CN115370150A - Concrete pouring system for constructional engineering - Google Patents

Abstract

The invention discloses a concrete pouring system for constructional engineering, which comprises a base, wherein a stirring storage device and a lifting device are arranged at the top of the base; the lifting device comprises a lifting part arranged on the top of the base and a swinging part arranged at the execution end of the lifting part, and a vibrating device is arranged on one side of the lifting part; pour the device including the material part of taking out that is located base top and feed end and storage vat intercommunication, locate the fixed centre gripping part and the vibrations collecting element of swing part bottom according to the preface, one end is connected and is taken out the second conveyer pipe that material part discharge end, other end connection swing part execution end and extend to in the fixed centre gripping part to and locate and take out material part discharge end and cover and locate the outside flexible spacing part of second conveyer pipe. The invention provides a device which is convenient for adjusting concrete pouring at different heights and preventing concrete from overflowing out of a mould during pouring.

Description

Concrete pouring system for constructional engineering

Technical Field

The invention mainly relates to the technical field of constructional engineering concrete pouring, in particular to a concrete pouring system for constructional engineering.

Background

Concrete has a vibration process when watering, vibrates in order to guarantee the concrete compactness, pours too thick and easily produces the hollowing phenomenon and pours in layers, and the layering is pour and can in time dispel the heat and be favorable to reducing the concrete temperature crack.

According to the building engineering construction concrete pouring device provided by the patent document with the application number of CN202122701837.7, the product comprises a first rotating shaft, a helical blade, a discharging pipe, a push rod, a pouring tank body and a stirring mechanism, wherein a second gear is driven to rotate by rotation of a rotating end of a third motor, the first gear is driven by the second gear to rotate a third rotating shaft, the stirring blade is driven to rotate by the third rotating shaft, concrete in the pouring tank body is stirred by the stirring blade, the risk of internal blockage caused by concrete solidification and agglomeration is prevented, a second rotating shaft is driven to rotate by rotation of the rotating end of the first motor, the second rotating shaft drives a circular plate to rotate under the rolling fit of a plurality of balls, the pouring tank body is driven to rotate by rotation of the second rotating shaft, the discharging pipe is driven to rotate by a discharging barrel body, the direction of the discharging pipe is convenient to adjust according to pouring requirements, the use is flexible, and the outflow and the blockage of the concrete in the pouring tank body can be controlled by an L-shaped inserting plate.

The product in the above-mentioned patent is convenient for adjust out the direction of feed cylinder, is convenient for carry out the shutoff to the concrete of pouring jar internal, and the concrete placement of not co-altitude is not convenient for adjust, and the concrete spills over the mould outward when the prevention of not being convenient for is pour.

Disclosure of Invention

The invention mainly provides an auxiliary material grinding machine for producing butyronitrile gloves, which is used for solving the technical problems in the background technology.

The technical scheme adopted by the invention for solving the technical problems is as follows:

a concrete pouring system for construction engineering comprises a base, wherein a stirring storage device and a lifting device are arranged at the top of the base, a pouring device is arranged at an execution end of the lifting device, the pouring device is used for sucking concrete raw materials in the stirring storage device for pouring, and the stirring storage device comprises a storage barrel arranged at the top of the base and a stirring component arranged in the storage barrel;

the lifting device comprises a lifting part arranged at the top of the base and a swinging part arranged at the execution end of the lifting part, and a vibrating device is arranged on one side of the lifting part;

pour the device including being located the material part is taken out in base top and feed end and storage vat intercommunication, locate according to the preface the fixed clamping component and the vibrations collecting element of swing part bottom, one end are connected and are taken out material part discharge end, the other end and connect swing part execution end and extend to second conveyer pipe in the fixed clamping component, and locate it locates to take out material part discharge end and cover the outside flexible spacing block of second conveyer pipe.

Preferably, the stirring component comprises a partition board horizontally arranged on the inner wall of the storage vat, a rotating motor arranged at the bottom of the partition board, a shaft lever arranged at the execution end of the rotating motor and positioned on the upper part of the partition board, and a plurality of stirring rods symmetrically arranged on the outer wall of the shaft lever. In the preferred embodiment, the concrete in the storage bucket is stirred by the stirring component, so that the concrete in the storage bucket is prevented from caking.

Preferably, the lifting component comprises first linear guide rails symmetrically arranged on the top of the base and sliding blocks, and two ends of each sliding block are respectively connected with two execution ends of the first linear guide rails. In the preferred embodiment, the second conveying pipe is lifted and lowered by the lifting component, so that pouring work at different heights can be adapted.

Preferably, the swing component comprises a second linear guide rail embedded at the bottom of the sliding block, and a sliding plate arranged at the execution end of the second linear guide rail. In the preferred embodiment, the sliding plate is convenient to swing through the swinging component so as to drive the second conveying pipe to swing.

Preferably, the material pumping part comprises a positioning frame arranged at the top of the base, a pumping machine arranged at the top of the positioning frame, a first conveying pipe with one end connected with the pumping machine and the other end communicated with the storage vat, and a discharge end of the pumping machine is connected with a second conveying pipe. In the preferred embodiment, the pumping component is used for facilitating the pumping of the concrete in the storage bucket into the second conveying pipe so as to facilitate the pouring operation.

Preferably, the limiting component comprises an extension tube sleeved on the outer wall of the second conveying tube. In the preferred embodiment, the limiting part is used for limiting the lifting of the second conveying pipe, so that the concrete in the second conveying pipe can be conveyed smoothly.

Preferably, the fixed clamping part comprises a limiting frame symmetrically arranged at the bottom of the sliding plate, fixed blocks symmetrically arranged at the bottom of the inner wall of the limiting frame, a rotating shaft with two ends respectively rotatably connected with the fixed blocks, and a U-shaped clamping ring sleeved on the outer wall of the rotating shaft. In the preferred embodiment, the fixed clamping component is used for conveniently and fixedly clamping the discharge pipe opening of the second conveying pipe, so that the discharge pipe opening is prevented from swinging randomly due to the impact force of concrete.

Preferably, the vibration collecting part comprises a third linear guide rail, a limiting plate, a fixed bolt, a bearing box, a vibration motor and a spring, wherein the third linear guide rail is symmetrically arranged at the bottom of the sliding plate, the limiting plate is arranged at an execution end of the third linear guide rail, the fixed bolt is arranged on one side of the limiting plate, the bearing box is sleeved on the outer wall of the fixed bolt, the vibration motor is arranged on one side of the limiting plate, and the spring is arranged at the execution end of the vibration motor. In the preferred embodiment, the vibration collecting component is used for collecting the excess materials at the discharge pipe opening of the second conveying pipe in a vibration mode when the pouring operation is stopped, so that the excess materials at the discharge pipe opening of the second conveying pipe can be prevented from dripping everywhere.

Preferably, the vibrating device is including locating the vibrating part of sliding block lateral wall, the vibrating part is including locating the fixed plate of sliding block lateral wall locates the first telescoping cylinder of fixed plate bottom locates the driving motor of first telescoping cylinder execution end, and locate the vibrating rod of driving motor execution end. In the preferred embodiment, the vibrating of the poured concrete is facilitated by vibrating elements.

Preferably, the base lateral wall is equipped with supplementary translation part, supplementary translation part is including locating the radar range finding sensor of base lateral wall. In the preferred embodiment, the auxiliary device can perform horizontal movement casting through the auxiliary translation component, so as to ensure the accurate casting position.

Compared with the prior art, the invention has the beneficial effects that:

the device is convenient for adjusting concrete pouring at different heights and preventing concrete from overflowing out of the mould during pouring.

According to the invention, the concrete in the storage barrel is stirred through the stirring storage device, and the stirring component in the stirring storage device is convenient for stirring the concrete in the storage barrel, so that the concrete in the storage barrel is prevented from caking.

Realize going up and down to pouring the device through elevating gear, be convenient for go up and down to the second conveyer pipe through the lifting unit among the elevating gear to in the operation of pouring of adaptation co-altitude, be convenient for swing the sliding plate through the swing part, so that drive the second conveyer pipe and swing.

Realize pouring of concrete through pouring device, be convenient for with the concrete suction second conveyer pipe in the storage vat through taking out the material part among the pouring device, so as to pour the operation, it is spacing when going up and down to the second conveyer pipe to be convenient for carry the concrete in the second conveyer pipe unobstructed through spacing part, be convenient for carry out fixed centre gripping to second conveyer pipe discharge pipe mouth through fixed clamping part, so as to prevent that discharge pipe mouth from swinging in disorder because of the impact force that receives the concrete, be convenient for pour the operation through vibrations collecting part and shake the collection to the clout of second conveyer pipe discharge pipe mouth when stopping, so as to prevent that the clout of second conveyer pipe discharge pipe mouth from dripping everywhere, be convenient for vibrate the concrete of pouring through vibrating part, be convenient for auxiliary device through supplementary translation part and carry out the horizontal migration and pour, so as to ensure that the position of pouring is accurate.

The present invention will be explained in detail below with reference to the drawings and specific embodiments.

Drawings

FIG. 1 is an isometric view of the overall construction of the present invention;

FIG. 2 is an exploded view of the stirring storage device according to the present invention;

FIG. 3 is an exploded view of the lifting device, the pouring device and the vibrating device of the present invention;

FIG. 4 is a top view of the overall structure of the present invention;

FIG. 5 is a front elevational view of the overall construction of the present invention;

FIG. 6 is a side view of the overall structure of the present invention;

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

FIG. 8 is an enlarged view of the structure at A of the present invention.

Description of the drawings: 10. a base; 20. a stirring storage device; 21. a material storage barrel; 22. a stirring member; 221. a partition plate; 222. rotating the motor; 223. a shaft lever; 224. a stirring rod; 30. a lifting device; 31. a lifting member; 311. a first linear guide rail; 312. a slider; 32. a swing member; 321. a second linear guide; 322. a sliding plate; 40. pouring a device; 41. a material pumping part; 411. a positioning frame; 412. a pumping machine; 413. a first delivery pipe; 42. a limiting component; 421. a telescopic pipe; 43. a fixed clamping member; 431. a limiting frame; 432. a fixed block; 433. a rotating shaft; 434. a U-shaped snap ring; 44. a shock collection member; 441. a third linear guide rail; 442. a limiting plate; 443. fixing the bolt; 444. a receiving box; 445. vibrating a motor; 446. a spring; 45. a second delivery pipe; 50. a vibrating device; 51. a vibrating member; 511. a fixing plate; 512. a first telescoping cylinder; 513. a drive motor; 514. vibrating a rod; 52. an auxiliary translation member; 521. provided is a radar ranging sensor.

Detailed Description

In order that the invention may be more fully understood, reference will now be made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration, various embodiments of the invention which may be practiced in different forms and not limited to the embodiments described herein, but on the contrary, the embodiments are provided so as to provide a more thorough and complete disclosure of the invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may be present, and when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present, as the terms "vertical", "horizontal", "left", "right" and the like are used herein for descriptive purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the knowledge of the terms used herein in the specification of the present invention is for the purpose of describing particular embodiments and is not intended to limit the present invention, and the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, 2, 4, 5 and 7, in a preferred embodiment of the present invention, a concrete pouring system for construction engineering includes a base 10, a mixing storage device 20 and a lifting device 30 are disposed on the top of the base 10, a pouring device 40 is disposed at an execution end of the lifting device 30, the pouring device 40 is used for pumping concrete raw material in the mixing storage device 20 for pouring, the mixing storage device 20 includes a storage tank 21 disposed on the top of the base 10, and a mixing component 22 disposed in the storage tank 21; the stirring component 22 includes a partition 221 horizontally disposed on the inner wall of the storage bin 21, a rotating motor 222 disposed at the bottom of the partition 221, a shaft 223 disposed at an executing end of the rotating motor 222 and located at the upper portion of the partition 221, and a plurality of stirring rods 224 symmetrically disposed on the outer wall of the shaft 223.

In the embodiment, concrete is filled into the storage vat 21, and the stirring component 22 stirs the concrete in the storage vat 21 to prevent the concrete in the storage vat 21 from caking;

further, when the stirring component 22 is in operation, the actuating end of the rotating motor 222 drives the shaft 223 to rotate, and the shaft 223 drives the stirring rod 224 to rotate, so that the stirring rod 224 stirs the concrete in the storage tank 21.

Referring to fig. 1, 3, 4, 5, 6 and 7, in a preferred embodiment of the present invention, the lifting device 30 includes a lifting member 31 disposed on the top of the base 10, and a swinging member 32 disposed at the executing end of the lifting member 31, and a vibrating device 50 is disposed on one side of the lifting member 31; the lifting component 31 includes first linear guide rails 311 symmetrically disposed on the top of the base 10, and sliding blocks 312 with two ends respectively connected to the executing ends of the first linear guide rails 311, and the swinging component 32 includes second linear guide rails 321 embedded in the bottoms of the sliding blocks 312, and sliding plates 322 disposed at the executing ends of the second linear guide rails 321.

In the present embodiment, the height of the casting device 40 is adjusted by the lifting member 31 according to the height to be cast, so that the height of the casting device 40 corresponds to the height to be cast;

further, when the lifting component 31 works, the execution end of the first linear guide rail 311 drives the sliding block 312 to lift;

further, when the swing component 32 works, the execution end of the second linear guide rail 321 drives the sliding plate 322 to slide;

referring to fig. 1, 3, 5, 6, 7 and 8, in a preferred embodiment of the present invention, the casting device 40 includes a material pumping component 41 located on the top of the base 10 and having a material feeding end communicating with the material storage barrel 21, a fixed clamping component 43 and a vibration collecting component 44 sequentially disposed on the bottom of the swinging component 32, a second conveying pipe 45 having one end connected to a material discharging end of the material pumping component 41 and the other end connected to an execution end of the swinging component 32 and extending into the fixed clamping component 43, and a telescopic limiting component 42 disposed on the material discharging end of the material pumping component 41 and covering the outside of the second conveying pipe 45; the pumping component 41 comprises a positioning frame 411 arranged at the top of the base 10, a pumping machine 412 arranged at the top of the positioning frame 411, a first delivery pipe 413 with one end connected with the pumping machine 412 and the other end connected with the storage vat 21, a discharge end of the pumping machine 412 connected with the second delivery pipe 45, a limiting component 42 comprising a telescopic pipe 421 sleeved on the outer wall of the second delivery pipe 45, a fixing clamping component 43 comprising a limiting frame 431 symmetrically arranged at the bottom of the sliding plate 322, a fixing block 432 symmetrically arranged at the bottom of the inner wall of the limiting frame 431, a rotating shaft 433 rotatably connected with the fixing block 432 at both ends respectively, and a U-shaped snap ring 434 sleeved on the outer wall of the rotating shaft 433, a vibration collecting component 44 comprising a third linear guide rail 441 symmetrically arranged at the bottom of the sliding plate 322, a limiting plate 442 arranged at an execution end of the third linear guide rail 441, a fixing bolt 443 arranged at one side of the limiting plate 442, a receiving box 444 sleeved on the outer wall of the fixing bolt 443, a vibration motor 443 arranged at one side of the limiting plate 442, and a spring 446 arranged at the execution end of the vibration motor 445. The vibrating device 50 is including locating the vibrating part 51 of sliding block 312 lateral wall, vibrating part 51 is including locating the fixed plate 511 of sliding block 312 lateral wall is located the first telescoping cylinder 512 of fixed plate 511 bottom is located the driving motor 513 of first telescoping cylinder 512 execution end, and is located the vibrating rod 514 of driving motor 513 execution end, the base 10 lateral wall is equipped with supplementary translation part 52, supplementary translation part 52 is including locating the radar ranging sensor 521 of base 10 lateral wall.

In the embodiment, the concrete in the storage tank 21 is pumped into the second conveying pipe 45 by the pumping component 41 for pouring, the limiting component 42 limits the lifting of the second conveying pipe 45, the fixed clamping component 43 fixedly clamps the discharge end of the second conveying pipe 45, and the vibration collecting component 44 vibrates and collects the excess material at the discharge end of the second conveying pipe 45;

further, when the limiting component 42 works, the extension tube 421 and the second delivery tube 45 synchronously extend and retract;

further, when the pumping component 41 works, the pumping machine 412 pumps the concrete in the storage vat 21 to the second conveying pipe 45 through the first conveying pipe 413;

further, when the fixed clamping component 43 works, the U-shaped clamping ring 434 is rotated through the rotating shaft 433 to rotate so as to fixedly clamp the discharge end of the second conveying pipe 45;

further, when the vibration collecting component 44 works, the execution end of the third linear guide rail 441 drives the limit plate 442 to slide, the execution end of the vibration motor 445 drives the spring 446 to vibrate, the spring 446 drives the limit frame 431 to vibrate, and the receiving box 444 receives concrete falling from the discharge end of the second conveying pipe 45;

further, when the vibrating component 51 works, the execution end of the first telescopic cylinder 512 drives the driving motor 513 to stretch, and the execution end of the driving motor 513 drives the vibrating rod 514 to vibrate;

further, when the auxiliary translation part 52 works, the controller receives the distance data between the casting mold and the device measured by the radar ranging sensor 521 and stops the casting work when the distance data exceeds the set range value.

The specific process of the invention is as follows:

the radar ranging sensor 521 is of model "LD06 LD19".

Concrete is filled into the storage vat 21, and the stirring component 22 stirs the concrete in the storage vat 21 to prevent the concrete in the storage vat 21 from caking;

when the stirring component 22 works, the actuating end of the rotating motor 222 drives the shaft lever 223 to rotate, and the shaft lever 223 drives the stirring rod 224 to rotate, so that the stirring rod 224 stirs the concrete in the storage bucket 21;

adjusting the height of the pouring device 40 through the lifting component 31 according to the height required to be poured, so that the height of the pouring device 40 corresponds to the height required to be poured;

when the lifting component 31 works, the execution end of the first linear guide rail 311 drives the sliding block 312 to lift;

when the swing component 32 works, the execution end of the second linear guide rail 321 drives the sliding plate 322 to slide;

concrete in the storage barrel 21 is pumped into the second conveying pipe 45 through the material pumping part 41 for pouring, the limiting part 42 limits the lifting of the second conveying pipe 45, the fixed clamping part 43 fixedly clamps the discharge end of the second conveying pipe 45, and the vibration collecting part 44 vibrates and collects excess materials at the discharge end of the second conveying pipe 45;

when the limiting component 42 works, the extension tube 421 and the second delivery tube 45 synchronously extend and retract; when the pumping part 41 works, the pumping machine 412 pumps the concrete in the storage vat 21 to the second conveying pipe 45 through the first conveying pipe 413;

when the fixed clamping component 43 works, the U-shaped clamping ring 434 is rotated through the rotating shaft 433 to fixedly clamp the discharge end of the second conveying pipe 45;

when the vibration collecting component 44 works, the execution end of the third linear guide rail 441 drives the limit plate 442 to slide, the execution end of the vibration motor 445 drives the spring 446 to vibrate, the spring 446 drives the limit frame 431 to vibrate, and the receiving box 444 receives concrete falling from the discharge end of the second conveying pipe 45;

when the vibrating component 51 works, the execution end of the first telescopic cylinder 512 drives the driving motor 513 to stretch, and the execution end of the driving motor 513 drives the vibrating rod 514 to vibrate in a rotating manner;

when the auxiliary translation component 52 works, the controller receives the distance data between the casting mold and the device measured by the radar ranging sensor 521 and stops the casting work when the distance data exceeds a set range value.

The invention is described above with reference to the accompanying drawings, it is obvious that the invention is not limited to the above-described embodiments, and it is within the scope of the invention to adopt such insubstantial modifications of the inventive method concept and solution, or to apply the inventive concept and solution directly to other applications without modification.

Claims (10)

1. A concrete pouring system for construction engineering comprises a base (10), and is characterized in that a stirring storage device (20) and a lifting device (30) are arranged at the top of the base (10), a pouring device (40) is arranged at the execution end of the lifting device (30), the pouring device (40) is used for sucking concrete raw materials in the stirring storage device (20) for pouring, and the stirring storage device (20) comprises a storage barrel (21) arranged at the top of the base (10) and a stirring component (22) arranged in the storage barrel (21);

the lifting device (30) comprises a lifting part (31) arranged at the top of the base (10) and a swinging part (32) arranged at the execution end of the lifting part (31), and a vibrating device (50) is arranged on one side of the lifting part (31);

pour device (40) including being located draw material part (41) of base (10) top and feed end and storage vat (21) intercommunication, locate in proper order fixed clamping component (43) and vibrations collecting element (44) of swing part (32) bottom, one end is connected and is drawn material part (41) discharge end, the other end and is connected swing part (32) execution end and extend to second conveyer pipe (45) in fixed clamping component (43), and locate draw material part (41) discharge end and cover and locate second conveyer pipe (45) outside flexible spacing part (42).

2. The constructional engineering concrete pouring system as recited in claim 1, wherein the stirring member (22) comprises a partition (221) horizontally arranged on the inner wall of the storage barrel (21), a rotating motor (222) arranged at the bottom of the partition (221), a shaft rod (223) arranged at the execution end of the rotating motor (222) and positioned at the upper part of the partition (221), and a plurality of stirring rods (224) symmetrically arranged on the outer wall of the shaft rod (223).

3. A concrete casting system for construction engineering according to claim 1, characterized in that said lifting means (31) comprise first linear guides (311) symmetrically arranged on the top of said base (10) and sliding blocks (312) connected at both ends to the actuating ends of said two first linear guides (311), respectively.

4. A concrete casting system for construction engineering according to claim 3, characterized in that said oscillating element (32) comprises a second linear guide (321) embedded in the bottom of said sliding block (312), sliding plates (322) provided at the execution end of said second linear guide (321).

5. The concrete pouring system for the constructional engineering as recited in claim 1, wherein the pumping component (41) comprises a positioning frame (411) arranged at the top of the base (10), a pumping machine (412) arranged at the top of the positioning frame (411), a first conveying pipe (413) with one end connected with the pumping machine (412) and the other end communicated with the storage barrel (21), and the discharge end of the pumping machine (412) is connected with a second conveying pipe (45).

6. Concrete pouring system for construction work according to claim 5, characterized in that said stop element (42) comprises an extension tube (421) fitted over the outer wall of said second delivery duct (45).

7. The concrete pouring system for the constructional engineering according to claim 4, wherein the fixed clamping components (43) comprise limiting frames (431) symmetrically arranged at the bottoms of the sliding plates (322), fixed blocks (432) symmetrically arranged at the bottoms of the inner walls of the limiting frames (431), rotating shafts (433) with two ends respectively rotatably connected with the fixed blocks (432), and U-shaped clamping rings (434) sleeved on the outer walls of the rotating shafts (433).

8. The concrete pouring system for the constructional engineering as recited in claim 4, wherein the vibration collecting member (44) comprises a third linear guide rail (441) symmetrically arranged at the bottom of the sliding plate (322), a limiting plate (442) arranged at the actuating end of the third linear guide rail (441), a fixing bolt (443) arranged at one side of the limiting plate (442), a receiving box (444) sleeved on the outer wall of the fixing bolt (443), a vibration motor (445) arranged at one side of the limiting plate (442), and a spring (446) arranged at the actuating end of the vibration motor (445).

9. A concrete casting system for construction engineering according to claim 3, characterized in that the vibrating device (50) comprises a vibrating member (51) arranged on the side wall of the sliding block (312), the vibrating member (51) comprises a fixing plate (511) arranged on the side wall of the sliding block (312), a first telescopic cylinder (512) arranged at the bottom of the fixing plate (511), a driving motor (513) arranged at the executing end of the first telescopic cylinder (512), and a vibrating rod (514) arranged at the executing end of the driving motor (513).

10. A concrete pouring system for construction works according to claim 1, characterized in that said lateral walls of said base (10) are provided with auxiliary translation means (52), said auxiliary translation means (52) comprising radar ranging sensors (521) provided on the lateral walls of said base (10).

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