CN220160484U - Anti-blocking concrete sand-stone separation equipment - Google Patents

Abstract

The utility model relates to anti-blocking concrete sand-stone separation equipment, which comprises a separator shell, wherein one end of the separator shell is provided with a sand discharge port for discharging sand grains and a stone discharge port for discharging stones; a hopper connected to the separator housing; the screening cylinder is connected in the separator shell, the screening cylinder is communicated with the hopper, a plurality of screening holes are formed in the peripheral wall of the screening cylinder, sand grains can pass through the screening cylinder through the screening holes of the screening cylinder, the screening cylinder is connected with a driving motor, and the driving motor can drive the screening cylinder to rotate around the axis of the driving motor; and the cleaning device is connected to the separator shell and comprises a cleaning ball body, the cleaning ball body is connected with a connecting spring, and the connecting spring applies acting force to the cleaning ball body, so that the cleaning ball body stretches into the screening hole of the screening cylinder. The utility model has the effects of cleaning the screening holes of the screening cylinder and preventing the screening cylinder from being blocked.

Description

Anti-blocking concrete sand-stone separation equipment

Technical Field

The utility model relates to the field of concrete treatment, in particular to anti-blocking concrete sand and stone separation equipment.

Background

The sand-stone separation equipment is core equipment used in a concrete recovery system, and has the main application scene that after a mixer truck discharges concrete grouting, the concrete mixer truck is flushed with water, a large amount of sand and stone mixtures are mixed in the flushed water to form slurry, and the stone has recycling value, so that the cleaning water mixed with the sand and the stone is led into the sand-stone separation equipment, and sand grains and the stone are separated by the sand-stone separation equipment, so that the recycling of the stone is realized.

The existing concrete sand-stone separation equipment is usually characterized in that mixed slurry mixed with stone and sand grains is poured into a screening cylinder with screening holes, and the mixed slurry in the screening cylinder is driven to rotate or stir, so that the mixed slurry and the screening cylinder relatively move, water and sand grains with smaller volumes are discharged from the screening holes of the screening cylinder, and stone with larger volumes is left in the screening cylinder, so that the separation of sand grains, slurry and stone is realized.

Aiming at the existing concrete sand and stone separation equipment, the inventor finds that the existing concrete sand and stone separation equipment can be mixed with muddy sand and stones into slurry by water for flushing a concrete mixer truck in the use process, and the more viscous slurry mixed liquid with higher density can block the screening holes of the screening cylinder, so that the sand and stone separation efficiency is lower.

Disclosure of Invention

In order to clean screening holes of a screening cylinder and prevent the screening cylinder from being blocked, the utility model provides anti-blocking concrete sand-stone separation equipment.

The utility model provides anti-blocking concrete sand-stone separation equipment which adopts the following technical scheme:

an anti-blocking concrete sand-stone separation device comprises,

the separator comprises a separator shell, wherein one end of the separator shell is provided with a sand discharge port for discharging sand grains and a stone discharge port for discharging stones;

a hopper connected to the separator housing;

the screening cylinder is connected in the separator shell, the screening cylinder is communicated with the hopper, a plurality of screening holes are formed in the peripheral wall of the screening cylinder, sand grains can pass through the screening cylinder through the screening holes of the screening cylinder, the screening cylinder is connected with a driving motor, and the driving motor can drive the screening cylinder to rotate around the axis of the driving motor; the method comprises the steps of,

the cleaning device is connected to the top of the separator shell and comprises a cleaning ball body, the cleaning ball body is connected with a connecting spring, and the connecting spring applies acting force to the cleaning ball body, so that the cleaning ball body stretches into a screening hole of the screening cylinder.

Through adopting above-mentioned technical scheme, when the user uses, the user pours the mixed thick liquid after sand, stone mix into the hopper, and in falling into screening section of thick bamboo along falling into, driving motor drives screening section of thick bamboo and rotates, thereby make the mixed thick liquid take place relative movement in screening section of thick bamboo with screening section of thick bamboo, outside the screening section of thick bamboo is gone out through the screening hole of screening section of thick bamboo to moisture and the mud sand that the volume is less in the mixed thick liquid in the removal in-process, the stone that the volume is great then remains in the screening section of thick bamboo, thereby realize separating mud sand and stone, when the screening hole of screening section of thick bamboo rotates to being close to cleaning device position department, the clearance spheroid stretches into the screening hole of screening section of thick bamboo under connecting spring's effect, push back into the screening section of thick bamboo with the mud sand that blocks up the screening hole, thereby reduce the mud sand and continue to block the screening hole of screening section of thick bamboo.

Optionally, the separator housing is connected with the mounting bracket, and the spout has been seted up to the mounting bracket, clearance spheroid sliding connection is in the spout of mounting bracket, and the clearance spheroid can stretch out outside the mounting bracket through the spout of mounting bracket.

Through adopting above-mentioned technical scheme, when the user uses, clearance spheroid sliding connection in the spout of mounting bracket, the spout of mounting bracket plays the effect of constraint clearance spheroid slip direction, makes the clearance spheroid can align screening hole of screening section of thick bamboo, avoids the clearance spheroid swing to lead to can't stretch into in the screening hole of screening section of thick bamboo.

Optionally, the size of the aperture of the screening hole of the screening cylinder near the position of the outer peripheral wall of the screening cylinder is larger than the aperture of the screening hole near the inner peripheral wall of the screening cylinder.

Through adopting above-mentioned technical scheme, when the user uses, the aperture size that screening hole is close to screening section of thick bamboo periphery wall position department is greater than the aperture size that is close to screening section of thick bamboo inner peripheral wall, makes the clearance ball can stretch into screening hole of screening section of thick bamboo more easily.

Optionally, the separator casing corresponds the screening section of thick bamboo below position department is connected with the drainage board, and the rivers can pass the drainage board setting, and the transversal circular arc of drainage board is personally submitted, and the drainage board is by keeping away from the sand outlet position department of separator casing to be close to the sand outlet position department downward sloping setting of separator casing.

Through adopting above-mentioned technical scheme, when the user uses, the silt and sand mixture that separates through screening section of thick bamboo falls on the drainage board, and rivers wear the drainage board, and silt and sand then remove the sand outlet through the separator housing along the drainage board of slope and discharge outside the organism.

Optionally, the water filtering plate is connected with a vibration motor, and the vibration motor can drive the water filtering plate to vibrate.

Through adopting above-mentioned technical scheme, when the user uses, vibrating motor can drive the reciprocal vibration of drainage board, reduces the silt particle that falls on the drainage board and takes place the adhesion, makes silt particle can be followed the drainage mouth of drainage board to the separator housing and discharged.

Optionally, the separator casing is connected with the water collection storehouse corresponding to the position below the water filtering plate, and the rivers that pass the water filtering plate can pass the water filtering plate and enter into the water collection storehouse.

Through adopting above-mentioned technical scheme, when the user uses, the water collecting bin plays the effect of collecting the rivers of wearing to filter the water board.

Optionally, cleaning device still includes washs shower nozzle and water pump, the water pump connect in the water collecting bin, washs the shower nozzle with the water pump is linked together, it connects in the separating centrifuge casing to wash the shower nozzle, it can be to screening section of thick bamboo direction blowout rivers clearance screening section of thick bamboo to wash the shower nozzle.

Through adopting above-mentioned technical scheme, when the user uses, rivers in the water collection storehouse are pumped into the washing shower nozzle by the water pump in, wash screening section of thick bamboo along washing shower nozzle blowout, reduce the condition that the downthehole silt sand of screening section of thick bamboo is hardened, be convenient for follow-up clear up the downthehole blocked silt sand of screening section of thick bamboo.

Optionally, the inner peripheral wall of the screening cylinder is connected with a spiral fan blade, and the spiral fan blade is arranged towards the stone discharging port of the separator shell.

Through adopting above-mentioned technical scheme, when the user uses, screening section of thick bamboo rotates and drives the spiral flabellum and rotate, and spiral flabellum rotates and drives the mixed thick liquid and remove to the stone exhaust mouth of separating centrifuge casing along the inner peripheral wall of screening section of thick bamboo.

Optionally, separator casing corresponds self row stone mouth position department and is connected with conveyor, conveyor include the transport casing and transfer in the transport casing axis of rotation, the periphery wall of axis of rotation is connected with auger blade, the axis of rotation can drive auger blade rotation, the transport casing bottom is kept away from separator casing position department and has been seted up the discharge port, and auger blade rotation can drive the grit along carrying the casing and pass through the discharge port discharge of transport casing.

Through adopting above-mentioned technical scheme, when the user uses, the user rotates the axis of rotation, makes the axis of rotation drive auger blade rotate, and the stone of the row of stone mouth exhaust through the separator housing is driven along carrying the length direction of casing by auger blade and removes, and the moisture that mixes in this in-process stone flows down along carrying the casing, and the stone then continues to remove, and until auger blade drives the stone and removes the discharge port position department of carrying the casing, the stone is discharged through carrying the discharge port of casing, realizes the abundant separation of stone and silt particle.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present utility model;

FIG. 2 is a cross-sectional view of the overall structure of an embodiment of the present utility model;

FIG. 3 is an enlarged view of portion A of FIG. 2;

FIG. 4 is a top view of a screen drum according to an embodiment of the present utility model;

fig. 5 is a cross-sectional view of the structure of a conveyor according to an embodiment of the present utility model.

Reference numerals illustrate: 1. a separator housing; 11. a frame; 12. a hopper; 13. a stone discharging port; 14. a sand discharge port; 15. a driving motor; 16. a water filtering plate; 17. a water collecting bin; 18. a vibration motor; 2. a sieving cylinder; 21. spiral fan blades; 22. screening holes; 3. a cleaning device; 31. a mounting frame; 32. a chute; 33. a connecting spring; 34. cleaning the ball; 4. a water pump; 41. a water pipe; 42. cleaning the spray head; 5. a conveying device; 51. a conveying housing; 52. a delivery tube; 53. filtering holes; 54. a rotating shaft; 55. auger blades; 56. lifting the motor; 57. a discharge port; 58. and a discharge pipe.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-5.

The embodiment of the utility model discloses anti-blocking concrete sand and stone separation equipment, which is disclosed by referring to fig. 1 and 2, and comprises a separator shell 1, a rack 11 fixedly connected in the shell and a hopper 12 fixedly connected with one end of the separator shell 1 along the length direction of the separator shell, wherein the hopper 12 is communicated with the separator shell 1. The separator housing 1 is provided with a sand discharge port 14 for discharging sand particles and a stone discharge port 13 for discharging stones at a position far away from the hopper 12. The screening cylinder 2 is rotatably connected in the separator shell 1 through the frame 11, the screening cylinder 2 is cylindrical, the opening is arranged towards the hopper 12, and the hopper 12 is communicated with the screening cylinder 2. The screening drum 2 is arranged in the separator housing 1 obliquely downwards from the end close to the hopper 12 to the end remote from the hopper 12. The inner peripheral wall of the screening cylinder 2 is fixedly connected with a spiral fan blade 21. The periphery wall of the screening cylinder 2 is provided with a plurality of screening holes 22, each screening hole 22 is in a horn shape, and the pore size of the screening hole 22 at the position close to the periphery wall of the screening cylinder 2 is larger than that of the screening hole 22 at the position close to the inner periphery wall of the screening cylinder 2. The separator housing 1 top is close to hopper 12 position department and installs driving motor 15, and driving motor 15's output shaft has the belt pulley, and the belt pulley cover is equipped with the belt, and the outer peripheral wall of screening section of thick bamboo 2 is located to the belt cover, and driving motor 15's output shaft rotation can drive screening section of thick bamboo 2 through belt and belt pulley and rotate.

Referring to fig. 2 and 3, a cleaning device 3 is further connected in the separator housing 1, the cleaning device 3 includes a mounting frame 31 fixedly connected to the inner wall of the separator housing 1 corresponding to the position above the sieving cylinder 2, and the length direction of the mounting frame 31 is set along the length direction of the separator housing 1. The bottom surface of the mounting frame 31 is arranged in an upward inclined manner from a position far away from the hopper 12 to a position close to the hopper 12, and the inclined direction of the bottom surface of the mounting frame 31 is mutually parallel to the axial direction of the screening cylinder 2. A plurality of spouts 32 have been seted up to mounting bracket 31 bottom, the interval between two adjacent spouts 32 is equal with the interval between two adjacent screening holes 22 of screening section of thick bamboo 2 periphery wall along screening section of thick bamboo 2 axial, the vertical setting of axial of spout 32, all fixedly connected with coupling spring 33 in every spout 32 of mounting bracket 31, every coupling spring 33 all fixedly connected with clearance spheroid 34, clearance spheroid 34 is made by elastic plastic material, clearance spheroid 34 sliding connection is in spout 32 that mounting bracket 31 corresponds. The connecting spring 33 applies a force to the cleaning sphere 34 that causes the cleaning sphere 34 to extend into the screening hole 22 of the screening drum 2.

When the sand and gravel screening machine is used by a user, the user pours sand and gravel mixed pulp into the sand and gravel screening machine through the hopper 12, the mixed pulp falls into the screening barrel 2 through the hopper 12, the driving motor 15 drives the screening barrel 2 to rotate through the belt and the belt pulley, the screening barrel 2 rotates to drive the spiral fan blades 21 to rotate, and accordingly the mixed pulp is driven to rotate in the screening barrel 2 along the inner peripheral wall of the screening barrel 2 and moves to the position, away from the hopper 12, of the screening barrel 2 along the inclined direction of the screening barrel 2 in the rotating process. In this process, the water and the sand particles with smaller volume in the mixed slurry fall out of the sieving cylinder 2 through the sieving holes 22 of the sieving cylinder 2, and the stones with larger volume are finally discharged from the stone discharge opening 13 of the separator housing 1 along with the movement of the sieving cylinder 2 in the inclined direction. In the process of rotating the screening cylinder 2, the cleaning balls 34 can repeatedly extend into the screening holes 22 of the screening cylinder 2, so that the mud and sand in the cleaning balls can be pushed into the screening cylinder 2, the blocking of the mud and sand in the screening holes 22 of the screening cylinder 2 is avoided, and the efficiency of separating sand grains and stones of the screening cylinder 2 is influenced.

Referring to fig. 1-3, a water filtering plate 16 is fixedly connected to the separator housing 1 at a position below the sieving cylinder 2, the water filtering plate 16 can cover the cross section of the separator housing 1, and water flow can pass through the water filtering plate 16. The water filtering plate 16 is arranged in a downward inclined mode from one end close to the hopper 12 to one end far away from the hopper 12, one end, far away from the hopper 12, of the water filtering plate 16 is connected to the position of the sand discharge port 14 of the separator shell 1, and mud and sand can slide along the water filtering plate 16 and be discharged through the sand discharge port 14 of the separator shell 1. The vibrating motor 18 is installed to the one end that separator housing 1 is close to hopper 12, and the output shaft fixed connection of vibrating motor 18 is in the drainage board 16, and vibrating motor 18 can drive the drainage board 16 vibration. The water collection bin 17 is fixedly connected to the position, corresponding to the lower position of the water filtering plate 16, in the separator shell 1, the water collection bin 17 can cover the cross section of the separator shell 1, and water flow penetrating through the water filtering plate 16 can fall into the water collection bin 17.

Referring to fig. 2 and 4, a water pump 4 is installed at a position of the separator housing 1 corresponding to the water collecting bin 17, the water pump 4 is communicated with the water collecting bin 17, a plurality of cleaning spray heads 42 are fixedly connected at a position of the separator housing 1 corresponding to the peripheral wall of the screening cylinder 2, the water spraying direction of the cleaning spray heads 42 is set towards the peripheral wall of the screening cylinder 2, the plurality of cleaning spray heads 42 are arranged along the length direction array of the separator housing 1, a water pipe 41 is fixedly connected with the plurality of cleaning spray heads 42 together, and the cleaning spray heads 42 are communicated with the water pump 4 through the water pipe 41.

In use, the silt and sand mixture separated by the screening drum 2 falls onto the water filter plate 16, and water therein falls into the water collection bin 17 through the water filter plate 16, and the silt and sand is discharged along the inclined water filter plate 16 through the sand discharge port 14 of the separator housing 1. In this process, the vibration motor 18 drives the water filter plate 16 to vibrate, so that the adhesion of the muddy sand on the surface of the water filter plate 16 is reduced, and the muddy sand can slide along the water filter plate 16 and be discharged through the sand discharge port 14 of the separator housing 1. The water flow in the water collecting bin 17 is pumped into the water pipe 41 by the water pump 4, then is conveyed to the cleaning spray heads 42 through the water pipe 41, and the peripheral wall of the screening cylinder 2 is cleaned by the water flow sprayed out by the cleaning spray heads 42, so that the mud and sand in the screening holes 22 of the screening cylinder 2 are softened, the mud and sand are prevented from hardening in the water flow, and the cleaning ball 34 is conveniently stretched into the screening holes 22 of the screening cylinder 2 to push the mud and sand into the screening cylinder 2. The cleaned water flows through the water filtering plate 16 again and flows into the water collecting bin 17.

Referring to fig. 5, a conveying device 5 is connected to the separator housing 1 at a position corresponding to the stone discharge opening 13, the conveying device 5 includes a conveying housing 51 and a conveying pipe 52 fixedly connected to the separator housing 1, the conveying housing 51 is fixedly connected to the position of the stone discharge opening 13 of the separator housing 1, and the conveying housing 51 is arranged in an upward inclined manner from a position close to the separator housing 1 to a position far from the separator housing 1. The conveying pipe 52 is positioned in the conveying shell 51, the axial direction of the conveying pipe 52 and the length direction of the conveying shell 51 are arranged in the same direction, one end of the conveying pipe 52 is fixedly connected to the frame 11 in the separator shell 1, the conveying pipe 52 is communicated with the screening cylinder 2, and stones in the screening cylinder 2 fall into the conveying pipe 52 through the screening cylinder 2. The peripheral wall of the conveying pipe 52 is provided with a plurality of filtering holes 53, and the water flow adhered to the surface of the stone can be discharged out of the conveying pipe 52 through the filtering holes 53 on the peripheral wall of the conveying pipe 52. The conveying shell 51 is rotatably connected with a rotating shaft 54 at a position corresponding to the middle position of the conveying pipe 52, and the axial direction of the rotating shaft 54 is coaxially arranged with the conveying pipe 52. One end of the rotating shaft 54 is connected with a lifting motor 56 through a belt and a belt pulley, and the lifting motor 56 can drive the rotating shaft 54 to rotate through the belt and the belt pulley. The outer peripheral wall of the rotating shaft 54 is fixedly connected with an auger blade 55, the auger blade 55 is positioned in the conveying pipe 52, and the auger blade 55 can drive stones to move upwards along the conveying pipe 52 by rotating. The bottom of the conveying shell 51 is provided with a discharge port 57 at a position far away from the separator shell 1, the conveying shell 51 is fixedly connected with a discharge pipe 58 at a position corresponding to the discharge port 57, the discharge pipe 58 is communicated with the conveying pipe 52, and stones can fall out through the conveying pipe 52.

The implementation principle of the anti-blocking concrete sand-stone separation equipment provided by the embodiment of the utility model is as follows: the user starts the driving motor 15 and the lifting motor 56, the driving motor 15 drives the sieving cylinder 2 to rotate through the belt and the belt pulley, the lifting motor 56 drives the rotating shaft 54 to rotate through the belt and the belt pulley, and the rotating shaft 54 rotates to drive the auger blades 55 to rotate in the conveying pipe 52. The user then pours the mixed slurry of water, mud and stone into the hopper 12, and the mixed slurry enters the screening drum 2 along the hopper 12. The screening cylinder 2 rotates to enable the mixed slurry therein to rotate along the inner wall of the screening cylinder 2 along with the spiral fan blades 21, so that water and mud sand with smaller volume in the mixed slurry fall out of the screening holes 22 of the screening cylinder 2 and fall onto the water filtering plate 16, and the separation of stone and mud sand is realized. The stones fall down in the inclined direction of the screening drum 2 and enter the conveying pipe 52, after which the stones in the conveying pipe 52 are driven by the rotating auger blade 55 to move along the inclined conveyor pipe 52 until the stones move to the position of the discharge pipe 58, and the stones are discharged outside the machine body through the discharge pipe 58 through the conveying casing 51. The water in the muddy sand falling onto the water filtering plate 16 passes through the water filtering plate 16 and enters the water collecting bin 17, and the muddy sand is discharged through the sand discharging port 14 of the separator housing 1 along with the obliquely arranged water filtering plate 16. During the rotation of the sieving cylinder 2, the cleaning ball 34 above the sieving cylinder 2 is pressed into the sieving hole 22 of the sieving cylinder 2 by the connecting spring 33, and the blocked mud and sand in the sieving hole 22 is pushed into the sieving cylinder 2. Along with the rotation of the screening cylinder 2, the side wall at the position of the screening hole 22 of the screening cylinder 2 is abutted against the cleaning ball 34 to push the cleaning ball 34 to extend into the sliding groove 32 of the mounting frame 31 along the sliding groove 32 in the direction away from the screening cylinder 2 until the next screening hole 22 is rotated to the position right below the sliding groove 32 of the mounting frame 31 along with the rotation of the screening cylinder 2, the cleaning ball 34 is pushed into the screening hole 22 of the screening cylinder 2 by the connecting ball again, so that the screening hole 22 of the screening cylinder 2 is repeatedly cleaned, and the muddy sand in the cleaning ball is pushed into the screening cylinder 2, so that the muddy sand blocking the screening cylinder 2 is reduced, and the sand and stone separation efficiency is lower.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (9)

1. Anti-blocking concrete sand and stone separation equipment, its characterized in that: comprising the steps of (a) a step of,

a separator shell (1), wherein one end of the separator shell (1) is provided with a sand discharge port (14) for discharging sand grains and a stone discharge port (13) for discharging stone blocks;

a hopper (12) connected to the separator housing (1);

screening tube (2), switching in separating centrifuge casing (1), screening tube (2) with hopper (12) are linked together, and a plurality of screening holes (22) have been seted up to screening tube (2) week wall, and the sand grain can pass screening tube (2) through screening tube (22) of screening tube (2), and screening tube (2) are connected with driving motor (15), and driving motor (15) can drive screening tube (2) and rotate around self axis; the method comprises the steps of,

cleaning device (3), connect in separating centrifuge casing (1) top, including clearance spheroid (34), clearance spheroid (34) are connected with coupling spring (33), coupling spring (33) apply the effort that makes clearance spheroid (34) stretch into screening hole (22) of screening section of thick bamboo (2) to clearance spheroid (34).

2. An anti-clogging concrete sand separation apparatus as claimed in claim 1, wherein: separator housing (1) is connected with mounting bracket (31), and spout (32) have been seted up to mounting bracket (31), clearance spheroid (34) sliding connection is in spout (32) of mounting bracket (31), and clearance spheroid (34) can stretch out outside mounting bracket (31) through spout (32) of mounting bracket (31).

3. An anti-clogging concrete sand separation apparatus as claimed in claim 2, wherein: the pore size of the screening hole (22) of the screening cylinder (2) close to the position of the outer peripheral wall of the screening cylinder (2) is larger than that of the screening hole (22) close to the inner peripheral wall of the screening cylinder (2).

4. An anti-clogging concrete sand separation apparatus as claimed in claim 1, wherein: the separator is characterized in that a water filtering plate (16) is connected to the position, corresponding to the lower position of the screening cylinder (2), of the separator shell (1), water flows can penetrate through the water filtering plate (16), the cross section of the water filtering plate (16) is arc-shaped, and the water filtering plate (16) is arranged in a downward inclined mode from the position of the sand discharging opening (14) far away from the separator shell (1) to the position of the sand discharging opening (14) close to the separator shell (1).

5. An anti-clogging concrete sand separation apparatus as recited in claim 4 wherein: the water filtering plate (16) is connected with a vibration motor (18), and the vibration motor (18) can drive the water filtering plate (16) to vibrate.

6. An anti-clogging concrete sand separation apparatus as recited in claim 5 wherein: the separator is characterized in that a water collection bin (17) is connected to the separator shell (1) at the position below the corresponding water filtering plate (16), and water flowing through the water filtering plate (16) can enter the water collection bin (17) through the water filtering plate (16).

7. An anti-clogging concrete sand separation apparatus as recited in claim 6 wherein: cleaning device (3) still include cleaning nozzle (42) and water pump (4), water pump (4) connect in water collection storehouse (17), cleaning nozzle (42) with water pump (4) are linked together, cleaning nozzle (42) are connected in separating centrifuge casing (1), cleaning nozzle (42) can be to screening section of thick bamboo (2) direction blowout rivers clearance screening section of thick bamboo (2).

8. An anti-clogging concrete sand separation apparatus as claimed in claim 1, wherein: the inner peripheral wall of the screening cylinder (2) is connected with a spiral fan blade (21), and the spiral fan blade (21) is arranged towards the stone discharge opening (13) of the separator shell (1).

9. An anti-clogging concrete sand separation apparatus as claimed in claim 1, wherein: separator housing (1) corresponds self row of stone mouth (13) position department and is connected with conveyor (5), and conveyor (5) are including carrying casing (51) and switching in carrying casing (51) axis of rotation (54), the periphery wall of axis of rotation (54) is connected with auger blade (55), axis of rotation (54) can drive auger blade (55) rotation, discharge port (57) have been seted up in separator housing (1) position department in separation housing (1) bottom portion of carrying, and auger blade (55) rotation can drive the grit along carrying casing (51) and pass through discharge port (57) of carrying casing (51) and discharge.