CN112723224A - Intelligent building material lifting equipment for high-rise building construction and lifting method - Google Patents

Abstract

The invention discloses intelligent building material lifting equipment for high-rise building construction, which comprises a base, wherein the bottom of the base is connected with a plurality of cushion blocks, two sides of the surface of the base are connected with stand columns, the upper sides of the stand columns are connected with mounting blocks, the lower sides of the stand columns are connected with fixed blocks, a driving shaft is connected between the mounting blocks at two sides, one side of the driving shaft is connected with a first bearing, the other side of the driving shaft is connected with a servo motor, two sides of the driving shaft are connected with first driving wheels, the first driving wheels at two sides are connected with a driving belt, the driving belt is connected with a second driving wheel, the second driving wheel is connected with a driven shaft, two sides of the driving belt are connected with buckling blocks, the buckling blocks are in buckling connection with a clamping seat, the clamping seat is connected, the bottom of the buffer telescopic column is connected with a sliding plate, the bottom of the sliding plate is connected with universal wheels, and a storage battery is installed in the base.

Description

Intelligent building material lifting equipment for high-rise building construction and lifting method

Technical Field

The invention belongs to the technical field of building construction, and particularly relates to intelligent building material lifting equipment and a lifting method for high-rise building construction.

Background

The building construction refers to production activities in the engineering construction implementation stage, is the construction process of various buildings, and also can be a process of changing various lines on a design drawing into a real object at a specified place. The method comprises foundation engineering construction, main structure construction, roofing engineering construction, decoration engineering construction and the like. The place of construction operation is called "construction site" or "job site", also called building site, in high-rise building construction, the long lifting device that needs to be used, but current lifting device when carrying out the transportation material, efficiency is low excessively, reduces the speed of construction to traditional lifting device is inconvenient before the use or is removed after using, need dismantle, is removing, has increased intensity of labour.

Disclosure of Invention

In view of the problems raised by the above background art, the present invention is directed to: aims to provide intelligent building material lifting equipment and a lifting method for high-rise building construction. In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows:

an intelligent building material lifting device for high-rise building construction comprises a base, wherein a plurality of cushion blocks are connected to the bottom of the base, stand columns are connected to two sides of the surface of the base, installation blocks are connected to the upper sides of the stand columns, fixing blocks are connected to the lower sides of the stand columns, a driving shaft is connected between the installation blocks on two sides, a first bearing is connected to one side of the driving shaft and installed in the installation blocks, a servo motor is connected to the other side of the driving shaft, a first driving wheel is connected to two sides of the driving shaft, a driving belt is connected to the first driving wheel on two sides, a second driving wheel is connected to the driving belt, a driven shaft is connected to the second driving wheel, second bearings are connected to two sides of the driven shaft and installed in the fixing blocks, buckling blocks are connected to two sides, the utility model discloses a safe and convenient electric power tool, including stand, cassette, apron, anticollision response piece, servo motor, base bottom, electric putter, the power take off end of electric putter is connected with the push pedal, the cassette is connected with the lifter plate, both sides the lifter plate is crisscross setting from top to bottom, the stand top is connected with the apron, the both sides of apron are connected with anticollision response piece, anticollision response piece and servo motor signal connection, base bottom both sides are equipped with the installation cavity, install electric putter in the installation cavity, electric putter's power take off end is connected with the push pedal, the push pedal bottom is connected with the flexible post of buffering, the flexible bottom of buffering is connected with the slide, the.

Further inject, the both sides of installation cavity are equipped with the guide way, the guide way is connected with the guide post, guide post sliding connection has the guide block, guide block fixed mounting is on the push pedal. The structural design increases the guiding effect.

Further limit, four corners of the bottom of the push plate are connected with buffer springs, and the free ends of the buffer springs are installed on the sliding plate. Such a structural design increases the cushioning effect.

Further inject, lifter plate surface fixedly connected with frame, lifter plate and frame are the integrated into one piece structural design. The building materials are convenient to place due to the structural design.

Further limit, the both sides of lifter plate are through laser welding fixedly connected with rail. Such a structural design increases the leakage-proof effect.

Further inject, detain the position piece and be equipped with the slot, the location inserted block is connected to the slot in, location inserted block top and cassette fixed connection, the cassette is the setting of shape of falling L, the cassette closely laminates with the one side of detaining the position piece. The clamping is more convenient and more fixed due to the structural design.

Further, the first driving wheel and the second driving wheel are provided with grooves, and the driving belts are arranged in the grooves. Such structural design makes the transmission effect better, and is more stable.

Further inject, the stand sets up as integrated into one piece structure with installation piece and fixed block. Such a design makes the connection more stable.

Further limiting, the bottoms of the cushion blocks are connected with rubber anti-skid pads. Such structural design increases anti-skidding effect.

A lifting method of intelligent building material lifting equipment for high-rise building construction is characterized by comprising the following steps:

s1: the electric push rod is controlled to push the push plate, the push plate pushes the buffering telescopic column, the buffering telescopic column pushes the sliding plate, the sliding plate pushes the universal wheels to be in contact with the bottom surface, the universal wheels support the base, and then the universal wheels slide by pushing the base and move positions;

s2: after the electric push rod is moved to the designated position, the electric push rod is controlled again, so that the electric push rod drives the push plate, the push plate drives the buffer telescopic column, the buffer telescopic column drives the sliding plate, the sliding plate drives the universal wheels to be recovered, the universal wheels are separated from the bottom surface, and the cushion blocks are contacted with the ground to carry out stable support;

s3: then, placing the construction building material to be lifted to the previous layer for use on a lifting plate, controlling a servo motor to enable the servo motor to drive a driving shaft to rotate, driving a first driving wheel while the driving shaft rotates, driving a driving belt by the first driving wheel, driving a second driving wheel by the driving belt, driving a second bearing to rotate by the second driving wheel, enabling one side of the driving belt to drive a buckling block, driving a clamping seat by the buckling block, driving the lifting plate filled with the construction building material to move upwards by the clamping seat, and driving an empty lifting plate to move downwards by the other side of the driving belt to load the construction building material;

s4: when the lifting plate with the construction building materials moves upwards, the servo motor stops when the clamping seat touches the anti-collision induction block, so that the lifting plate on one side stops on the upper layer to unload materials, and the lifting plate on the other side stops at the bottom to load materials.

The invention has the following advantages:

1. according to the invention, by arranging the two lifting plates, the lifting plates on one side are arranged in a structure of one lifting plate at the left side, one lifting plate at the right side and one lifting plate at the upper side and one lifting plate at the lower side, so that when the lifting plate on one side lifts the construction building materials to discharge upwards, the lifting plate on the other side descends and loads the construction building materials, and through bidirectional movement work, the efficiency of material transportation is improved, and the construction speed is accelerated;

2. according to the invention, the universal wheels are arranged, the electric push rod is controlled to push the push plate, the push plate pushes the buffer telescopic column, the buffer telescopic column pushes the sliding plate, the sliding plate pushes the universal wheels to be in contact with the bottom surface, the universal wheels support the base, then the universal wheels slide by pushing the base, and the position of the universal wheels is moved, so that the universal wheels can be conveniently moved before or after use, and the labor intensity of workers is reduced.

Drawings

The invention is further illustrated by the non-limiting examples given in the accompanying drawings;

fig. 1 is a schematic structural view of an intelligent building material lifting device for high-rise building construction according to an embodiment of the invention;

FIG. 2 is a schematic sectional view of an intelligent building material lifting device for high-rise building construction according to an embodiment of the present invention;

FIG. 3 is a schematic sectional view of a lifter plate of an intelligent building material lifting device for high-rise building construction according to an embodiment of the present invention;

fig. 4 is an enlarged schematic structural view of a part a of an intelligent building material lifting device for high-rise building construction according to an embodiment of the invention;

the main element symbols are as follows:

the device comprises a base 1, a cushion block 2, an upright post 3, a mounting block 4, a fixing block 5, a driving shaft 6, a first bearing 7, a servo motor 8, a first driving wheel 9, a driving belt 10, a second driving wheel 11, a driven shaft 12, a second bearing 13, a buckling block 14, a clamping seat 15, a lifting plate 16, a cover plate 17, an anti-collision sensing block 18, a mounting cavity 19, an electric push rod 20, a push plate 21, a buffer telescopic column 22, a sliding plate 24, a universal wheel 25, a storage battery 26, a guide groove 27, a guide column 28, a guide block 29, a buffer spring 30, a frame 31, a fence 32, a positioning insertion block 33 and a groove 34.

Detailed Description

In order that those skilled in the art can better understand the present invention, the following technical solutions are further described with reference to the accompanying drawings and examples.

As shown in fig. 1-4, the intelligent building material lifting device for high-rise building construction of the invention comprises a base 1, a plurality of cushion blocks 2 connected to the bottom of the base 1, upright posts 3 connected to both sides of the surface of the base 1, mounting blocks 4 connected to the upper sides of the upright posts 3, a fixing block 5 connected to the lower sides of the upright posts 3, a driving shaft 6 connected between the mounting blocks 4, a first bearing 7 connected to one side of the driving shaft 6, the first bearing 7 installed in the mounting blocks 4, a servo motor 8 connected to the other side of the driving shaft 6, first transmission wheels 9 connected to both sides of the driving shaft 6, a transmission belt 10 connected to the first transmission wheels 9, a second transmission wheel 11 connected to the second transmission wheel 11, a driven shaft 12 connected to both sides of the driven shaft 12, second bearings 13 installed in the fixing blocks 5, and catch blocks, detain 14 buckles of position piece and be connected with cassette 15, cassette 15 is connected with lifter plate 16, both sides lifter plate 16 is crisscross setting from top to bottom, 3 tops of stand are connected with apron 17, the both sides of apron 17 are connected with anticollision response piece 18, anticollision response piece 18 and servo motor 8 signal connection, 1 bottom both sides of base are equipped with installation cavity 19, install electric putter 20 in the installation cavity 19, electric putter 20's power take off end is connected with push pedal 21, push pedal 21 bottom is connected with the flexible post 22 of buffering, the flexible post 22 bottom of buffering is connected with slide 24, slide 24 bottom is connected with universal wheel 25, install battery 26 in the base 1, battery 26's output is connected with servo motor 8 and electric putter 20 electricity, battery 26 is equipped with charging socket.

Preferably, guide grooves 27 are formed in two sides of the mounting cavity 19, guide posts 28 are connected to the guide grooves 27, guide blocks 29 are slidably connected to the guide posts 28, and the guide blocks 29 are fixedly mounted on the push plate 21. The structural design increases the guiding effect. In fact, other guide configurations for mounting cavity 19 are contemplated as appropriate.

Preferably, the four corners of the bottom of the push plate 21 are connected with buffer springs 30, and the free ends of the buffer springs 30 are mounted on the slide plate 24. Such a structural design increases the cushioning effect. In fact, other configurations of the pusher plate 21 are contemplated as appropriate.

Preferably, the surface of the lifting plate 16 is fixedly connected with a frame 31, and the lifting plate 16 and the frame 31 are designed as an integrally formed structure. The building materials are convenient to place due to the structural design. In fact, other configurations of the lifter plate 16 are contemplated as appropriate.

Preferably, rails 32 are fixedly attached to both sides of the lifting plate 16 by laser welding. Such a structural design increases the leakage-proof effect. In fact, other configurations of the lifter plate 16 are contemplated as appropriate.

Preferably, the fastening block 14 is provided with a slot, a positioning insert 33 is connected in the slot, the top of the positioning insert 33 is fixedly connected with the clamping seat 15, the clamping seat 15 is in an inverted L-shaped structure, and the clamping seat 15 is tightly attached to one side of the fastening block 14. The clamping is more convenient and more fixed due to the structural design. In fact, other structural shapes of the retaining block 14 and the retaining base 15 can be considered according to specific situations.

Preferably, the first drive wheel 9 and the second drive wheel 11 are provided with a recess 34, and the drive belt 10 is mounted in the recess 34. Such structural design makes the transmission effect better, and is more stable. In fact, other transmission configurations are contemplated as the case may be.

Preferably, the upright post 3, the mounting block 4 and the fixing block 5 are integrally formed. Such a design makes the connection more stable. In fact, other structural shapes of the upright post 3, the mounting block 4 and the fixing block 5 can be considered according to specific situations.

Preferably, the bottoms of the cushion blocks 2 are connected with rubber non-slip mats. Such structural design increases anti-skidding effect. In fact, other configurations of the spacer 2 may be used, as the case may be.

When the device is used, the electric push rod 20 is controlled to push the push plate 21, the push plate 21 pushes the buffer telescopic column 22, the buffer telescopic column 22 pushes the sliding plate 24, the sliding plate 24 pushes the universal wheel 25 to contact with the bottom surface, the universal wheel 25 supports the base 1, then the universal wheel 25 slides by pushing the base 1, the position is convenient to move, after the device is moved to a specified position, the electric push rod 20 is controlled again, the electric push rod 20 drives the push plate 21, the push plate 21 drives the buffer telescopic column 22, the buffer telescopic column 22 drives the sliding plate 24, the sliding plate 24 drives the universal wheel 25 to recover, the universal wheel 25 leaves the bottom surface, the cushion block 2 is contacted with the ground to stably support, the smoothness during supporting is improved through the cushion block 2, then construction needing to be lifted to a previous layer for use is placed on the lifting plate 16, the servo motor 8 is controlled, the servo motor 8 drives the driving shaft 6 to rotate, the driving shaft 6 drives the first driving wheel 9 when rotating, the first driving wheel 9 drives the driving belt 10, the driving belt 10 drives the second driving wheel 11, the second driving wheel 11 drives the second bearing 13 to rotate, one side of the driving belt 10 drives the buckling block 14, the buckling block 14 drives the clamping seat 15, the clamping seat 15 drives the lifting plate 16 filled with construction building materials to move upwards, the other side of the driving belt 10 drives the empty lifting plate 16 to move downwards, the construction building materials are loaded, when the lifting plate 16 filled with the construction building materials moves upwards, when the clamping seat 15 touches the anti-collision induction block 18, the servo motor 8 stops, the lifting plate 16 on one side stops on the upper layer to unload, the lifting plate 16 on the other side stops at the bottom to load materials, and the working efficiency is improved.

An intelligent building material lifting method for high-rise building construction is characterized by comprising the following steps:

s1: by controlling the electric push rod 20, the electric push rod 20 pushes the push plate 21, the push plate 21 pushes the buffer telescopic column 22, the buffer telescopic column 22 pushes the sliding plate 24, the sliding plate 24 pushes the universal wheel 25 to be in contact with the bottom surface, the universal wheel 25 supports the base 1, and then the universal wheel 25 slides by pushing the base 1 to move the position;

s2: after the electric push rod 20 is moved to the designated position, the electric push rod 20 is controlled again, so that the electric push rod 20 drives the push plate 21, the push plate 21 drives the buffer telescopic column 22, the buffer telescopic column 22 drives the sliding plate 24, the sliding plate 24 drives the universal wheel 25 to recover, the universal wheel 25 leaves the bottom surface, and the cushion block 2 is in contact with the ground to carry out stable support;

s3: then, placing the construction building material to be lifted to the previous layer for use on a lifting plate 16, controlling a servo motor 8 to enable the servo motor 8 to drive a driving shaft 6 to rotate, driving the driving shaft 6 to rotate and simultaneously driving a first driving wheel 9, driving a driving belt 10 by the first driving wheel 9, driving a second driving wheel 11 by the driving belt 10, driving a second bearing 13 to rotate by the second driving wheel 11, enabling one side of the driving belt 10 to drive a buckling block 14, driving a clamping seat 15 by the buckling block 14, driving the lifting plate 16 filled with the construction building material to move upwards by the clamping seat 15, and driving an empty lifting plate 16 to move downwards by the other side of the driving belt 10 to load the construction building material;

s4: when the lifting plate 16 filled with construction building materials moves upwards and the clamping seat 15 touches the anti-collision induction block 18, the servo motor 8 stops, so that the lifting plate 16 on one side stays at the upper layer for discharging, and the lifting plate 16 on the other side stays at the bottom for loading materials.

The foregoing embodiments are merely illustrative of the principles of the present invention and its efficacy, and are not to be construed as limiting the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (10)

1. The utility model provides a high-rise building construction is with intelligent building materials jacking equipment which characterized in that: comprises a base (1), wherein the bottom of the base (1) is connected with a plurality of cushion blocks (2), two sides of the surface of the base (1) are connected with upright posts (3), the upside of each upright post (3) is connected with an installation block (4), the lower side of each upright post (3) is connected with a fixed block (5), two sides of each installation block (4) are connected with a driving shaft (6), one side of each driving shaft (6) is connected with a first bearing (7), the first bearing (7) is installed in each installation block (4), the other side of each driving shaft (6) is connected with a servo motor (8), two sides of each driving shaft (6) are connected with first driving wheels (9), two sides of each first driving wheel (9) are connected with a driving belt (10), each driving belt (10) is connected with a second driving wheel (11), and each second driving wheel (, the two sides of the driven shaft (12) are connected with second bearings (13), the second bearings (13) are installed in a fixed block (5), the two sides of the driving belt (10) are connected with buckling blocks (14), the buckling blocks (14) are connected with clamping seats (15) in a buckling mode, the clamping seats (15) are connected with lifting plates (16), the lifting plates (16) on the two sides are arranged in a vertically staggered mode, the top of the stand column (3) is connected with a cover plate (17), the two sides of the cover plate (17) are connected with anti-collision induction blocks (18), the anti-collision induction blocks (18) are in signal connection with a servo motor (8), installation cavities (19) are formed in the two sides of the bottom of the base (1), electric push rods (20) are installed in the installation cavities (19), the power output ends of the electric push rods (20) are connected with push plates (21), the bottom of the push, the buffer telescopic column (22) is connected with the slide plate (24) at the bottom, the slide plate (24) is connected with the universal wheel (25) at the bottom, a storage battery (26) is installed in the base (1), the output end of the storage battery (26) is electrically connected with the servo motor (8) and the electric push rod (20), and the storage battery (26) is provided with a charging socket.

2. The intelligent building material lifting equipment for high-rise building construction according to claim 1, wherein: the both sides of installation cavity (19) are equipped with guide way (27), guide way (27) are connected with guide post (28), guide post (28) sliding connection has guide block (29), guide block (29) fixed mounting is on push pedal (21).

3. The intelligent building material lifting equipment for high-rise building construction according to claim 2, wherein: four corners of the bottom of the push plate (21) are connected with buffer springs (30), and the free ends of the buffer springs (30) are installed on the sliding plate (24).

4. The intelligent building material lifting equipment for high-rise building construction according to claim 3, wherein: the lifting plate (16) is fixedly connected with a frame (31), and the lifting plate (16) and the frame (31) are designed into an integrally formed structure.

5. The intelligent building material lifting equipment for high-rise building construction according to claim 4, wherein: the two sides of the lifting plate (16) are fixedly connected with a fence (32) through laser welding.

6. The intelligent building material lifting equipment and the lifting method for high-rise building construction according to claim 5, wherein the lifting equipment comprises: the buckle position block (14) is provided with a slot, a positioning insert block (33) is connected in the slot, the top of the positioning insert block (33) is fixedly connected with the clamp seat (15), the clamp seat (15) is arranged in an inverted L-shaped structure, and the clamp seat (15) is tightly attached to one side of the buckle position block (14).

7. The intelligent building material lifting equipment for high-rise building construction according to claim 6, wherein: the first transmission wheel (9) and the second transmission wheel (11) are both provided with grooves (34), and the transmission belt (10) is arranged in the grooves (34).

8. The intelligent building material lifting equipment for high-rise building construction according to claim 7, wherein: the upright post (3), the mounting block (4) and the fixing block (5) are arranged in an integrated structure.

9. The intelligent building material lifting equipment for high-rise building construction according to claim 8, wherein: the bottoms of the cushion blocks (2) are connected with rubber non-slip mats.

10. A lifting method of a lifting device according to any one of claims 1 to 9, comprising the steps of:

s1: the electric push rod (20) is controlled to push the push plate (21), the push plate (21) pushes the buffering telescopic column (22), the buffering telescopic column (22) pushes the sliding plate (24), the sliding plate (24) pushes the universal wheel (25) to be in contact with the bottom surface, the universal wheel (25) supports the base (1), and then the base (1) is pushed to enable the universal wheel (25) to slide and move;

s2: after the electric push rod (20) is moved to a specified position, the electric push rod (20) is controlled again, the electric push rod (20) drives the push plate (21), the push plate (21) drives the buffering telescopic column (22), the buffering telescopic column (22) drives the sliding plate (24), the sliding plate (24) drives the universal wheel (25) to be recovered, the universal wheel (25) is separated from the bottom surface, and the cushion block (2) is contacted with the ground to be stably supported;

s3: then, a construction building material needing to be lifted to a previous layer for use is placed on a lifting plate (16), a servo motor (8) is controlled, the servo motor (8) drives a driving shaft (6) to rotate, the driving shaft (6) drives a first driving wheel (9) at the same time of rotating, the first driving wheel (9) drives a driving belt (10), the driving belt (10) drives a second driving wheel (11), the second driving wheel (11) drives a second bearing (13) to rotate, one side of the driving belt (10) drives a buckling block (14), the buckling block (14) drives a clamping seat (15), the clamping seat (15) drives the lifting plate (16) filled with the construction building material to move upwards, and the other side of the driving belt (10) drives an empty lifting plate (16) to move downwards to load the construction building material;

s4: when the lifting plate (16) filled with construction building materials moves upwards and the clamping seat (15) touches the anti-collision sensing block (18), the servo motor (8) stops, so that the lifting plate (16) on one side stays on the upper layer for discharging, and the lifting plate (16) on the other side stays on the bottom for loading materials.

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