JP3150844B2 - Excavated waste soil treatment and regeneration plant - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plant for treating and reclaiming excavated waste soil (remaining soil or sludge) generated during various works.

[0002]

2. Description of the Related Art A cast-in-place pile method generally used in the related art is to form a pile directly in the ground by drilling on site. There are three types of this method: In the earth drill method, a cylindrical bucket is rotated to dig down, and every time soil is accumulated in the bucket, the bucket is pulled up to discharge the soil. In the all-casing method, a hammer grab bucket is dropped to seize earth and sand, and a casing tube is inserted into the hole so that the earth and sand do not collapse. In the reverse method, soil and sand are sucked up together with muddy water.

[0003] At present, the excavated soil is treated as sludge industrial waste for the cast-in-place pile method.
For example, as a method of dehydrating and solidifying sludge, addition of a cement-based solidifying agent, addition of a lime-based solidifying agent, temporary sun drying, and the like are performed. In such a treatment, reusable sand is also discarded, and strong alkalinity has a large effect on the environment.

[0004] In the case of the excavated waste soil treatment of the cast-in-place pile construction as well as the problem of the general waste treatment, the facilities for treating the waste and the disposal of the waste have been increasing year by year. There are few places and it is a big social and environmental problem.

However, the current state of excavated soil treatment in cast-in-place pile construction is as described above, and recycling of excavated waste soil is considerably delayed. In particular, in the earth drill method, since the excavated waste soil is in the form of high-concentration mud, it is difficult to treat the waste soil. At present, no effective recycling has been attempted.

An object of the present invention is to provide a plant for recycling excavated waste soil generated in various works including a cast-in-place pile work such as an earth drill method.

[0007]

As shown in the drawings of the first embodiment (FIGS. 1 to 4) or the drawings of the second embodiment (FIGS. 5 and 6), the excavation waste according to the first invention is described below. in the soil treatment recycling plant, as a primary treatment facility E _1, a first separator 1 and the first agitating means 2 and the second separator 4 and the second agitating means 6 and the third separator device 5 third agitating means 7 And Wherein in the first separator 1, the drilling waste soil predetermined
The first sediment A having a size equal to or more than the predetermined size and the second soil having a predetermined size or less are separated. In the first stirring means 2, the second earth and sand of a predetermined size or less from the first separation device 1 is stirred with muddy water to make raw water. In the second separation device 4, the raw water from the first stirring means 2 has a predetermined size smaller than the second earth and sand.
The upper third soil B, C is separated into muddy water including the fourth soil smaller than a predetermined size smaller than the third soil B, C. The second stirring means 6 stirs the muddy water containing the fourth earth and sand of a predetermined size or less from the second separation device 4. The third separation device 5
In the above, the muddy water from the second stirring means 6 is separated into a fifth sediment finer than the fourth sediment and having a predetermined size or more , and a muddy water containing the sixth sediment finer than the fifth earth and having a predetermined size or less . Then, the fifth sediment is separated into the second separating device 4
To return to. The third stirring means 7 stirs the muddy water containing the sixth earth and sand of a predetermined size or less from the third separation device 5. A return path 34 is provided for returning the muddy water from the third stirring means 7 to at least one of the first stirring means 2 and the first separation device 1.

[0008] The excavated waste soil treatment and regeneration plant according to the second invention is provided with fourth separation devices 9 and 59 in addition to the first invention. In the fourth separation devices 9 and 59, the muddy water from the third stirring means 7 is supplied to the sixth sediment D having a predetermined size or less .
And other separated water. Return paths 56 and 58 are provided for returning the separated water from the fourth separation devices 9 and 59 to at least one of the third stirring means 7, the second separation device 4, and the first separation device 1. I have.

[0009]

According to the first aspect of the present invention, the first separation device 1 produces the sediment A, and the second separation device 4 and the third separation device 5 produce the sediment B and C. Further, the muddy water from the third separation device 5 is returned to the first stirring device 2 and the first separation device 1 by the return path 34 via the third stirring device 7, and the amount of raw water is maintained.

[0010] In the second invention, in addition to the first invention, the earth and sand D is produced by the fourth separation devices 9,59.
Separated water is finally produced from the fourth separating devices 9 and 59, returned from the respective return paths 56 and 58, and diluted water for concentration adjustment of the third stirring means 7, the first separating device 1 or It is reused as washing water for the second separation device 4.

[0011] That is to say, to waste soil excavated in the form of mud and having a high concentration that is difficult to be separated into an effective substance, dewatering treatment separated water to be circulated is added and mixed to form a muddy state. A major feature is that various kinds of soil are produced from the muddy water, thereby effectively utilizing the excavated soil.

[0012]

First Embodiment First, an excavated waste soil treatment and regeneration plant according to a first embodiment of the present invention will be described with reference to FIGS.

The excavated waste soil treatment and regeneration plant shown in FIG. 1 can be roughly classified into a primary treatment facility E ₁ and a secondary treatment facility E ₂ . In primary treatment facility E ₁ has a low head screen 1 as the first separator, the raw water agitation tank 2 as the first stirring means, a double screen 4 as the second separator and a cyclone 5 as a third separator device Sand collector 3 comprising sieve fluid stirring tank 6 as second stirring means, muddy water adjustment stirring tank 7 as third stirring means, and stored muddy water stirring tank 8
And is installed. In the secondary treatment facility E _2, a screw decanter 9 of a fourth separating unit, installation and dilution water tank 10, the PAC tank 11, a clean fluid tank 12, a coagulant dissolving tank 13, a coagulant reservoir 14 Have been.

In the low head screen 1,
As shown in FIGS. 1 and 3, a sieve 16 vibrated by a vibrator 15 is provided, and excavated soil put in a hopper 17 as a supply port is separated by the vibrating sieve 16. And 2
Sediment A (gravel and clay) having a size of 5 mm or more is removed, and they are carried out from the outlet 1a by the belt conveyor 18. On the other hand, earth and sand (gravels and clay) of 25 mm or less is
Is sent to the raw water stirring tank 2 containing muddy water and is stirred by the blade stirrer 19. Water level float switch 20
Is for detecting the amount of raw water in the raw water stirring tank 2, and is an example of means for measuring the water level to detect the amount of raw water.

In the double screen 4 of the sand collector 3, as shown in FIGS. 1 and 2, an upper sieve 23 and a lower sieve 24 vibrated by a vibrator 22 are provided. The raw water is supplied to the supply port 4a by the first pump 21 based on the detection of the rise in the water level of the water level float switch 20.
From the lower sieve 24. The earth and sand B having a size of 2.5 to 3.0 mm or more separated by the lower sieve 24 is carried out by the belt conveyor 25 from the outlet 4b. On the other hand, 2.5
Mud water containing earth and sand of not more than mm is stored in the sieve water stirring tank 6 of the sand collector 3 from the outlet 4c, and is stirred by the blade stirrer 26. The water level float switch 27 is for detecting the amount of muddy water in the sieve fluid stirring tank 6. The overflow mud in the sieve agitation tank 6 returns to the raw water agitation tank 2 through an overflow pipe 28.

The mud in the sieve mud stirring tank 6 is supplied to a second pump 29 based on the detection of a rise in the water level by a water level float switch 27.
From the supply port 5a to the cyclone 5 of the sand collector 3
Sent to By the centrifugal action of this cyclone 5,
Mud water containing earth and sand of 2.5 mm or less is 0.074-2.5
mm and 0.074 mm or less. Sediment C of 0.074~2.5mm is sent over the upper sieve 23 in double screen 4 through the supply port 4d from the outlet 5b, the belt conveyor from the vibration dehydrated with outlet 4e by sand accumulated thereon sieve 23 It is carried out by 30 . The muddy water that has fallen from the upper sieve 23 onto the lower sieve 24 is treated in the same manner as described above. On the other hand, 0.074 mm
Mud containing the following clay is sent from the outlet 5c of the cyclone 5 to the mud adjusting and stirring tank 7 as overwater.

The adjusted muddy water stirring tank 7 stores the muddy water from the cyclone 5 and is stirred by a blade stirrer 31. The muddy water in the adjustment stirring tank 7 is circulated by a third pump 32 through a hydrometer 32 as a concentration detecting means.
The density is detected by measuring the specific gravity of the muddy water by the specific gravity meter 33. When the raw water level in the raw water stirring tank 2 drops,
The water level float switch 20 detects the lowering of the water level.
The fourth pump 34a is driven based on the detection signal, and the muddy water in the adjustment stirring tank 7 is supplied to the raw water stirring tank 2 by the return pipe 34. Therefore, the amount of raw water in the raw water stirring tank 2 is stabilized. The water level float switch 35 is for detecting the amount of muddy water in the adjusting and stirring tank 7, and is an example of a means for measuring the water level to detect the amount of muddy water. When the water level float switch 35 detects that the water level of the muddy water in the adjustment stirring tank 7 has reached a certain level or more, the fifth pump 3 based on the detection signal.
6 is driven, and the excess muddy water in the adjustment stirring tank 7 is sent to the stored muddy water stirring tank 8.

In this storage tank 8, the muddy water is stirred by a blade stirrer 37. When the sixth pump 38 is driven based on the detection of a decrease in the water level of the water level float switch 35 in the adjustment stirring tank 7, the muddy water in the storage tank 8 is returned to the adjustment stirring tank 7. The water level float switch 39 is for detecting the amount of muddy water in the stored muddy water stirring tank 8. When the water level float switch 39 detects that the muddy water level in the stored muddy water agitation tank 8 has exceeded a certain level, the seventh pump 4
0 is driven, mud in貯泥water stirring tank 8 is supplied as the screw decanter 9 screw agitator 41 in the secondary treatment facility E _2.

[0019] As described above, when the water level float switch 39 that the water level in the mud in貯泥water stirring tank 8 becomes constant below is detected in the secondary processing equipment E _2, Shimizu said clean fluid tank 12 is It is sent to the flocculant dissolving tank 13 by the eighth pump 42, and the various organic polymer flocculants and fresh water are stirred by the blade stirrer 43 to form a solution having a concentration of 0.1 to 0.2%. This solution is sent to the flocculant storage tank 14 by a ninth pump 44 and is stirred by a blade stirrer 45. Further, this solution is sent to the screw stirrer 41 by a tenth pump 46. On the other hand, polyaluminum chloride as a kind of inorganic coagulant in the PAC tank 11 is sent to the screw stirrer 41 by an eleventh pump 47. The addition amount of this polyaluminum chloride is 10 to 20 k.
g / sst. The muddy water from the muddy water stirring tank 8, the solution from the flocculant storage tank 14, and the polyaluminum chloride from the PAC tank 11 are mixed by the screw stirrer 41 and supplied to the screw decanter 9. The flocculant solution and the polyaluminum chloride are used to help separate muddy water.

In the screw decanter 9, as shown in FIG. 4, a rotary cylinder 49 is provided in a casing 48, and a screw conveyor 50 is provided in the rotary cylinder 49. A rotary cylinder 49 is provided around a central axis 50a by a differential gear mechanism 50b.
As a result, relative rotation with respect to the screw conveyor 50 is achieved. The mixed liquid from the screw stirrer 41 is formed into a floc shape in which each particle in the muddy water is combined, and is supplied to the supply port 51.
And the rotation center shaft 50a of the screw conveyor 50
It flows out between the outer periphery of the conveyor 50 and the inner periphery of the rotary cylinder 49 through the inside. Then, the water is separated into dewatered soil and separated water by centrifugal separation, and the dewatered soil D is carried out by the belt conveyor 53 through the outlet 52, and the separated water is sent to the dilution water tank 10 through the outlet 54 to be re-used. It is stored as use water.

When the specific gravity of the muddy water detected by the hydrometer 33 in the adjusting and stirring tank 7 rises above a certain level, the twelfth
When the pump 55 is driven, the water in the dilution water tank 10 is returned to the return pipe 56.
Is passed to the adjusting and stirring tank 7 to dilute the muddy water therein. Further, the water in the dilution water tank 10 is sent by the thirteenth pump 57 through the return pipe 58 to the upper screen 23 of the double screen 4 of the sand collector 3 and is sent to the screen 16 of the low head screen 1, Used as washing shower water.

The excavated waste soil treatment and regeneration plant according to the first embodiment has the following features. (A) Primary treatment equipment E for excavated waste soil (remaining soil or sludge-like material) generated by cast-in-place pile construction by the earth drill method, etc.
_{In 1} , separation is performed by the following processing.

First, by the low head screen 1, 2
It produces sediment A of 5 mm or more. Second, sand collector 3 consisting of double screen 4 and cyclone 5
With the soil B of more than 2.5-3.0mm, 0.074
It produces up to 2.5 mm of earth and sand C.

[0024] (b) In addition, in the secondary processing equipment E _2, and the mud exiting from the primary processing facility E ₁ was separated by the following process. Thirdly, the screw decanter 9 produces earth and sand D of 0.074 mm or less.

[0025] (c) is treated with all the muddy water coming from the primary processing facility E ₁ secondary processing equipment E _2, it is effectively utilized by processing all of the product water out of the screw decanter 9 below.

[0026] First, and reused as the specific gravity adjusting dilution water mud in adjusting the stirring tank 7 in the primary processing facility E _1. Secondly, and reused as washing shower water for the double screen 4 and a low head screen 1 of sand collector 3 in the primary processing facility E _1.

As shown in (a), (b) and (c) above, all of the excavated waste soil which has been difficult to regenerate in the past is actively used as the four types of recycled soil A, B, C and D.
It can be effectively used for various applications depending on their properties.

Further, water separated from the excavated waste soil is not discharged in consideration of the environment, and is effectively used in the equipment. Since it is desirable not to release this water at all, it is managed so that no excess water is generated.

[0029]

Second Embodiment Next, a second embodiment of the present invention will be described with reference to FIGS. In this second embodiment, in place of the screw decanter 9 in the primary processing facility E ₂ of the first embodiment, a filter press 59 as a fourth separator
I use. In this connection, while omitting the secondary processing equipment E ₂ DeKiyoshi aquarium 12 of the first embodiment and the coagulant dissolving tank 13 and the coagulant reservoir 14 screw agitator 41, primary treatment of the first embodiment We are adding a slurry stirred tank 60 in the equipment E _1.

[0030] water level float switch 39 that the water level of the mud in貯泥water stirred tank 8 by the primary processing facility E ₁ exceeds a specific detects, seventh pump 40 is driven, the mud from貯泥water stirring tank 8 While being sent to the slurry stirring tank 60, the eleventh pump 47 is driven in the PAC tank 11 to send the polyaluminum chloride to the slurry stirring tank 60,
They are stirred by the blade stirrer 61. The water level float switch 62 is for detecting the amount of slurry in the slurry stirring tank 60.

As shown in FIG. 6, in the filter press 59, the fixed holding plate 64 and the movable holding plate 6
In a state where the filter plates 66 are pressed against each other, the filter cloths 67 are also pressed and sandwiched between the filter plates 66 adjacent to each other, and a filter chamber 68 surrounded by the filter cloths 67 is formed. Is done. When the water level float switch 62 detects that the water level of the slurry has become equal to or higher than a predetermined level in the slurry stirring tank 60, the fourteenth pump 63 is driven and the fixed holding plate 64
The slurry is supplied from the slurry stirring tank 60 to the slurry pressure inlet 69 on the side. This slurry is pressed into each filter chamber 68 through the communication hole 70 of each filter plate 66, and the water in each filter chamber 68 is discharged from the filtrate outlet 71 through both filter cloths 67. The dewatered cake K remains in each filtration chamber 68. When the movable holding plate 65 is separated from the fixed holding plate 64, each filter plate 66 is moved one by one to the movable holding plate 65 side. At this time, each filter plate 66 separates, and the dewatered cake K falls on the belt conveyor 72. The dewatered cake K is sent from the belt conveyor 72 to the crusher 73. Thereafter, the earth and sand D is carried out by the belt conveyor 74. On the other hand, the water discharged from the filtrate outlet 71 falls on the water receiving tray 75 and is then sent to the dilution water tank 10.

The other operations are the same as in the first embodiment. Also in the second embodiment, as in the case of the first embodiment, the excavated waste soil is composed of four types of recycled soil A, B,
In addition to being effectively used as C and D, the water generated during the production is effectively used in the facility without being discharged.

Considering the above embodiments, the following concept can be understood. (A) The first separation device (low head screen 1) according to claim 1 has a sieve 16, a supply port (hopper 17) for excavated soil placed on the sieve 16, and a predetermined size that does not pass through the sieve 16. The outlet 1a through which the first earth and sand A is carried out and the outlet 1b through which the second earth and sand smaller than a predetermined size passing through the sieve 16 are carried out. Here, the sieve 16 has a predetermined size depending on whether the excavated soil passes through many small holes.
This refers to a material that can be sorted into earth and sand having a size equal to or larger than a predetermined size and earth and sand having a size equal to or less than a predetermined size , and does not necessarily require vibration.

(B) The first stirring means in claim 1 is a raw water stirring tank 2 having a stirring function (blade stirrer 19).
It is. (C) The second separation device (double screen 4 of the sand collector 3) in claim 1 has a sieve (the upper sieve 23 and the lower sieve 24), and sieves the raw water from the raw water stirring tank 2 of (b). 24, an outlet 4b for carrying out soil B having a predetermined size or more that is not passed through the sieve 24 (finer than the second sand), and a predetermined outlet passing through the sieve 24.
And an outlet 4c for carrying out muddy water containing fourth earth and sand ( thinner than the third earth and sand B). The sieves 23 and 24 mentioned here have the same meaning as the sieve of (a).

(D) The second stirring means in claim 1 is a sieve water stirring tank 6 having a stirring function (blade stirrer 26). (E) The third separation device according to claim 1 is a centrifuge (cyclone 5), and the sieve water stirring tank 6 according to (d) above.
Supply port 5a into which the muddy water enters from, an outlet 5b through which the fifth earth and sand (thinner than the fourth earth and sand) of a predetermined size or more are carried out, and a sixth earth and sand (thinner than the fifth earth and sand) of a predetermined size or less And an outlet 5c through which muddy water containing the same is discharged. In the second separation device (double screen 4) of the above (c), the sediment from the outlet 5b is put into the sieve 23.
It has a supply port 4d placed on the upper side and an outlet 4e from which earth and sand C that does not pass through the sieve 23 is carried out. This second separation device (double screen 4) comprises an upper sieve 23 and a lower sieve 2
4 is provided. The earth and sand from the outlet 5b are supplied to the supply port 4d.
Is led to the upper sieve 23. The earth and sand C that does not pass through the upper sieve 23 is carried out from the outlet 4e. Here, the cyclone 5 is a device that separates and collects using the centrifugal force generated when the muddy water entering from the supply port 5a turns, and when the muddy water moves toward the outlet 5b while turning around the central discharge pipe, the mass is reduced. Large and larger soils of a predetermined size or more are discharged to the outer periphery of the swirling flow by centrifugal force and accumulate at the outlet 5b, and muddy water containing soil of a predetermined size or less is carried out from the outlet 5c of the central discharge pipe. I have.

(F) The third stirring means in claim 1 is a muddy water adjustment stirring tank 7 having a stirring function (blade stirrer 31). (G) The fourth separation device according to claim 2 is a centrifugal separator (screw decanter 9) or a pressure filter (filter press 59), and the supply port 51 into which the muddy water from the adjusting and stirring tank 7 described in (f) enters. , 69 and outlets 52, 72 through which the sixth soil D having a predetermined size or less is carried out, and outlets 54, 75 through which finally remaining separated water is carried out.

(H) The centrifugal separator is a general term for those utilizing centrifugal force for separating muddy water. Among them, the screw decanter 9 of (g) is a so-called cylindrical decanter, and muddy water supplied from the supply port 51 to the rotary cylinder 49 is concentrated and dewatered in the rotary cylinder 49, and the separated water is supplied to the outlet 5.
4 and the soil D concentrated on the inner peripheral surface of the rotary cylinder 49 is forcibly conveyed to the outlet 52 by the screw conveyor 50.

(I) The above-mentioned pressure filter is a general term for those which pressurize and filter muddy water. Among them, (g)
In the filter press 59, a plurality of filter plates 66 are provided between the relatively movable plates 64 and 65 which are close to and separated from each other.
Are arranged side by side in the direction of relative movement, and both filter cloths 67 are provided between the filter plates 66, and the filter cloths 67 between the filter plates 66 pressed against each other between the both boards 64, 65 are clamped. A filter chamber 68 surrounded by both filter cloths 67 is formed between the filter plates 66, and when the slurry is pressed into each filter chamber 68 from the slurry pressure inlet 69 communicating with each filter chamber 68, Is discharged from the filtrate outlet 71 through the filter cloth 67, and the dewatered cake K remaining in each filter chamber 68 is discharged along with the separation of each filter plate 66.

(V) Separated water from the fourth separator of (g) is sent to the dilution water tank 10. Each return path 56, 58 in claim 2 is connected to this dilution water tank 10. (R) A stirring tank (stirring water stirring tank 8 or slurry stirring tank 60) for stirring the muddy water from the adjustment stirring tank 7 described in (f) above is provided, and the muddy water from this stirring tank is subjected to the fourth separation in (g) above. Supplying equipment.

(ヲ) In the muddy water adjusting and stirring tank 7 of (f), a concentration detecting means 33 is provided.
A control means for driving and controlling a pump 55 is provided so that when the measured concentration of 3 becomes higher than the set concentration, the separated water is sent from the dilution water tank 10 of the above (v) to the adjusted stirring tank 7 through the return pipe 56. I have. Accordingly, the final separated water is fed by a required amount, and the concentration of the muddy water in the adjustment stirring tank 7 is automatically kept constant, so that the muddy water can be surely separated in the fourth separating device (g).

(W) In the raw water stirring tank 2 of (B), a raw water amount detecting means 20 is provided.
When the measured raw water amount of 0 becomes larger than the set raw water amount,
A control means for driving and controlling the pump 34a so as to send the muddy water from the muddy water adjusting and stirring tank 7 to the raw water stirring tank 2 through the return pipe 34 is provided. Therefore, the amount of raw water can be automatically kept constant, and the raw water can be smoothly supplied to the second separation device in (c).

(F) The coagulant from the muddy water coagulant supply means is supplied to the fourth separation device of (g). In the above embodiment, the PAC tank 11
And the coagulant storage tank 14 and the like.

[0043]

According to the excavated waste soil treatment and regeneration plant of the present invention, excavated waste soil, which had been difficult to regenerate in the past, is separated and dewatered to produce recycled soil A, B, C, and D. It can be effectively used for applications. In addition, the separated water from the excavated waste soil can be circulated and used effectively in the facility without being discharged.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing an excavated waste soil treatment and regeneration plant according to a first embodiment.

FIG. 2 is an enlarged view of the sand collector shown in FIG.

FIG. 3 is an enlarged view of the low head screen shown in FIG.

FIG. 4 is an enlarged view of the screw decanter shown in FIG.

FIG. 5 is a circuit diagram showing an excavated waste soil treatment and regeneration plant according to a second embodiment.

FIG. 6 is an enlarged view of the filter press shown in FIG.

[Explanation of symbols]

1. Low head screen as first separating device 2.
Raw water stirring tank as first stirring means, 3 ... sand collector, 4 ... double screen as second separation device, 5 ...
Cyclone as a third separating device, 6 ... sieve water stirring tank as second stirring means, 7 ... muddy water adjusting stirring tank as third stirring means, 8 ... stored muddy water stirring tank, 9 ... screw as fourth separating device Decanter, 10: dilution water tank, 11: PAC
Tank, 14: flocculant storage tank, 16: sieve, 23: upper sieve, 2
4 Lower sieve, 34 Return pipe as return path, 56 Return pipe as return path, 58 Return pipe as return path, 59
... Filter press as fourth separating device, 60. Slurry stirring tank, AD: earth and sand.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-6-106193 (JP, A) JP-A-7-51698 (JP, A) JP-A-7-25948 (JP, A) 35980 (JP, B2) (58) Fields investigated (Int. Cl. ⁷ , DB name) B03B 9/00-9/06 B09B 5/00 C02F 11/00 C02F 12/12-11/14 E02F 7/00

Claims (2)

(57) [Claims] And 1. A first separation apparatus for separating drilling waste soil to a predetermined size or more first sediment and (A) and a predetermined size following the second sediment (1) from the first separator (1) A first stirring means (2) for stirring the second earth and sand having a predetermined size or less together with the muddy water into raw water; and a raw water from the first stirring means (2) which is finer than the second earth and sand having a predetermined size or more . A second separation device (4) for separating into three soils (B, C) and a muddy water containing a fourth earth and sand smaller than a predetermined size smaller than the third soil (B, C); A second stirring means (6) for stirring the muddy water containing the fourth earth and sand having a predetermined size or less from 4); and a muddy water from the second stirring means (6) having a predetermined size finer than the fourth earth and sand. a fifth sediment, in the muddy water containing the sixth sediment following detailed predetermined size than the fifth sediment Apart and the fifth sediment the second separator (4) third separation device back to (5), first to stir the mud containing a predetermined size following the sixth sediment from the third separator (5) A return path for returning the muddy water from the third stirring means (7) to one of the first stirring means (2) and the first separation device (1). 34) An excavated waste soil treatment and regeneration plant characterized by the provision of 34). The muddy water from the third stirring means (7) is supplied to a predetermined
A fourth separator (9, 59) for separating the sixth earth and sand (D) having a size equal to or smaller than water and other separated water, and a third stirring unit (9, 59) for separating the separated water from the fourth separator (9, 59). 7), second separating device (4) and first separating device (1)
Return route to return to at least one of (56,
The excavated waste soil treatment and regeneration plant according to claim 1, wherein 58) is provided.