CN218282678U

CN218282678U - Resource separation equipment

Info

Publication number: CN218282678U
Application number: CN202222296162.7U
Authority: CN
Inventors: 黄钊平
Original assignee: Zhongshan Yuantaili Transportation Co ltd
Current assignee: Zhongshan Yuantaili Transportation Co ltd
Priority date: 2022-08-30
Filing date: 2022-08-30
Publication date: 2023-01-13
Anticipated expiration: 2032-08-30

Abstract

The utility model discloses a resource separation equipment, including the equipment base, be equipped with first sieving mechanism on the equipment base in proper order, second sieving mechanism and third sieving mechanism, first sieving mechanism includes that first rivers erode part and first sieve mesh, the below that is equipped with the mud storage pool on the equipment base and is located first sieve mesh still is equipped with the suction part on the equipment base, the second sieving mechanism includes well screen cloth, the sieve mesh of well screen cloth is less than first screen cloth, it deposits the position to be equipped with the sand on the equipment base, still be equipped with the mixture storage pond on the equipment base, still be equipped with on the equipment base and can suck the suction subassembly that earth received the field with the mixture in the mixture storage pond, third sieving mechanism includes fine screen cloth, the sieve mesh of fine screen cloth is less than the sieve mesh of well screen cloth, still be equipped with conveyer on the equipment base. The utility model aims at overcoming the defects of the prior art and providing a resource separation device capable of recovering fine sand in building foundation mud.

Description

Resource separation equipment

[ technical field ] A method for producing a semiconductor device

The utility model relates to a resource separation equipment.

[ background ] A method for producing a semiconductor device

At present, a great amount of building foundation mud is dug in the urban construction process, the building foundation mud contains fine sand for building houses, and the building foundation mud is generally thrown into a soil receiving field directly, so that waste is caused, and therefore, a resource separation device capable of recycling the fine sand in the building foundation mud is needed.

[ Utility model ] A method for manufacturing a semiconductor device

The utility model aims at overcoming the defects of the prior art and providing a resource separation device capable of recovering fine sand in building foundation mud.

The utility model discloses a realize through following technical scheme:

a resource separation device comprises a device base 1, a first screening device 2, a second screening device 3 and a third screening device 4 are sequentially arranged on the device base 1, said first screening device 2 comprises a first water scouring member 21 for scouring the building foundation sludge to decompose the building foundation sludge into a mortar and first coarse solids, said first screening means 2 further comprise a primary screen 22 capable of allowing the slurry to drip and of shaking the first coarse solids down to the first deposit 11 on the base 1 of the apparatus, a slurry storage tank 12 is arranged on the equipment base 1 and below the primary screen 22, a suction component 5 capable of sucking the slurry in the slurry storage tank 12 upwards to the second screening device 3 is also arranged on the equipment base 1, the second screening device 3 comprises a middle screen 31 which can decompose and filter the mud sucked up by the suction part 5 into silt and second coarse solid, the sieve pores of the middle sieve net 31 are smaller than the primary sieve net 22, the equipment base 1 is provided with a sand storage position 13 for sand formed by dehydrating silt decomposed by the middle sieve net 31, the equipment base 1 is also provided with a mixture storage tank 14 for storing second coarse solid matters falling off from the middle screen 31 and water removed from the mud, the equipment base 1 is also provided with a suction assembly which can suck the mixture in the mixture storage pool 14 to a soil accepting field, the third screening device 4 comprises a fine screen 41 for further screening the sand dug from the sand storage 13, the fine screen 41 having a mesh size smaller than that of the medium screen 31, the equipment base 1 is also provided with a conveying device 6 which can convey the sand screened by the fine screen 41 to the outside.

The transportation device 6 comprises a support 61 arranged on the equipment base 1, a rotating frame 62 capable of rotating relative to the support 61 is arranged on the support 61, a plurality of hoppers 63 used for receiving and transporting sand screened out from the fine screen 41 are arranged on the rotating frame 62 in a circumferential mode, a second water flow washing part 64 used for washing the sand in the hoppers 63 is further arranged on the rotating frame 62, a fourth screen 65 connected with the hoppers 63 and used for washing water flow passing after the sand passes through is arranged on the rotating frame 62, and a transportation frame 66 used for transporting the sand outwards is further arranged below the set position of the hoppers 63 on the equipment base 1.

The fourth screen 65 is arranged in a circular shape and the fourth screen 65 encloses a screen space 650.

The transportation frame 66 is provided with a transportation surface 661 which can contain sand and make the material slide outward from the equipment base 1.

The rear end of the fine screen 41 is connected with an inlet platform 42 which can be used for excavating equipment to feed sand excavated from the sand storage position 13 into the fine screen 41, the front end of the fine screen 41 is connected with a discharge pipeline 43 which can be used for discharging gravel in the sand to the mixture storage pool 14, the fine screen 41 is also connected with a fourth water flow washing part 44 which is used for washing soil in the sand, the side edge of the fine screen 41 is provided with a discharge hole 411 which can discharge screened sand, and a feeding hole 611 which can guide the sand to enter the hopper 63 is arranged on the support 61 and below the discharge hole 411.

The fine screen 41 is a roller screen.

The middle screen mesh 31 is also provided with a third water flow scouring part 32 for scouring silt, the rear side of the middle screen mesh 31 and the equipment base 1 are also provided with a plurality of baffle plates 7 for preventing broken stones from being discharged out of the equipment base 1, and an inclined plate 8 capable of guiding the broken stones and the muddy water to enter the mixture storage pool 14 is connected between the baffle plates 7.

First rivers wash out part 21 including establishing the suction pump 211 on equipment base 1, suction pump 211 on be connected with the trunk line 212 that draws water, trunk line 212 that draws water on be connected with many water spray branch pipes 213 that can spray water outwards, trunk line 212 and suction part 5 between still be equipped with the moisturizing pipeline 214 of being connected the two.

The equipment base 1 is a ship body capable of floating on the water surface, a first platform 15 on which the excavating equipment can walk is arranged on the equipment base 1, the first stacking part 11 and the slurry storage tank 12 are arranged on the first platform 15, a second platform 16 on which the excavating equipment can walk is further arranged on the equipment base 1, and the mixture storage tank 14 is arranged on the second platform 16.

A stirring component 9 is arranged in the slurry storage tank 12, the stirring component 9 comprises a stirring frame 91 arranged in the slurry storage tank 12, a driving part 92 is arranged on the stirring frame 91, and a stirring knife 93 capable of rotating relative to the stirring frame 91 is connected to an output shaft of the driving part 92; the first screening device 2 further comprises a stockpiling hopper 23 which is arranged on the upper side of the primary screen 22 and used for receiving the building foundation mud, and the first water flow washing part 21 is connected to the stockpiling hopper 23.

Compared with the prior art, the utility model discloses there is following advantage:

1. after the transportation tool carrying the building foundation mud is moved to the equipment base, the building foundation mud is excavated and sent to the equipment base by the excavating equipment on the equipment base, at the moment, the building foundation mud is washed by the first water flow washing part and is decomposed into mud and first coarse solid matters, the first coarse solid matters mainly comprise stones, reinforcing steel bars, iron blocks, wood and other large solid matters in the building foundation mud, most of the mud in the building foundation mud is converted into the mud and drops into the mud storage tank, the remaining first coarse solid matters incapable of being converted into the mud fall into the first storage place, the mud in the mud storage tank is upwards sucked to the middle screen by the sucking part, the middle screen further decomposes the mud into mud and sand slurry and second coarse solid matters, the mud slurry flows into the sand storage place to be dehydrated, the sand is obtained after the dehydration, meanwhile, the second coarse solid matters and the mud water are discharged into the mixture storage tank, the mixture in the mixture storage tank is sucked to be stored in the storage place by the sucking assembly, the sand storage place is conveyed to the fine sand storage place through the excavating equipment, the sand required particle size is further extracted, and the sand is transported to the whole transportation device conveniently.

2. The second coarse solid in the mixture storage tank and muddy water separated from the muddy water are pumped to a shore soil receiving field by the pumping assembly. And the first coarse solid objects such as stones, steel bars, iron blocks, wood and the like at the first stacking position are transported by the transport vehicle for recycling. Due to the fact that the sand in the building soil is extracted and recycled through multiple screening, the mixture which cannot be utilized in the mixture storage pool is sucked to the soil receiving field through the suction assembly, and efficiency is high. Therefore, during the treatment of the building foundation mud, a part of the large solids is carried away by the transport vehicle, a part of the sand is extracted and recovered, and a part is pumped to the mud receiving site. Compare with the processing method of traditional building foundation mud, adopt the utility model discloses resource splitter not only can be quick handle building foundation mud, but also can be with the fine sand reuse in the building foundation mud, more environmental protection.

[ description of the drawings ]

Fig. 1 is one of the perspective views of the resource separation apparatus of the present invention;

fig. 2 is a second perspective view of the resource separation apparatus of the present invention;

FIG. 3 is a schematic diagram of the resource separation apparatus of the present invention;

FIG. 4 is a side view of the resource separation apparatus of the present invention;

fig. 5 is a perspective view of a third separation device in the resource separation apparatus of the present invention;

fig. 6 is a perspective view of a transportation device in the resource separation apparatus of the present invention;

fig. 7 is a cross-sectional view of the stirring component of the resource separating device of the present invention.

[ detailed description ] embodiments

As shown in fig. 1 to 7, a resource separation device comprises a device base 1, wherein a first screening device 2, a second screening device 3 and a third screening device 4 are sequentially arranged on the device base 1, the first screening device 2 comprises a first water flow scouring part 21 for scouring building foundation mud to decompose the building foundation mud into silt slurry and first coarse solid substances, the first screening device 2 further comprises a primary screen 22 for allowing the mud to drip and shaking the first coarse solid substances to a first depositing part 11 on the device base 1, a mud 12 is arranged on the device base 1 and below the primary screen 22, a suction part 5 capable of sucking the mud in the mud 12 upwards to the second screening device 3 is further arranged on the device base 1, the second screening device 3 comprises a middle screen 31 capable of decomposing the mud sucked by the suction part 5 into silt slurry and second coarse solid substances, the mesh of the primary screen 31 is smaller than that of the sand slurry in the secondary screen 22, a fine screen 13 for storing the mixture of sand slurry and sand slurry is arranged on the device base 1, and a fine screen 13 for storing the sand slurry and transporting the sand slurry mixture to a fine screen 13 arranged on the device base 1, and a fine screen 13 for transporting the device to a sand storage tank for storing the sand slurry, and transporting the sand slurry from the device base 1 to an external storage tank, and a sand storage tank for storing the sand storage tank 13.

When the transportation vehicle carrying the building foundation mud 10 is moved to the equipment base 1, the excavating equipment 103 on the equipment base 1 excavates the building foundation mud 10 outwards into the equipment base 1, at the same time, the first water flow scouring part 21 scours the building foundation mud 10, so that the building foundation mud 10 is decomposed into slurry 101 and first coarse solid matters 102, the first coarse solid matters 102 are mainly large objects such as stones, steel bars, iron blocks, wood and the like in the building foundation mud 10, most of the building foundation mud 10 is argillized into the slurry 101 and drops into the slurry storage tank 12, the remaining first coarse solid matters 102 incapable of being argillized into the slurry 101 fall into the first storage place 11, the slurry 101 in the slurry storage tank 12 is upwards sucked to the middle screen 31 by the suction part 5, the middle screen 31 further decomposes the slurry 101 into the slurry 1011 and the second coarse solid matters 1012, the slurry 1011 flows into the sand storage place 13 and is dewatered and stored, meanwhile, the second coarse solid matters 1012 and the separated slurry are discharged to the storage place 14, the mixture is transported to the fine sand storage tank 13 through the sand screening device, and the whole process of excavating equipment is carried out to the fine sand storage tank 6, and the whole transporting process is convenient for excavating and transporting. The muddy water separated from the second coarse solid matter 1012 and the muddy water 1011 in the mixture storage tank 14 is sucked by the suction means not shown in the drawings to the shore soil accepting site. And the first coarse solid matters such as stones, steel bars, iron blocks, wood and the like in the first stacking position 11 are transported by the transport vehicle for recycling. Due to the fact that the sand in the building soil is extracted and recycled through multiple screening, the mixture which cannot be utilized in the mixture storage pool 14 is sucked to the soil receiving field through the suction assembly, and the efficiency is high. Therefore, during the treatment of the building foundation mud, a part of the large solids is carried away by the transport vehicle, a part of the sand is extracted and recovered, and a part is pumped to the soil receiving site. Compare with the processing method of traditional building foundation mud, adopt the utility model discloses resource separation equipment, processing building foundation mud that not only can be quick, but also can utilize the fine sand in the building foundation mud once more, more environmental protection.

As shown in fig. 6, as shown in fig. 3 and 5, the transportation device 6 includes a support 61 disposed on the equipment base 1, a rotating frame 62 capable of rotating relative to the support 61 is disposed on the support 61, a plurality of hoppers 63 for receiving and transporting sand screened from the fine screen 41 are disposed on the rotating frame 62 around the circumference, a second water flow washing part 64 for washing sand in the hoppers 63 is further disposed on the rotating frame 62, a fourth screen 65 connected to the plurality of hoppers 63 and used for washing water after the sand passes through is disposed on the rotating frame 62, and a transportation frame 66 for transporting sand outwards is further disposed below a set position of the hoppers 63 on the equipment base 1. The rotating frame 62 is circular. The sand screened by the third screening device 4 gradually flows out to the bracket 61 and flows into the hopper 63, the rotating frame 62 rotates to gradually fill the plurality of hoppers 63, the plurality of hoppers 63 are overturned downwards gradually along with the opening of the hopper 63 when the rotating frame 62 reaches a preset position, the sand is poured onto the transportation frame 66 by the hoppers 63, and the transportation frame 66 directly transports the sand into a transportation vehicle without other transportation tools. When sand is contained in the hopper 63 and moves upwards, the cleaning hopper 63 washes the sand in the hopper downwards, when the hopper 63 moves to a preset position along with the rotating frame 62, the opening part of the cleaning hopper faces downwards, the sand in the hopper 63 is gradually poured into the transporting frame 66, when the hopper 63 which has poured the sand moves to the lower part of the transporting frame 62 along with the rotating frame 62, the opening part of the cleaning hopper 63 is gradually arranged upwards, and at the moment, the hopper 63 can contain the sand.

As shown in fig. 3 and 5, the transportation rack 66 is provided with a transportation surface 661 capable of containing sand and making the material slide outward from the apparatus base 1. And transportation frame 66 department can also set up drying equipment etc. and be used for drying the sand, and the long enough convenience that inclined plane 661 set up is air-dried. The transport frame 66 may be a belt having an inclined surface 661.

As shown in fig. 3 and 5, an inlet platform 42 for the excavating equipment to feed sand excavated from the sand storage position 13 into the fine screen 41 is connected to the rear end of the fine screen 41, a discharge pipe 43 for discharging crushed stones in the sand into the mixture storage tank 14 is connected to the front end of the fine screen 41, a fourth water flushing part 44 for flushing soil in the sand is further connected to the fine screen 41, a discharge hole 411 for discharging screened sand is formed in the side edge of the fine screen 41, and a feed port 611 for guiding sand into the hopper 63 is formed in the bracket 61 and below the discharge hole 411. The inlet platform 42 facilitates the excavating equipment 103 to temporarily place sand, so that the sand can sufficiently pass through the fine screen 41, and a better vibrating screen effect is achieved. The feed port 611 has a support plate disposed obliquely to facilitate the downward flow of sand into the hopper 63.

As shown in fig. 3 and 6, the fourth screen 65 is disposed in a circular shape and the fourth screen 65 encloses a screen space 650. During cleaning, a part of sand enters the screen space 650, and at the moment, the sand and water drop to the inner side of the fourth screen 65 and gradually enter other hoppers 63 in the rotating process of the rotating frame 62, so that waste is avoided.

As shown in fig. 2 and 3, the middle screen 31 is further provided with a third water flow scouring part 32 for scouring mud and sand, the rear side of the middle screen 31 and the equipment base 1 are further provided with a plurality of baffle plates 7 for preventing the crushed stones from being discharged out of the equipment base 1, and an inclined plate 8 capable of guiding the crushed stones and muddy water into the mixture storage tank 14 is connected between the baffle plates 7. The middle screen 31 is obliquely arranged, the second coarse solid 1012 screened by the middle screen 31 rolls downwards to be stopped by one of the baffle plates 7, gradually flows into the mixture storage pool 14 through the inclined plate 8, and mud water and sand and stones in the mixture storage pool 14 are discharged outwards through the suction assembly.

As shown in fig. 1 and fig. 2, the equipment base 1 is a ship hull capable of floating on the water surface. Therefore, the transportation equipment for the building foundation mud 10 can run in rivers according to needs and can be moored to a place needing to be moored according to needs, namely, after one soil accepting field is filled up, the transportation equipment can run to the place near the other soil accepting field, therefore, the utility model discloses resource separation equipment.

As shown in fig. 2, the equipment base 1 is provided with a first platform 15 on which the excavating equipment can travel, the first piling site 11 and the slurry storage tank 12 are provided on the first platform 15, the equipment base 1 is further provided with a second platform 16 on which the excavating equipment can travel, and the mixture storage tank 14 is provided on the second platform 16. When the excavating equipment 103 works, the excavating equipment can conveniently and freely excavate and feed materials by walking on the first platform 15 and the second platform 16. Because, if the excavating equipment 103 is driven to a transport ship for transporting the construction foundation mud 10 for excavating and feeding, the space for the movement is small and the efficiency is lowered.

As shown in fig. 1 and fig. 2, the first water flushing component 21 includes a water pump 211 disposed on the equipment base 1, the water pump 211 is connected to a main water pipe 212, the main water pipe 212 is connected to a plurality of water spraying branch pipes 213 capable of spraying water outwards, and a water replenishing pipe 214 connected to the main water pipe 212 and the suction component 5 is further disposed between the main water pipe 212 and the suction component 5. The water spray branch pipe 213 is connected to the first hopper 23. The suction component 5 comprises a suction pump 51 and a suction pipe 52 connected with the suction pump, when the mud 101 in the mud storage tank 12 is low, the water replenishing pipeline 214 is opened to replenish water to the suction pipe 52, the situation that the mud 101 in the mud storage tank 12 is low to cause the suction component 5 to suck air can be avoided, and the equipment damage can be avoided.

As shown in fig. 7, the slurry storage tank 12 is provided with an agitating member 9 therein, the agitating member 9 includes an agitating frame 91 provided in the slurry storage tank 12, the agitating frame 91 is provided with a driving member 92, and an output shaft of the driving member 92 is connected to an agitating blade 93 capable of rotating relative to the agitating frame 91. The driving member 92 drives the stirring knife 93 to rotate, so that the mud 101 can be prevented from settling in the mud storage pool 12, and the larger mud lumps in the mud 101 falling from the sieve holes of the primary sieve 22 can be stirred to be finer, so that the mud 101 can be diluted more, and the mud 101 can be sucked into the mud storage pool more easily. The stirring frame 91 is provided with a guy cable 94 which is connected with the stirring frame 91 and can pull the stirring frame 91 to rotate relative to the base body 11 so as to pull the stirring knife 93 out of the slurry storage tank 12. When the stirring knife 93 is jammed, the stirring knife 93 can be pulled out of the slurry storage tank 12 through the inhaul cable 94 for maintenance, and maintenance is more convenient.

As shown in fig. 1, at least two sets of the first screening devices 2 are arranged on the equipment base 1, so that at least two pieces of excavating equipment 103 can be simultaneously walked on the first platform 15, and the building foundation mud 10 can be simultaneously excavated from the transport ship through the two pieces of excavating equipment 103, so that the efficiency is higher.

As shown in fig. 1, the first screening device 2 further comprises a stockpiling hopper 23 disposed above the primary screen 22 for receiving the construction foundation mud 10, and the water scouring member 21 is connected to the stockpiling hopper 23. Building foundation mud 10 excavated by the excavating equipment 103 is thrown into the stockpiling hopper 23, the building foundation mud 10 is flushed in the stockpiling hopper 23, mud 101 and first coarse solid 102 formed by decomposition roll on the primary screen 22 to carry out vibration screening, the problem that the building foundation mud 10 is directly thrown on the primary screen 22 to be flushed to cause too short decomposition time of the building foundation mud 10 is avoided, large mud groups which can be decomposed due to too short flushing time are prevented from falling into the stacking position of the first coarse solid 102 without being timely decomposed is avoided, and therefore the building foundation mud 10 can be decomposed and converted into the mud 101 and the first coarse solid 102 to the maximum extent, the first coarse solid 102 falling into the stacking position of the first coarse solid 102 is reduced, the transportation times of subsequent transport vehicles are reduced, the efficiency is improved, the cost is reduced, the first coarse solid 102 can be recycled, and the energy is saved, and the environment is protected.

Claims

1. A resource separation apparatus, characterized in that: the device comprises a device base (1), wherein a first screening device (2), a second screening device (3) and a third screening device (4) are sequentially arranged on the device base (1), the first screening device (2) comprises a first water flow scouring part (21) for scouring building base mud to decompose the building base mud into silt and first coarse solids, the first screening device (2) further comprises a primary screen mesh (22) which can be used for allowing mud to drip and can vibrate the first coarse solids to a first stacking part (11) on the device base (1), a mud storage tank (12) is arranged on the device base (1) and below the primary screen mesh (22), the device base (1) is further provided with a suction part (5) which can upwards suck the mud in the mud storage tank (12) to the second screening device (3), the second screening device (3) comprises a sand screen mesh storage device (31) which can suck the mud sucked in the suction part (5) to filter the silt and the primary screen mesh (31) in the secondary screen mesh (3), and a mixture of the secondary screen mesh (31) which is used for storing silt and sand which is smaller than a dewatering device (31) which is arranged on the primary screen mesh storage device (1) and can suck the silt and can deposit silt, the silt (31) and a coarse screen mesh storage device (31) which is used for storing silt and can deposit silt, the silt (31) and can deposit silt which is arranged on the device base (1), the third screening device (4) comprises a fine screen (41) capable of further screening the sand dug from the sand storage position (13), the screen hole of the fine screen (41) is smaller than that of the medium screen (31), and a conveying device (6) capable of conveying the sand screened by the fine screen (41) to the outside is further arranged on the equipment base (1).

2. The resource separation apparatus according to claim 1, characterized in that: the sand screening and conveying device is characterized in that the conveying device (6) comprises a support (61) arranged on the equipment base (1), a rotating frame (62) capable of rotating relative to the support (61) is arranged on the support (61), a plurality of hoppers (63) used for receiving and conveying sand screened out from the fine screen (41) are arranged on the rotating frame (62) in a surrounding mode, a second water flow washing component (64) used for washing the sand in the hoppers (63) is further arranged on the rotating frame (62), a fourth screen (65) connected with the hoppers (63) and used for washing water after the sand passes through is arranged on the rotating frame (62), and a conveying frame (66) used for conveying the sand outwards is further arranged below the arrangement position of the hoppers (63) on the equipment base (1).

3. The resource separation apparatus according to claim 2, characterized in that: the fourth screen (65) is arranged in a circular shape, and a screen space (650) is enclosed by the fourth screen (65).

4. The resource separation apparatus according to claim 2, characterized in that: the conveying frame (66) is provided with a conveying surface (661) which can contain sand and enable materials to slide outwards the equipment base (1).

5. The resource separation apparatus according to claim 2, characterized in that: the sand screening device is characterized in that an inlet platform (42) which can be used for excavating equipment to send sand excavated from a sand storage position (13) into the fine screen (41) is connected to the rear end of the fine screen (41), a discharge pipeline (43) which can be used for discharging broken stones in the sand into a mixture storage pool (14) is connected to the front end of the fine screen (41), a fourth water flow scouring part (44) which is used for scouring soil in the sand is further connected to the fine screen (41), a discharge hole (411) which can discharge the screened sand is formed in the side edge of the fine screen (41), and a feeding hole (611) which can guide the sand to enter a hopper (63) is formed in the position, which is located below the discharge hole (411), on the support (61).

6. The resource separation apparatus according to claim 5, characterized in that: the fine screen (41) is a roller screen.

7. The resource separation apparatus according to claim 1, characterized in that: the middle screen (31) is also provided with a third water flow scouring part (32) for scouring silt, the rear side of the middle screen (31) is positioned on the equipment base (1) and is also provided with a plurality of baffle sheets (7) for preventing the broken stones from being discharged out of the equipment base (1), and an inclined plate (8) capable of guiding the broken stones and the muddy water to enter the mixture storage pool (14) is connected between the baffle sheets (7).

8. The resource separation apparatus according to claim 1, characterized in that: first rivers wash out part (21) including establishing suction pump (211) on equipment base (1), suction pump (211) on be connected with main pipe of drawing water (212), main pipe of drawing water (212) on be connected with many water spray branch pipe (213) that can outwards spray water, main pipe of drawing water (212) and suction part (5) between still be equipped with the moisturizing pipeline (214) of being connected the two.

9. The resource separation apparatus according to claim 5, characterized in that: the device comprises a device base (1) and is characterized in that the device base (1) is a ship body capable of floating on the water surface, a first platform (15) capable of enabling the excavating device to walk on the device base (1) is arranged on the device base (1), a first stacking position (11) and a slurry storage pool (12) are arranged on the first platform (15), a second platform (16) capable of enabling the excavating device to walk on the device base (1) is further arranged on the device base, and a mixture storage pool (14) is arranged on the second platform (16).

10. The resource separation apparatus according to claim 1, characterized in that: a stirring component (9) is arranged in the slurry storage tank (12), the stirring component (9) comprises a stirring frame (91) arranged in the slurry storage tank (12), a driving part (92) is arranged on the stirring frame (91), and a stirring knife (93) capable of rotating relative to the stirring frame (91) is connected to an output shaft of the driving part (92); the first screening device (2) further comprises a stacking hopper (23) arranged on the upper side of the primary screen (22) and used for receiving the building foundation mud, and the first water flow scouring part (21) is connected to the stacking hopper (23).