CN114308623B

CN114308623B - Efficient gravel filtering device for building engineering

Info

Publication number: CN114308623B
Application number: CN202111653369.9A
Authority: CN
Inventors: 李琴; 霍山; 上官玉明; 刘梅
Original assignee: Guizhou Education University
Current assignee: Guizhou Education University
Priority date: 2021-12-30
Filing date: 2021-12-30
Publication date: 2023-03-28
Anticipated expiration: 2041-12-30
Also published as: CN114308623A

Abstract

The invention relates to a sand and stone impurity filtering device, in particular to a high-efficiency sand and stone impurity filtering device for constructional engineering. The technical problem to be solved is as follows: the utility model provides a grit is filtered to rotation type, impurity can automatic roll-off, can filter miscellaneous device with the efficient grit that the grit of caking was broken up moreover for building engineering. The technical scheme of the invention is as follows: the utility model provides an miscellaneous device is strained to grit for efficient building engineering, is provided with the base including base, backup pad, spacing ring etc. backup pad bottom, and the backup pad upper portion left and right sides all is provided with the spacing ring. This miscellaneous device is strained to grit for efficient building engineering through shake mechanism, slewing mechanism and break up the combined action of mechanism, makes the workman pour the grit into the feeding frame in the back, through the first slide bar of lug intermittent type formula extrusion, and then makes three shake the pole and remove about, easily breaks up the grit of caking to overcome the unable problem of handling the grit that current miscellaneous device exists of straining.

Description

Efficient gravel filtering device for building engineering

Technical Field

The invention relates to a sand and gravel filtering device, in particular to an efficient sand and gravel filtering device for constructional engineering.

Background

Can often use the grit in the building work progress, often mix impurity such as bold stone or long branch in the grit, so need filter the debris to the grit.

Patent application No.: CN202022015788.7 a be used for aggregate for building engineering to strain miscellaneous equipment, including the sieve workbin, one side outer wall intercommunication of sieve workbin has the install bin, the discharge gate has been seted up to another lateral wall of sieve workbin, the feeder hopper is installed on the top of sieve workbin, the dust cover fixed with sieve workbin lateral wall is installed in the outside of discharge gate, it is connected with first axis of rotation to rotate between the both sides wall of dust cover, the rotation motor is installed to the lateral wall of install bin, it is connected with the second axis of rotation to rotate between the both sides inner wall of install bin, the one end of second axis of rotation is fixed with the output that rotates the motor, the conveyer belt has been cup jointed between first axis of rotation and the second axis of rotation, the both sides inner wall of sieve workbin all is fixed with the slip cap, sliding connection has the slide bar in the slip cap, two be fixed with the sieve flitch between the slide bar, a lateral wall slip of sieve workbin has run through the catch bar, the one end and one of catch bar are fixed, the other end of catch bar is fixed with the lug, be fixed with the lug between the lateral wall of sieve workbin, be fixed with the spring between the lateral wall of sieve rotational axis of rotation, it is connected with the third axis of rotation inner wall, it is connected with the third rotational axis of rotation, the cam tight fit lug has the cam contact of cam.

The sand and stone impurity filtering device for the building engineering enables the material sieving plate to move back and forth through the matching work of the cam and the convex block, and carries out impurity filtering work on sand and stone; the sand and stone in the feed hopper are dredged and shunted while the material is sieved by the operation of the shunting block; but can have some problems, adopt the mode of sieve flitch shake about, the grit is filtered, the impurity that the filtration came out appears easily piles up together, lead to the sieve flitch to be blockked up, then need artifically to take out impurity, can reduce the efficiency of filtering the grit, shunt the piece in the course of the work in addition, if meet the grit of caking, can lead to shunting the piece and be blocked when reciprocating, and then destroy and shunt the piece, cause the situation of jam simultaneously, consequently research and development a rotation type filters the grit now, impurity can automatic roll-off, and can filter miscellaneous device with the grit for the efficient building engineering that the grit of caking was broken up.

Disclosure of Invention

In order to overcome the use and be used for gravel and sand for building engineering to strain miscellaneous equipment and can have impurity to pile up, need the manual work to take out impurity, run into the grit of caking and can appear the shortcoming of jam, the technical problem that solves is: the utility model provides a grit is filtered to rotation type, impurity can automatic roll-off, can filter miscellaneous device with the efficient grit that the grit of caking was broken up moreover for building engineering.

The technical scheme of the invention is as follows: the utility model provides an efficient is miscellaneous device is strained to grit for building engineering, the on-line screen storage device comprises a base, a supporting plate, the spacing ring, the rotary drum, first spring, the cartridge filter, slewing mechanism, break up mechanism and shake mechanism, the backup pad bottom is provided with the base, the base can support whole efficient is miscellaneous device is strained to grit for building engineering, the backup pad upper portion left and right sides all is provided with the spacing ring, the rotary type is connected with the rotary drum between the spacing ring, the rotary drum inner wall left and right sides all is provided with 8 first springs along the circumferencial direction, all be provided with the cartridge filter between all first spring the inner, the cartridge filter is the high setting in the low right side in a left side, the backup pad top is provided with breaks up the mechanism, break up and be provided with shake mechanism in the mechanism.

Further, slewing mechanism is equipped with the ring gear including servo motor, pivot, gear and ring gear, rotary drum right side outer wall circumferencial direction cover, and backup pad top right side is provided with servo motor, is provided with the pivot on the servo motor output shaft, and the cover is equipped with the gear in the pivot.

Further, the scattering mechanism comprises a first fixing plate, a feeding frame, a guide pipe, a first connecting plate, a shaking rod, a second connecting plate, a second spring and a connecting rod, the first fixing plate is arranged on the right side of the top of the supporting plate, the feeding frame is arranged on the right side of the first fixing plate, the guide pipe is arranged at the bottom of the feeding frame, the first connecting plate is arranged on the right side of the lower portion of the first fixing plate, the first connecting plate and the guide pipe are connected and communicated, the left portion of the first connecting plate and the right portion of the rotary drum are rotatably connected, 7 shaking rods are uniformly arranged on the feeding frame, three shaking rods are slidably connected in the feeding frame, the rest 4 shaking rods are respectively fixed in the feeding frame, each movable shaking rod is respectively located between two fixed shaking rods, the second connecting plate is arranged between the left sides of the movable three shaking rods, 3 second springs are arranged between the right side of the second connecting plate and the feeding frame, the second spring is sleeved on the left side of the shaking rods, the middle of the left side of the second connecting rod is provided with the connecting rod, and the connecting rod is slidably connected with the feeding frame.

Further, the shaking mechanism comprises a guide sleeve, a first slide bar and a convex block, the convex block is arranged on the lower portion of the right side of the gear, the guide sleeve is arranged in the middle of the left side of the feeding frame, the first slide bar is connected to the guide sleeve in a sliding mode, and the upper portion of the first slide bar is connected with the connecting rod in a sliding mode.

Furthermore, the intermittent feeding mechanism comprises a fixed block, a guide rod, a third spring, a third slide bar, a material blocking disc and a spiral rod, wherein the fixed block is arranged on the upper right side of the first connecting plate, the guide rod is arranged in the fixed block and between the first connecting plate, the third slide bar is connected onto the guide rod in a sliding mode, the third spring is arranged between the left side of the third slide bar and the left side of the guide rod, the third spring is wound on the outer side of the guide rod, the material blocking disc is arranged on the left side of the lower portion of the third slide bar, and the spiral rod is arranged on the right side of the rotating shaft.

Further, still including vibration mechanism, vibration mechanism is including the second fixed plate, the second slide bar, the fourth spring, the knocker, connection pad and stirring piece, left spacing ring top is provided with the second fixed plate, sliding connection has the second slide bar on the second fixed plate, second slide bar bottom is provided with the knocker, be provided with the fourth spring between knocker top and the second fixed plate, the fourth spring is around in the second slide bar outside, the cartridge filter left side is provided with the connection pad, the connection pad outer wall evenly is provided with 6 stirring pieces along the circumferencial direction.

Furthermore, the device also comprises a discharging mechanism, and the discharging mechanism is arranged at the lower part of the supporting plate.

Further, discharge mechanism is including bull stick, transmission band and motor, and backup pad lower part rotary type is connected with 5 bull sticks, all is provided with the transmission wheel on the bull stick, around having the transmission band between the transmission wheel, and backup pad lower part left front side is provided with the motor, and motor output shaft rear side and adjacent bull stick are connected.

Compared with the prior art, the invention has the following advantages: according to the efficient gravel filtering device for the building engineering, through the combined action of the shaking mechanism, the rotating mechanism and the scattering mechanism, workers can intermittently extrude the first sliding rod through the convex block after pouring gravel into the feeding frame, so that the three shaking rods move left and right to easily scatter the caked gravel, and the problem that the caked gravel cannot be treated by the conventional gravel filtering device is solved; then, under the rotating work of the filter cartridge, the sand and stone are automatically filtered, and under the action of setting the filter cartridge to be left low and right high, impurities can automatically slide out leftwards in the sand and stone filtering process, so that the sand and stone can be effectively prevented from being accumulated; the pivot is rotated and is driven the hob and rotate, and the hob can extrude the third slide bar left for keep off charging tray and first connecting plate and have the gap, so make things convenient for the grit feeding, keep off charging tray and first connecting plate closed back afterwards, the grit stops the feeding, so can realize intermittent type formula with the grit landing feeding left, this can avoid disposable feeding and then lead to blockking up.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a perspective sectional view of the present invention.

Fig. 4 is a partial perspective view of the present invention.

Fig. 5 is an exploded view of a portion of the three-dimensional structure of the present invention.

Fig. 6 is a schematic perspective view of the rotating mechanism of the present invention.

FIG. 7 is a perspective view of the scattering mechanism of the present invention.

FIG. 8 is a perspective view of a portion of the break-up mechanism of the present invention.

Fig. 9 is a schematic perspective view of a shaking mechanism according to the present invention.

Fig. 10 is a schematic perspective view of a part of the shaking mechanism of the present invention.

Fig. 11 is a schematic perspective view of the intermittent feeding mechanism of the present invention.

Fig. 12 is a partial perspective sectional view of the intermittent feed mechanism of the present invention.

Fig. 13 is a schematic perspective view of the vibration mechanism of the present invention.

Fig. 14 is a schematic perspective view of a first discharging mechanism of the present invention.

Fig. 15 is a schematic perspective view of a second discharging mechanism of the present invention.

In the reference symbols: 1-base, 2-support plate, 3-stop ring, 4-drum, 5-first spring, 6-cartridge filter, 7-rotating mechanism, 70-servomotor, 71-rotating shaft, 72-gear, 73-gear ring, 8-breaking mechanism, 80-first fixed plate, 81-feed frame, 82-guide, 83-first connecting plate, 84-shaking rod, 85-second connecting plate, 86-second spring, 87-connecting rod, 9-shaking mechanism, 90-guide sleeve, 91-first sliding rod, 92-lug, 10-intermittent feed mechanism, 101-fixed block, 102-guide rod, 103-third spring, 104-third sliding rod, 105-stock stopping plate, 106-screw rod, 11-vibrating mechanism, 111-second fixed plate, 112-second sliding rod, 113-fourth spring, 114-knocker, 115-connecting plate, 116-moving block, 12-discharge mechanism, 121-rotating rod, 122-conveying belt, 123-motor.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

Example 1

The utility model provides an efficient gravel and sand filter device for building engineering, as shown in fig. 1-10, including base 1, a supporting plate 2, spacing ring 3, the rotary drum 4, first spring 5, the cartridge filter 6, slewing mechanism 7, break up mechanism 8 and

shake mechanism

9, 2 bottoms of backup pad are equipped with base 1 through the bolt, base 1 can support whole efficient gravel and sand filter device for building engineering, spacing ring 3 has all been welded to 2 upper portion left and right sides in backup pad, the rotary type is connected with rotary drum 4 between the spacing ring 3, spacing ring 3 can lead rotary drum 4, the inner wall left and right sides of rotary drum 4 all is equipped with 8 first spring 5 along the circumferencial direction, all be equipped with cartridge filter 6 between 5 the inner of first spring, cartridge filter 6 is the high setting of low right side in left side, cartridge filter 6 can filter the grit, can filter out the impurity in the grit, first spring 5 can play the buffering effect to cartridge filter 6, backup pad 2 tops are equipped with slewing mechanism 7, slewing mechanism 7 can drive rotary drum 4 and rotate, backup pad 2 tops are equipped with breaks up mechanism 8, break up the mechanism 8 and is equipped with shake mechanism 9.

As shown in fig. 6, the rotating mechanism 7 includes a servo motor 70, a rotating shaft 71, a gear 72 and a gear ring 73, the gear ring 73 is sleeved on the outer wall of the right side of the rotating drum 4 in the circumferential direction, the servo motor 70 is arranged on the right side of the top of the supporting plate 2 through a bolt, the rotating shaft 71 is arranged on an output shaft of the servo motor 70, the gear 72 is sleeved on the rotating shaft 71, the output shaft of the servo motor 70 rotates to drive the gear 72 to rotate through the rotating shaft 71, and the gear 72 rotates to drive the gear ring 73 to rotate.

As shown in fig. 7 and 8, the scattering mechanism 8 includes a first fixing plate 80, a feeding frame 81, a guide pipe 82, a first connecting plate 83, a shaking rod 84, a second connecting plate 85, a second spring 86 and a connecting rod 87, the first fixing plate 80 is welded on the right side of the top of the support plate 2, the servo motor 70 is located in the first fixing plate 80, the first fixing plate 80 can protect the servo motor 70, the feeding frame 81 is arranged on the right side of the first fixing plate 80 through bolts, sand is poured into the feeding frame 81, the guide pipe 82 is arranged at the bottom of the feeding frame 81, the first connecting plate 83 is arranged on the right side of the lower portion of the first fixing plate 80, the first connecting plate 83 is connected and communicated with the guide pipe 82, the left portion of the first connecting plate 83 is rotatably connected with the right portion of the rotary drum 4, 7 shaking rods 84 are uniformly arranged on the feeding frame 81, three shaking rods 84 are slidably connected in the feeding frame 81, the rest 4 shaking rods 84 are respectively fixed in the feeding frame 81, each shaking rod 84 is arranged between the left side of the two fixed shaking rods 84, three shaking rods 84 are arranged between the left side connecting plates, the left side of the second connecting plate 85 and the left side of the second connecting plate 85, and the left side of the shaking rod 87, the second connecting plate 85 are arranged between the left side of the second connecting plate 87, and the second connecting plate 85, the left side of the shaking rod 87, the shaking rod 85, the second connecting plate 87, and the second connecting plate 85 are arranged between the shaking rod 87, and the left side of the shaking rod 85, and the shaking rod 87, and the shaking rod 85, and the left side of the shaking rod 87, the second connecting plate 87, and the shaking rod 85 are connected in a shaking rod 87.

As shown in fig. 9 and 10, the shaking mechanism 9 includes a guide sleeve 90, a first slide bar 91 and a projection 92, the projection 92 is welded on the lower portion of the right side of the gear 72, the guide sleeve 90 is arranged in the middle of the left side of the feeding frame 81 through a bolt, the first slide bar 91 is slidably connected on the guide sleeve 90, when the projection 92 contacts with the first slide bar 91, the first slide bar 91 is moved rightwards, so that the connecting rod 87 is moved rightwards, and the upper portion of the first slide bar 91 is slidably connected with the connecting rod 87.

When the efficient sand and gravel filtering device for the building engineering is used in a building construction site, firstly, a collecting frame is placed under a filter cartridge 6, a servo motor 70 is started, an output shaft of the servo motor 70 rotates to drive a rotating shaft 71 to rotate, the rotating shaft 71 rotates to drive a gear 72 to rotate, the gear 72 rotates to drive a lug 92 to rotate, the lug 92 can extrude a first slide bar 91 when rotating, the first slide bar 91 is driven to move rightwards, the first slide bar 91 moves rightwards to drive a connecting rod 87 to move rightwards, the connecting rod 87 moves rightwards to drive a second connecting plate 85 and three shaking bars 84 to move rightwards, a second spring 86 is compressed, the lug 92 rotates when being separated from the first slide bar 91, the second connecting plate 85 and the three shaking bars 84 are driven to move leftwards to reset under the action of the second spring 86, the connecting rod 87 and the first slide bar 91 move leftwards to reset, the three shaking bars 84 move in a reciprocating cycle, agglomerated sand and can be scattered under the mutual cooperation of 4 fixed shaking bars 84, then the sand and fall down through a clamping seam between the sand and then falls into the filter cartridge 82; gear 72 rotates and drives ring gear 73 and rotate, ring gear 73 rotates and drives rotary drum 4 and rotate, rotary drum 4 rotates and drives first spring 5 and cartridge filter 6 rotatory, cartridge filter 6 constantly rotates, can filter the grit, the grit after the filtration can drop to collect in the frame downwards, because cartridge filter 6 is the high setting in the low right side in a left side, therefore bold grit and other impurity then sideslip left, can easily filter the grit, if there is the grit card when cartridge filter 6, the workman can use to strike the piece and strike cartridge filter 6, at the in-process of striking, cartridge filter 6 can rock, and first spring 5 is warp, so the grit of card in cartridge filter 6 can drop downwards, if do not use this device, can close servo motor 70.

Example 2

On the basis of embodiment 1, as shown in fig. 3, 11 and 12, the intermittent feeding mechanism 10 is further included, an intermittent feeding effect can be achieved, the intermittent feeding mechanism 10 includes a fixed block 101, a guide rod 102, a third spring 103, a third slide rod 104, a material blocking disc 105 and a spiral rod 106, the fixed block 101 is arranged on the upper right side of the first connection plate 83 through a bolt, the guide rod 102 is welded between the inside of the fixed block 101 and the first connection plate 83, the third slide rod 104 is connected to the guide rod 102 in a sliding mode, the guide rod 102 guides the third slide rod 104, the third spring 103 is arranged between the left side of the third slide rod 104 and the left side of the guide rod 102, the third spring 103 is wound on the outer side of the guide rod 102, the material blocking disc 105 is welded on the left side of the lower portion of the third slide rod 104, sand can slide to the middle position of the first connection plate 83, the material blocking disc 105 can move left and right, an intermittent feeding effect can be achieved, the spiral rod 106 is arranged on the right side of the rotating shaft 71, and the spiral rod 106 can rotationally move the third slide rod 104.

Under a normal state, the material blocking disc 105 blocks the first connecting plate 83, sand and stone can be blocked in the guide pipe 82, the rotating shaft 71 rotates to drive the screw rod 106 to rotate, when the screw rod 106 is in contact with the third slide rod 104, the third slide rod 104 can move leftwards, the third spring 103 is compressed, the third slide rod 104 moves leftwards to drive the material blocking disc 105 to move leftwards, a gap exists between the material blocking disc 105 and the first connecting plate 83, and the sand and stone can fall into the filter cylinder 6 leftwards through the gap, so that a filtering effect is achieved; when the screw rod 106 and the third sliding rod 104 are separated, the third sliding rod 104 and the material blocking disc 105 are driven to move rightwards to reset under the action of the third spring 103, the material blocking disc 105 and the first connecting plate 83 are overlapped, the first connecting plate 83 is closed, sand stops sliding leftwards at the moment, and the operation is repeated, so that the sand can be fed intermittently and slides leftwards, and the blockage caused by one-time feeding can be avoided.

As shown in fig. 1, fig. 2, fig. 3, fig. 11 and fig. 13, the vibration mechanism 11 is further included, the filter cartridge 6 is automatically vibrated, the vibration mechanism 11 includes a second fixing plate 111, a second sliding rod 112, a fourth spring 113, a knocker 114, a connecting plate 115 and a shifting block 116, the second fixing plate 111 is arranged at the top of the left limiting ring 3 through bolts, the second sliding rod 112 is slidably connected to the second fixing plate 111, the second fixing plate 111 guides the second sliding rod 112, the knocker 114 is welded at the bottom of the second sliding rod 112, the fourth spring 113 is arranged between the top of the knocker 114 and the second fixing plate 111, the fourth spring 113 is wound outside the second sliding rod 112, the fourth spring 113 can drive the knocker 114 to move downwards, the connecting plate 115 is welded at the left side of the

filter cartridge

6, and 6 shifting blocks 116 are uniformly welded at the outer wall of the connecting plate 115 along the circumferential direction.

The filter cartridge 6 rotates to drive the connecting disc 115 to rotate, the connecting disc 115 rotates to drive the shifting block 116 to rotate, when the shifting block 116 is in contact with the knocker 114, the knocker 114 and the second slide bar 112 are driven to move upwards, the fourth spring 113 is compressed, when the shifting block 116 is separated from the knocker 114, the second slide bar 112 and the knocker 114 are driven to move downwards under the action of the fourth spring 113, the knocker 114 moves downwards to impact the connecting disc 115, the connecting disc 115 is made to vibrate, the shifting block 116 continuously extrudes the knocker 114, the knocker 114 can knock the connecting disc 115, and then the filter cartridge 6 is made to vibrate, so that sand blocked in the filter cartridge 6 can be continuously shaken and blanked, and blocking can be prevented.

As shown in fig. 1, fig. 2, fig. 3, fig. 14 and fig. 15, the utility model further comprises a discharging mechanism 12, the gravel after filtering drops to the transmission band 122, it is convenient for people to collect the gravel, the discharging mechanism 12 comprises a rotating rod 121, a transmission band 122 and a

motor

123, 5 rotating rods 121 are rotatably connected to the lower part of the supporting plate 2, transmission wheels are arranged on the rotating rods 121, the transmission band 122 is wound between the transmission wheels, the motor 123 is arranged on the left front side of the lower part of the supporting plate 2 through bolts, the rear side of the output shaft of the motor 123 is connected with the adjacent rotating rod 121, and the output shaft of the motor 123 rotates to drive the left rotating rod 121 to rotate.

The grit after filtering drops down on transmission band 122, and people can start motor 123, and motor 123 output shaft rotates and drives left bull stick 121 and rotate for transmission wheel and transmission band 122 rotate, make the grit transport to the right, so be convenient for the workman collect the grit, close motor 123 when not using.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The efficient sandstone filtration device for the building engineering is characterized by comprising a base (1), a support plate (2), limiting rings (3), rotary drums (4), first springs (5), filter drums (6), rotating mechanisms (7), scattering mechanisms (8) and shaking mechanisms (9), wherein the base (1) is arranged at the bottom of the support plate (2), the limiting rings (3) are arranged on the left side and the right side of the upper portion of the support plate (2), the rotary drums (4) are rotatably connected between the limiting rings (3), 8 first springs (5) are arranged on the left side and the right side of the inner wall of each rotary drum (4) along the circumferential direction, the filter drums (6) are arranged between the inner ends of all the first springs (5), the filter drums (6) are arranged in a left-low-right-high mode, the filter drums (6) are composed of a plurality of spiral strips, the rotating mechanisms (7) are arranged at the top of the support plate (2), the scattering mechanisms (8) are arranged at the top of the support plate (2), and the shaking mechanisms (9) are arranged on the scattering mechanisms (8);

the rotating mechanism (7) comprises a servo motor (70), a rotating shaft (71), a gear (72) and a gear ring (73), the gear ring (73) is sleeved on the outer wall of the right side of the rotating drum (4) in the circumferential direction, the servo motor (70) is arranged on the right side of the top of the supporting plate (2), the rotating shaft (71) is arranged on an output shaft of the servo motor (70), and the gear (72) is sleeved on the rotating shaft (71);

the breaking mechanism (8) comprises a first fixing plate (80), a feeding frame (81), a guide pipe (82), a first connecting plate (83), a shaking rod (84), a second connecting plate (85), a second spring (86) and a connecting rod (87), the first fixing plate (80) is arranged on the right side of the top of the supporting plate (2), the feeding frame (81) is arranged on the right side of the first fixing plate (80), the guide pipe (82) is arranged at the bottom of the feeding frame (81), the first connecting plate (83) is arranged on the right side of the lower portion of the first fixing plate (80), the first connecting plate (83) is connected and communicated with the guide pipe (82), the left portion of the first connecting plate (83) is rotatably connected with the right portion of the rotary drum (4), 7 shaking rods (84) are uniformly arranged on the feeding frame (81), three shaking rods (84) are connected in the feeding frame (81) in a sliding mode, the other 4 shaking rods (84) are respectively fixed in the feeding frame (81), each shaking rod (84) is respectively located between two fixed shaking rods (84), the second connecting plates (85) are arranged on the left side of the movable shaking rods, the left side of the second connecting plate (86) and the second spring (86) are sleeved on the left side of the second connecting plate (85), a connecting rod (87) is arranged in the middle of the left side of the second connecting plate (85), and the connecting rod (87) is connected with the feeding frame (81) in a sliding manner;

the intermittent feeding mechanism (10) comprises a fixed block (101), a guide rod (102), a third spring (103), a third slide rod (104), a material blocking disc (105) and a spiral rod (106), the fixed block (101) is arranged on the upper right side of the first connecting plate (83), the guide rod (102) is arranged between the inside of the fixed block (101) and the first connecting plate (83), the third slide rod (104) is connected with the guide rod (102) in a sliding mode, the third spring (103) is arranged between the left side of the third slide rod (104) and the left side of the guide rod (102), the third spring (103) is wound on the outer side of the guide rod (102), the material blocking disc (105) is arranged on the left side of the lower portion of the third slide rod (104), and the spiral rod (106) is arranged on the right side of the rotating shaft (71); the third sliding rod (104) moves leftwards to drive the material blocking disc (105) to move leftwards, and a gap exists between the material blocking disc (105) and the first connecting plate (83).

2. The efficient sandstone filtration device for the construction engineering as claimed in claim 1, wherein the shaking mechanism (9) comprises a guide sleeve (90), a first slide rod (91) and a convex block (92), the convex block (92) is arranged at the lower part of the right side of the gear (72), the guide sleeve (90) is arranged at the middle part of the left side of the feeding frame (81), the first slide rod (91) is connected onto the guide sleeve (90) in a sliding manner, and the upper part of the first slide rod (91) is connected with the connecting rod (87) in a sliding manner.

3. The efficient sand and gravel filtering device for the building engineering is characterized by further comprising a vibrating mechanism (11), wherein the vibrating mechanism (11) comprises a second fixing plate (111), a second sliding rod (112), a fourth spring (113), a knocker (114), a connecting disc (115) and a shifting block (116), the second fixing plate (111) is arranged at the top of the limiting ring (3) on the left side, the second sliding rod (112) is connected onto the second fixing plate (111) in a sliding mode, the knocker (114) is arranged at the bottom of the second sliding rod (112), the fourth spring (113) is arranged between the top of the knocker (114) and the second fixing plate (111), the fourth spring (113) is wound on the outer side of the second sliding rod (112), the connecting disc (115) is arranged on the left side of the filter cartridge (6), and 6 shifting blocks (116) are uniformly arranged on the outer wall of the connecting disc (115) in the circumferential direction.

4. The efficient sandstone filtration device for the construction engineering as claimed in claim 3, further comprising a discharging mechanism (12), wherein the discharging mechanism (12) is arranged at the lower part of the support plate (2).

5. The efficient sandstone filtration device for the construction engineering as claimed in claim 4, wherein the discharging mechanism (12) comprises rotating rods (121), a transmission belt (122) and a motor (123), the lower part of the support plate (2) is rotatably connected with 5 rotating rods (121), the rotating rods (121) are respectively provided with a transmission wheel, the transmission belt (122) is wound between the transmission wheels, the motor (123) is arranged on the left front side of the lower part of the support plate (2), and the rear side of an output shaft of the motor (123) is connected with the adjacent rotating rods (121).