CN111734143A - Pouring equipment for column - Google Patents

Abstract

The invention relates to the field of building pouring, in particular to pouring equipment for a column, which comprises an engine body and four longitudinal bars which penetrate through the engine body and are arrayed in a circumferential manner, the machine body can be disassembled into an upper part and a lower part along the sealing ring, and the machine body is integrated into a whole during working, a first working cavity is arranged above the inner part of the machine body, a transmission cavity is arranged in the machine body and is positioned below the first working cavity, a motor is arranged in the machine body and is positioned above the first working cavity, the output shaft of the motor penetrates through the first working cavity and the transmission cavity, and the climbing device is arranged in the first working cavity.

Description

Pouring equipment for column

Technical Field

The invention relates to the field of building pouring, in particular to pouring equipment for a column.

Background

In the conventional pouring process of a building column body, the time between every two steps needs to be controlled, every step is performed by separate operation, time and labor are wasted, layered pouring is needed when the column body is too high, the quality of the poured column body is unqualified easily due to improper operation, and therefore a full-automatic pouring device for the column body is needed to be designed, and the existing problems are solved.

Disclosure of Invention

The invention aims to provide a column pouring device which can overcome the defects in the prior art, so that the practicability of the device is improved.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a column pouring device, which comprises a machine body and four longitudinal ribs which penetrate through the machine body and are arrayed circumferentially, wherein the machine body can be disassembled into an upper part and a lower part along a sealing ring, the upper part and the lower part are integrated during working, a first working cavity is arranged above the interior of the machine body, a transmission cavity below the first working cavity is arranged in the machine body, a motor above the first working cavity is arranged in the machine body, an output shaft of the motor penetrates through the first working cavity and the transmission cavity, a climbing device is arranged in the first working cavity, the climbing device provides power through the output shaft and moves upwards along the longitudinal ribs to drive the whole device to climb upwards, a second working cavity which is arranged below the transmission cavity and communicated with the transmission cavity is arranged in the machine body, and a welding device is arranged in the second working cavity and the transmission cavity together, the welding device welds the stirrups stored in the second working cavity on the longitudinal ribs through electric welding to enable the poured cylinder to be firmer, a third working cavity positioned on the inner side of the second working cavity is arranged in the machine body, a pouring device is arranged in the third working cavity and comprises a first rotating shaft which is rotatably arranged on the top wall of the third working cavity and extends downwards to the outside of the machine body, a first connecting groove matched with the output shaft is arranged at the top of the first rotating shaft, the first rotating shaft and the output shaft rotate synchronously during working, a feed inlet connected with and used for conveying concrete is arranged on the rear side end wall of the third working cavity, a discharge outlet is arranged on the bottom wall of the third working cavity, stirring blades positioned in the third working cavity are fixedly arranged on the outer surface of the first rotating shaft, and a scraper positioned at the bottom of the third working cavity is fixedly arranged on the outer surface of the first rotating shaft, the pouring device is characterized in that concrete is introduced into the feeding hole, the concrete is poured downwards through the scraping plate after being stirred by the stirring blades, a vibrating device connected with the machine body through a spring is arranged below the machine body, and the vibrating device removes air bubbles from the poured concrete through vibration and vibrates uniformly.

Further, the climbing device comprises a first bevel gear fixedly arranged on the outer surface of the output shaft and positioned in the first working cavity, the side wall of the first working cavity is symmetrically and rotatably provided with a second rotating shaft, the end surface of the second rotating shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the side wall of the first working cavity is symmetrically provided with a first supporting arm taking the second rotating shaft as a symmetric shaft, the first supporting arm is elastically connected with the first working cavity, the end surface of the first supporting arm is fixedly provided with a first sleeve, a roller shaft is rotatably arranged in the first sleeve, two ends of the roller shaft are fixedly provided with rollers jointed with the longitudinal ribs, the outer surface of the roller shaft is fixedly provided with a first belt pulley, the outer surface of the second rotating shaft is fixedly provided with a second belt pulley connected with the first belt pulley in a matching way through a first belt, the climbing device provides the power of the output shaft for the second rotating shaft through the first bevel gear, meanwhile, the roller is always attached to the longitudinal rib through the first supporting arm under the action of the spring, and the second rotating shaft drives the roller to rotate through the first belt, so that the whole device moves upwards along the longitudinal rib under the action of the climbing device.

Further, the welding device comprises a third bevel gear fixedly arranged on the outer surface of the output shaft and positioned in the transmission cavity, the bottom wall of the transmission cavity is symmetrically and fixedly provided with a second supporting arm, the upper end of the second supporting arm is fixedly provided with a second sleeve, a third rotating shaft is rotatably arranged in the second sleeve, a fourth bevel gear meshed with the third bevel gear is fixedly arranged on the end surface of the third rotating shaft close to the output shaft, a fifth bevel gear is fixedly arranged on the end surface of the third rotating shaft far away from the output shaft, a fourth rotating shaft is rotatably arranged on the rear side end wall of the transmission cavity, a sixth bevel gear meshed with the fifth bevel gear is fixedly arranged on the outer surface of the fourth rotating shaft, a third belt wheel positioned on the rear side of the sixth bevel gear is fixedly arranged on the outer surface of the fourth rotating shaft, and a fifth rotating shaft positioned below the fourth rotating shaft is rotatably arranged on the rear side end wall of the second working cavity, the outer surface of the fifth rotating shaft is fixedly provided with a fourth belt wheel which is connected with the third belt wheel through a second belt in a matching way, the outer surface of the fifth rotating shaft is fixedly provided with a fan-shaped wheel which is positioned at the front side of the fourth belt wheel, the inner part of the second working cavity is provided with the stirrups which are stacked above the fan-shaped wheel, the left side wall and the right side wall of the second working cavity are symmetrically provided with spiral grooves, the inner part of each spiral groove is fixedly provided with a sliding rod, the outer surface of the sliding rod is provided with a sliding block in an up-and-down sliding way, the top of the sliding block is connected with the spiral grooves through springs and is connected with the sliding rod through torsional springs, the sliding block can rotate around the sliding rod along the spiral grooves under the action of the torsional springs when the outer surface of the sliding rod slides downwards, the top wall of the sliding, the fixed extension that is provided with in briquetting chamber bottom outside the slider electric welding, fan-shaped wheel rotates a week and has one the stirrup can fall and push down on the slider the briquetting is started the electric welding will the stirrup with indulge the muscle welding together, at the welded in-process the stirrup is pressed the slider lapse keeps the stirrup with indulge the relative stillness of muscle, after welding a period because the helicla flute with lead to under the effect of torsional spring the slider rotates to both sides, the slider resumes the state originally again under the effect of spring.

Further, the vibration device comprises a vibration block arranged below the machine body, a connecting rod is fixedly arranged at the top of the vibration block and connected in a connecting groove arranged at the bottom wall of the machine body through a spring, four vibration rods are fixedly arranged at the bottom of the vibration block in an array manner, a fourth working chamber is arranged in the vibration block, a sixth rotating shaft which is connected with the first rotating shaft through a spring and rotates synchronously is arranged on the top wall of the fourth working chamber in a rotating manner, a seventh bevel gear positioned in the fourth working chamber is fixedly arranged at the bottom of the sixth rotating shaft, a seventh rotating shaft is rotatably arranged on the side wall of the fourth working chamber, an eighth bevel gear meshed with the seventh bevel gear is fixedly arranged on the outer surface of the seventh rotating shaft, and first eccentric wheels positioned at two sides of the eighth bevel gear are symmetrically arranged on the outer surface of the seventh rotating shaft, fourth working chamber diapire rotates and is provided with the eighth pivot, eighth pivot top fixed be provided with eighth bevel gear meshing's ninth bevel gear, eighth pivot surface fixation has and is located the second eccentric wheel of ninth bevel gear below, thereby vibrator passes through the rotation of sixth pivot drives first eccentric wheel with the rotation of second eccentric wheel drives the vibrations of vibrations piece, thereby drives the vibrations of vibrating arm, the vibrating arm inserts and eliminates the bubble in the concrete and shakes even concrete through vibrations in pouring concrete.

The invention has the beneficial effects that: the column pouring equipment provided by the invention can realize simultaneous column pouring and timely vibration removal of air bubbles in the poured concrete, the whole process is automatically operated under the driving of the motor, and the problem of unqualified pouring quality caused by improper operation in the pouring process is avoided.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall construction of a column casting apparatus of the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic diagram of B-B of FIG. 1;

FIG. 4 is a schematic view of a portion of C-C of FIG. 1;

FIG. 5 is a schematic view of a portion of D-D of FIG. 1;

FIG. 6 is a schematic view of a portion E of FIG. 1;

FIG. 7 is a partial schematic view of F-F of FIG. 6;

fig. 8 is a schematic view of the structure of the stirrup in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-8, wherein for ease of description the orientations described below are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The pouring equipment for a column described in conjunction with fig. 1-8 comprises a machine body 1 and four longitudinal bars 3 which penetrate through the machine body 1 and are circumferentially arrayed, wherein the machine body 1 can be disassembled into an upper part and a lower part along a sealing ring 57, and is integrated into a whole during working, a first working chamber 2 is arranged above the interior of the machine body 1, a transmission chamber 15 which is positioned below the first working chamber 2 is arranged in the machine body 1, a motor 101 which is positioned above the first working chamber 2 is arranged in the machine body 1, an output shaft 4 of the motor 101 penetrates through the first working chamber 2 and the transmission chamber 15, a climbing device 102 is arranged in the interior of the first working chamber 2, the climbing device 102 provides power through the output shaft 4 to move upwards along the longitudinal bars 3 so as to drive the whole device to climb upwards, a second working chamber 29 which is positioned below the transmission chamber 15 and is communicated with the transmission chamber 15 is arranged in the machine body 1, the second working chamber 29 and the transmission chamber 15 are provided with a welding device 103 together, the welding device 103 welds the stirrup 58 stored in the second working chamber 29 on the longitudinal rib 3 through an electric welding 42 to make the poured column more firm, a third working chamber 30 located inside the second working chamber 29 is arranged in the machine body 1, a pouring device 104 is arranged inside the third working chamber 30, the pouring device 104 comprises a first rotating shaft 32 rotatably arranged on the top wall of the third working chamber 30 and extending downwards to the outside of the machine body 1, a first connecting groove 33 matched with the output shaft 4 is arranged at the top of the first rotating shaft 32, the first rotating shaft 32 and the output shaft 4 rotate synchronously during operation, a feed inlet 31 connected with and conveying concrete is arranged on the rear side end wall of the third working chamber 30, and a discharge outlet 36 is arranged on the bottom wall of the third working chamber 30, first pivot 32 external fixed surface is provided with and is located stirring leaf 34 in the third working chamber 30, first pivot 32 external fixed surface is provided with and is located the scraper blade 35 of third working chamber 30 bottom, pour device 104 by feed inlet 31 lets in the concrete, process after stirring leaf 34 stirs, the scraper blade 35 is followed the concrete discharge gate 36 is pour downwards, organism 1 below be provided with organism 1 passes through spring coupling's vibrator 105, vibrator 105 gets rid of the bubble and vibrations are even through the concrete that will pour through vibrations.

Beneficially, the climbing device 102 includes a first bevel gear 5 fixedly disposed on the outer surface of the output shaft 4 and located in the first working chamber 2, a second rotating shaft 6 is symmetrically and rotatably disposed on the side wall of the first working chamber 2, a second bevel gear 7 engaged with the first bevel gear 5 is fixedly disposed on the end surface of the second rotating shaft 6, a first supporting arm 13 taking the second rotating shaft 6 as a symmetric axis is symmetrically disposed on the side wall of the first working chamber 2, the first supporting arm 13 is elastically connected to the first working chamber 2, a first sleeve 12 is fixedly disposed on the end surface of the first supporting arm 13, a roller shaft 11 is rotatably disposed in the first sleeve 12, rollers 14 attached to the longitudinal ribs 3 are fixedly disposed at two ends of the roller shaft 11, a first belt pulley 10 is fixedly disposed on the outer surface of the roller shaft 11, a second belt pulley 8 cooperatively connected with the first belt pulley 10 through a first belt 9 is fixedly disposed on the outer surface of the second rotating shaft 6, the climbing device 102 provides the power of the output shaft 4 to the second rotating shaft 6 through the first bevel gear 5, meanwhile, the first support arm 13 attaches the roller 14 to the longitudinal rib 3 all the time under the action of the spring, and the second rotating shaft 6 drives the roller 14 to rotate through the first belt 9, so that the whole device moves upwards along the longitudinal rib 3 under the action of the climbing device 102.

Beneficially, the welding device 103 includes a third bevel gear 23 fixedly disposed on the outer surface of the output shaft 4 and located in the transmission cavity 15, the bottom wall of the transmission cavity 15 is symmetrically and fixedly provided with a second supporting arm 21, the upper end of the second supporting arm 21 is fixedly provided with a second sleeve 20, the second sleeve 20 is rotatably provided with a third rotating shaft 19, the end surface of the third rotating shaft 19 close to the output shaft 4 is fixedly provided with a fourth bevel gear 22 engaged with the third bevel gear 23, the end surface of the third rotating shaft 19 far from the output shaft 4 is fixedly provided with a fifth bevel gear 18, the rear end wall of the transmission cavity 15 is rotatably provided with a fourth rotating shaft 17, the outer surface of the fourth rotating shaft 17 is fixedly provided with a sixth bevel gear 16 engaged with the fifth bevel gear 18, the outer surface of the fourth rotating shaft 17 is fixedly provided with a third belt pulley 24 located at the rear side of the sixth bevel gear 16, the rear end wall of the second working chamber 29 is provided with a fifth rotating shaft 27 below the fourth rotating shaft 17 in a rotating manner, the outer surface of the fifth rotating shaft 27 is fixedly provided with a fourth belt wheel 26 connected with the third belt wheel 24 through a second belt 25 in a matching manner, the outer surface of the fifth rotating shaft 27 is fixedly provided with a sector wheel 28 positioned at the front side of the fourth belt wheel 26, the stirrup 58 stacked above the sector wheel 28 is placed inside the second working chamber 29, the left and right side walls of the second working chamber 29 are symmetrically provided with spiral grooves 37, a sliding rod 38 is fixedly arranged inside the spiral groove 37, a sliding block 40 is arranged on the outer surface of the sliding rod 38 in a vertical sliding manner, the top of the sliding block 40 is connected with the spiral groove 37 through a spring and is connected with the sliding rod 38 through a torsion spring 39, and when the outer surface of the sliding rod 38 slides downwards, the sliding block 40 rotates around the sliding rod 38 along the spiral groove 37 under the action of, the top wall of the sliding block 40 is provided with a pressing block cavity 43 with a downward opening and located below the stirrup 58, a pressing block 41 connected through a spring is arranged in the pressing block cavity 43 in a sliding mode, the bottom of the pressing block cavity 43 is fixedly provided with an electric welding 42 extending out of the sliding block 40, one stirrup 58 can fall on the sliding block 40 to press the pressing block 41 and start the electric welding 42 to weld the stirrup 58 and the longitudinal rib 3 together when the sector wheel 28 rotates for one circle, the stirrup 58 presses the sliding block 40 to slide downwards in the welding process, the relative rest of the stirrup 58 and the longitudinal rib 3 is kept, the sliding block 40 rotates towards two sides due to the effect of the spiral groove 37 and the torsion spring 39 after being welded for a period of time, and the sliding block 40 restores to the original state under the effect of the spring.

Beneficially, the vibration device 105 comprises a vibration block 44 disposed below the machine body 1, a connecting rod 53 is fixedly disposed on the top of the vibration block 44, the connecting rod 53 is connected in a connecting groove 56 disposed on the bottom wall of the machine body 1 through a spring, four vibration rods 46 are fixedly disposed on the bottom of the vibration block 44 in an array, a fourth working chamber 45 is disposed inside the vibration block 44, a sixth rotating shaft 52 which is connected with the first rotating shaft 32 through a spring and rotates synchronously is rotatably disposed on the top wall of the fourth working chamber 45, a seventh bevel gear 51 disposed inside the fourth working chamber 45 is fixedly disposed on the bottom of the sixth rotating shaft 52, a seventh rotating shaft 49 is rotatably disposed on the side wall of the fourth working chamber 45, an eighth bevel gear 55 engaged with the seventh bevel gear 51 is fixedly disposed on the outer surface of the seventh rotating shaft 49, first eccentric gears 50 disposed on both sides of the eighth bevel gear 55 are symmetrically disposed on the outer surface of the seventh rotating shaft 49, an eighth rotating shaft 47 is rotatably disposed on the bottom wall of the fourth working chamber 45, a ninth bevel gear 54 engaged with the eighth bevel gear 55 is fixedly disposed at the top end of the eighth rotating shaft 47, a second eccentric wheel 48 located below the ninth bevel gear 54 is fixedly disposed on the outer surface of the eighth rotating shaft 47, the vibration device 105 drives the first eccentric wheel 50 and the second eccentric wheel 48 to rotate to drive the vibration block 44 to vibrate through the rotation of the sixth rotating shaft 52, so as to drive the vibration rod 46 to vibrate, and the vibration rod 46 is inserted into the poured concrete to eliminate air bubbles in the concrete through vibration and uniformly vibrate the concrete.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

Sequence of mechanical actions of the whole device: when the device of the invention works, firstly, a cylinder mold to be poured and four longitudinal bars 3 in the cylinder are fixed, then the hoop 58 is put into the second working cavity 29, the upper part and the lower part of the machine body 1 are combined into a whole, the longitudinal bars 3 are inserted into the mold, then the motor 101 is started, so as to drive the output shaft 4 to rotate, so as to drive the first bevel gear 5 to rotate, so as to drive the second bevel gear 7 to rotate, so as to drive the second rotating shaft 6 to rotate, so as to drive the second belt wheel 8 to rotate, so as to drive the first belt 9 to rotate, so as to drive the roller 14 to be always attached to the longitudinal bars 3 to rotate, so that the whole device moves upwards along the longitudinal bars 3 under the action of the climbing device 102, and simultaneously, the output shaft 4 rotates to drive the third bevel gear 23 to rotate, thereby driving the fourth bevel gear 22 to rotate, thereby driving the third rotating shaft 19 to rotate, thereby driving the sixth bevel gear 16 to rotate, thereby driving the fourth rotating shaft 17 to rotate, thereby driving the sector wheel 28 to rotate through the second belt 25, one stirrup 58 will fall onto the sliding block 40 to press the pressing block 41 and start the electric welding 42 to weld the stirrup 58 and the longitudinal bar 3 together, the stirrup 58 will press the sliding block 40 to slide downwards during the welding process, so as to keep the stirrup 58 and the longitudinal bar 3 relatively stationary, after a period of welding, the sliding block 40 will rotate towards both sides due to the effect of the spiral groove 37 and the torsion spring 39, the sliding block 40 will return to the original state under the effect of the spring to wait for the next stirrup 58 to fall, the output shaft 4 rotates and simultaneously drives the first rotating shaft 32 to rotate, so as to drive the stirring blade 34 and the scraping blade 35 to rotate, so that the concrete enters the third working cavity 30 at the feeding hole 31 to be uniformly stirred and then is poured into a mold from the discharging hole 36, meanwhile, the first rotating shaft 32 rotates and drives the sixth rotating shaft 52 to rotate, so as to drive the first eccentric wheel 50 and the second eccentric wheel 48 to rotate to drive the vibration block 44 to vibrate, so as to drive the vibration rod 46 to vibrate, the vibration rod 46 is inserted into the poured concrete to eliminate air bubbles in the concrete through vibration and uniformly vibrate the concrete, all the steps are simultaneously carried out, the whole device is lifted along with the lifting of the pouring height, and the motor rotation is stopped until the pouring is finished.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (4)

1. The utility model provides a pouring equipment of post, includes the organism and runs through four vertical muscle of organism and circumference array, its characterized in that: the machine body can be disassembled into an upper part and a lower part along a sealing ring, the upper part and the lower part are integrated during working, a first working cavity is arranged above the inner part of the machine body, a transmission cavity is arranged below the first working cavity, a motor is arranged above the first working cavity, an output shaft of the motor penetrates through the first working cavity and the transmission cavity, a climbing device is arranged in the first working cavity, the climbing device provides power through the output shaft to move upwards along the longitudinal rib so as to drive the whole device to climb upwards, a second working cavity is arranged below the transmission cavity and communicated with the transmission cavity, a welding device is arranged in the second working cavity and the transmission cavity together, and the welding device welds the stirrup stored in the second working cavity on the longitudinal rib through electric welding so as to enable a poured cylinder to be firmer, a third working cavity which is positioned at the inner side of the second working cavity is arranged in the machine body, a pouring device is arranged at the inner part of the third working cavity and comprises a first rotating shaft which is rotatably arranged on the top wall of the third working cavity and downwardly extends to the outside of the machine body, a first connecting groove which is matched with the output shaft is arranged at the top part of the first rotating shaft, the first rotating shaft and the output shaft synchronously rotate during working, a feed inlet which is connected with and used for conveying concrete is arranged on the rear side end wall of the third working cavity, a discharge outlet is arranged on the bottom wall of the third working cavity, a stirring blade which is positioned in the third working cavity is fixedly arranged on the outer surface of the first rotating shaft, a scraping plate which is positioned at the bottom of the third working cavity is fixedly arranged on the outer surface of the first rotating shaft, concrete is introduced from the feed inlet, and is poured downwards from the discharge outlet through the scraping plate after being stirred by the stirring blade, the machine body is characterized in that a vibration device connected with the machine body through a spring is arranged below the machine body, and the vibration device can remove air bubbles from poured concrete through vibration and can vibrate uniformly.

2. Pouring equipment for columns according to claim 1, characterized in that: the climbing device comprises a first bevel gear fixedly arranged on the outer surface of the output shaft and positioned in the first working cavity, the side wall of the first working cavity is symmetrically and rotatably provided with a second rotating shaft, the end surface of the second rotating shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the side wall of the first working cavity is symmetrically provided with first supporting arms taking the second rotating shaft as a symmetric shaft, the first supporting arms are elastically connected with the first working cavity, the end surface of the first supporting arm is fixedly provided with a first sleeve, the first sleeve is rotatably provided with a roller shaft, two ends of the roller shaft are fixedly provided with rollers jointed with the longitudinal ribs, the outer surface of the roller shaft is fixedly provided with a first belt pulley, the outer surface of the second rotating shaft is fixedly provided with a second belt pulley matched and connected with the first belt pulley through a first belt, and the climbing device provides the power of the output shaft for the second rotating shaft through the first bevel gear, meanwhile, the roller is always attached to the longitudinal rib by the first supporting arm under the action of the spring, and the second rotating shaft drives the roller to rotate through the first belt, so that the whole device moves upwards along the longitudinal rib under the action of the climbing device.

3. Pouring equipment for columns according to claim 1, characterized in that: the welding device comprises a third bevel gear which is fixedly arranged on the outer surface of the output shaft and is positioned in the transmission cavity, the bottom wall of the transmission cavity is symmetrically and fixedly provided with a second supporting arm, the upper end of the second supporting arm is fixedly provided with a second sleeve, a third rotating shaft is rotatably arranged in the second sleeve, a fourth bevel gear which is meshed with the third bevel gear is fixedly arranged on the end surface of the third rotating shaft close to the output shaft, a fifth bevel gear is fixedly arranged on the end surface of the third rotating shaft far away from the output shaft, a fourth rotating shaft is rotatably arranged on the rear side end wall of the transmission cavity, a sixth bevel gear which is meshed with the fifth bevel gear is fixedly arranged on the outer surface of the fourth rotating shaft, a third belt wheel positioned on the rear side of the sixth bevel gear is fixedly arranged on the outer surface of the fourth rotating shaft, and a fifth rotating shaft positioned below the fourth rotating shaft is rotatably arranged on the, the outer surface of the fifth rotating shaft is fixedly provided with a fourth belt wheel which is connected with the third belt wheel through a second belt in a matching way, the outer surface of the fifth rotating shaft is fixedly provided with a fan-shaped wheel which is positioned at the front side of the fourth belt wheel, the inner part of the second working cavity is provided with the stirrups which are stacked above the fan-shaped wheel, the left side wall and the right side wall of the second working cavity are symmetrically provided with spiral grooves, the inner part of each spiral groove is fixedly provided with a sliding rod, the outer surface of the sliding rod is provided with a sliding block in an up-and-down sliding way, the top of the sliding block is connected with the spiral grooves through springs and is connected with the sliding rod through torsional springs, the sliding block can rotate around the sliding rod along the spiral grooves under the action of the torsional springs when the outer surface of the sliding rod slides downwards, the top wall of the sliding, the fixed extension that is provided with in briquetting chamber bottom outside the slider electric welding, fan-shaped wheel rotates a week and has one the stirrup can fall and push down on the slider the briquetting is started the electric welding will the stirrup with indulge the muscle welding together, at the welded in-process the stirrup is pressed the slider lapse keeps the stirrup with indulge the relative stillness of muscle, after welding a period because the helicla flute with lead to under the effect of torsional spring the slider rotates to both sides, the slider resumes the state originally again under the effect of spring.

4. Pouring equipment for columns according to claim 1, characterized in that: the vibration device comprises a vibration block arranged below the machine body, a connecting rod is fixedly arranged at the top of the vibration block and connected in a connecting groove arranged at the bottom wall of the machine body through a spring, four vibration rods are fixedly arranged at the bottom of the vibration block in an array manner, a fourth working chamber is arranged in the vibration block, a sixth rotating shaft which is connected with the first rotating shaft through a spring and rotates synchronously is arranged on the top wall of the fourth working chamber in a rotating manner, a seventh bevel gear positioned in the fourth working chamber is fixedly arranged at the bottom of the sixth rotating shaft, a seventh rotating shaft is rotatably arranged on the side wall of the fourth working chamber, an eighth bevel gear meshed with the seventh bevel gear is fixedly arranged on the outer surface of the seventh rotating shaft, first eccentric wheels positioned at two sides of the eighth bevel gear are fixedly and symmetrically arranged on the outer surface of the seventh rotating shaft, and an eighth rotating shaft is rotatably arranged at the bottom wall of the fourth working chamber, the top end of the eighth rotating shaft is fixedly provided with a ninth bevel gear meshed with the eighth bevel gear, a second eccentric wheel located below the ninth bevel gear is fixed on the outer surface of the eighth rotating shaft, the vibration device drives the first eccentric wheel and the second eccentric wheel to rotate through rotation of the sixth rotating shaft to drive the vibration block to vibrate, so that the vibration rod is driven to vibrate, and the vibration rod is inserted into poured concrete to eliminate bubbles in the concrete through vibration and uniformly vibrate the concrete.

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