CN220030714U - Civil engineering material processing agitating unit - Google Patents

Abstract

The utility model is applicable to the technical field of civil engineering material processing, and provides a civil engineering material processing stirring device which comprises a stirring tank and a stirring and scattering assembly, wherein the stirring tank is rotatably arranged on a shaking vibration base; the stirring and scattering assembly consists of a scattering cylinder and an extrusion type stirring rod structure; the extrusion type stirring rod structure comprises a prismatic pipe and a prismatic column; a plurality of extrusion rods A which are distributed at equal intervals are fixed on the prismatic pipe main body, and a plurality of extrusion rods B which are distributed at equal intervals are fixed on the prismatic pipe main body; the prismatic pipes are periodically inserted in the prismatic movement, so that the extruding rods B are longitudinally pushed on the basis of transversely stirring, and the prismatic pipes are longitudinally extruded with the extruding rods A which are longitudinally staggered, so that the extruding rods B are upwardly pushed on the premise of transversely and longitudinally mixing and stirring, the extruding rods A are downwardly blocked, specific stirring treatment is carried out according to a concentrated area of the materials, and the phenomenon that the civil engineering materials are dispersed to a non-stirring area in the stirring process to reduce the stirring effect is avoided.

Description

Civil engineering material processing agitating unit

Technical Field

The utility model relates to the technical field of civil engineering material processing, in particular to a civil engineering material processing stirring device.

Background

Among many civil engineering materials, there are some operations that require secondary operations, such as screening after crushing of concrete blocks, and feeding the sand after sorting into operations for making concrete; in the secondary processing process of stirring during the processing of civil engineering materials, stirring is realized by a certain circulation of a stirrer, so that the materials are uniformly mixed, and in order to achieve the aim of uniform mixing, the materials are required to be realized by a device of forced convection and uniform mixing.

At present, stirring modes are various and can be roughly divided into simple transverse stirring on the whole, simple longitudinal stirring on the whole and transverse and longitudinal mixing stirring on the whole, but no matter the simple longitudinal stirring or the transverse and longitudinal mixing stirring, the whole is also moved longitudinally together, the materials are also driven together integrally, the stirring effect is easy to be limited, for example, specific stirring treatment cannot be carried out according to a concentrated area of the materials.

Disclosure of Invention

Technical problems: the utility model aims to solve the defects in the prior art: whether simple longitudinal stirring or transverse and longitudinal mixing stirring, the stirring device also moves longitudinally integrally, materials are driven integrally, the stirring effect is limited easily, for example, the stirring device for processing civil engineering materials can not be provided specifically according to the problem that specific stirring treatment can not be carried out in a concentrated area of the materials.

The specific technical scheme is as follows: the civil engineering material processing stirring device comprises a stirring tank, wherein the stirring tank is rotatably arranged on a shaking vibration base, and the shaking vibration base is used for providing power to drive the stirring tank to swing left and right so as to shake the civil engineering material arranged in the stirring tank; the device also comprises a stirring and scattering assembly, wherein the stirring and scattering assembly is arranged in the shaking stirring tank; the stirring and scattering assembly consists of a scattering cylinder and an extrusion type stirring rod structure which is inserted on the central line of the scattering cylinder column; the scattering cylinder consists of a cylinder body and a plurality of scattering holes arranged on the cylinder body; the extrusion stirring rod structure comprises a prismatic pipe and a prismatic column, wherein the prismatic column is movably inserted into the prismatic pipe; a plurality of extrusion rods A which are distributed at equal intervals are fixed on the prismatic pipe main body, and a plurality of extrusion rods B which are distributed at equal intervals are fixed on the prismatic pipe main body; the extrusion rods A and the extrusion rods B are distributed in a staggered manner along the longitudinal direction of the prismatic pipe; the prismatic pipe main body is provided with a plurality of chute bodies which are in one-to-one correspondence with the extrusion rods B; the chute body is used for longitudinally sliding the extrusion rod B back and forth in the chute body; one end of the prismatic pipe, which is far away from the prismatic pipe, is positioned at the top and bottom of the scattering cylinder and is rotated on a bearing seat by an air cylinder, the bearing seat is fixed at the bottom of the stirring tank, and the scattering cylinder is fixed at the bottom of the stirring tank; one end of the prism, which is far away from the prism pipe, is fixed with a rotating shaft, the rotating shaft is fixed on an output shaft of a power motor, and the power motor is arranged inside the stirring tank.

In summary, the vibration base swings left and right to shake the civil engineering materials arranged in the stirring tank, and the civil engineering materials periodically pass through the scattering cylinder to realize that the scattering cylinder is matched with the scattering cylinder to provide the dispersion and mixing degree of the civil engineering materials, and the civil engineering materials are concentrated in the stirring area at the bottom of the stirring tank; after the civil engineering materials are concentrated in the stirring area, the power motor is matched with the edges of the prismatic pipes and the prismatic pipes through the rotating shaft, so that the prismatic pipes and the prismatic pipes rotate synchronously, and a plurality of extrusion rods A and a plurality of extrusion rods B are distributed in a staggered manner along the longitudinal direction of the prismatic pipes to stir the civil engineering materials in the concentrated stirring area; meanwhile, the cylinder is started to drive the prismatic pipe to periodically penetrate through the prismatic pipe in a moving mode, the extrusion rod B is driven to longitudinally slide back and forth in the sliding groove body, so that the extrusion rod B longitudinally pushes materials on the basis of transversely stirring, the extrusion rod A longitudinally misplaced and distributed in the longitudinal direction extrudes civil engineering materials, the extrusion rod B pushes materials upwards on the premise of realizing transversely and longitudinally mixing and stirring, the extrusion rod A performs specific stirring treatment on the downward material blocking concrete according to a concentrated area of the materials, and the civil engineering materials are prevented from being dispersed to a non-stirring area in the stirring process, so that the stirring effect is reduced.

According to the technical scheme of the civil engineering material processing stirring device, the extruding rods A and B are in the shape of quadrangular frustum, and the edges of the extruding rods A and B face to the longitudinal direction along the prismatic pipe and are used for crushing the civil engineering material in the longitudinal stirring process.

According to the technical scheme of the civil engineering material processing stirring device, the stirring tank comprises a stirring tank cover assembly and a stirring tank body; the stirring tank cover assembly is arranged at the top of the stirring tank body; the stirring and scattering assembly is arranged inside the stirring tank body, and a discharging door is arranged on the side wall of the stirring tank body.

According to a further technical scheme, the stirring tank cover assembly comprises a stirring tank cover, and the stirring tank cover is detachably arranged on the stirring tank body through a locking ring; the stirring tank cover is additionally provided with a lifting device, and the lifting device is used for adjusting the height of the stirring tank cover to finish the switching operation of the stirring tank body.

According to the optimized technical scheme, the lifting device comprises an air cylinder telescopic rod, a first fixing plate is fixed at one end head of the air cylinder telescopic rod, and the first fixing plate is fixed on the side wall of the stirring tank body; a connecting plate is fixed at the end of the other end of the air cylinder telescopic rod, and the connecting plate and the first fixed plate are distributed in parallel; the connecting plate is fixed on the stirring tank cover through the connecting column.

According to the technical scheme of the civil engineering material processing stirring device, the shaking vibration base comprises a shaking base and a vibration base, and the vibration base is arranged on the shaking base.

According to a further technical scheme, a supporting bottom plate is arranged on the shaking base, and two side driving plates which are distributed in parallel are arranged on the supporting bottom plate; the stirring tank is rotatably installed between the two side driving plates, and rotation power is provided by the side driving plates.

According to the optimized technical scheme, the side driving plate comprises a vertical plate, and the vertical plate is arranged on the supporting bottom plate through a reinforcing plate; the top of the vertical plate is fixedly provided with a second fixing plate, the second fixing plate is fixedly provided with a motor, an output shaft of the motor is fixedly provided with a driving shaft, and the driving shaft is fixed on the stirring tank and is used for providing power to drive the stirring tank to swing left and right so as to shake civil engineering materials arranged in the stirring tank.

According to a further technical scheme of the utility model, a shell is arranged on the vibration seat, and the shell is arc-shaped; an elastic cushion is paved inside the shell, the elastic cushion is made of rubber, and a knocking piece is movably inserted in the elastic cushion; the knocking piece consists of a bottom plate and a plurality of knocking heads fixed on the bottom plate, and the knocking heads are movably inserted on the elastic cushion.

According to the optimized technical scheme, the knocking head comprises a telescopic rod, and a spring is sleeved outside the telescopic rod; one end of the telescopic rod is fixed with a hinged ball which is hinged on the bottom plate; the striking ball is fixed at the other end of the telescopic rod; one end of the spring is connected to the bottom plate, and the other end is connected to the striking ball.

Therefore, the motor drives the stirring tank to swing left and right on the shaking base to shake the civil engineering material arranged in the stirring tank, and in the process, when the stirring tank sequentially passes through the vibration base, the knocking heads knock the stirring tank by using the knocking balls, and after the stirring tank sequentially passes through the plurality of local knocking heads, the knocking heads elastically reset by using the springs; the stirring tank is continuously knocked by a plurality of knocking heads, and the auxiliary stirring and the dispersion of civil engineering materials are realized.

The beneficial effects are that: compared with the prior art, the civil engineering material processing and stirring device provided by the utility model has the advantages that the vibration base is rocked left and right to shake the civil engineering material arranged in the stirring tank, and the civil engineering material periodically passes through the scattering cylinder to realize that the scattering cylinder is matched with the scattering cylinder to provide the dispersion and mixing degree of the civil engineering material, and the civil engineering material is concentrated in the stirring area at the bottom of the stirring tank; after the civil engineering materials are concentrated in the stirring area, the power motor is matched with the edges of the prismatic pipes and the prismatic pipes through the rotating shaft, so that the prismatic pipes and the prismatic pipes rotate synchronously, and a plurality of extrusion rods A and a plurality of extrusion rods B are distributed in a staggered manner along the longitudinal direction of the prismatic pipes to stir the civil engineering materials in the concentrated stirring area; meanwhile, the cylinder is started to drive the prismatic pipe to periodically penetrate through the prismatic pipe in a moving mode, the extrusion rod B is driven to longitudinally slide back and forth in the sliding groove body, so that the extrusion rod B longitudinally pushes materials on the basis of transversely stirring, the extrusion rod A longitudinally misplaced and distributed in the longitudinal direction extrudes civil engineering materials, the extrusion rod B pushes materials upwards on the premise of realizing transversely and longitudinally mixing and stirring, the extrusion rod A performs specific stirring treatment on the downward material blocking concrete according to a concentrated area of the materials, and the civil engineering materials are prevented from being dispersed to a non-stirring area in the stirring process, so that the stirring effect is reduced.

Drawings

FIG. 1 is a schematic structural view of a civil engineering material processing stirring device of the utility model;

FIG. 2 is a schematic view of the shake base of FIG. 1;

FIG. 3 is a schematic view of the plexor member of FIG. 2;

FIG. 4 is a schematic view of the tapping head of FIG. 3;

FIG. 5 is a schematic view of the wobble base of FIG. 2;

FIG. 6 is a schematic view of the side drive plate of FIG. 5;

FIG. 7 is a schematic view of the structure of the stirring tank in FIG. 1;

FIG. 8 is a schematic view of the structure of the agitator tank cap assembly of FIG. 7;

FIG. 9 is a schematic structural view of a stirring and scattering assembly in the civil engineering material processing stirring device;

FIG. 10 is a schematic view of the scattering cylinder of FIG. 9;

FIG. 11 is a schematic view of the structure of the extrusion stirring rod of FIG. 9;

fig. 12 is an enlarged schematic view of the structure of fig. 11 at a.

In the reference numerals:

shaking the vibration base 1 and the stirring tank 2;

shaking the base 11, shaking the base 12, the outer casing 13, the elastic pad 14, the knocking piece 15;

a stirring tank cover assembly 21, a stirring tank body 22, a discharging door 23 and a stirring and scattering assembly 24;

a support base plate 111, a side drive plate 112;

a base plate 151, a striking head 152;

the stirring device comprises a locking ring 211, a stirring tank cover 212, a first fixing plate 213, a cylinder telescopic rod 214, a connecting plate 215 and a connecting column 216;

a break-up cylinder 241, an extruded stirring rod structure 242;

reinforcing plate 1121, motor 1122, fixing plate two 1123, riser 1124;

click ball 1521, spring 1522, telescoping rod 1523, articulation ball 1524;

the rib pipe 2421, the prism 2422, the rotating shaft 2423, the chute body 2424, the extrusion rod A2425, the extrusion rod B2426 and the air cylinder 2427.

Detailed Description

The present utility model will be described in further detail with reference to specific embodiments in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiments of the utility model

As shown in fig. 1, 7, 9-12: the civil engineering material processing stirring device comprises a stirring tank 2, wherein the stirring tank 2 is rotatably arranged on a shaking vibration base 1, and the shaking vibration base 1 is used for providing power to drive the stirring tank 2 to swing left and right so as to shake the civil engineering material arranged in the stirring tank 2;

therefore, after the civil engineering materials to be stirred are arranged in the stirring tank 2, the shaking vibration base 1 is started, the civil engineering materials arranged in the stirring tank 2 are shaken by means of the power provided by the shaking vibration base 1, so that the purposes of providing the dispersion and mixing degree of the civil engineering materials on the one hand and concentrating the civil engineering materials on the stirring area on the other hand are achieved, the civil engineering materials are prevented from being dispersed to the non-stirring area in the stirring process, and the stirring effect is reduced;

the device also comprises a stirring and scattering assembly 24, wherein the stirring and scattering assembly 24 is arranged inside the shaking stirring tank 2; the stirring and scattering assembly 24 consists of a scattering cylinder 241 and an extrusion type stirring rod structure 242 which is inserted on the central line of the column of the scattering cylinder 241;

the scattering cylinder 241 is composed of a cylinder body and a plurality of scattering holes arranged on the cylinder body; the extrusion stirring rod structure 242 comprises a prism 2421 and a prism 2422, wherein the prism 2422 is movably inserted into the prism 2421; a plurality of squeeze rods A2425 which are distributed at equal intervals are fixed on the main body of the prismatic pipe 2421, and a plurality of squeeze rods B2426 which are distributed at equal intervals are fixed on the main body of the prismatic pipe 2422; the plurality of squeeze bars a2425 and the plurality of squeeze bars B2426 are distributed in a staggered manner in the longitudinal direction along the rib pipe 2421; the main body of the rib pipe 2421 is provided with a plurality of chute bodies 2424, and the chute bodies 2424 and the extrusion rods B2426 are in one-to-one correspondence; the chute body 2424 is used for longitudinally sliding the extrusion rod B2426 back and forth in the chute body;

one end of the prismatic pipe 2421 far away from the prismatic pipe 2422 is positioned at the top and bottom of the scattering cylinder 241 and is rotated on a bearing seat by an air cylinder 2427, the bearing seat is fixed at the bottom of the stirring tank 2, and the scattering cylinder 241 is fixed at the bottom of the stirring tank 2;

one end of the prism 2422 far away from the prism pipe 2421 is fixed with a rotating shaft 2423, the rotating shaft 2423 is fixed on an output shaft of a power motor, and the power motor is arranged in the stirring tank 2;

therefore, after the power motor is started, power is transmitted to the rotating shaft 2423, the rotating shaft 2423 utilizes the edge cooperation of the prismatic tube 2421 and the prismatic tube 2422 to realize synchronous rotation of the prismatic tube 2421 and the prismatic tube 2422, and a plurality of extrusion rods A2425 and a plurality of extrusion rods B2426 are distributed in a staggered manner along the longitudinal direction of the prismatic tube 2421 to stir; simultaneously, the cylinder 2427 is started to drive the prismatic pipe 2421 to move on the prismatic pipe 2422 to periodically penetrate, and in the process, the extrusion rod B2426 is driven to longitudinally slide back and forth in the chute body 2424, so that the extrusion rod B2426 is longitudinally pushed on the basis of transversely stirring, and extrudes civil engineering materials with the extrusion rod A2425 which is longitudinally staggered, the extrusion rod B2426 is pushed upwards on the premise of realizing transverse and longitudinal mixing and stirring, and the extrusion rod A2425 is subjected to specific stirring treatment according to the concentrated area of the materials.

In summary, the vibration base 1 is rocked to the left and right to shake the civil engineering materials arranged in the stirring tank 2, and the civil engineering materials periodically pass through the scattering cylinder 241, so that on one hand, the scattering mixing degree of the civil engineering materials is provided by matching with the scattering cylinder 241, and on the other hand, the civil engineering materials are concentrated in the stirring area at the bottom of the stirring tank 2; after the civil engineering material is concentrated in the stirring area, the power motor is matched with the edges of the prismatic pipes 2421 and the prismatic pipes 2422 through the rotating shaft 2423, so that the prismatic pipes 2421 and the prismatic pipes 2422 synchronously rotate, and a plurality of extrusion rods A2425 and a plurality of extrusion rods B2426 are distributed along the longitudinal direction of the prismatic pipes 2421 in a staggered manner to stir the civil engineering material in the concentrated stirring area; simultaneously, the cylinder 2427 is started to drive the prismatic pipe 2421 to move and periodically penetrate through the prismatic pipe 2422, the extrusion rod B2426 is driven to longitudinally slide back and forth in the chute body 2424, the material is longitudinally pushed on the basis of transversely stirring the extrusion rod B2426, the civil engineering material is extruded by the extrusion rod A2425 which is longitudinally distributed in a staggered mode, the material is pushed upwards by the extrusion rod B2426 on the premise of transversely and longitudinally mixing and stirring, the extrusion rod A2425 performs specific stirring treatment on the downward material blocking concrete according to a concentrated area of the material, and the civil engineering material is prevented from being dispersed to a non-stirring area in the stirring process, so that the stirring effect is reduced.

Embodiments of the utility model

As shown in fig. 11 and 12: the extrusion rods A2425 and B2426 are both in a quadrangular frustum shape, and edges of the extrusion rods A2425 and B2426 face to the longitudinal direction along the prismatic pipes 2421, so as to crush civil engineering materials in the longitudinal stirring process.

Embodiments of the utility model

As shown in fig. 7 and 8: the stirring tank 2 comprises a stirring tank cover assembly 21 and a stirring tank body 22; the stirring tank cover assembly 21 is arranged at the top of the stirring tank body 22; the stirring and scattering assembly 24 is arranged inside the stirring tank body 22, and a discharging door 23 is arranged on the side wall of the stirring tank body 22.

Embodiments of the utility model

As shown in fig. 8: the stirring tank cover assembly 21 comprises a stirring tank cover 212, and the stirring tank cover 212 is detachably arranged on the stirring tank body 22 through a locking ring 211; the stirring tank cover 212 is additionally provided with a lifting device, and the lifting device is used for adjusting the height of the stirring tank cover 212 to finish the opening and closing operation of the stirring tank body 22.

Embodiments of the utility model

As shown in fig. 8: the lifting device comprises a cylinder telescopic rod 214, a first fixing plate 213 is fixed at one end of the cylinder telescopic rod 214, and the first fixing plate 213 is fixed on the side wall of the stirring tank body 22;

a connecting plate 215 is fixed at the end of the other end of the air cylinder telescopic rod 214, and the connecting plate 215 and the first fixing plate 213 are distributed in parallel;

the connection plate 215 is fixed to the agitator tank cover 212 by a connection post 216.

Therefore, after the cylinder expansion link 214 is started, the cylinder expansion link 214 drives the connecting plate 215 and the connecting column 216 by means of expansion adjustment of the cylinder expansion link 214 by taking the first fixing plate 213 as a supporting point, so that the stirring tank cover 212 and the stirring tank body 22 are closed and separated, the stirring tank body 22 is opened and closed, and after the stirring tank cover 212 and the stirring tank body 22 are separated, the civil engineering material is installed inside the stirring tank body 22.

Embodiments of the utility model

As shown in fig. 2: the shaking vibration base 1 comprises a shaking base 11 and a vibration base 12, and the vibration base 12 is arranged on the shaking base 11.

Embodiments of the utility model

As shown in fig. 2, 5 and 6: the shaking base 11 is provided with a supporting bottom plate 111, and the supporting bottom plate 111 is provided with two parallel side driving plates 112;

the agitator tank 2 is rotatably installed between the two side drive plates 112, and rotational power is supplied by the side drive plates 112.

Embodiments of the utility model

As shown in fig. 6: the side driving plate 112 includes a vertical plate 1124, and the vertical plate 1124 is mounted on the supporting base plate 111 through a reinforcing plate 1121;

a second fixing plate 1123 is fixed on the top of the vertical plate 1124, a motor 1122 is fixed on the second fixing plate 1123, a driving shaft is fixed on an output shaft of the motor 1122, and the driving shaft is fixed on the stirring tank 2 and is used for providing power to drive the stirring tank 2 to swing left and right so as to shake civil engineering materials arranged in the stirring tank 2.

Therefore, after the motor 1122 is started, the motor 1122 transmits power to the stirring tank 2 through the driving shaft, and drives the stirring tank 2 to swing left and right on the shaking base 11 to shake the civil engineering materials arranged in the stirring tank 2, so that the purpose of providing the dispersion and mixing degree of the civil engineering materials on one hand and the purpose of centralizing the civil engineering materials in a stirring area on the other hand is achieved, the phenomenon that the civil engineering materials are dispersed in a non-stirring area in the stirring process is avoided, and the stirring effect is reduced.

Embodiments of the utility model

As shown in fig. 2 and 3: the vibration seat 12 is provided with a shell 13, and the shell 13 is arc-shaped; an elastic pad 14 is paved inside the shell 13, the elastic pad 14 is made of rubber, and a knocking piece 15 is movably inserted in the elastic pad 14; the knocking member 15 is composed of a base plate 151 and a plurality of knocking heads 152 fixed on the base plate 151, wherein the knocking heads 152 are movably inserted into the elastic pads 14.

Embodiments of the utility model

As shown in fig. 4: the knocking head 152 includes a telescopic rod 1523, and a spring 1522 is sleeved outside the telescopic rod 1523;

one end of the telescopic rod 1523 is fixed with a hinge ball 1524, and is hinged on the bottom plate 151 by the hinge ball 1524;

the other end of the telescopic rod 1523 is fixed with a knocking ball 1521;

spring 1522 is attached at one end to base 151 and at the other end to tapping ball 1521.

Therefore, the motor 1122 drives the stirring tank 2 to swing left and right on the swing base 11 to swing the civil engineering material installed in the stirring tank 2, and in the process, when the stirring tank 2 sequentially passes through the vibration base 12, the knocking head 152 uses the knocking ball 1521 to knock the stirring tank 2, and after the stirring tank 2 sequentially passes through the local plurality of knocking heads 152, the knocking head 152 uses the spring 1522 to elastically reset; the stirring tank 2 is continuously knocked by the plurality of knocking heads 152, so that the auxiliary stirring and the civil engineering material dispersion are realized.

The working principle of the utility model is as follows:

the vibration base 1 swings left and right to shake the civil engineering materials arranged in the stirring tank 2, and the civil engineering materials periodically pass through the scattering cylinder 241, so that on one hand, the scattering mixing degree of the civil engineering materials is provided by being matched with the scattering cylinder 241, and on the other hand, the civil engineering materials are concentrated in a stirring area at the bottom of the stirring tank 2; after the civil engineering material is concentrated in the stirring area, the power motor is matched with the edges of the prismatic pipes 2421 and the prismatic pipes 2422 through the rotating shaft 2423, so that the prismatic pipes 2421 and the prismatic pipes 2422 synchronously rotate, and a plurality of extrusion rods A2425 and a plurality of extrusion rods B2426 are distributed along the longitudinal direction of the prismatic pipes 2421 in a staggered manner to stir the civil engineering material in the concentrated stirring area; simultaneously, the cylinder 2427 is started to drive the prismatic pipe 2421 to movably and periodically penetrate through the prismatic pipe 2422, and drive the extrusion rod B2426 to longitudinally slide back and forth in the chute body 2424, so that the extrusion rod B2426 longitudinally pushes materials on the basis of transversely stirring and extrudes civil engineering materials with the extrusion rod A2425 longitudinally distributed in a staggered manner, the extrusion rod B2426 pushes materials upwards on the premise of realizing transverse and longitudinal mixing stirring, the extrusion rod A2425 carries out specific stirring treatment on the downward material blocking concrete according to a concentrated area of the materials, and the civil engineering materials are prevented from being dispersed to a non-stirring area in the stirring process, so that the stirring effect is reduced;

the motor 1122 drives the stirring tank 2 to swing left and right on the swing base 11 to swing the civil engineering material arranged in the stirring tank 2, and in the process, when the stirring tank 2 sequentially passes through the vibration base 12, the knocking heads 152 knock the stirring tank 2 by using the knocking balls 1521, and after the stirring tank 2 sequentially passes through the local plurality of knocking heads 152, the knocking heads 152 elastically reset by using the springs 1522; the stirring tank 2 is continuously knocked by the plurality of knocking heads 152, so that the auxiliary stirring and the civil engineering material dispersion are realized.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present utility model, and although the present utility model has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present utility model.

Claims (10)

1. A civil engineering material processing stirring device is characterized in that,

the civil engineering material shaking device comprises a stirring tank (2), wherein the stirring tank (2) is rotatably arranged on a shaking vibration base (1), and the shaking vibration base (1) is used for providing power to drive the stirring tank (2) to swing left and right so as to shake civil engineering material arranged in the stirring tank (2);

the device also comprises a stirring and scattering assembly (24), wherein the stirring and scattering assembly (24) is arranged inside the shaking stirring tank (2); the stirring and scattering assembly (24) consists of a scattering cylinder (241) and an extrusion type stirring rod structure (242) which is inserted on the central line of the column of the scattering cylinder (241);

the scattering cylinder (241) consists of a cylinder body and a plurality of scattering holes arranged on the cylinder body; the extrusion type stirring rod structure (242) comprises a prismatic pipe (2421) and a prismatic column (2422), wherein the prismatic column (2422) is movably inserted into the prismatic pipe (2421); a plurality of squeeze rods A (2425) which are distributed at equal intervals are fixed on the prismatic pipe (2421) main body, and a plurality of squeeze rods B (2426) which are distributed at equal intervals are fixed on the prismatic pipe (2422) main body; the plurality of squeeze bars A (2425) and the plurality of squeeze bars B (2426) are distributed in a staggered manner in the longitudinal direction along the rib pipe (2421); the main body of the prismatic pipe (2421) is provided with a plurality of chute bodies (2424), and the chute bodies (2424) and the extrusion rods B (2426) are in one-to-one correspondence; the chute body (2424) is used for longitudinally sliding the extrusion rod B (2426) back and forth in the chute body;

one end of the prismatic pipe (2421) far away from the prismatic pipe (2422) is positioned at the top and bottom of the scattering cylinder (241) and is rotated on a bearing seat by an air cylinder (2427), the bearing seat is fixed at the bottom of the stirring tank (2), and the scattering cylinder (241) is fixed at the bottom of the stirring tank (2);

one end of the prism (2422) far away from the prism pipe (2421) is fixed with a rotating shaft (2423), the rotating shaft (2423) is fixed on an output shaft of a power motor, and the power motor is arranged inside the stirring tank (2).

2. The civil engineering material processing and stirring device according to claim 1, wherein the extrusion rod a (2425) and the extrusion rod B (2426) are both in a quadrangular frustum shape, and edges of the extrusion rod a and the extrusion rod B (2426) face in the longitudinal direction along the prismatic pipe (2421) for crushing the civil engineering material in the longitudinal stirring process.

3. The civil engineering material processing stirring device of claim 1, wherein,

the stirring tank (2) comprises a stirring tank cover assembly (21) and a stirring tank body (22); the stirring tank cover assembly (21) is arranged at the top of the stirring tank body (22);

the stirring and scattering assembly (24) is arranged inside the stirring tank body (22), and a discharging door (23) is arranged on the side wall of the stirring tank body (22).

4. A civil engineering material processing stirring device as set forth in claim 3, characterized in that,

the stirring tank cover assembly (21) comprises a stirring tank cover (212), and the stirring tank cover (212) is detachably arranged on the stirring tank body (22) through a locking ring (211);

the stirring tank cover (212) is additionally provided with a lifting device, and the lifting device is used for adjusting the height of the stirring tank cover (212) to finish the opening and closing operation of the stirring tank body (22).

5. The civil engineering material processing stirring device of claim 4, wherein,

the lifting device comprises an air cylinder telescopic rod (214), a first fixing plate (213) is fixed at one end head of the air cylinder telescopic rod (214), and the first fixing plate (213) is fixed on the side wall of the stirring tank body (22);

a connecting plate (215) is fixed at the end of the other end of the air cylinder telescopic rod (214), and the connecting plate (215) and the first fixed plate (213) are distributed in parallel;

the connecting plate (215) is fixed on the stirring tank cover (212) through the connecting column (216).

6. The civil engineering material processing stirring device according to claim 1, wherein the shaking vibration base (1) comprises a shaking base (11) and a vibration base (12), and the vibration base (12) is installed on the shaking base (11).

7. The civil engineering material processing stirring device of claim 6, wherein,

a supporting bottom plate (111) is arranged on the shaking base (11), and two side driving plates (112) which are distributed in parallel are arranged on the supporting bottom plate (111);

the stirring tank (2) is rotatably installed between two side driving plates (112), and rotation power is provided by the side driving plates (112).

8. The civil engineering material processing stirring device of claim 7, wherein,

the side driving plate (112) comprises a vertical plate (1124), and the vertical plate (1124) is arranged on the supporting bottom plate (111) through a reinforcing plate (1121);

the top of the vertical plate (1124) is fixedly provided with a second fixing plate (1123), the second fixing plate (1123) is fixedly provided with a motor (1122), the output shaft of the motor (1122) is fixedly provided with a driving shaft, and the driving shaft is fixed on the stirring tank (2) and is used for providing power to drive the stirring tank (2) to swing left and right so as to shake civil engineering materials arranged in the stirring tank (2).

9. The civil engineering material processing stirring device of claim 6, wherein,

a shell (13) is arranged on the vibration seat (12), and the shell (13) is arc-shaped; an elastic pad (14) is paved inside the shell (13), the elastic pad (14) is made of rubber, and a knocking piece (15) is movably inserted in the elastic pad (14);

the knocking piece (15) consists of a bottom plate (151) and a plurality of knocking heads (152) fixed on the bottom plate (151), wherein the knocking heads (152) are movably inserted on the elastic pad (14).

10. The civil engineering material processing stirring device of claim 9, wherein,

the knocking head (152) comprises a telescopic rod (1523), and a spring (1522) is sleeved outside the telescopic rod (1523);

one end of the telescopic rod (1523) is fixed with a hinging ball (1524), and the telescopic rod is hinged on the bottom plate (151) by the hinging ball (1524);

the other end of the telescopic rod (1523) is fixed with a striking ball (1521);

one end of the spring (1522) is connected to the bottom plate (151), and the other end is connected to the knocking ball (1521).