CN113119308A - Corrosion-resistant concrete apparatus for producing that permeates water - Google Patents

Abstract

The invention provides a corrosion-resistant pervious concrete production device, and relates to the technical field of corrosion-resistant pervious concrete equipment. The quantitative assembly is arranged in the box body and comprises a spring, a telescopic rod, a buffer storage bin, a fixed plate, a rack, a gear, a rotating rod, an eccentric wheel, an outer frame and a baffle plate, and the spring and the telescopic rod are fixedly connected to the inside of the buffer storage bin. This corrosion-resistant concrete apparatus for producing that permeates water, the fixed plate moves left and drives the rack motion left, the rack moves left and drives gear revolve, gear revolve drives the eccentric wheel and rotates, the eccentric wheel rotates and drives the frame downstream, frame downstream drives the baffle downstream, the baffle downstream blocks the feed inlet, this structure is of value to the ration toward the inside powder raw materials such as cement, mountain flour of adding in buffer memory storehouse, and then be convenient for the back mix cement, mountain flour, save time, use manpower sparingly.

Description

Corrosion-resistant concrete apparatus for producing that permeates water

Technical Field

The invention relates to a corrosion-resistant pervious concrete production device, and belongs to the technical field of corrosion-resistant pervious concrete manufacturing equipment.

Background

The pumping device gradually becomes a common device in concrete construction, has the characteristics of high construction speed, good quality, labor saving, convenient construction and the like, and is widely applied to the engineering fields of general concrete production, building structure concrete, road concrete, mass concrete, high-rise buildings and the like.

As the corrosion-resistant pervious concrete with higher performance requirement, the corrosion-resistant pervious concrete is required to be rapidly and rapidly prepared during preparation, particularly when a large amount of the concrete is mixed, the preparation must be rapid in order to ensure timeliness, and delay caused by manual intervention is reduced as much as possible.

Disclosure of Invention

Technical problem to be solved

The invention aims to solve the problems, and provides a corrosion-resistant pervious concrete production device to solve the problems that in the prior art, powdery raw materials such as cement and stone powder cannot be quantitatively added into a buffer storage bin when the raw materials are conveyed, and the raw materials are added after being proportioned by manpower, so that time and labor are wasted.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: the corrosion-resistant pervious concrete production device comprises a box body, wherein a quantitative component is arranged in the box body;

the quantitative component comprises a spring, a telescopic rod, a buffering bin, a fixed plate, a rack, a gear, a rotating rod, an eccentric wheel, an outer frame and a baffle, wherein the spring and the telescopic rod are fixedly connected inside the buffering bin, the spring and the telescopic rod are fixedly connected to one side of the fixed plate, the fixed plate is slidably connected to the inside of the buffering bin, the buffering bin is fixedly connected to the inside of the box body, the rack is fixedly connected to the top of the fixed plate, the gear is arranged on the top of the rack and meshed with the rack, the gear and the eccentric wheel are fixedly connected to the outer side of the rotating rod, the outer frame is arranged on the outer side of the eccentric wheel, the baffle is fixedly connected to.

Preferably, the equal fixedly connected with inlet pipe in box both sides, buffer memory storehouse bottom fixedly connected with discharging pipe, this structure is favorable to ration to adding raw materials such as cement and mountain flour inside the buffer memory storehouse.

Preferably, the discharge pipe outside is provided with the solenoid valve, box top is rotated and is connected with the sleeve.

Preferably, the sleeve top fixedly connected with positive and negative motor, the inside spout of having seted up of sleeve.

Preferably, the inside sliding connection of sleeve has the lead screw, lead screw outside fixedly connected with slider, and this structure is favorable to carrying out abundant mixing stirring to the raw materials, increases the product quality of later stage concrete.

Preferably, the sliding block is slidably connected to the inside of the sliding groove, and a support plate is fixedly connected to the inside of the box body, so that the structure is beneficial to supporting the screw rod.

Preferably, the screw rod penetrates through the support plate and is in threaded connection with the support plate, and a stirring rod is fixedly connected to the outer side of the screw rod, so that the structure is beneficial to supporting the screw rod.

Preferably, box top fixedly connected with branch, branch fixed connection is in positive and negative motor outside, and this structure is favorable to supporting positive and negative motor.

The invention has the following beneficial effects: on the one hand, the fixed plate moves leftwards to drive the rack to move leftwards, the rack moves leftwards to drive the gear to rotate, the gear rotates to drive the eccentric wheel to rotate, the eccentric wheel rotates to drive the outer frame to move downwards, the outer frame moves downwards to drive the baffle to move downwards, the baffle moves downwards to block the feeding hole, the structure is beneficial to quantitatively adding powder raw materials such as cement and stone powder into the caching bin, the rear surface of the structure is convenient for mixing the cement and the stone powder, the time is saved, and the labor is saved. On the other hand, the lead screw is rotated while downstream and can be driven the puddler and rotate while downstream, mixes the stirring to the raw materials, and positive and negative motor is just driving the lead screw upward movement, drives the puddler upward movement, can make the raw materials carry out abundant mixing, and this structure is of value to carrying out abundant mixing to the raw materials, increases the product quality of later stage concrete.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic diagram of a cache bin structure according to the present invention;

FIG. 3 is a schematic view of the rack structure of the present invention;

FIG. 4 is a schematic view of a lead screw structure according to the present invention;

FIG. 5 is a schematic view of an overall structure of the present invention;

FIG. 6 is an enlarged view of the portion A of FIG. 5 according to the present invention;

FIG. 7 is a cross-sectional view of the present invention;

FIG. 8 is an enlarged view of the portion B of FIG. 7 according to the present invention;

FIG. 9 is a schematic view of the stirring apparatus of the present invention;

FIG. 10 is an internal structural view of a stirring apparatus;

FIG. 11 is a schematic view of a first bevel gear structure;

fig. 12 is a schematic view of a concrete screw structure of the stirring device.

In the figure: m1, a box body; m2, a spring; m3, a telescopic rod; m4, cache bins; m5, fixing plate; m6, rack; m7, gear; m8, rotating rod; m9, eccentric wheel; m10, outer frame; m11, a baffle; m12, feed pipe; m13, a discharge pipe; m14, electromagnetic valve; m15, a sleeve; m16, a positive and negative motor; m17, a screw rod; m18, a support plate; m19, a stirring rod; m20, a strut; k1, body; k2, gears; k3, a knee lever; k4, a first cavity; k5, a second cavity; k6, third cavity; k7, baffles; k8, fixed block;

k9, connecting rod; k10, a first breaker plate; k11, rotating rod; k12, incomplete gear; k13, rack plate; k14, connecting plate; k15, connecting plate; k16, a slider; k17, a second breaker plate; k18, connecting rod; k19, a third crushing plate; k20, separator plate; k21, a crushing roller; k22, a material collecting plate; k23, a motor; k24, pulley; k25, belt; g1, outer box; g2, cannula; g3, screw; g4, a first bevel gear; g5, a first stirring rod; g6, disc; g7, connecting rod; g8, second bevel gear; g9, a second stirring rod; g10, cross bar; g11, annular chute; g12, a scraper; g13, a strip groove; g14, support plate; g15, a slide block; g16, a positive and negative motor; g17, support bars; g18, feed pipe.

Detailed Description

The embodiment of the invention provides a corrosion-resistant pervious concrete production device, and specifically comprises a box body m1 and a quantitative assembly arranged inside a box body m1, referring to fig. 1, fig. 2 and fig. 3. Particularly, the quantitative assembly in the invention comprises a spring m2, a telescopic rod m3, a buffer bin m4, a fixing plate m5, a rack m6, a gear m7, a rotating rod m8, an eccentric wheel m9, an outer frame m10 and a baffle m11, wherein the spring m2 and the telescopic rod m3 are fixedly connected inside the buffer bin m 4. The spring m2 and the telescopic rod m3 are both fixedly connected to one side of a fixing plate m5, the fixing plate m5 is connected to the inside of a buffer bin m4 in a sliding mode, the buffer bin m4 is fixedly connected to the inside of a box body m1, and the rack m6 is fixedly connected to the top of the fixing plate m 5; gear m7 is arranged on the top of rack m6 and is meshed with rack m6, gear m7 and eccentric wheel m9 are both fixedly connected to the outer side of rotating rod m8, outer frame m10 is arranged on the outer side of eccentric wheel m9, baffle m11 is fixedly connected to the bottom of outer frame m10, and baffle m11 is connected to one side of the interior of the buffer box in a sliding manner.

When the concrete buffer is used, concrete enters the buffer bin m4 through the feeding pipe m12, and the fixing plate m5 is connected to the inside of the buffer bin m4 in a sliding mode, so that the fixing plate m5 can be driven to move leftwards under the extrusion force of the concrete; because spring m2 and telescopic link m3 are fixedly connected to the other side of fixed plate m5, fixed plate m5 moves to the left and can drive spring m2 and telescopic link m3 to contract, meanwhile, because rack m6 is fixedly connected to the top of fixed plate m5, fixed plate m5 moves to the left and drives rack m6 to move to the left. Since the gear m7 is arranged on the top of the rack m6 and is meshed with the rack m6, the rack m6 moves leftwards to drive the gear m7 to rotate, since the gear m7 is fixedly connected to the outer side of the rotating rod m8, the gear m7 rotates to drive the rotating rod m8 to rotate, since the eccentric wheel m9 is fixedly connected to the outer side of the rotating rod m8, the rotating rod m8 rotates to drive the eccentric wheel m9 to rotate, and since the outer frame m10 is arranged on the outer side of the eccentric wheel m9, the eccentric wheel m9 rotates to drive the outer frame m10 to. Because the baffle m11 is fixedly connected to the bottom of the outer frame m10, the outer frame m10 moves downwards to drive the baffle m11 to move downwards, and the baffle m11 moves downwards to block the feed inlet. This structure is favorable to ration to add powder raw materials such as cement, mountain flour inside buffer memory storehouse m4, is convenient for the back to mix cement, mountain flour, saves time, uses manpower sparingly.

Referring to fig. 1, 2 and 4 again, feeding pipes m12 are fixedly connected to two sides of a box m1, a discharging pipe m13 is fixedly connected to the bottom of a buffer storage bin m4, an electromagnetic valve m14 is arranged on the outer side of the discharging pipe m13, a sleeve m15 is rotatably connected to the top of a box m1, a positive and negative motor m16 is fixedly connected to the top of the sleeve m15, and a sliding groove is formed in the sleeve m 15. The inside sliding connection of sleeve m15 has lead screw m17, the outside fixedly connected with slider in lead screw m17, slider sliding connection is inside the spout, the inside fixedly connected with extension board m18 of box m1, lead screw m17 runs through extension board m18 and with extension board m18 threaded connection, the outside fixedly connected with puddler m19 of lead screw m17, box m1 top fixedly connected with branch m20, branch m20 fixedly connected in the positive and negative motor m16 outside.

Opening the electromagnetic valve m14 to pour all the raw materials into the box m1 for storage, starting the positive and negative motor m16 after the mixing is finished, and rotating the positive and negative motor m16 to drive the sleeve m15 to rotate because the sleeve m15 is fixedly connected with the output end of the positive and negative motor m 16. Because the slider is connected in the inside of the sliding groove in a sliding mode, the sleeve m15 rotates to drive the screw rod m17 to rotate. Lead screw m17 runs through extension board m18 and with extension board m18 threaded connection, sleeve m15 rotates and drives lead screw m17 and rotates the limit and move down, lead screw m17 rotates the limit and can drive puddler m19 and rotate the limit and move down, mix the stirring to the raw materials, positive and negative motor m16 is driving lead screw m17 upward movement in the contrary, drive puddler m19 upward movement, can make the raw materials carry out abundant mixing, this structure is favorable to carrying out abundant mixing to the raw materials, increase the product quality of later stage concrete.

In summary, in this embodiment, the fixing plate m5 moves leftward to drive the baffle m11 to move downward, the baffle m11 moves downward to block the feeding hole, the fixing plate m5 moves leftward to drive the spring m2 and the telescopic rod m3 to contract, the fixing plate m5 moves leftward to drive the rack m6 to move leftward, and the rack m6 moves leftward to drive the gear m7 to rotate. The gear m7 rotates to drive the rotating rod m8 to rotate, the rotating rod m8 rotates to drive the eccentric wheel m9 to rotate, the eccentric wheel m9 rotates to drive the outer frame m10 to move downwards, the outer frame m10 moves downwards to drive the baffle m11 to move downwards, and the baffle m11 moves downwards to block a feeding hole.

In order to obtain better preparation efficiency and improve preparation effect, corresponding supporting equipment, such as a crushing device for crushing aggregate and a stirring device for mixing and stirring all materials, can be added in the invention, so that the corrosion-resistant pervious concrete is prepared, the equipment are mutually matched for use, and a person skilled in the art can adaptively associate and match the equipment together through a common spiral conveying shaft, a belt or other existing transfer tools to form a more complete corrosion-resistant pervious concrete preparation system.

Specifically, referring to fig. 5-8, the crushing device includes a body k1, and a crushing assembly is disposed inside the body k 1. Broken subassembly includes two gear k2 and curved bar k3, organism k1 is inside to be provided with first cavity k4, second cavity k5 and third cavity k6, two gear k2 all set up inside first cavity k4, two gear k2 one side are provided with baffle k7, baffle k7 fixed connection is in the inside top of organism k1, baffle k7 one side fixedly connected with fixed block k8, the inside connecting rod k9 that is provided with of fixed block k8, curved bar k3 rotates and connects in connecting rod k9 top. The crank lever k3 is rotatably connected inside the machine body k1, the bottom end of the connecting rod k9 is fixedly connected with a first crushing plate k10, the two gears k2 are fixedly connected with rotating levers k11, the rotating levers k11 are rotatably connected inside the machine body k1, and the front sides of the two gears k2 are fixedly connected with incomplete gears k 12; the incomplete gear k12 is fixedly connected to the inside of the rotating rod k11, and the bottom end of the incomplete gear k12 is engaged with a rack plate k 13. The bottom end of the gear k2 is provided with a connecting plate k14, a connecting plate k15 is fixedly connected between a rack plate k13 and the connecting plate k14, a sliding plate k16 is connected inside a rack plate k13 and the connecting plate k14 in a sliding manner, the sliding plate k16 is fixedly connected inside a machine body k1, a second crushing plate k17 is fixedly connected to one side of the rack plate k13, a cam is arranged inside the second cavity k5, a connecting rod k18 is fixedly connected inside the cam, and the connecting rod k18 is rotatably connected inside the machine body k 1. Cam one end is rotated and is connected with the horizontal pole, the horizontal pole top articulates there is third broken board k19, third broken board k19 pastes with second cavity k5 inner wall both sides mutually, the passageway has been seted up between second cavity k5 and the third cavity k6, organism k1 outside is provided with motor k23, organism k1 and fixed connection in motor k 23's output is run through to curved bar k3 one end, organism k1 is all run through to connecting rod k18 and bull bar k11 one end, a bull bar k11, the equal fixedly connected with of connecting rod k18 and curved bar k3 outside is a plurality of band pulley k24, a bull bar k11, the connecting rod k18 and the curved bar k3 outside all overlaps and is equipped with two belt k 25.

The stone material that will need to be broken is placed on the transport plate, when the weight of bigger stone material can not be born to separator plate k20, make separator plate k20 be close to down to first cavity k4 rapidly through articulated and make the stone material fall into inside first cavity k4, because the baffle k7 of the inside fixed connection of organism k1 can block bigger stone material, avoid the stone material to hit first crushing plate k10 to fall on a plurality of awls. When starter motor k23 rotated and drives curved bar k3 and rotate, utilize curved bar k3 can drive connecting rod k9 and go up and down because connecting rod k9 and first crushing board k10 descend for fixed connection to connecting rod k9 goes up and down to drive first crushing board k10 and break the raw stone material. Meanwhile, a belt k25 is used for matching with and driving a rotating rod k11 to rotate, a rotating rod k11 rotates and drives a gear k2 fixedly connected with the outer side to rotate, two gears k2 are meshed to rotate, two incomplete gears k12 are indirectly driven to rotate, one incomplete gear k12 drives a rack plate k13 to move due to the fact that the two incomplete gears k12 are parallel to each other and staggered in position, and a connecting plate k15 fixedly connected between a connecting plate k14 and the rack plate k13 is used for driving the connecting plate k14 to move. Can block the great former stone material that drops through the removal of connecting plate k14, indirectly driven second crushing board k17 to one side removal to former stone material extrusion breakage, in extrusion broken process, another incomplete gear k12 drives rack board k13 through the meshing and removes to drive connecting plate k14 and remove and get back to original position, make the former stone material continue to drop the breakage inside through the through-hole entering third cavity k 6. When less raw stones move to second cavity k5 and drop and collide with second crushing board k17 inside second cavity k5, belt k25 cooperation of establishing through connecting rod k18 and bull stick k11 outside cover, make third crushing board k19 drive cam and connecting rod k18 and do reciprocating motion from top to bottom, make the less raw stones of broken back pass through the passageway and get into inside third cavity k6, the mesh of distinguishing the raw stones has been reached, the efficiency of the broken raw stones of extrusion has been improved, make the crushing effect of raw stones better, and is more even, and broken efficiency is higher.

Referring to fig. 5 and 7 again, a transport plate is fixedly connected to the top end of the body k1, a separation plate k20 is hinged inside the transport plate, a spring is fixedly connected between the separation plate k20 and the first cavity k4, and a plurality of stabs are fixedly connected inside the body k 1. Third cavity k6 inner wall both sides are rotated and are connected with two crushing roller k21, crushing roller k21 bottom both sides all are provided with two swash plates, two equal fixed connection of swash plate are inside organism k1, be provided with receipts flitch k22 between two swash plates, a receipts flitch k22 fixed connection is in an swash plate one side, a plurality of logical grooves have been seted up to a receipts flitch k22 is inside, two receipts flitch k22 are fixed connection, two receipts flitch k22 one side bottoms are provided with the receipts workbin respectively.

In addition, when the crushed raw stone material enters the third cavity k6, the crushed raw stone material is continuously crushed by utilizing the rotation of the two crushing rollers k21, the crushing is more thorough, the crushed raw stone material generates thick and thin aggregates and falls into the two material receiving plates k22 by utilizing the two inclined plates, and therefore the thick and thin aggregates are screened, the thick and thin aggregates can be collected by the material receiving box, the purpose of collecting the thick and thin aggregates is achieved, the working efficiency is improved, the raw stone material can be favorably crushed to separate the thick and thin aggregates, and the quality of the aggregates is improved.

Moreover, the invention is also specially equipped with a stirring device for stirring and preparing corrosion-resistant pervious concrete, and the structure of the stirring device is shown in fig. 9-12, and the stirring device is provided with an outer box g1, and a stirring component is arranged inside the outer box g 1. In detail, the stirring assembly comprises a sleeve g2, a screw g3, a first bevel gear g4, a first stirring rod g5, a disk g6, two connecting rods g7, two second bevel gears g8 and a second stirring rod g9, wherein the sleeve g2 penetrates through an outer box g1 and is rotatably connected with the outer box g 1. The sleeve g2 is slidably connected to the outer side of the screw g3, the first bevel gear g4 and the disc g6 are both fixedly connected to the outer side of the screw g3, the disc g6 is arranged at the top of the first bevel gear g4, the first stirring rod g5 is fixedly connected to one end of the screw g3, and one ends of the two connecting rods g7 are both extended into the disc g6 and rotatably connected with the disc g 6. The second bevel gears g8 are fixedly connected to the outer side of the connecting rod g7, the two second bevel gears g8 are arranged on two sides of the first bevel gear g4 respectively and are meshed with the first bevel gear g4, the second stirring rod g9 is fixedly connected to one end of the connecting rod g7, a support plate g14 is fixedly connected to the inner portion of the outer box g1, a screw g3 penetrates through the support plate g14 and is in threaded connection with the support plate g14, and a sliding block g15 is fixedly connected to the outer side of the screw g 3. The inside recess of having seted up of sleeve pipe g2, slider g15 sliding connection is inside the recess, and positive and negative motor g16 of sleeve pipe g2 top fixedly connected with, positive and negative motor g16 outside fixedly connected with bracing piece g17, bracing piece g17 fixed connection in outer container g1 top, outer container g1 one side fixedly connected with inlet pipe g 18.

When the stirring device needs to be used, firstly, concrete raw materials are placed inside the outer box g1, the forward and reverse motor g16 is started at the moment, the forward and reverse motor g16 rotates to drive the sleeve g2 to rotate, and the sleeve g2 rotates to drive the screw g3 to rotate due to the fact that the sliding block g15 is connected inside the groove in a sliding mode. Because screw g3 runs through support plate g14 and is connected with support plate g14 screw thread, sleeve g2 drives screw g3 and rotates the limit and moves down, because disc g6 is fixed connection in the screw g3 outside, screw g3 rotates and drives disc g6 to rotate, because first bevel gear g4 is fixed connection in the screw g3 outside, screw g3 rotates and drives first bevel gear g4 to rotate. Moreover, the first stirring rod g5 is fixedly connected to one end of the screw rod g3, the screw rod g3 rotates to drive the first stirring rod g5 to move downwards while rotating, and meanwhile, as the two second bevel gears g8 are respectively arranged on two sides of the first bevel gear g4 and meshed with the first bevel gear g4, the first bevel gear g4 rotates to drive the second bevel gear g8 to rotate. Because the second bevel gear g8 is fixedly connected to the outer side of the screw g3, the connecting rod g7 penetrates through the disk g6 and is rotatably connected with the disk g6, and the second bevel gear g8 rotates to drive the connecting rod g7 to rotate. Because second puddler g9 fixed connection is in connecting rod g7 one end, and connecting rod g7 rotates and drives second puddler g9 and rotates, can drive first puddler g5 and second puddler g9 and rotate the upward-downward motion simultaneously through positive and negative motor g 16's positive and negative rotation, can make the concrete mixing more even. This structure is of value to carrying out all-round stirring with horizontal rotation about the concrete is perpendicular, and then makes the concrete mix more evenly.

Referring to fig. 2 and 3 again, a cross bar g10 is fixedly connected to the outer side of the screw g3, an annular sliding groove g11 is formed in the outer box g1, a scraper g12 is slidably connected to one end of the cross bar g10, the scraper g12 is slidably connected to the annular sliding groove g11, a strip-shaped groove g13 is formed in one side of the scraper g12, and the cross bar g10 is slidably connected to the strip-shaped groove g 13.

When the invention is used: because horizontal pole g10 fixed connection is in the screw rod g3 outside, and then screw rod g3 rotates and drives horizontal pole g10 and rotate, because horizontal pole g10 sliding connection is inside strip-shaped groove g13, horizontal pole g10 slides from top to bottom in strip-shaped groove g13 is inside. Meanwhile, scraper g12 sliding connection is inside annular spout g11, and horizontal pole g10 rotates and drives scraper g12 and rotate in annular spout g11 is inside, can scrape off the concrete of outer container g1 inner wall adhesion, and this structure is favorable to scraping off the concrete of the inside production of outer container g1, avoids the concrete adhesion on outer container g1 inner wall, influences agitating unit's use.

In the specific application, the forward and reverse motor g16 rotates to drive the screw g3 to rotate and move downwards, the screw g3 rotates to drive the disc g6 to rotate, the screw g3 rotates to drive the first stirring rod g5 to rotate and move downwards, the first bevel gear g4 rotates to drive the second bevel gear g8 to rotate, the second bevel gear g8 rotates to drive the connecting rod g7 to rotate, and the connecting rod g7 rotates to drive the second stirring rod g9 to rotate. Positive and negative motor g 16's positive and negative rotation can drive first puddler g5 and second puddler g9 limit and rotate the limit and move up and down, can make concrete mixing more even, and screw rod g3 rotates and drives horizontal pole g10 and rotate, and horizontal pole g10 rotates and drives scraper blade g12 at the inside rotation of annular spout g11, and then can strike off the concrete of outer container g1 inner wall adhesion.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides a corrosion-resistant pervious concrete apparatus for producing, includes box (m1), its characterized in that: a quantitative component is arranged inside the box body (m 1);

the quantitative component comprises a spring (m2), an expansion rod (m3), a buffer storage bin (m4), a fixed plate (m5), a rack (m6), a gear (m7), a rotating rod (m8), an eccentric wheel (m9), an outer frame (m10) and a baffle plate (m11), wherein the spring (m11) and the expansion rod (m11) are fixedly connected inside the buffer storage bin (m11), the spring (m11) and the expansion rod (m11) are fixedly connected to one side of the fixed plate (m11), the fixed plate (m11) is slidably connected inside the buffer storage bin (m11), the buffer storage bin (m11) is fixedly connected inside a box body (m11), the rack (m11) is fixedly connected to the top of the fixed plate (m11), the gear rotating rod (m11) is arranged at the top of the rack (m11) and is meshed with the rack (m11), the gear (m11) and the eccentric wheel (m11) are fixedly connected to the outer side of the buffer storage bin (m11), the baffle (m11) is fixedly connected to the bottom of the outer frame (m10), and the baffle (m11) is connected to one side of the inside of the buffer box in a sliding mode.

2. The apparatus for producing corrosion-resistant pervious concrete according to claim 1, characterized in that: the equal fixedly connected with inlet pipe (m12) in box (m1) both sides, buffer bin (m4) bottom fixedly connected with discharging pipe (m 13).

3. The apparatus for producing corrosion-resistant pervious concrete according to claim 2, characterized in that: an electromagnetic valve (m14) is arranged on the outer side of the discharge pipe (m13), and the top of the box body (m1) is rotatably connected with a sleeve (m 15).

4. The apparatus for producing corrosion-resistant pervious concrete according to claim 3, characterized in that: the top of the sleeve (m15) is fixedly connected with a positive and negative motor (m16), and a sliding groove is formed in the sleeve (m 15).

5. The apparatus for producing corrosion-resistant pervious concrete according to claim 3, characterized in that: the inner part of the sleeve (m15) is connected with a screw rod (m17) in a sliding mode, and the outer side of the screw rod (m17) is fixedly connected with a sliding block.

6. The apparatus for producing corrosion-resistant pervious concrete according to claim 5, characterized in that: the sliding block is connected to the inside of the sliding groove in a sliding mode, and a support plate (m18) is fixedly connected to the inside of the box body (m 1).

7. The apparatus for producing corrosion-resistant pervious concrete according to claim 6, characterized in that: the screw rod (m17) penetrates through the support plate (m18) and is in threaded connection with the support plate (m18), and the stirring rod (m19) is fixedly connected to the outer side of the screw rod (m 17).

8. The apparatus for producing corrosion-resistant pervious concrete according to claim 4, characterized in that: the top of the box body (m1) is fixedly connected with a supporting rod (m20), and the supporting rod (m20) is fixedly connected to the outer side of the positive and negative motor (m 16).

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