CN111827289A

CN111827289A - High slope pouring method

Info

Publication number: CN111827289A
Application number: CN202010717548.3A
Authority: CN
Inventors: 张云鹏; 吴照忠
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-23
Filing date: 2020-07-23
Publication date: 2020-10-27

Abstract

The invention relates to the field of pouring, in particular to a high slope pouring method which comprises a bottom plate, a mounting box, an adjusting structure, a sliding hole, a pouring suspension rod, a connecting block, a sliding column, a screw rod, a first sliding groove and a mounting structure. The invention fixes the conveying pipeline for pouring the side slope cement through the pouring suspension rod capable of adjusting the angle, and performs the side slope pouring work, the pouring suspension rod can correspondingly adjust the angle according to the side slope angle to be poured, the connecting block and the pouring suspension rod can rotate through the rotation of the screw rod, so that the change of the angle of the pouring suspension rod is realized, the device can be more conveniently and quickly arranged by corresponding to the side slope pouring work with various angles, the pouring suspension rod is connected with the mounting structure for fixing the cement conveying pipeline, and meanwhile, the height of the cement conveying pipeline positioned on the pouring suspension rod can be freely adjusted, so that the cement pouring can be performed on areas with different heights on the side slope, and the side slope pouring work efficiency is effectively improved.

Description

High slope pouring method

Technical Field

The invention relates to the field of pouring, in particular to a high slope pouring method.

Background

The side slope support refers to a retaining, reinforcing and protecting measure which is taken for the side slope to ensure the safety of the side slope and the environment. The commonly used supporting structure types are: gravity retaining wall, buttress retaining wall, cantilever support, plate rib type or lattice type anchor rod retaining wall support, row pile type anchor rod retaining wall support, anchor spraying support and slope ratio method. Most all need use the cement structure to the mode of strutting on side slope, pour side slope supporting construction through using cement, treat that cement solidifies the back, supporting construction has just had higher intensity, prevents to produce the landslide phenomenon, ensures going on smoothly of building engineering.

However, when cement is poured on a high slope, the angles of the slopes in different areas are different, and for some slope supporting structures with steep angles, the operation is inconvenient when the cement is poured, and pouring equipment on the slope is easy to slip off, so that the potential safety hazard of personnel is formed.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a high slope pouring method.

The technical scheme adopted by the invention for solving the technical problems is as follows: a high slope pouring method comprises the following steps:

s1: according to the gradient of the side slope to be poured marked on the drawing, a mounting box is fixedly connected to one side of the bottom plate, and an adjusting structure arranged inside the mounting box adjusts the angle of the pouring suspension rod, so that the inclination angle of the pouring suspension rod is the same as the gradient of the side slope;

s3: after the angle adjustment of the cast suspension rod in the step S1 is completed, the end part of the conveying pipe for conveying cement mortar is fixed on the fixing ring of the mounting structure, and the driving of the mounting structure enables the sliding block for fixing the fixing ring to slide along the second sliding groove on the side edge of the cast suspension rod, so that the cement conveying pipeline reaches the required height;

s3: after the cement conveying pipe is prepared in the step S2, the end part of the bottom plate is fixedly connected to a driven transport vehicle, and the pulley at the bottom of the bottom plate is vertically arranged with the pouring suspension rod, so that the pouring device can conveniently move and pour along the slope toe of the side slope integrally;

wherein, one side of the bottom plate is fixedly connected with a mounting box, an adjusting structure is arranged in the mounting box, the adjusting structure comprises a sliding hole, a casting suspension rod, a connecting block, a sliding column, a screw rod and a first sliding groove, one end of the casting suspension rod is provided with the sliding hole, the sliding column is in sliding connection with the casting suspension rod through the sliding hole, two ends of the sliding column are respectively and fixedly connected to two opposite side walls of the mounting box, one end of the casting suspension rod, which is provided with the sliding hole, is rotatably connected with one end of the connecting block, the other end of the connecting block is rotatably connected with one end of the screw rod, the first sliding groove is arranged in the mounting box, one end of the screw rod, which is close to the connecting block, is in threaded connection with the mounting box, and the other end of the screw rod, which is far away from the connecting block, is in sliding connection with the mounting box, and the side surface of the casting suspension rod is connected with a mounting structure.

Preferably, the screw is rotated for convenience. Make the screw rod slide in the pivoted simultaneously, adjust the angle of pouring the polished rod, it still includes thread disc and gear to adjust the structure, the screw rod deviates from the one end of connecting block is "one" font structure, the screw rod deviates from the one end of connecting block with gear sliding connection, one side of gear with thread disc meshes mutually.

Preferably, in order to facilitate the adjustment of the angle of the cast suspension rod by workers and facilitate the practical use, the adjusting structure further comprises a rocker, the rocker is rotatably connected with the mounting box, and the rocker is fixedly connected with the threaded disc.

Preferably, in order to reduce friction between the gear and the inner side wall of the mounting box and save labor when a worker adjusts the angle of the cast suspension rod, the adjusting structure further comprises a plurality of balls arranged on two sides of the gear, the balls are in rolling connection with the inner side wall of the mounting box, and two sides of the gear are in sliding connection with the balls.

Preferably, in order to facilitate the movement of the whole device along the slope toe of the side slope in actual use and cement pouring of the side slope, four pulleys are mounted on the bottom plate and are respectively arranged at four corners of the bottom plate, and the four pulleys are perpendicular to the pouring suspension rods.

Preferably, in order to fix a cement conveying pipeline for side slope pouring on the pouring suspension rod, the mounting structure comprises a fixing ring, a sliding block and a second sliding groove, the second sliding groove is formed in the side face of the pouring suspension rod, the sliding block is in sliding connection with the pouring suspension rod through the second sliding groove, and the fixing ring is fixedly connected to one side of the sliding block.

Preferably, in order to conveniently adjust the position of the cement discharge pipeline on the pouring suspension rod so as to realize the cement pouring of different height places on the side slope, the mounting structure further comprises a motor and a screw rod, the motor is mounted on one side of the pouring suspension rod, the screw rod is fixedly connected with the driving end of the motor, the other end of the screw rod is rotatably connected with one end of the pouring suspension rod, and the screw rod is in threaded connection with the sliding block.

The invention has the beneficial effects that:

(1) the invention provides a high slope pouring method, which is characterized in that a conveying pipeline for pouring slope cement is fixed through a pouring suspension rod capable of adjusting the angle, slope pouring work is carried out, the pouring suspension rod can correspondingly adjust the angle according to the slope angle needing to be poured, a connecting block and the pouring suspension rod are rotated through the rotation of a screw rod during adjustment, the change of the angle of the pouring suspension rod is realized, and the slope pouring work with various angles can be dealt with.

(2) The invention provides a high slope pouring method, which is characterized in that the angle adjustment of a pouring suspension rod is stable and accurate, so that the device is more convenient and quicker to set, a mounting structure is connected to the pouring suspension rod and used for fixing a cement conveying pipeline, and the height of the cement conveying pipeline positioned on the pouring suspension rod can be freely adjusted, so that cement pouring can be performed on areas with different heights on a slope, and the slope pouring work efficiency is effectively improved.

Drawings

FIG. 1 is a flow chart of a method of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention;

FIG. 3 is a schematic view of the attachment structure of the mounting box and the adjustment structure shown in FIG. 2;

FIG. 4 is an enlarged view of portion A of FIG. 3;

FIG. 5 is a schematic view of the connection of the adjustment structure and the mounting structure shown in FIG. 2;

fig. 6 is a schematic view of a connection structure of the mounting structure shown in fig. 2.

In the figure: 1. the device comprises a bottom plate, 2, pulleys, 3, a mounting box, 4, an adjusting structure, 41, a rocker, 42, a sliding hole, 43, a pouring suspension rod, 44, a connecting block, 45, a sliding column, 46, a threaded disc, 47, a screw rod, 48, a gear, 49, a first sliding groove, 49a, a ball, 5, a mounting structure, 51, a motor, 52, a fixing ring, 53, a screw rod, 54, a sliding block, 55 and a second sliding groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, a high slope casting method includes the following steps:

s1: according to the gradient of the side slope to be poured marked on the drawing, a mounting box 3 is fixedly connected to one side of a bottom plate 1, and an adjusting structure 4 arranged inside the mounting box 3 adjusts the angle of a pouring suspension rod 43, so that the inclination angle of the pouring suspension rod 43 is the same as the gradient of the side slope;

s2: after the angle adjustment of the casting suspension rod 43 in the step S1 is completed, the end of the conveying pipe for conveying cement mortar is fixed to the fixing ring 52 of the mounting structure 5, and the driving of the mounting structure 5 enables the sliding block 54 for fixing the fixing ring 52 to slide along the second sliding groove 55 on the side of the casting suspension rod 43, so that the cement conveying pipeline reaches the required height;

s3: after the cement conveying pipe is prepared in the step S2, the end part of the bottom plate 1 is fixedly connected to a driven transport vehicle, and the pulley 2 at the bottom of the bottom plate 1 is vertically arranged with the pouring suspension rod 43, so that the pouring device can conveniently move and pour along the slope toe of the side slope integrally;

the mounting box 3 is fixedly connected to one side of the bottom plate 1, the adjusting structure 4 is arranged inside the mounting box 3, the adjusting structure 4 includes a sliding hole 42, a casting suspension rod 43, a connecting block 44, a sliding column 45, a screw 47 and a first sliding groove 49, the sliding hole 42 is formed in one end of the casting suspension rod 43, the sliding column 45 is slidably connected with the casting suspension rod 43 through the sliding hole 42, two ends of the sliding column 45 are fixedly connected to two opposite side walls of the mounting box 3 respectively, one end of the casting suspension rod 43, where the sliding hole 42 is formed, is rotatably connected with one end of the connecting block 44, the other end of the connecting block 44 is rotatably connected with one end of the screw 47, the first sliding groove 49 is formed in the mounting box 3, one end of the screw 47 and the connecting block 44 is in threaded connection with the mounting box 3, and the other end of the screw 47 and the connecting block 44 are slidably connected with the mounting box 3 through the first sliding groove 49 And the side surface of the casting suspension rod 43 is connected with a mounting structure 5.

As a technical optimization scheme of the present invention, the adjusting structure 4 further includes a threaded disc 46 and a gear 48, an end of the screw 47 facing away from the connecting block 44 is in a "one-line" shape, an end of the screw 47 facing away from the connecting block 44 is slidably connected to the gear 48, and one side of the gear 48 is engaged with the threaded disc 46.

As a technical optimization scheme of the present invention, the adjusting structure 4 further includes a rocker 41, the rocker 41 is rotatably connected with the mounting box 3, and the rocker 41 is fixedly connected with the threaded disc 46.

As a technical optimization scheme of the present invention, the adjusting structure 4 further includes a plurality of balls 49a, the plurality of balls 49a are disposed on two sides of the gear 48, the plurality of balls 49a are connected with an inner sidewall of the mounting box 3 in a rolling manner, and two sides of the gear 48 are connected with the plurality of balls 49a in a sliding manner.

As a technical optimization scheme of the invention, four pulleys 2 are mounted on the bottom plate 1, the four pulleys 2 are respectively arranged at four corners of the bottom plate 1, and the four pulleys 2 are perpendicular to the casting suspension rod 43.

As a technical optimization scheme of the present invention, the mounting structure 5 includes a fixing ring 52, a sliding block 54 and a second sliding groove 55, the second sliding groove 55 is opened on a side surface of the casting suspension rod 43, the sliding block 54 is slidably connected with the casting suspension rod 43 through the second sliding groove 55, and one side of the sliding block 54 is fixedly connected with the fixing ring 52.

As a technical optimization scheme of the present invention, the mounting structure 5 further includes a motor 51 and a lead screw 53, the motor 51 is mounted on one side of the casting suspension rod 43, the lead screw 53 is fixedly connected to a driving end of the motor 51, the other end of the lead screw 53 is rotatably connected to one end of the casting suspension rod 43, and the lead screw 53 is in threaded connection with the slider 54.

When the invention is used, firstly, the angle of the casting suspension rod 43 is adjusted according to the slope of the slope to be cast, the rocker 41 positioned at the side edge of the mounting box 34 is rocked, the thread disc 46 connected with the rocker 41 rotates, the side edge of the thread disc 46 is meshed with the gear 48, the gear 48 rotates, the two sides of the gear 48 are provided with a plurality of balls 49a, the friction between the two sides of the gear 48 and the inner side wall of the mounting box 3 is effectively reduced, the labor is saved when a worker rotates the rocker 41, the rotation of the gear 48 drives the screw rod 47 to rotate, the screw rod 47 is vertically arranged with the rocker 41, the transmission direction is convenient to be converted, as the screw rod 47 is in threaded connection with the mounting box 3, the screw rod 47 transversely moves while rotating, the casting suspension rod 43 rotates on the sliding column 45 through the connecting block 44, the angle adjustment of the casting suspension rod 43 is realized, because the one end of screw rod 47 runs through gear 48, make the biggest turned angle who pours polished rod 43 obtain the restriction, hoisting device's security, after the angle modulation is accomplished, the conveyer pipe end fixing that will carry cement mortar is on retainer plate 52, carry out electric connection with motor 51 and external power source, drive lead screw 53 rotates, lead screw 53 rotates and makes the slider 54 of retainer plate 52 slide along the second spout 55 of pouring polished rod 43 side, make cement conveying pipeline reach required height, after the readiness, with bottom plate 1 end fixed connection on driven haulage vehicle, because pulley 2 and the perpendicular setting of pouring polished rod 43 of bottom plate 1 bottom, conveniently pour the whole slope toe of following of device and remove the watering.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A high slope pouring method is characterized in that: the method comprises the following steps:

s1: according to the gradient of a side slope to be poured marked on a drawing, a mounting box (3) is fixedly connected to one side of a bottom plate (1), and an adjusting structure (4) arranged inside the mounting box (3) is used for adjusting the angle of a pouring suspension rod (43), so that the inclination angle of the pouring suspension rod (43) is the same as the gradient of the side slope;

s2: after the angle adjustment of the casting suspension rod (43) in the step S1 is completed, the end part of the conveying pipe for conveying cement mortar is fixed on the fixing ring (52) of the mounting structure (5), and the driving of the mounting structure (5) enables the sliding block (54) for fixing the fixing ring (52) to slide along the second sliding groove (55) on the side edge of the casting suspension rod (43), so that the cement conveying pipeline reaches the required height;

s3: after the cement conveying pipe is prepared in the step S2, the end part of the bottom plate (1) is fixedly connected to a driven transport vehicle, and the pulley (2) at the bottom of the bottom plate (1) is vertically arranged with the pouring suspension rod (43), so that the pouring device can conveniently move and pour along the slope toe of the side slope integrally;

wherein one side of the bottom plate (1) is fixedly connected with a mounting box (3), an adjusting structure (4) is arranged in the mounting box (3), the adjusting structure (4) comprises a sliding hole (42), a pouring suspension rod (43), a connecting block (44), a sliding column (45), a screw rod (47) and a first sliding groove (49), the sliding hole (42) is formed in one end of the pouring suspension rod (43), the sliding column (45) is in sliding connection with the pouring suspension rod (43) through the sliding hole (42), two ends of the sliding column (45) are respectively and fixedly connected to two opposite side walls of the mounting box (3), one end of the pouring suspension rod (43) where the sliding hole (42) is formed is rotatably connected with one end of the connecting block (44), the other end of the connecting block (44) is rotatably connected with one end of the screw rod (47), the first sliding groove (49) is formed in the mounting box (3), one end, close to the connecting block (44), of the screw rod (47) is in threaded connection with the mounting box (3), one end, away from the connecting block (44), of the screw rod (47) is in sliding connection with the mounting box (3) through the first sliding groove (49), and the side face of the pouring suspension rod (43) is connected with the mounting structure (5).

2. The high slope casting method according to claim 1, characterized in that: adjust structure (4) and still include thread disc (46) and gear (48), screw rod (47) deviate from the one end of connecting block (44) is "one" font structure, screw rod (47) deviate from the one end of connecting block (44) with gear (48) sliding connection, one side of gear (48) with thread disc (46) mesh mutually.

3. The high slope casting method according to claim 2, characterized in that: the adjusting structure (4) further comprises a rocker (41), the rocker (41) is rotatably connected with the mounting box (3), and the rocker (41) is fixedly connected with the threaded disc (46).

4. The high slope casting method according to claim 2, characterized in that: the adjusting structure (4) further comprises a plurality of balls (49a), the balls (49a) are arranged on two sides of the gear (48), the balls (49a) are in rolling connection with the inner side wall of the mounting box (3), and two sides of the gear (48) are in sliding connection with the balls (49 a).

5. The high slope casting method according to claim 1, characterized in that: four pulleys (2) are installed on the bottom plate (1), the four pulleys (2) are respectively arranged at four corners of the bottom plate (1), and the four pulleys (2) and the pouring suspension rod (43) are vertically arranged.

6. The high slope casting method according to claim 1, characterized in that: the mounting structure (5) comprises a fixing ring (52), a sliding block (54) and a second sliding groove (55), the second sliding groove (55) is formed in the side face of the pouring suspension rod (43), the sliding block (54) is in sliding connection with the pouring suspension rod (43) through the second sliding groove (55), one side of the sliding block (54) is fixedly connected with the fixing ring (52), the mounting structure (5) further comprises a motor (51) and a lead screw (53), the motor (51) is mounted on one side of the pouring suspension rod (43), the lead screw (53) is fixedly connected with the driving end of the motor (51), the other end of the lead screw (53) is rotatably connected with one end of the pouring suspension rod (43), and the lead screw (53) is in threaded connection with the sliding block (54).