for selecting the crushed aggregate crushed in the crusher by size; A transfer conveyor for transferring the selected crushed aggregates by size; Both ends of the transfer conveyor is passed through, the upper and lower parts and the front and rear surfaces have a structure, and a drying unit for supplying hot air at a predetermined temperature to the crushing aggregate of the inner transfer conveyor is installed to reduce the moisture content of the crushing aggregate and ; Both ends of the conveying conveyor is opened, the upper and lower parts and the front and rear surfaces are closed, and the AP cooler of the warmed crushed aggregate epidermis (Asphalt) installed with a cold air blower to supply cold air of a predetermined temperature to the crushed aggregate of the inner conveying conveyor a cooling unit for cooling oil); And a separation unit configured to separate the crushed aggregates bonded to each other by the AP oil among the crushed aggregates passed through the cooling unit.
Therefore, by controlling the temperature of the hot air supplied during the particle size sorting process according to the moisture content of the crushed aggregate made by waste asphalt crushing, the softening of AP oil on the surface of the crushed aggregate is minimized. It provides a recycling aggregate manufacturing system to improve to a similar level.

Description

Circulating aggregate manufacturing system {MANUFACTURING SYSTEM FOR RECLAIMING AGGREGATE}

The present invention relates to a circulating aggregate manufacturing system and a method thereof, and in particular, to solve the problem that the crushed aggregates are bonded to each other by AP oil (Asphalt oil) in the process of crushing the waste asphalt to the particle size discrimination of small particles By making it easy, the circulating aggregate manufacturing system to produce a quality similar to that of natural aggregate that retains the characteristics of raw asphalt concrete (including aggregate, stone powder, asphalt oil, sand, etc.) as it is, and its It is about a method.

In general, the asphalt paved road has a different size of aggregate mixed with AP oil depending on the surface layer and substrate.

Therefore, as described above, in case of repairing or repairing for a long time, the paved asphalt had to be separated from the road surface and disposed of.

As the above-mentioned waste asphalt has a great impact on environmental pollution, although the government has made various efforts to promote the recycling business from private operators, the construction company that paves the asphalt road recycles the waste asphalt or waste asphalt. It is a situation to avoid using aggregate.

In other words, when new aggregates and recycled aggregates are mixed in a certain ratio, recycled aggregates, new aggregates, and APs are collected by collecting waste asphalt and crushing it to about 25cm in the case of primary crushing, and then crushing to less than 13mm in the case of secondary crushing. When generating new ascon by mixing oil, aggregate recycled from waste ascon is not a perfect new aggregate but contains AP oil, and the aggregate is deteriorated due to long-term use. Because of this, when mixing with new aggregates, there is a problem of deteriorating the durability of the new ascon quality as well.

Therefore, suppliers or contractors who supply new materials do not trust the use of recycled aggregates that recycled waste asphalt, thereby avoiding the use of waste, resulting in an increase in waste asphalt and waste asphalt, resulting in enormous capital costs for disposal. Damage and adversely affect the surrounding environment.

Particularly, in the case of suppliers supplying new goods, even if the recycled aggregate recycled waste ascon is used, if the quality of the product is guaranteed, it can not only save a lot of costs, but also collect the profits generated from collecting the waste asphalt and produce new goods. It can generate huge profits from the raw material cost which is saved while reducing the cost, so it can have the effect of gaining profits for both environment, supply, and profit. Therefore, it is required to request that the products produced by recycling waste ascon be used in manufacturing new materials. do.

The present invention has been invented in view of the above, and in the production of recycled aggregate or recycled sand by crushing and sorting construction waste such as waste concrete, waste ascon, red brick, etc. By removing the binders such as cement or asphalt to produce high-quality recycled aggregates or recycled sand.

The above object is a circulating aggregate manufacturing system for shredding waste asphalt pavement on the road with a crusher to be utilized as a circulating aggregate, wherein the crushed aggregate crushed in the crusher has a plurality of screens having different mesh sizes A sorting unit (110) for selecting the crushed aggregates by passing the size (102) in size order; Transfer conveyor 120 for transferring each of the crushed aggregates selected by the size by the sorting unit 110 by size; Both ends are opened to allow the transfer conveyor 120 to pass, the upper and lower parts and the front and rear surfaces are closed, and the hot air blower 122 is installed to supply the hot air at a predetermined temperature to the crushing aggregate of the inner transfer conveyor 120. A drying unit 130 for lowering the moisture content of the aggregate; Both ends are opened to allow the transfer conveyor 120 to pass, and the upper and lower parts and the front and rear surfaces are closed, and a cold air blower 132 is installed to supply cold air at a predetermined temperature to the crushed aggregate of the inner transfer conveyor 120. Cooling unit 140 for cooling the AP oil (Asphalt oil) of the crushed aggregate skin; By the circulation aggregate manufacturing system, characterized in that it comprises a separation unit 150 for separating the crushed aggregates bonded to each other by AP oil (Asphalt oil) of the crushed aggregates passed through the cooling unit 140 Is achieved.

Here, the size of the mesh formed on the plurality of screens 102 is preferably 13mm or more, 13mm to 10mm, 9mm or less, 5mm or less.

And, the conveying belt of the conveying conveyor 120 is made of a mesh (mesh) structure, the heat supplied to the drying unit 130 is preferably 40 ℃ to 50 ℃.

In addition, it is preferable to further include a temperature control unit 124 for controlling the temperature of the hot air supplied from the hot air blower 122 according to the moisture content of the crushed aggregate crushed in the crusher.

The separation unit 150 may include a housing 142 installed adjacent to the other end of the transfer conveyor 120 and having a predetermined angle of inclination from one end toward the other end thereof; The crushed aggregate supplied by the conveying conveyor 120 passing through the drying unit 130 and the cooling unit 140 is rotated by the power of the drive motor 144 is installed inside the housing 142 spaced apart. Separating pipe 146 made of a mesh structure to be transferred to the other end while being separated from each other by a physical impact; It is installed on the lower portion of the housing 142 includes a conveying conveyor 148 for transferring the aggregate separated in the separation pipe 146 to the other end of the housing 142.

In addition, it is preferable to further include an auxiliary cold air fan 149 to supply a cold air of a predetermined temperature to the separation pipe 146.

Conventionally, the particle size of ascon mixture is largely divided into 10mm or more, 10-5mm, and 5mm or less. However, the existing recycled aggregate has only 13mm or less and 13 ~ 10mm, 9mm or less. According to the present invention it is possible to produce a circular aggregate of 5mm or less to participate in the particle size distribution of 5mm or less that has not been managed previously has the effect of improving the function of ascon while enabling more systematic particle size management.

In addition, by controlling the particle size of the fine aggregate portion of less than 5mm can be used to maximize the AP content of the aggregate, it has the effect of increasing the corporate competitiveness rate by reducing the manufacturing cost by reducing the amount of new AP.

1 is a block diagram schematically showing the configuration of the present invention;
Figure 2 shows the structure of the separation unit of the present invention.

The present invention relates to a circulating aggregate manufacturing system for crushing waste asphalt paved on the road with a crusher to be utilized as a circulating aggregate.

Hereinafter, the configuration and operation of the present invention will be described with reference to FIGS. 1 to 2.

First, as shown in FIG. 1, the crushed aggregates crushed in the crusher are classified by size in the sorting unit 110, and the sorted crushed aggregates by size are respectively dried into the drying unit 130 through the transfer conveyor 120. Transferred.

Here, the sorting unit 110 is provided with a plurality of screens 102 (primary screen, secondary screen, tertiary screen, quaternary screen), as shown in FIG. It has mesh structures of different sizes.

The size of the mesh constituting the screen 102 is 13 mm or more, 13 mm to 10 mm, and 9 mm to 5 mm, respectively, so that the crushed aggregate is selected by size while passing through each screen 102.

In addition, the crushed aggregates selected by sizes by the sorting unit 110 are individually transported by the transport conveyor 120 for each size as shown in FIG. 1.

Here, each of the conveying conveyor 120 is to pass through the drying unit 130 to be described later, in this case, the drying unit 130 may allow only one conveying conveyor 120 to pass through, a plurality of The present invention can be provided to be passed through the conveying conveyor 120 is not limited to this and can be variously changed by the manufacturer's design.

The drying unit 130 has a structure in which both ends are open so that the conveying conveyor 120 passes, and a hot air blower 122 is installed to supply hot air to the conveying conveyor 120 or the crushed aggregate that is passed through, or remotely. It consists of a structure in which a hot air pipe is configured to transfer only hot air from the installed hot air blower 122.

At this time, the conveying belt of the conveying conveyor 120 has a mesh structure (mesh), it is preferable that the hot air is evenly transmitted to the crushed aggregate so that the moisture content is effectively lowered.

In addition, the temperature of the hot air supplied to the drying unit 130 is set to 40 ℃ to 50 ℃, to prevent the AP oil thinned on the surface of the crush aggregate to reach the melting point and to join the AP oil of the adjacent crush aggregate. It is preferable.

That is, the AP oil chopped on the surface of the crushed aggregate has a physical property that starts to melt from about 60 ℃ so that the hot air having a temperature below that so that the temperature inside the drying unit 130 does not reach 60 ℃ By doing so, the temperature inside the drying unit 130 is preferably maintained at 60 ° C. or less.

In particular, in the case of the crushed aggregate having a size of 5mm or less has a rapidly melting properties when reaching 60 ℃, it is very important to control the temperature inside the drying unit 130 does not reach the melting point of the AP oil.

Here, by additionally installing a temperature control unit 124 for controlling the temperature of the hot air supplied from the hot air blower 122 in accordance with the moisture content of the crushed aggregate crushed in the crusher, hot air of a higher temperature is supplied in accordance with the moisture content of the crushed aggregate It is preferable to make it possible, and to make it possible to supply low temperature hot air.

As described above, when hot air is supplied with high temperature hot air, AP oil is melted and bonded to adjacent crushed aggregates. However, crushed aggregates joined by the separating unit 150 to be described later may be separated by inducing a collision. After passing through the unit 150, the apparatus according to the present invention is further passed through the drying unit 130 to which low-temperature hot air is supplied, thereby finally lowering the moisture content of the crushed aggregate to the moisture content required by the manufacturer. Since it can be operated, the temperature control of the hot air by the temperature control unit 124 may be very important.

In addition, the top and bottom and front and rear surfaces are closed and only the inlet and outlet sides through which the conveying conveyor 120 is opened so that heat loss does not occur when the hot air is supplied to the conveying conveyor 120 or the crushed aggregate from the drying unit 130. It is preferable that it consists of a structure.

On the other hand, the conveying belt of the conveying conveyor 120 is configured to have a mesh structure, so that the hot air is evenly supplied from the upper, lower portion of the conveying belt while the crushed aggregate is not passed, the moisture content of the crushed aggregate is effectively lowered It is desirable to be able to.

In addition, the transfer conveyor 120 passing through the drying unit 130 as described above is to pass through the cooling unit 140 to be described later, the structure of the drying unit 130 and the cooling unit 140 described above is Most of them are similar.

That is, both ends of the transfer conveyor 120 is passed through, the upper and lower and front and rear surfaces have a structure closed, the cold air blower 132 for supplying cold air of a predetermined temperature to the crushing aggregate of the inner transfer conveyor 120 is the inside After the cold air blower 132 is installed in or remotely installed, the cold air pipe for supplying only cold air is connected to the inside of the cooling unit 140, and the installation structure and position of the cold air blower 132 are according to the intention of the designer. Adoption can be changed in various ways.

Therefore, the crushed aggregate of the conveying conveyor 120 entering the cooling unit 140 via the drying unit 130 is a state in which the moisture content is lowered, but is conveyed in the warmed state by the hot air of the drying unit 130. The AP oil of the shredded aggregate epidermis thus warmed is cooled by the cold air of the cold air blower 132.

Of course, the conveying belt of the conveying conveyor 120 preferably has a mesh structure.

As described above, the crushed aggregate passing through the cooling unit 140 may have AP oil (Asphalt oil) melted while passing through the dry unit 130, and adjacent crushed aggregates may be bonded to each other.

However, as described above, since the temperature of the hot air supplied from the drying unit 130 and the temperature inside the drying unit 130 are such that hot air at an appropriate temperature is supplied through the temperature control unit 124, the crushed aggregates are mutually different. Even if they are bonded, because they are partially bonded, they can be easily separated from the separation unit 150 to be poor, so that the crushed aggregate can be finally produced as a recycled aggregate intended by the manufacturer.

The separation unit 150 is provided with a housing 142 of a predetermined size, the other end of the housing 142 is installed in an inclined state at a predetermined angle as shown in Figure 2, Inside the housing 142, a separation pipe 146 is installed in a state spaced apart from the inner diameter surface of the housing 142 by a predetermined distance.

At this time, the separation pipe 146 has a mesh structure, the size of the mesh is provided differently depending on the size of the crushed aggregate transported by the conveying conveyor (120).

That is, the crushed aggregate is transferred to each different conveying conveyor 120 according to the size as described above to finally reach the separation unit 150 via the drying unit 130 and the cooling unit 140, Accordingly, a plurality of separation units 150 are also provided according to the size classification, the mesh constituting the separation pipe 146 of the separation unit 150 is preferably provided in accordance with the size of the crushed aggregate to be transported.

As described above, the crushed aggregate separated from the separator tube 146 falls into the housing 142 at the lower portion of the separator tube 146, and the transfer conveyor 148 is shown at the lower portion of the housing 142 as shown in FIG. Installed together so that the crushed aggregate falling to the lower portion of the housing 142 can be transferred to the outside of the other end of the housing 142.

On the other hand, the separation pipe 146 is rotated by the power of the drive motor 144 as shown in Figure 2, is supplied by the conveying conveyor 120 of the drying unit 130 and the cooling unit 140 The crushed aggregate is introduced into one end of the separation tube 146 of the separation unit 150, and the crushed aggregate introduced into the separation tube 146 as the separation tube 146 rotates is the self-collision and the housing 142 and the separation by rotation. The inclination of the tube 146 is transferred toward the other end.

At this time, if the size of the shredded aggregate transported by the conveying conveyor 120 is 9mm or less in size, since the mesh size of the separation pipe 146 is manufactured to be easy to select the shredded aggregate of 9mm or less, shredded aggregate The crushed aggregates independently rotated and not bonded to each other are passed through the mesh of the separating pipe 146 to be separated from the housing 142 and then discharged by the conveying conveyor 148 under the housing 142. Interbonded crushed aggregates have a size larger than 9 mm, so that the collision phenomenon due to rotation continuously occurs without passing through the mesh.

As a result, in the separation unit 150 as described above, the crushed aggregates bonded to each other are induced by a collision by the rotation of the separating pipe 146, so that they are separated in the bonded state, and the separated crushed aggregates are separated in the separation pipe 146. It is to be separated from the crushed aggregate is passed through the mesh of the).

Here, the cold air of a predetermined temperature generated in the auxiliary cold air blower 149 to the separation pipe 146 is supplied to the cold air outlet 146a formed in the separation pipe 146 as shown in FIG. It is desirable to be able to separate the bonded crushed aggregate more easily.

102: screen 110: screening unit
120: conveying conveyor of the drying unit or cooling unit
122: hot air fan 124: temperature control unit
130: drying unit 132: cold air
140: cooling unit 142: housing
144: drive motor 146: separation pipe
148: conveying conveyor of separation unit
149: auxiliary cold fan 150: separation unit

Claims (7)

In the circulating aggregate manufacturing system for crushing the waste asphalt paved on the road with a crusher to be used as the circulating aggregate,
A sorting unit (110) for sorting the shredded aggregates by size by passing the shredded aggregates shredded by the shredder in order of size through a plurality of screens (102) having different mesh sizes;
Transfer conveyor 120 for transferring each of the crushed aggregates selected by the size by the sorting unit 110 by size;
Both ends are opened to allow the transfer conveyor 120 to pass, the upper and lower parts and the front and rear surfaces are closed, and the hot air blower 122 is installed to supply the hot air at a predetermined temperature to the crushing aggregate of the inner transfer conveyor 120. A drying unit 130 for lowering the moisture content of the aggregate;
Both ends are opened to allow the transfer conveyor 120 to pass, and the upper and lower parts and the front and rear surfaces are closed, and a cold air blower 132 is installed to supply cold air at a predetermined temperature to the crushed aggregate of the inner transfer conveyor 120. Cooling unit 140 for cooling the AP oil (Asphalt oil) of the crushed aggregate skin;
Recycling aggregate manufacturing system comprising a separation unit 150 for separating the crushed aggregates bonded to each other by AP oil (Asphalt oil) of the crushed aggregates passed through the cooling unit 140. The method of claim 1,
The size of the mesh formed on the plurality of screen 102 is 13mm or more, 13mm ~ 10mm, 9mm or less, 5mm or less, characterized in that the circulation aggregate manufacturing system. The method of claim 1,
The conveying belt of the conveying conveyor 120 is a circulation aggregate manufacturing system, characterized in that consisting of a mesh (mesh) structure. The method of claim 1,
Heat supplied to the drying unit 130 is circulating aggregate manufacturing system, characterized in that 40 ℃ ~ 50 ℃. The method of claim 1,
And a temperature control unit (124) for controlling the temperature of the hot air supplied from the hot air blower (122) according to the moisture content of the crushed aggregate crushed in the crusher. The method of claim 1,
The separation unit 150,
The separation unit 150,
A housing 142 installed adjacent to the other end of the transfer conveyor 120 and having a predetermined angle of inclination from one end toward the other end;
The crushed aggregate supplied by the conveying conveyor 120 passing through the drying unit 130 and the cooling unit 140 is rotated by the power of the drive motor 144 is installed inside the housing 142 spaced apart. Separating pipe 146 made of a mesh structure to be transferred to the other end while being separated from each other by a physical impact;
The circulation aggregate manufacturing system, characterized in that it comprises a conveying conveyor (148) installed in the lower housing 142 to transfer the aggregate separated in the separation pipe (146) to the outside of the other end of the housing (142). The method according to claim 6,
The circulation aggregate manufacturing system, characterized in that it further comprises an auxiliary cold air fan (149) to supply a cold air of a predetermined temperature to the separation pipe (146).

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