CN112127366B - Automatic ground stake of preparation steel reinforcement cage pours equipment - Google Patents

Abstract

The invention discloses ground pile pouring equipment for automatically manufacturing a reinforcement cage, which comprises a main shell, wherein a working cavity is arranged in the main shell, a reinforcement cage winding mechanism is arranged in the working cavity, the reinforcement cage winding mechanism comprises a driving motor, the driving motor is fixedly connected to the inner wall of the upper side of the working cavity, the right end of the driving motor is fixedly connected with a driving connecting rod, and the right side of the driving connecting rod is fixedly connected to a driving gear. The quality of the ground pile is improved, and a part of capital consumption is saved because additional vibration equipment is not needed for vibration.

Description

Automatic ground stake of preparation steel reinforcement cage pours equipment

Technical Field

The invention relates to the field of building pouring, in particular to ground pile pouring equipment for automatically manufacturing a reinforcement cage.

Background

The ground pile is a building foundation form with high bearing capacity, wide application range and long history. With the improvement of production level and the development of scientific technology, the types, processes, design theories, calculation methods and application ranges of foundation piles are greatly developed, and the foundation piles are widely applied to projects such as high-rise buildings, ports, bridges and the like. The foundation effect of ground foundation pile is that the soil layer that the deeper bearing capacity of underground is good is passed to the load to satisfy bearing capacity and settlement's requirement, and steel reinforcement cage preparation difficulty when current ground pile is pour needs artifical scene to make according to the degree of depth of ground pile, will consume a large amount of time and manpower and just can accomplish, need place its help that needs the hoist in the ground pile after having made, and construction cost is high.

Disclosure of Invention

The invention aims to solve the technical problem of providing ground pile pouring equipment for automatically manufacturing a reinforcement cage, and solving the problem of low efficiency of manually manufacturing the reinforcement cage.

The invention is realized by the following technical scheme.

The invention relates to ground pile pouring equipment for automatically manufacturing a reinforcement cage, which comprises a main shell, wherein a working cavity is arranged in the main shell, a reinforcement cage winding mechanism is arranged in the working cavity, the reinforcement cage winding mechanism comprises a driving motor, the driving motor is fixedly connected to the inner wall of the upper side of the working cavity, the right end of the driving motor is fixedly connected with a driving connecting rod, the right side of the driving connecting rod is fixedly connected to a driving gear, the lower end of the driving gear is meshed with a driving inner gear, the driving inner gear is embedded in a reinforcement rotating wheel disc, thirty-six reinforcement positioning cavities are arranged in the reinforcement rotating wheel disc, the lower end of the reinforcement rotating wheel disc is rotatably connected in a support separating plate, the left end of the reinforcement rotating wheel disc is fixedly connected with three uniformly distributed feeding box bodies, each feeding box body, feed bracing piece right-hand member fixedly connected with feed magnet, every feed magnet right-hand member fixedly connected with feed spring, feed spring fixed connection is on feeding the electro-magnet, every feed electro-magnet fixed connection be in feed the box right-hand member, every feed the bracing piece left end and all connect on the feed wheel, be equipped with in the feed wheel with thirty six feed chambers that reinforcing bar location chamber corresponds, per two it compresses tightly the electro-magnet, every to all be equipped with between the feed chamber compress tightly two of compress tightly electro-magnet fixedly connected with and compress tightly reset spring, every compress tightly reset spring fixed connection on the pressure strip, every pressure strip sliding connection is in the feed wheel, the feed wheel lower extreme rotates to be connected on feeding the slider, feed slider lower extreme sliding connection be in support on the separator.

The right side of the steel bar rotating wheel disc is provided with a steel bar cage placing mechanism, the steel bar cage placing mechanism comprises a rotating plate, the left end of the rotating plate is slidably connected with a splint supporting block, a fixture block electromagnet is embedded in the splint supporting block, the lower end of the fixture block electromagnet is fixedly connected with a fixture block spring, the lower end of the fixture block spring is fixedly connected to the fixture block, the fixture block is embedded in the rotating plate, the splint supporting block is rotatably connected with two clamping rotating shafts which are symmetrical front and back by taking the splint supporting block as a center, each clamping rotating shaft is internally provided with a torsional spring, each clamping rotating shaft is fixedly connected with a splint, the splint is embedded with a clamping electromagnet, each splint is fixedly connected with a vibration block, the right side of the splint supporting block is provided with a splint bottom block, the splint bottom block is slidably connected to the rotating, the upper end of the rack electromagnet is fixedly connected with a rack spring, the upper end of the rack spring is fixedly connected to the rack, the front end and the rear end of the rack are respectively meshed with a connecting gear, each connecting gear is meshed with a rotary half-tooth, each rotary half-tooth is rotatably connected into the clamping plate bottom block, each rotary half-tooth is fixedly connected with a reinforcing cage clamping support plate, a clamping cavity with an opening facing left is arranged in each reinforcing cage clamping support plate, two clamping block telescopic boxes which are vertically symmetrical by taking the reinforcing cage clamping support plates as centers are embedded in each reinforcing cage clamping support plate, each clamping block telescopic box is internally and slidably connected with a clamping block connecting telescopic rod, each clamping block connecting telescopic rod is fixedly connected to a clamping block magnet, each clamping block magnet is fixedly connected with a clamping block spring, and the clamping block springs are fixedly connected to the clamping block electromagnet, the clamp splice electro-magnet fixed connection be in on the flexible box of clamp splice, every the clamp splice is connected the telescopic link and is close to the tight piece of one end fixedly connected with that steel reinforcement cage presss from both sides tight backup pad center, rotor plate right-hand member fixed connection is on rotating the wheel, it is on rotating the motor to rotate wheel fixed connection, it is on the dwang backup pad to rotate motor fixed connection.

Preferably, a wire distributing telescopic rod is fixedly connected to the center of the left end of the steel bar rotating wheel disc, a wire distributing wheel is fixedly connected to the left end of the wire distributing telescopic rod, and six uniformly distributed wire distributing plates are fixedly connected to the wire distributing wheel.

Preferably, the rotor plate lower extreme fixedly connected with supports and rotates the connecting axle, support and rotate the connecting axle and rotate the connection on supporting the telescopic link, support telescopic link left end fixedly connected with and support the axis of rotation, support the axis of rotation and rotate the connection and be in the dwang backup pad, support telescopic link right-hand member fixedly connected with two with support the telescopic link and be the support transmission electro-magnet of central longitudinal symmetry, every support transmission electro-magnet right-hand member fixedly connected with and support reset spring, support reset spring right-hand member fixed connection and support transmission magnet, support transmission magnet fixed connection be in support on the telescopic link extension bar.

Preferably, a winding steel bar supporting block is arranged at the front end of the steel bar rotating wheel disc, the winding steel bar supporting block is slidably connected in a housing on the front side of the main housing, two gear magnets which are vertically symmetrical with the winding steel bar supporting block as a center are slidably connected to the winding steel bar supporting block, a gear spring is fixedly connected to each of the front end and the rear end of each gear magnet, each gear spring is fixedly connected to a gear electromagnet, the front end of each gear electromagnet is fixedly connected to the winding steel bar supporting block, the rear end of each gear electromagnet is fixedly connected to the main housing and is slidably connected with the winding steel bar supporting block, a winding steel bar connecting port is embedded in each winding steel bar supporting block, a welding gun is fixedly connected to the upper end of the rear side of each winding steel bar supporting block, a sensor is embedded in the rear side of, the detection device is characterized in that the detection spring is fixedly connected to the detection transmission rod, the lower end of the detection transmission rod is rotatably connected to the detection transmission shaft, the detection transmission shaft is fixedly connected with the detection rod, the rear end of the winding steel bar supporting block is embedded with a cutting electromagnet, the lower end of the cutting electromagnet is fixedly connected with a cutting reset spring, the lower end of the cutting reset spring is fixedly connected to a cutting connecting block, the cutting connecting block is slidably connected to the inside of the winding steel bar supporting block, the rear end of the cutting connecting block is fixedly connected with a cutter, and the cutter is slidably connected to the.

Preferably, it is equipped with the stirring chamber to support the separator plate lower extreme, including fixed connection in the stirring chamber support agitator motor on the terminal surface under the separator plate, agitator motor lower extreme fixedly connected with stirring rod, stirring rod lower extreme fixed connection is on the stirring wheel, two uses of stirring wheel lower extreme fixedly connected with the stirring rod that the stirring wheel is central bilateral symmetry, stirring chamber right-hand member fixedly connected with cement conveyer pipe, fixedly connected with cement pump on the cement conveyer pipe.

The invention has the beneficial effects that: the invention can automatically complete the ground pile pouring and can manufacture the reinforcing steel bar into the reinforcing steel bar cage by winding the winding reinforcing steel bar on the reinforcing steel bar, compared with the manual work, the efficiency is higher, the manpower resource is saved, meanwhile, the reinforcing steel bar cage can be automatically placed in the ground pile and fixed, the reinforcing steel bar cage is vibrated when the cement is poured, the cement is firmer through the transmission of the reinforcing steel bar, the quality of the ground pile is improved, and a part of the fund consumption is saved without additionally using a vibration device for vibration.

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.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic view of the embodiment of the present invention in the direction of A-A in FIG. 1;

FIG. 3 is a schematic view of the embodiment of the present invention in the direction B-B in FIG. 1;

FIG. 4 is a schematic view of the embodiment of the present invention in the direction of C-C in FIG. 1;

FIG. 5 is a schematic view of the embodiment of the present invention in the direction D-D in FIG. 1;

FIG. 6 is an enlarged schematic view of the embodiment of the present invention at E in FIG. 1;

FIG. 7 is an enlarged schematic view at F in FIG. 1 according to an embodiment of the present invention;

FIG. 8 is an enlarged schematic view of the embodiment of the present invention at G in FIG. 2;

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.

Combine 1-8 the ground stake equipment of pouring of an automatic preparation steel reinforcement cage, including main casing body 10, including working chamber 11 in the main casing body 10, be equipped with steel reinforcement cage winding mechanism 80 in the working chamber 11, steel reinforcement cage winding mechanism 80 includes driving motor 17, driving motor 17 fixed connection is in working chamber 11 upside inner wall, driving motor 17 right-hand member fixedly connected with drive connecting rod 18, drive connecting rod 18 right side fixed connection is on drive gear 20, the meshing of drive gear 20 lower extreme is on drive internal gear 36, drive internal gear 36 inlays in steel reinforcement rotary wheel disc 21, be equipped with thirty six reinforcing bar location chamber 22 in the steel reinforcement rotary wheel disc 21, the rotation of steel reinforcement rotary wheel disc 21 lower extreme is connected in supporting separator 27, steel reinforcement rotary wheel disc 21 left end fixed connection has three evenly distributed's feed box 14, each feeding box body 14 is internally and slidably connected with a feeding supporting rod 13, the right end of each feeding supporting rod 13 is fixedly connected with a feeding magnet 15, the right end of each feeding magnet 15 is fixedly connected with a feeding spring 16, the feeding spring 16 is fixedly connected to a feeding electromagnet 19, each feeding electromagnet 19 is fixedly connected to the right end of the feeding box body 14, the left end of each feeding supporting rod 13 is connected to a feeding wheel 12, thirty-six feeding cavities 79 corresponding to the reinforcing steel bar positioning cavities 22 are arranged in the feeding wheel 12, a pressing electromagnet 77 is arranged between every two feeding cavities 79, each pressing electromagnet 77 is fixedly connected with two pressing return springs 76, each pressing return spring 76 is fixedly connected to a pressing plate 75, each pressing plate 75 is slidably connected in the feeding wheel 12, and the lower end of the feeding wheel 12 is rotatably connected to a feeding slide block 26, the lower end of the feed slide 26 is slidably connected to the support and separation plate 27.

A steel reinforcement cage placing mechanism 90 is arranged on the right side of the steel reinforcement rotating wheel disc 21, the steel reinforcement cage placing mechanism 90 comprises a rotating plate 45, the left end of the rotating plate 45 is slidably connected with a clamping plate supporting block 40, a clamping block electromagnet 60 is embedded in the clamping plate supporting block 40, the lower end of the clamping block electromagnet 60 is fixedly connected with a clamping block spring 61, the lower end of the clamping block spring 61 is fixedly connected to a clamping block 62, the clamping block 62 is embedded in the rotating plate 45, two clamping rotating shafts 39 which are symmetrical front and back by taking the clamping plate supporting block 40 as a center are rotatably connected to the clamping plate supporting block 40, a torsion spring 63 is arranged in each clamping rotating shaft 39, a clamping plate 37 is fixedly connected to each clamping rotating shaft 39, a clamping electromagnet 38 is embedded in each clamping plate 37, a vibration block 59 is fixedly connected to each clamping plate 37, and a bottom, the clamping plate bottom block 44 is connected to the rotating plate 45 in a sliding mode, a rack electromagnet 74 is embedded in the clamping plate bottom block 44, a rack spring 73 is fixedly connected to the upper end of the rack electromagnet 74, the upper end of the rack spring 73 is fixedly connected to a rack 72, two ends of the rack 72 are respectively meshed with a connecting gear 71, each connecting gear 71 is meshed with a rotating half-tooth 70, each rotating half-tooth 70 is rotatably connected to the inside of the clamping plate bottom block 44, a reinforcement cage clamping support plate 32 is fixedly connected to each rotating half-tooth 70, a clamping cavity 35 with a leftward opening is formed in the reinforcement cage clamping support plate 32, two clamping block telescopic box bodies 68 which are vertically symmetrical by taking the reinforcement cage clamping support plate 32 as a center are embedded in each reinforcement cage clamping support plate 32, and a clamping block connecting telescopic rod 67 is slidably connected to the inside each clamping block telescopic box body 68, every telescopic link 67 fixed connection is connected to the clamp splice on clamp splice magnet 66, clamp splice magnet 66 fixedly connected with clamp splice spring 65, clamp splice spring 65 fixed connection is on clamp splice electro-magnet 64, clamp splice electro-magnet 64 fixed connection be in on the flexible box 68 of clamp splice, every clamp splice connection telescopic link 67 is close to the one end fixedly connected with clamp splice 69 at reinforcing cage clamp support plate 32 center, rotor plate 45 right-hand member fixed connection is on rotating wheel 47, rotating wheel 47 fixed connection is on rotating motor 46, rotating motor 46 fixed connection is on dwang backup pad 50.

Beneficially, the wire distributing telescopic rod 25 is fixedly connected to the center of the left end of the steel bar rotating wheel disc 21, the wire distributing wheel 24 is fixedly connected to the left end of the wire distributing telescopic rod 25, and six uniformly distributed wire distributing plates 23 are fixedly connected to the wire distributing wheel 24.

Beneficially, rotating plate 45 lower extreme fixedly connected with supports rotation connecting axle 82, support rotation connecting axle 82 and rotate to be connected on supporting telescopic link 86, support telescopic link 86 left end fixedly connected with and support axis of rotation 81, support axis of rotation 81 and rotate to be connected in on the dwang backup pad 50, support telescopic link 86 right-hand member fixedly connected with two use support telescopic link 86 is the support transmission electro-magnet 83 of central longitudinal symmetry, every support transmission electro-magnet 83 right-hand member fixedly connected with and support reset spring 84, support reset spring 84 right-hand member fixed connection on supporting transmission magnet 85, support transmission magnet 85 fixed connection be in support telescopic link 86 extension bar.

Beneficially, a winding steel bar supporting block 55 is arranged at the front end of the steel bar rotating wheel disc 21, the winding steel bar supporting block 55 is slidably connected in the front housing of the main housing 10, two gear magnets 53 which are vertically symmetrical with the winding steel bar supporting block 55 as the center are slidably connected on the winding steel bar supporting block 55, a gear spring 52 is fixedly connected at each of the front and rear ends of each gear magnet 53, each gear spring 52 is fixedly connected to a gear electromagnet 51, the front gear electromagnet 51 is fixedly connected to the winding steel bar supporting block 55, the rear gear electromagnet 51 is fixedly connected to the main housing 10 and slidably connected with the winding steel bar supporting block 55, a winding steel bar connecting port 56 is embedded in the winding steel bar supporting block 55, and a welding gun 58 is fixedly connected to the rear upper end of the winding steel bar supporting block 55, the sensor 92 is embedded at the rear side of the winding steel bar supporting block 55, the detection spring 91 is fixedly connected to the lower end of the sensor 92, the detection spring 91 is fixedly connected to the detection transmission rod 89, the lower end of the detection transmission rod 89 is rotatably connected to the detection transmission shaft 88, the detection rod 87 is fixedly connected to the rear end of the detection transmission shaft 88, the cutting electromagnet 93 is embedded at the rear end of the winding steel bar supporting block 55, the cutting reset spring 94 is fixedly connected to the lower end of the cutting electromagnet 93, the lower end of the cutting reset spring 94 is fixedly connected to the cutting connecting block 95, the cutting connecting block 95 is slidably connected to the inside of the winding steel bar supporting block 55, the cutter 96 is fixedly connected to the rear end of the cutting connecting block 95.

Beneficially, support the division board 27 lower extreme and be equipped with stirring chamber 31, including fixed connection in the stirring chamber 31 support the agitator motor 29 on the terminal surface under the division board 27, agitator motor 29 lower extreme fixedly connected with stirring connecting rod 28, stirring connecting rod 28 lower extreme fixed connection is on stirring wheel 57, stirring wheel 57 lower extreme fixedly connected with two use stirring wheel 57 is central bilateral symmetry's puddler 30, stirring chamber 31 right-hand member fixedly connected with cement conveyer pipe 49, fixedly connected with cement pump 48 on the cement conveyer pipe 49.

When a reinforcement cage needs to be manufactured, the branching wheel 24 is pulled leftwards, the branching telescopic rod 25 extends out to determine the diameter of the reinforcement cage, then the supporting reinforcement is inserted into the corresponding reinforcement positioning cavity 22 through the feeding cavity 79, the wound reinforcement is inserted into the wound reinforcement connecting port 56, then the driving motor 17 is started to drive the driving connecting rod 18 to rotate, the driving connecting rod 18 drives the driving gear 20 to rotate, the driving gear 20 drives the driving internal gear 36 to rotate, the driving internal gear 36 drives the reinforcement rotating wheel disc 21 to rotate, the reinforcement rotating wheel disc 21 drives the reinforcement positioning cavity 22 to rotate, the reinforcement positioning cavity 22 drives the supporting reinforcement to rotate, the reinforcement rotating wheel disc 21 drives the feeding box body 14 to rotate, the feeding box body 14 drives the feeding wheel 12 and the reinforcement rotating wheel disc 21 to synchronously rotate, the reinforcement rotating wheel disc 21 drives the branching telescopic rod 25 to synchronously rotate, and the branching telescopic rod 25 drives the branching wheel 24, then the feeding electromagnet 19 is started to drive the feeding magnet 15 to move leftwards through repulsion, the feeding spring 16 is stretched, the feeding magnet 15 drives the feeding support rod 13 to move leftwards, the feeding support rod 13 drives the feeding wheel 12 to move leftwards, so that the feeding wheel 12 is far away from the steel bar rotating wheel disc 21, then the pressing electromagnet 77 is started to push the pressing magnet 78 to be far away from the pressing electromagnet 77 through repulsion, the pressing reset spring 76 is stretched, the pressing magnet 78 drives the pressing plate 75 to clamp the supporting steel bar entering the feeding cavity 79, then the feeding electromagnet 19 is powered off, the feeding spring 16 pulls the feeding magnet 15 to be restored to the initial state, the feeding magnet 15 drives the feeding wheel 12 to be restored to the initial state, the feeding wheel 12 drives the supporting steel bar to move rightwards to extend out from the steel bar positioning cavity 22, the gear electromagnet 51 is started to attract the gear magnet 53 to move, the support block 55 of the steel bar winding drives the steel bar winding to move to the position where the steel bar is extended, when the detection rod 87 touches the steel bar, the force applied to the sensor 92 through the detection spring 91 changes, the sensor 92 controls the welding gun 58 to start to weld the steel bar winding on the steel bar, the steel bar rotating wheel disc 21 rotates to drive the steel bar winding to wind the steel bar winding on the steel bar, when the detection rod 87 touches the steel bar for the twelfth time, the cut-off electromagnet 93 is controlled to start, the cut-off electromagnet 93 drives the cut-off connecting block 95 to move upwards, the cut-off connecting block 95 drives the cutter 96 to move upwards to cut off the steel bar winding, then the feeding electromagnet 19 starts to feed the steel bar to the right to start the next winding, the wound steel bar enters the clamping cavity 35 to push the steel bar cage clamping support plate 32 to move to the right, after the steel bar cage is wound, the clamping electromagnet 38 starts to be attracted by the, then the clamping block electromagnet 64 is started to push the clamping block magnet 66 to extend through repulsion, the clamping block magnet 66 drives the clamping block connecting telescopic rod 67 to extend, the clamping block connecting telescopic rod 67 drives the clamping block 69 to clamp the front end of the steel reinforcement cage, then the rotating motor 46 is started to drive the rotating wheel 47 to rotate, the rotating wheel 47 drives the rotating plate 45 to rotate, then the supporting transmission electromagnet 83 is started to push the supporting transmission magnet 85 to move through repulsion, the supporting transmission magnet 85 drives the supporting telescopic rod 86 to extend, the supporting telescopic rod 86 pushes the supporting rotation connecting shaft 82 to extend, the rotating plate 45 is pushed to rotate, the rotating plate 45 rotates ninety degrees, the rotating plate 45 drives the steel reinforcement cage to rotate ninety degrees to the upper part of the ground pile, then the clamping block electromagnet 64 is powered off, the clamping block spring 65 pulls the clamping block connecting telescopic rod 67 to restore to the initial state, then the rack electromagnet 74 is started to drive the rack 72 to move downwards, the connecting gear 71 drives the rotating half-tooth 70 to rotate, the rotating half-tooth 70 drives the reinforcement cage clamping support plate 32 to rotate ninety degrees to separate from the reinforcement cage, then the fixture block electromagnet 60 is started to drive the fixture block 62 to move upwards, the splint support block 40 slides downwards on the rotating plate 45, the splint support block 40 drives the reinforcement cage to slide downwards to place the reinforcement cage in the ground pile, then the stirring motor 29 is started to drive the stirring connecting rod 28 to rotate, the stirring connecting rod 28 drives the stirring wheel 57 to rotate, the stirring wheel 57 drives the stirring rod 30 to rotate, the stirring rod 30 stirs the concrete in the stirring cavity 31, cement pump 48 is then activated to deliver the concrete in mixing chamber 31 into the pile through cement delivery tube 49, then the vibration block 59 is started to drive the clamping plate 37 to vibrate, the clamping plate 37 drives the clamping electromagnet 38 to vibrate, and the clamping electromagnet 38 drives the reinforcement cage to vibrate so that the concrete is more compact.

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 an automatic equipment is pour to ground stake of preparation steel reinforcement cage, includes the main casing body, its characterized in that: the steel bar cage winding mechanism comprises a driving motor, the driving motor is fixedly connected to the inner wall of the upper side of the working cavity, the right end of the driving motor is fixedly connected with a driving connecting rod, the right side of the driving connecting rod is fixedly connected to a driving gear, the lower end of the driving gear is meshed with a driving internal gear, the driving internal gear is embedded in a steel bar rotating wheel disc, thirty-six steel bar positioning cavities are arranged in the steel bar rotating wheel disc, the lower end of the steel bar rotating wheel disc is rotatably connected in a supporting separation plate, the left end of the steel bar rotating wheel disc is fixedly connected with three uniformly-distributed feeding box bodies, each feeding box body is internally and slidably connected with a feeding supporting rod, the right end of the feeding supporting rod is fixedly connected with a feeding magnet, and the right end of each feeding magnet is fixedly connected, the feeding device comprises a feeding box body, feeding springs, a feeding support rod, a steel bar positioning cavity, a pressing electromagnet, a pressing reset spring, a pressing plate and a feeding slide block, wherein the feeding springs are fixedly connected to the feeding electromagnets, each feeding electromagnet is fixedly connected to the right end of the feeding box body, the left end of each feeding support rod is connected to the feeding wheel, thirty-six feeding cavities corresponding to the steel bar positioning cavities are arranged in the feeding wheel, the pressing electromagnet is arranged between every two feeding cavities, each pressing electromagnet is fixedly connected with two pressing reset springs, each pressing reset spring is fixedly connected to the pressing plate, each pressing plate is slidably connected into the feeding wheel, the lower end of the feeding wheel is rotatably connected to the feeding slide block, and;

the right side of the steel bar rotating wheel disc is provided with a steel bar cage placing mechanism, the steel bar cage placing mechanism comprises a rotating plate, the left end of the rotating plate is slidably connected with a splint supporting block, a fixture block electromagnet is embedded in the splint supporting block, the lower end of the fixture block electromagnet is fixedly connected with a fixture block spring, the lower end of the fixture block spring is fixedly connected to the fixture block, the fixture block is embedded in the rotating plate, the splint supporting block is rotatably connected with two clamping rotating shafts which are symmetrical front and back by taking the splint supporting block as a center, each clamping rotating shaft is internally provided with a torsional spring, each clamping rotating shaft is fixedly connected with a splint, the splint is embedded with a clamping electromagnet, each splint is fixedly connected with a vibration block, the right side of the splint supporting block is provided with a splint bottom block, the splint bottom block is slidably connected to the rotating, the upper end of the rack electromagnet is fixedly connected with a rack spring, the upper end of the rack spring is fixedly connected to the rack, the front end and the rear end of the rack are respectively meshed with a connecting gear, each connecting gear is meshed with a rotary half-tooth, each rotary half-tooth is rotatably connected into the clamping plate bottom block, each rotary half-tooth is fixedly connected with a reinforcing cage clamping support plate, a clamping cavity with an opening facing left is arranged in each reinforcing cage clamping support plate, two clamping block telescopic boxes which are vertically symmetrical by taking the reinforcing cage clamping support plates as centers are embedded in each reinforcing cage clamping support plate, each clamping block telescopic box is internally and slidably connected with a clamping block connecting telescopic rod, each clamping block connecting telescopic rod is fixedly connected to a clamping block magnet, each clamping block magnet is fixedly connected with a clamping block spring, and the clamping block springs are fixedly connected to the clamping block electromagnet, the clamping block electromagnets are fixedly connected to the clamping block telescopic box body, one end, close to the center of the reinforcement cage clamping support plate, of each clamping block connecting telescopic rod is fixedly connected with a clamping block, the right end of the rotating plate is fixedly connected to a rotating wheel, the rotating wheel is fixedly connected to a rotating motor, and the rotating motor is fixedly connected to a rotating rod support plate;

the front end of the steel bar rotating wheel disc is provided with a winding steel bar supporting block, the winding steel bar supporting block is connected in a shell on the front side of the main shell in a sliding manner, the winding steel bar supporting block is connected with two gear magnets which are vertically symmetrical by taking the winding steel bar supporting block as a center in a sliding manner, the front end and the rear end of each gear magnet are respectively and fixedly connected with a gear spring, each gear spring is fixedly connected onto a gear electromagnet, the front end of each gear electromagnet is fixedly connected onto the winding steel bar supporting block, the rear end of each gear electromagnet is fixedly connected onto the main shell and is in sliding connection with the winding steel bar supporting block, a winding steel bar connecting port is embedded in the winding steel bar supporting block, the upper end of the rear side of the winding steel bar supporting block is fixedly connected with a welding gun, the detection device is characterized in that the detection spring is fixedly connected to the detection transmission rod, the lower end of the detection transmission rod is rotatably connected to the detection transmission shaft, the detection transmission shaft is fixedly connected with the detection rod, the rear end of the winding steel bar supporting block is embedded with a cutting electromagnet, the lower end of the cutting electromagnet is fixedly connected with a cutting reset spring, the lower end of the cutting reset spring is fixedly connected to a cutting connecting block, the cutting connecting block is slidably connected to the inside of the winding steel bar supporting block, the rear end of the cutting connecting block is fixedly connected with a cutter, and the cutter is slidably connected to the.

2. The ground pile pouring equipment for automatically manufacturing the reinforcement cage according to claim 1, wherein: the steel bar rotating wheel disc is characterized in that a wire distributing telescopic rod is fixedly connected to the center of the left end of the steel bar rotating wheel disc, a wire distributing wheel is fixedly connected to the left end of the wire distributing telescopic rod, and six uniformly distributed wire distributing plates are fixedly connected to the wire distributing wheel.

3. The ground pile pouring equipment for automatically manufacturing the reinforcement cage according to claim 1, wherein: the utility model discloses a telescopic link support device, including rotor plate, rotating plate, support rotation connecting axle, support telescopic link left end fixedly connected with support axis of rotation, support the axis of rotation and rotate to be connected in the dwang backup pad, support telescopic link right-hand member fixedly connected with two with support the telescopic link and be the support transmission electro-magnet of central longitudinal symmetry, every support transmission electro-magnet right-hand member fixedly connected with and support reset spring, support reset spring right-hand member fixed connection on supporting transmission magnet, support transmission magnet fixed connection be in support on the telescopic link extension bar.

4. The ground pile pouring equipment for automatically manufacturing the reinforcement cage according to claim 1, wherein: support the separator plate lower extreme and be equipped with the stirring chamber, including fixed connection in the stirring chamber support agitator motor on the terminal surface under the separator plate, agitator motor lower extreme fixedly connected with stirring rod, stirring rod lower extreme fixed connection is on the stirring wheel, two uses of stirring wheel lower extreme fixedly connected with stir the wheel and be central bilateral symmetry's puddler, stirring chamber right-hand member fixedly connected with cement conveyer pipe, fixedly connected with cement pump on the cement conveyer pipe.

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