CN219445502U - Cement pouring equipment for producing standing rim stone - Google Patents

Abstract

The application discloses cement pouring equipment for producing standing stones relates to the technical field of standing stone production equipment, and comprises a storage tank, a stirring device and a discharging device, wherein a cavity is formed in the storage tank, and a first discharging port communicated with the cavity is formed in the bottom of the storage tank; the stirring device comprises a stirring assembly and a first driving piece, the stirring assembly is positioned in the cavity, and the first driving piece drives the stirring assembly to work; the discharging device comprises a rotating piece and a second driving piece, the rotating piece is rotationally connected with the storage tank, and the second driving piece drives the rotating piece to rotate; the rotary part is provided with a second discharge hole, and in the process of rotating the rotary part, the second discharge hole is communicated with the first discharge hole and the rotary part closes the first discharge hole. The application can enable cement pouring equipment to pour enough concrete into the mould according to the sizes of different moulds.

Description

Cement pouring equipment for producing standing rim stone

Technical Field

The application relates to the technical field of standing rim stone production equipment, in particular to cement pouring equipment for standing rim stone production.

Background

The standing stone is a boundary stone arranged on a road and used for distinguishing functional areas such as a pavement, a sidewalk, a green belt and the like.

The existing standing stone is generally produced in two modes, one is formed by cutting stone materials, and the other is formed by pouring concrete. The method for producing the standing rim stone by concrete pouring comprises the following steps: injecting the pre-stirred concrete into a standing rim stone mold through cement pouring equipment, and solidifying to obtain the standing rim stone.

However, in the conventional cement pouring equipment, the amount of concrete poured into the mold is controlled by a manual control mode, the amount of concrete poured by the cement pouring equipment under manual control is flexible but difficult to quantify, and the phenomenon that the pouring amount of concrete in the mold is insufficient or superfluous easily occurs, so that the quality of the solidified standing stone can be influenced, and the waste of concrete materials can be caused.

Disclosure of Invention

The utility model provides a cement pouring equipment for standing rim stone production makes cement pouring equipment can pour sufficient concrete in the mould according to the size of different moulds.

The application provides a cement pouring equipment for producing vertical margin stone, adopts following technical scheme:

the cement pouring equipment for producing the standing rim stone comprises a storage tank, a stirring device and a discharging device, wherein a cavity is formed in the storage tank, and a first discharging hole communicated with the cavity is formed in the bottom of the storage tank; the stirring device comprises a stirring assembly and a first driving piece, the stirring assembly is positioned in the cavity, and the first driving piece drives the stirring assembly to work; the discharging device comprises a rotating piece and a second driving piece, the rotating piece is rotationally connected with the storage tank, and the second driving piece drives the rotating piece to rotate; the rotary part is provided with a second discharge hole, and in the process of rotating the rotary part, the second discharge hole is communicated with the first discharge hole and the rotary part closes the first discharge hole.

By adopting the technical scheme, the first driving member controls the stirring assembly to work so that the concrete in the storage tank is uniformly mixed, the second driving member drives the rotating member to rotate, and when the rotating member rotates to the state that the second discharge port is communicated with the first discharge port, the concrete in the storage tank can flow out of the die through the first discharge port and the second discharge port in sequence for pouring; when the rotating piece rotates until the second discharge hole is not communicated with the first discharge hole, the rotating piece covers the first discharge hole to stop the concrete in the storage tank from flowing out; the rotating speed of the rotating piece is controlled through the second driving piece, and the outflow amount of concrete in the storage tank after the rotating piece rotates for a circle can be controlled, so that the cement pouring equipment can pour enough concrete into the mould according to the sizes of different moulds.

Optionally, the discharging device further comprises a movable part for adjusting the size of the second discharging hole, a yielding groove is formed in the rotary part, and one end of the yielding groove is communicated with the second discharging hole; the movable piece is arranged on the rotating piece, and the movable piece can move in and out of the abdication groove.

Through adopting above-mentioned technical scheme, need not through adjusting the rotation rate of second driving piece control rotation piece, the rotation rate of second driving piece control rotation piece is invariable, through the size of control movable part activity regulation second discharge gate to the volume of concrete outflow in the storage tank after the accuse brake piece rotates a week, the messenger is to the process that cement pouring equipment concreting volume was adjusted more convenient and fast.

Optionally, discharging device still includes the regulating part, the regulating part with rotate the piece and rotate and be connected, the one end of regulating part is located rotate the piece and deviate from one side of storage tank, the other end of regulating part is located in the groove of stepping down and with the moving part offsets, the regulating part rotates the promotion the moving part activity.

Through adopting above-mentioned technical scheme, the staff rotates in the below control regulating part of rotating the piece, can control the regulating part and promote the movable part activity to further make the process of adjusting the volume of cement pouring equipment pouring concrete more convenient and fast.

Optionally, the discharging device further comprises a positioning component, the positioning component is arranged on one side, away from the storage tank, of the rotating piece, and the positioning component clamps and positions one end, away from the yielding groove, of the adjusting piece.

Through adopting above-mentioned technical scheme, after locating component presss from both sides tight location with the regulating part, can improve the position stability of moving part, reduce and rotate the in-process because the regulating part still can take place to rotate and make the moving part receive external force to influence the activity, lead to the probability that the size of second discharge gate changed to make the second discharge gate can keep the size.

Optionally, the positioning assembly includes two clamping members and two control members, the clamping members are slidably connected with the storage tank, and the two clamping members are respectively located at two sides of the adjusting member; the control piece is located the clamping piece deviates from the one side of regulating part, the control piece with storage tank screw thread cooperation, just the one end of control piece with the clamping piece offsets.

Through adopting above-mentioned technical scheme, rotate the control and order about the clamping piece and slide towards the direction that is close to the regulating part, can make two clamping pieces press from both sides the clamping position the regulating part in the both sides of regulating part, can make positioning assembly's operation convenient and fast more.

Optionally, the discharging device further includes an elastic member, and the elastic member drives the movable member to keep abutting against the adjusting member.

Through adopting above-mentioned technical scheme, the effort of elastic component will make the movable part keep offseting with the regulating part to improve the control effect of regulating part to movable part position, and then improve the reliability that the regulating part adjusted the second discharge gate size.

Optionally, a guiding surface is provided at one end of the movable member away from the bottom of the yielding groove, and the guiding surface is positioned at one end of the movable member close to the storage tank; the guide surface is an inclined surface, and one end of the guide surface, which is close to the second discharge hole, is an inclined lower end.

Through adopting above-mentioned technical scheme, after the concrete in the storage tank flows out through first discharge gate and second discharge gate in succession, stay in the concrete at the top of the part that the moving part is located the groove of stepping down outward can follow the guide surface and flow down, reduce the probability that the concrete remained on the fly leaf.

Optionally, the stirring assembly includes a shaft body and a plurality of blades, one end of the shaft body is connected with the first driving piece, and the first driving piece drives the shaft body to rotate by taking the axis of the shaft body as a rotation shaft; the blades are arranged on the periphery of the shaft body, and the blades in motion apply acting force to the concrete in the direction close to the first discharge hole.

Through adopting above-mentioned technical scheme, when stirring subassembly work stirs the concrete in the storage tank, a plurality of blades can drive the concrete to remove towards first discharge gate to the concrete can flow from first discharge gate smoothly when guaranteeing to pour the concrete.

In summary, the present application includes at least one of the following beneficial effects:

1. the cement pouring equipment can pour enough concrete into the mould according to the sizes of different moulds;

2. the concrete pouring device has the advantages that the cement pouring device can be conveniently adjusted by workers according to the sizes of different dies, and the operation is simple and convenient.

Drawings

FIG. 1 is a schematic structural view of a cement pouring device for producing a riser stone according to an embodiment of the present application;

FIG. 2 is a cross-sectional view of a cement casting apparatus for use in the production of a riser stone in accordance with an embodiment of the present application;

FIG. 3 is a partial schematic view of the bottom of a cement casting apparatus for producing a riser stone according to an embodiment of the present application;

fig. 4 is a cross-sectional view taken from the perspective A-A of fig. 2.

Reference numerals illustrate: 1. a storage tank; 11. a cavity; 12. a first discharge port; 2. a stirring device; 21. a first driving member; 22. a stirring assembly; 221. a shaft body; 222. a blade; 3. a discharging device; 31. a second driving member; 32. a rotating member; 321. a second discharge port; 322. a relief groove; 33. a movable member; 331. a guide surface; 34. an adjusting member; 341. an operation end; 342. a pushing end; 35. a positioning assembly; 351. a clamping member; 352. a guide member; 353. a control member; 36. an elastic member.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-4.

The embodiment of the application discloses cement pouring equipment for producing standing stones.

Referring to fig. 1 and 2, the cement pouring apparatus includes a storage tank 1, a stirring device 2 and a discharging device 3, wherein concrete is stored in the storage tank 1, the stirring device 2 continuously stirs the concrete in the storage tank 1, and the discharging device 3 is used for controlling the time and the quantity of the concrete in the storage tank 1 flowing out, so that the quantity of the concrete poured into the mold each time in the storage tank 1 can be matched with the size of the mold.

The storage tank 1 uses ground as supporting fixed mounting, and the inside of storage tank 1 has the cavity 11 that is used for storing concrete, and first discharge gate 12 has been seted up to the bottom of storage tank 1, and the concrete in the cavity 11 can follow first discharge gate 12 vertical downwardly flow. In this embodiment, the cross-section of the first outlet 12 is preferably fan-shaped.

The stirring device 2 comprises a first driving member 21 and a stirring assembly 22, wherein the first driving member 21 is fixedly arranged at the top of the storage tank 1, and the stirring assembly 22 is positioned in the cavity 11. The stirring assembly 22 comprises a shaft body 221 and a plurality of blades 222, the axis of the shaft body 221 is vertical and coincides with the axis of the storage tank 1, and one end of the shaft body 221 in the axis direction is fixedly connected with the first driving piece 21; the blades 222 are fixedly mounted on the circumferential side of the shaft body 221, the blades 222 are distributed in layers along the axial direction of the shaft body 221, and the blades 222 on the same layer are distributed in a circumferential array with the axial line of the shaft body 221 as an axis. The first driving piece 21 drives the shaft body 221 to rotate by taking the axis of the first driving piece as a rotation shaft, so that the blades 222 are driven to move, the moving blades 222 not only can play a role in stirring concrete in the cavity 11, but also can push the concrete below the first driving piece to move towards a direction close to the first discharging hole 12. In this embodiment, the first driving member 21 is preferably a stepping motor.

Referring to fig. 2 and 3, the discharging device 3 includes a rotating member 32 and a second driving member 31, the rotating member 32 is mounted at the bottom of the storage tank 1, the rotating member 32 is rotationally connected with the storage tank 1, and the rotation axis of the rotating member 32 coincides with the axis of the storage tank 1; the second driving member 31 is fixedly installed at the bottom of the storage tank 1 and located in the cavity 11, and the rotating member 32 is fixedly connected with the second driving member 31, and the second driving member 31 can drive the rotating member 32 to rotate, and each time drives the rotating member 32 to rotate for one circle. In this embodiment, the second driving member 31 is preferably a servo motor.

Referring to fig. 3 and 4, the discharging device 3 further includes a movable member 33, a second discharging hole 321 is formed in the rotating member 32, and a yielding groove 322 adapted to the movable member 33 is formed in the rotating member 32, and one end of the yielding groove 322 is communicated with the second discharging hole 321. The movable member 33 is movably connected with the rotating member 32, and the movable member 33 rotates along the rotation axis of the rotating member 32 during the moving process of the movable member 32. When the movable piece 33 moves to the limit position towards the bottom of the groove close to the relief groove 322, the movable piece 33 is wholly positioned in the relief groove 322; when the movable member 33 moves to the limit position toward the bottom of the groove away from the relief groove 322, the movable member 33 is still partially located in the relief groove 322. In the process of rotating the rotating member 32, the second discharge port 321 is communicated with the first discharge port 12, and the rotating member 32 covers the first discharge port 12 in two states; during the movement of the movable member 33, the second discharge port 321 changes in size, so that the discharge device 3 changes the amount of concrete discharged from the storage tank 1 each time.

One end of the movable member 33 far away from the bottom of the abdication groove 322 is provided with a guide surface 331 at one side close to the storage tank 1, the guide surface 331 is an inclined surface, and one end of the guide surface 331 close to the second discharge hole 321 is an inclined lower end. When the rotating member 32 rotates and the concrete in the cavity 11 flows out through the first discharge port 12 and the second discharge port 321, a part of the concrete will be left at the bottom of the portion of the movable member 33 penetrating the relief groove 322, and the concrete can continue to flow down along the guiding surface 331, so that the concrete in the cavity 11 can be actually poured in the mold after flowing out from the first discharge port 12.

The discharging device 3 further comprises an adjusting member 34 for controlling the movable member 33 to move, the adjusting member 34 is integrally L-shaped, two ends of the adjusting member 34 are respectively provided with an operating end 341 and a pushing end 342, and the adjusting member 34 is formed by fixedly connecting the operating end 341 and the pushing end 342. The adjusting member 34 is rotatably connected to the rotating member 32, and the rotation axis of the adjusting member 34 coincides with the rotation axis of the rotating member 32 and is parallel to the longitudinal direction of the operation end 341. After the adjusting member 34 is installed, the pushing end 342 is located in the yielding groove 322, and the pushing end 342 is located at one side of the movable member 33 near the bottom of the yielding groove 322. The operator controls the adjusting member 34 to rotate through the operating end 341, so as to drive the pushing end 342 to push the movable member 33 to move.

Referring to fig. 3, the discharging device 3 further includes a positioning assembly 35 for fixing the position of the regulating member 34, the positioning assembly 35 including two clamping members 351, two guide members 352, and two control members 353. The two clamping pieces 351 are respectively positioned at two sides of the radial direction of the operation end 341, the guide piece 352 is positioned at one side of the clamping piece 351 away from the operation end 341 and is fixedly connected with the clamping piece 351, the guide piece 352 is in sliding connection with the rotating piece 32, the clamping piece 351 is in sliding connection with the rotating piece 32 through the guide piece 352, the sliding direction of the clamping piece 351 is horizontal, and the sliding directions of the two clamping pieces 351 are the same; the control member 353 is also located on a side of the clamping member 351 facing away from the operating end 341, the control member 353 is in threaded engagement with the rotating member 32, and one end of the control member 353 abuts against the clamping member 351. The rotation control member 353 drives the clamping member 351 to slide in a direction approaching the operation end 341, so that the operation end 341 is clamped and positioned by the two clamping members 351.

Referring to fig. 2 and 4, the discharging device 3 further includes an elastic member 36, the elastic member 36 is installed in the yielding groove 322, one end of the elastic member 36 is fixedly connected with the movable member 33, the other end of the elastic member 36 is fixedly connected with the bottom of the yielding groove 322, and the elastic member 36 drives the movable member 33 to move in a direction close to the bottom of the yielding groove 322, so that the movable member 33 is kept against the pushing end 342. In this embodiment, the elastic member 36 is preferably a tension spring having an arcuate path.

The implementation principle of cement pouring equipment for producing the standing stone is as follows:

before the cement pouring equipment is used, the adjusting piece 34 is controlled to rotate to adjust the size of the second discharging hole 321 according to the size of the die to be poured, so that the amount of concrete flowing out of the cavity 11 after the rotating piece 32 rotates for one circle just meets the pouring requirement of the die to be poured; and then the mould is arranged below the rotating piece 32 and aligned with the first discharge hole 12 along the vertical direction, and then the second driving piece 31 is controlled to drive the rotating piece 32 to rotate for one circle, so that the concrete in the cavity 11 can flow out to the mould through the first discharge hole 12 and the second discharge hole 321 in sequence to finish pouring.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The cement pouring equipment for producing the standing stone is characterized by comprising a storage tank (1), a stirring device (2) and a discharging device (3), wherein a cavity (11) is formed in the storage tank (1), and a first discharging hole (12) communicated with the cavity (11) is formed in the bottom of the storage tank (1); the stirring device (2) comprises a stirring assembly (22) and a first driving piece (21), wherein the stirring assembly (22) is positioned in the cavity (11), and the first driving piece (21) drives the stirring assembly (22) to work; the discharging device (3) comprises a rotating piece (32) and a second driving piece (31), the rotating piece (32) is rotationally connected with the storage tank (1), and the second driving piece (31) drives the rotating piece (32) to rotate; the rotary part (32) is provided with a second discharge hole (321), and in the process of rotating the rotary part (32), the conditions that the second discharge hole (321) is communicated with the first discharge hole (12) and the rotary part (32) covers the first discharge hole (12) exist.

2. The cement pouring device for producing the standing stone according to claim 1, wherein the discharging device (3) further comprises a movable piece (33) for adjusting the size of the second discharging hole (321), a yielding groove (322) is formed in the rotating piece (32), and one end of the yielding groove (322) is communicated with the second discharging hole (321); the movable piece (33) is arranged on the rotating piece (32), and the movable piece (33) can move in and out of the abdication groove (322).

3. Cement pouring equipment for producing standing stones according to claim 2, characterized in that the discharging device (3) further comprises an adjusting piece (34), the adjusting piece (34) is rotationally connected with the rotating piece (32), one end of the adjusting piece (34) is located at one side of the rotating piece (32) deviating from the storage tank (1), the other end of the adjusting piece (34) is located in the yielding groove (322) and is propped against the movable piece (33), and the adjusting piece (34) rotationally pushes the movable piece (33) to move.

4. A cement pouring device for producing a riser stone according to claim 3, wherein the discharging device (3) further comprises a positioning assembly (35), the positioning assembly (35) is arranged on one side of the rotating member (32) away from the storage tank (1), and the positioning assembly (35) clamps and positions one end of the adjusting member (34) away from the yielding groove (322).

5. Cement pouring device for the production of standing stones according to claim 4, characterized in that said positioning assembly (35) comprises two gripping elements (351) and two control elements (353), said gripping elements (351) being slidingly connected to said tank (1), two gripping elements (351) being located on either side of said adjustment element (34); the control piece (353) is located on one side, away from the adjusting piece (34), of the clamping piece (351), the control piece (353) is in threaded fit with the storage tank (1), and one end of the control piece (353) abuts against the clamping piece (351).

6. Cement pouring device for the production of standing stones according to claim 4, characterized in that the discharge device (3) further comprises an elastic element (36), said elastic element (36) forcing the movable element (33) against the regulating element (34).

7. Cement pouring device for producing standing stones according to claim 2, characterised in that the end of the movable part (33) remote from the bottom of the yielding groove (322) is provided with a guiding surface (331), the guiding surface (331) being located at the end of the movable part (33) close to the storage tank (1); the guide surface (331) is an inclined surface, and one end of the guide surface (331) close to the second discharging hole (321) is an inclined lower end.

8. The cement pouring device for producing the standing stone according to claim 1, wherein the stirring assembly (22) comprises a shaft body (221) and a plurality of blades (222), one end of the shaft body (221) is connected with the first driving piece (21), and the first driving piece (21) drives the shaft body (221) to rotate by taking the axis of the shaft body as a rotating shaft; the blades (222) are arranged on the periphery side of the shaft body (221), and the blades (222) in motion apply force to the concrete in the direction approaching the first discharge hole (12).