KR100985277B1 - Collection apparatus of rock silt by rock sludge - Google Patents

Abstract

The present invention is to make fine aggregate by crushing the rock and crush the by-product stone powder to separate and recover the silt from the rock sludge before treating the sludge generated in the process of manufacturing fine aggregate such as artificial crushed sand. The present invention relates to a rock silt recovery device that can reduce the amount of chemicals used and minimize the generation of waste.
A cylindrical main body 10; A first inclined plate 11 installed to be inclined inside the main body 10 and having a lower end spaced apart from an inner wall of the main body 10; A second inclined plate 12 installed in the main body 10 in a direction opposite to the first inclined plate 11 and having a lower end spaced apart from an inner wall and a bottom of the main body 10; A conical water chamber 20 having an upper end fixed to the upper edge of the main body 10 and a hole 21 through which rock silt escapes; A sludge inlet pipe 15 installed above the main body 10 to supply rock sludge to the upper side of the first inclined plate 11; An overflow tube 22 installed to communicate with an upper end of the water chamber 20 and discharging the clear water located above the water chamber 20 to a settling tank; And a discharge pipe 16 communicating with the lower end of the second inclined plate 12 to discharge the settled rock silt.
Therefore, by minimizing the fine components of the effluent discharged to the sedimentation tank can reduce the consumption of chemicals in the water treatment, it is possible to significantly reduce the amount of sludge cake finally discharged. In addition, by recovering the high-strength rock silt contained in the rock sludge and using it for concrete production, the strength of concrete can be greatly improved and the amount of sand used in concrete production can be reduced.

Description

Collection of rock silt {Collection Apparatus of Rock Silt by Rock Sludge}

The present invention, before the chemical treatment of the rock sludge generated in the process of producing fine aggregates such as artificial crushed stone by crushing the rock to make coarse aggregate (crushed by-product) and crushing the by-product stone powder The present invention relates to a rock silt recovery device that separates and recovers silt from sludge, thereby reducing the amount of chemicals used in post-treatment and minimizing the amount of waste generated.

In recent years, as the construction industry using reinforced concrete is activated and natural aggregate is absolutely lacking, the utilization of artificial aggregate and recycled aggregate is increasing as a substitute for natural aggregate. Artificial aggregates are manufactured by crushing rocks of quarries and the like, and are classified into coarse aggregates and fine aggregates according to their thickness.

When the rock is crushed for the production of artificial aggregates, although there are some differences depending on the quality of the rock, roughly 43% of the coarse aggregates are generated. However, this stone powder can be used only for a specific purpose such as asphalt or ascon, and is very rarely used, so most of it is landfilled or left unattended, and this waste disposal problem is a factor that inhibits the production of artificial aggregate. Doing. Accordingly, a method of producing fine aggregates by processing stone powder has been developed, and by applying this method, a huge amount of fine aggregates up to 35% of crude aggregates can be obtained.

The apparatus for producing aggregate from rock is the Crusher Plant and the Sand Plant. In the Crusher Plant, raw materials are crushed to produce crude aggregate, and the by-product stone powder is crushed again in the sand plant to fine aggregate. Produces.

In the crasher plant, various kinds of crashers are used to crush raw materials, to separate soil powder, and to crush and sort several times to produce coarse aggregate of the required size. The substandard stone powder from this process is fed to the sand plant producing fine aggregate.

Most sand plants produce fine aggregates by using a wet manufacturing method. The granules are crushed using a sand crasher such as Barmac, and a sand vacuum screen is used to sort products. At this time, in order to remove dust generated during the crushing process of stone powder, the work is washed with water. The sludge generated in this process (hereinafter referred to as 'rock sludge') has fine sand components (hereinafter referred to as 'rock silt'). If it is included, it is post-treatment work because it will cause environmental pollution.

In order to post-treat the rock sludge generated in the production process of the fine aggregate, a power cyclone apparatus and a settler are used. The power cyclone apparatus classifies and recovers the sand in the rock sludge using centrifugal force, and the rock sludge discharged from the power cyclone apparatus is supplied to the settling tank. Since the chemical component such as a coagulant or flocculant is added to the precipitation tank, the rock silt aggregates and precipitates, and the precipitate is dehydrated using a filter press to make a sludge cake.

These sludge cakes are not recycled and become landfilled or piled up. Since the production of fine aggregates occurs in nearly the same amount as fine aggregates, it is difficult to secure landfills or yards and there is a concern of environmental pollution due to leachate.

In addition, the rock silt contained in the sludge cake is a very useful ingredient unlike soil powder, but it is not fully utilized. In general, fine powder in aggregate increases the unit yield of concrete and decreases the strength and durability of concrete, but rock silt is very useful because it increases the strength of concrete through the fine powder effect. In addition, when 3 to 5% of fine powder is contained in the concrete, the bleeding is reduced to have an appropriate level of viscosity, thereby reducing the material separation of the concrete. However, when the fine amount is more than 7%, the number of units required to maintain viscosity is excessive. In this case, the bleeding of the concrete may occur at 2 to 3% or less, which may result in material separation, and the filling may be degraded during construction, resulting in a rough surface of the concrete.

In other words, the conventional sand plant equipment is dehydrated after treating the entire rock sludge during the treatment of the rock sludge generated during the production of fine aggregates, and the chemical cannot be recovered sufficiently because the rock silt contained in the rock sludge cannot be recovered sufficiently. Since the amount of sludge cake consumed and finally discharged is large, it is difficult to dispose, and there is a disadvantage in that it does not fully utilize rock silt useful for concrete production.

The present invention has been made in order to solve the above-mentioned conventional problems, by recovering the rock silt contained in the rock sludge generated in the process of producing fine aggregates by water to treat the water, the consumption of chemicals used in the water treatment process It is an object of the present invention to provide a rock silt recovering device which can reduce and at the same time obtain useful rock silt.

In addition, an object of the present invention is to provide a rock silt recovery device to reduce the amount of sediment due to the chemical treatment by recovering the rock silt contained in the rock sludge to reduce the dehydration load and to reduce the amount of sludge cake.

The rock silt recovery apparatus of the present invention for achieving the above object comprises a cylindrical main body; A first inclined plate installed to be inclined inside the main body, the lower end of which is spaced apart from an inner wall of the main body; A second inclined plate installed in the main body to be inclined in a direction opposite to the first inclined plate and having a lower end spaced apart from an inner wall and a bottom of the main body; A conical water chamber having an upper end fixed to an upper edge of the main body and a hole through which rock silt escapes; A sludge inlet pipe installed at an upper side of the main body to supply rock sludge to an upper side of the first inclined plate; An overflow tube installed to communicate with an upper end of the water chamber and discharging the clear water located above the water chamber to a settling tank; And a discharge pipe communicating with the lower side of the second inclined plate and discharging the sedimentary rock silt.

In addition, according to the rock silt recovering apparatus of the present invention, a curved block plate having a hole formed in the center portion sagging downward is further provided on the upper side of the water chamber, and the overflow tube is communicated on the upper side of the blocking plate. It is done.

In addition, according to the rock silt recovering apparatus of the present invention, a hat-shape outer guide is installed in the lower portion of the water chamber and guides the rock silt exiting through the hole of the water chamber to the lower side of the second inclined plate; And a hat-shaped inner guide for guiding the sedimentary rock silt installed in the water chamber to the inner wall side of the water chamber.

In addition, according to the rock silt recovery apparatus of the present invention, the inner guide is formed in a structure in which two cone members connected to the support are arranged up and down, and is fixed to the inside of the water chamber by another support.

In addition, according to the rock silt recovery apparatus of the present invention, the water chamber is installed through the first inclined plate, the outer guide and its support is characterized in that installed through the second inclined plate.

In addition, according to the rock silt recovery apparatus of the present invention, the sludge inflow pipe is installed in a plurality of locations spaced apart from each other is characterized in that the vortex is formed by the collision of the introduced rock sludge.

The rock silt recovery apparatus of the present invention separates and recovers the rock silt contained in the rock sludge, thereby minimizing the fine components of the effluent discharged to the sedimentation tank, thereby reducing the consumption of chemicals during water treatment and finally reducing the amount of sludge cake discharged. The effect can be greatly reduced.

In addition, according to the rock silt recovery apparatus of the present invention, by recovering the high-strength rock silt contained in the rock sludge to be used in the production of concrete, it contributes to the high strength of the concrete and to reduce the amount of sand used in concrete production There is.

In addition, according to the rock silt recovering apparatus of the present invention, since the fine components of the rock sludge are sedimented and separated naturally without using external power, there is an effect of almost no maintenance cost.

In addition, according to the rock silt recovery device of the present invention, by blocking the upper part of the water chamber filled with water with a blocking plate and supplying only the clear water that has passed through the center hole to the settling tank can minimize the load of the settling tank and dehydration device It has an effect.

1 is a schematic view showing a rock silt recovery apparatus according to the present invention.
Figure 2 is a perspective view of the outer portion of the rock silt recovery device of the present invention cut away.
3 is a reference diagram showing the movement path of the rock silt in the rock silt recovery device of the present invention.
Figure 4 is a reference diagram showing the discharge path of the water separated from the rock silt in the rock silt recovery apparatus of the present invention.

Hereinafter, referring to the rock silt recovery apparatus of the present invention with reference to the accompanying drawings.

The rock silt recovery apparatus according to the present invention includes a cylindrical main body 10, as shown in Figs. A first inclined plate 11 installed to be inclined inside the main body 10 and having a lower end spaced apart from an inner wall of the main body 10; A second inclined plate 12 installed in the main body 10 in a direction opposite to the first inclined plate 11 and having a lower end spaced apart from an inner wall and a bottom of the main body 10; A conical water chamber 20 having an upper end fixed to an upper edge of the main body 10 and a hole 21 formed at a lower end thereof; A blocking plate 25 having a curved surface, which is further installed above the water chamber 20 and has a central portion formed therein with a hole 25 'bent downward; And a hat-shaped outer guide 13 installed at the lower portion of the water chamber 20 to guide the rock silt exiting through the hole 21 of the water chamber 20 to the lower side of the second inclined plate 12. ; A hat-shaped inner guide 23 for guiding the rock silt installed and settled inside the water chamber 20 toward the inner wall of the water chamber 20; A sludge inlet pipe 15 installed above the main body 10 to supply rock sludge to the upper side of the first inclined plate 11; An overflow pipe 22 installed to communicate with the water chamber 20 from an upper side of the blocking plate 25 and discharging the clear water located above the water chamber 20 to a settling tank; And a discharge pipe 16 communicating with a lower end of the second inclined plate 12 to discharge the settled rock silt.

Here, the water chamber 20 is installed through the first inclined plate 11, a plurality of supports 14 for fixing the outer guide 13 to the outer guide 13 and the water chamber 20. ) Is installed through the second inclined plate 12. In addition, the inner guide 23 is formed in a structure in which two cone members 23a connected by a plurality of support members 23b are disposed up and down, and a plurality of other support members installed in any one of the cone members 23a. It is fixed to the inside of the water chamber 20 by 23c.

The rock silt recovery device of the present invention configured as described above is to recover and separate the rock silt contained in the rock sludge and then send clear water containing only a trace amount of rock to the sedimentation tank.

By supplying and treating the rock sludge to the power cyclone (not shown), the fine aggregate is separated firstly, and the remaining rock sludge is sent to the settling tank (not shown), and the rock sludge is pumped by a pump (not shown) to introduce the sludge. The tube 15 is introduced into the body 10. In this case, when two or more sludge inlet pipes 15 are installed, the rock silt is easily separated by colliding with the introduced rock sludge to cause vortices. The rock sludge introduced into the main body 10 flows along the first slope plate 11 and the second slope plate 12, and in this process, the rock silt included in the rock sludge is separated. The separated rock silt exits through the gap between the lower ends of the first inclined plate 11 and the second inclined plate 12 and the inner wall of the main body 10, and then descends along the inner wall of the main body 10. At this time, the rock sludge flowing along the first slope plate 11 or the second slope plate 12 impinges the inner wall of the main body 10 at the lower end of the first slope plate 11 or the second slope plate 12. Therefore, the separation of the rock silt is made smoothly.

The rock silt separated from the rock sludge through the above process is discharged through the discharge pipe 16 connected to the lower end of the main body 10 and separated from the water by being filtered by a screen of a specific standard and exited to the bottom of the screen. Water is recycled to the power cyclone or sand plant.

As the rock silt is separated from the rock sludge as described above, water is filled in the main body 10. That is, since the diameter of the discharge pipe 16 is smaller than the diameter of the sludge inlet pipe 15, water that does not escape to the discharge pipe 16 is gradually filled. Accordingly, water is introduced into the water chamber 20 through the hole 21 of the water chamber 20, and a little air remains at the bottom of the first inclined plate 11 to allow the The water will not be completely filled inside. Further, since the rock sludge introduced through the sludge inlet pipe 15 continues to flow on the upper surface of the first inclined plate 11, water is preferentially filled in the water chamber 20 which is not subjected to resistance. Thereafter, the water filled in the water chamber 20 is discharged through the hole 25 'of the blocking plate 25 installed above the water chamber 20 and then supplied to the settling tank through the overflow pipe 22. .

In addition, since the water filled in the water chamber 20 hardly flows, the rock silt contained in the water cannot be separated and gradually settles in the stagnant water. The settled rock silt moves along the inner surface of the water chamber 20 and then exits through the hole 21 at the lower end, and along the upper surface of the outer guide 22 positioned below the water chamber 20. It is discharged to the lower portion of the second slope plate 12. In addition, the rock silt settled in the water chamber 20 is discharged through the hole 21 after moving to the inner wall of the water chamber 20 by the cone member 23a having a double structure.

On the other hand, instead of recovering the rock silt from the rock sludge discharged from the power cyclone as described above, the rock silt contained in the sludge cake is fed to the main body 10 by mixing and stirring sufficient water into the existing sludge cake. As with the recovery, it can also be used for reprocessing the sludge cake. In this case, however, it is preferable to reduce the consumption of additional water by supplying a liquid sludge cake to one of the plurality of sludge inflow pipes and supplying ordinary rock sludge to the remaining sludge inflow pipes.

Although the preferred embodiments of the present invention have been described above, the scope of the present invention is not limited to such specific embodiments, and those of ordinary skill in the art are appropriately within the scope described in the claims of the present invention. Changes will be possible.

10: main body
11: first slope
12: Second Incline
13: external guide
14: support
15: sludge inlet pipe
16: discharge pipe
20: water chamber
21: hole
22: overflow tube
23: Inside guide
23a: cone member
23b, 23c: support
25: blocking plate

Claims (6)

A cylindrical main body 10;
A first inclined plate 11 installed to be inclined inside the main body 10 and having a lower end spaced apart from an inner wall of the main body 10;
A second inclined plate 12 installed in the main body 10 in a direction opposite to the first inclined plate 11 and having a lower end spaced apart from an inner wall and a bottom of the main body 10;
A conical water chamber 20 having an upper end fixed to the upper edge of the main body 10 and a hole 21 through which rock silt escapes;
A sludge inlet pipe 15 installed above the main body 10 to supply rock sludge to the upper side of the first inclined plate 11;
An overflow tube 22 installed to communicate with an upper end of the water chamber 20 and discharging the clear water located above the water chamber 20 to a settling tank;
A rock silt recovery device comprising: a discharge pipe (16) communicating with a lower end of the second inclined plate (12) and discharging the settled rock silt. The method of claim 1,
A curved block plate 25 having a curved shape where the center portion 25 'is formed to be sag downward is further provided on the upper side of the water chamber 20,
The overflow pipe (22) is a rock silt recovery device characterized in that the communication in the upper side of the blocking plate (25). The method of claim 1,
And a hat-shaped outer guide 13 installed at the lower portion of the water chamber 20 to guide the rock silt exiting through the hole 21 of the water chamber 20 to the lower side of the second inclined plate 12. ; Rock silt recovery apparatus further comprises a; a hat-shaped inner guide (23) for guiding the rock silt installed and settled inside the water chamber (20) toward the inner wall side of the water chamber (20). The method of claim 3,
The inner guide 23 is formed in a structure in which two cone members 23a connected to the support 23b are arranged up and down, and fixed to the inside of the water chamber 20 by another support 23c. Rock silt recovery apparatus. The method of claim 3,
The water chamber 20 is installed through the first slope plate 11,
The external guide (13) and its support (14) is a rock silt recovery device, characterized in that installed through the second inclined plate (12). The method of claim 1,
The sludge inlet pipe 15 is installed in a plurality of spaced apart from each other rock silt recovery device, characterized in that the vortex is formed by the collision of the introduced rock sludge.

Images