CN213671615U - Bilateral stirring device of reinforcing bar - Google Patents

Abstract

The utility model provides a bilateral stirring device for reinforcing steel bars, which comprises a stirring support, a plurality of rollers, a conveying motor and two stirring mechanisms, wherein the rollers are sequentially arranged at intervals along the length direction of the stirring support and are rotatably connected to the stirring support, the rollers are sequentially connected in a transmission way, and the output end of the conveying motor is connected with one roller in a transmission way; the material turning mechanisms comprise material turning shafts, a plurality of turning plates and material turning push rods, the material turning shafts are rotatably connected to the material turning supports, the turning plates are sequentially arranged at intervals along the length direction of the material turning shafts, and one ends of the turning plates are fixedly connected with the material turning shafts; the material turning push rod is hinged to the material turning support and located below the roller, and the telescopic end of the material turning push rod is hinged to one turning plate; the stirring push rod extension of stirring mechanism promotes to turn over the board and rotates around the stirring axle, turns over the upset that the board rose and drive the reinforcing bar simultaneously for the reinforcing bar rolls to one side of corresponding trip shaft along turning over the board and falls, and two tilters can overturn respectively to the both sides of stirring support, possess fine practicality.

Description

Bilateral stirring device of reinforcing bar

Technical Field

The utility model relates to a reinforcing bar processing production technical field especially relates to a bilateral stirring device of reinforcing bar.

Background

At present, reinforcing steel bars of different specifications and sizes are processed in reinforcing steel bar processing plants in the market so as to meet the construction requirements of infrastructures such as expressways, bridges and subways. For example, the steel bars with different specifications are cut into steel bars with different sizes, and the like, so as to meet the requirements of reinforced cement members such as concrete columns, plates, beams and the like with various shapes.

Aiming at the processing of reinforcing steel bars in batches with different specifications and sizes and different lengths, the batch shearing of the reinforcing steel bars is important equipment required in the processing process of the reinforcing steel bars. Among the prior art, general numerical control reinforcing bar shearing production line, one-way stirring stores reinforcing bar finished product volume few, but also can not use with other equipment coordination, and it is troublesome, hard that its middle reinforcing bar is transported, leads to work efficiency low, and is with high costs, has the limitation in selection and use.

SUMMERY OF THE UTILITY MODEL

In view of this, it is necessary to provide a steel bar bilateral material turning device to solve the problems of low work efficiency caused by the small amount of finished steel bar products, trouble and labor for transferring intermediate steel bars in the conventional unidirectional material turning and storage.

The utility model provides a bilateral stirring device of reinforcing bar, include:

a material turning support;

the rollers are sequentially arranged at intervals along the length direction of the material turning support and are rotationally connected to the material turning support, the rollers are sequentially connected in a transmission manner, and rotating shafts of the rollers are parallel to the width direction of the material turning support;

the conveying motor is fixed on the material turning support, and the output end of the conveying motor is in transmission connection with a roller;

the two material turning mechanisms are respectively arranged on two sides of the material turning support in the length direction; each material turning mechanism comprises a material turning shaft, a plurality of turning plates and a material turning push rod, and the material turning shaft is rotatably connected to the material turning support; the plurality of turning plates are sequentially arranged at intervals along the length direction of the material turning shaft, and one end of each turning plate is fixedly connected with the material turning shaft; the material turning push rod is hinged to the material turning support and located below the roller, and the telescopic end of the material turning push rod is hinged to one turning plate; the turning plate is provided with an opening position and a furling position, and the height of the turning plate does not exceed the roller at the furling position.

Optionally, the material blocking mechanism comprises material blocking plates and material blocking push rods, the material blocking push rods are vertically fixed to the material turning support and located below the rollers, the telescopic ends of the material blocking push rods are fixedly connected with the material blocking plates, and the material blocking plates can penetrate between two adjacent rollers operatively.

Optionally, the material blocking mechanism further comprises two slide rails vertically arranged on the material turning support, sliding grooves of the two slide rails are oppositely arranged, and two side edges of the material blocking plate are slidably arranged in the sliding grooves of the two slide rails.

Optionally, the material blocking mechanisms are multiple and are arranged at intervals in sequence along the length direction of the material turning support.

Optionally, the conveying motor and one roller are connected through a chain transmission, and the rollers are connected through the chain transmission in sequence.

The utility model has the advantages that:

the utility model provides a bilateral stirring device of reinforcing bar is because the reinforcing bar can drive under a plurality of roller pivoted effects of conveyor motor and convey to the assigned position, then stirring push rod extension promotion in a stirring mechanism turns over the board and rotates around the stirring axle, turn over the upset of driving the reinforcing bar when board rises, make the reinforcing bar roll to one side of corresponding trip shaft along turning over the board, and after the reinforcing bar transmission of different specifications comes, stirring push rod extension promotion in another stirring mechanism turns over the board and rotates around the stirring axle, turn over the upset of driving the reinforcing bar when board rises, make the reinforcing bar of different specifications roll to one side of corresponding trip shaft along turning over the board, thereby realize that the branch both sides of the reinforcing bar of two batches of different specifications are deposited, the work efficiency of reinforcing bar transportation in the middle of having improved, and the practicality is fine.

Drawings

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

Fig. 1 is an isometric view of a steel bar grading blanking production line in the first embodiment of the present invention;

fig. 2 is an isometric view of a reinforcing bar loading device according to a first embodiment of the present invention;

FIG. 3 is an enlarged schematic view of the portion A in FIG. 2;

fig. 4 is a schematic view of an installation structure of a reinforcing steel bar double-side turning device, a reinforcing steel bar grading blanking bin and a reinforcing steel bar bending device in the first embodiment of the present invention;

FIG. 5 is an enlarged view of the portion B of FIG. 4;

fig. 6 is an enlarged schematic view of a portion C in fig. 4.

Detailed Description

The following detailed description of the preferred embodiments of the invention, which is to be read in connection with the accompanying drawings, forms a part of this application, and together with the embodiments of the invention, serve to explain the principles of the invention and not to limit its scope.

It will be understood that, although the terms first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another.

Example one

Combine shown in fig. 1, the embodiment of the utility model discloses a hierarchical blanking production line of reinforcing bar, including reinforcing bar loading attachment 1, reinforcing bar shearing mechanism 2, the bilateral turning device 3 of reinforcing bar, the hierarchical blanking storehouse 4 of reinforcing bar and reinforcing bar bending apparatus 5, reinforcing bar loading attachment 1, reinforcing bar shearing mechanism 2 and the bilateral turning device 3 of reinforcing bar connect gradually, and the hierarchical blanking storehouse 4 of reinforcing bar sets up in the bilateral turning device 3's of reinforcing bar one side, and reinforcing bar bending apparatus 5 sets up the opposite side at the bilateral turning device 3 of reinforcing bar. That is to say, reinforcing bar bilateral turning device 3 can turn the reinforcing bar to both sides, turns to reinforcing bar grading blanking storehouse 4 then can classify the storage to the reinforcing bar automatically, and turns to reinforcing bar bending apparatus 5 then can carry out bending to the reinforcing bar.

The following describes the reinforcing bar feeding device 1 of this embodiment with reference to fig. 2 and fig. 3, where the reinforcing bar feeding device 1 of this embodiment includes a feeding mechanism 11 and two feeding mechanisms 12. The feeding mechanism 11 is a long strip-shaped conveying mechanism, and two feeding mechanisms 12 are arranged on two sides of the feeding mechanism 11 along the length direction of the feeding mechanism 11. Specifically, the feeding mechanism 11 includes a feeding bracket 111, a plurality of rollers 112 and a feeding motor, the feeding bracket 111 is of a frame structure, the upper end of the feeding bracket is a rectangular frame, the plurality of rollers 112 are sequentially arranged along the length direction of the rectangular frame of the feeding bracket 111 at intervals and rotatably connected in the rectangular frame of the feeding bracket 111, the rotating shafts of the plurality of rollers 112 are parallel to the width direction of the feeding bracket 111, and the plurality of rollers 112 are sequentially connected by chain transmission, that is, one end of one roller 112 and one end of another roller 112 adjacent to the one roller are driven by chain, while the other end of another roller 112 and the other end of another roller 112 adjacent to the other roller are driven by chain transmission, and thus the transmission is staggered until all the rollers 112 are driven and connected. It should be noted that belt transmission can be adopted among the rollers 112, the number of the rollers 112 is set according to actual needs, and when the steel bar to be cut is long, the feeding range of the feeding bracket 111 can be extended and more rollers 112 are provided. The feeding motor is fixed in the middle of the feeding bracket 111, and the feeding motor is connected with a roller 112 through chain transmission or belt transmission according to actual requirements. When the feeding motor drives one roller 112 to rotate, the roller 112 on the whole feeding bracket 111 rotates, so that the reinforcing steel bars on the feeding bracket 111 are conveyed to the reinforcing steel bar shearing device 2 along the length direction of the feeding bracket 111 for shearing.

Further, each feeding mechanism 12 of the present embodiment includes a feeding bracket 121, a plurality of transmission assemblies 122, a driving motor 123, a main connecting shaft 124, a plurality of slide carriages 125, an auxiliary connecting shaft 126, a plurality of stop levers 127 and a linear push rod 128, where the feeding bracket 121 is also a frame structure, the main connecting shaft 124 is rotatably disposed on the feeding bracket 121, in the present embodiment, the main connecting shaft is rotatably disposed on a side of the feeding bracket 121 away from the feeding bracket 111, and an axis of the main connecting shaft 124 is parallel to a length direction of the feeding bracket 121; the driving motor 123 is fixed in the middle of the feeding bracket 121 and is chain-driven with the main connecting shaft 124, and when the driving motor 123 rotates, the whole main connecting shaft 124 also rotates. Of course, the driving motor 123 and the main connecting shaft 124 may be belt-driven.

Further, a plurality of transmission assemblies 122 are arranged on the feeding support 121 at intervals in sequence, each transmission assembly 122 comprises two transmission wheels and transmission strips, one transmission wheel is coaxially fixed on the main connecting shaft 124, the other transmission wheel is arranged on one side, facing the feeding mechanism 11, of one transmission wheel in a rotating mode, the two transmission wheels are connected through the transmission strips in a transmitting mode, in the feeding process, the steel bar blank is placed on the transmission strips, the main connecting shaft 124 is driven to rotate by the driving motor 123, therefore, one transmission wheel is driven to rotate, the steel bar is conveyed to the feeding mechanism 11 in the rotating process of the transmission belt, the upper end of each transmission strip is higher than the feeding support 111, and the steel bar can be conveniently rolled to the feeding support 111 from the feeding support 121. It should be noted that the plurality of driving assemblies 122 of the present embodiment are chain driving assemblies 122, the driving wheels are chain wheels, and the driving belts are chains. Of course, the chain transmission assembly 122 of the present embodiment can also be replaced by a belt transmission assembly 122 according to actual needs, that is, the transmission wheel is a pulley, and the transmission belt is a belt.

Further, a plurality of carriages 125 are fixed on the side of the feeding frame 121 facing the feeding mechanism 11, and one end of the carriages 125 facing the feeding mechanism 11 is inclined downward, so that the reinforcing bars can slide down along the carriages 125 to the feeding frame 111 when being conveyed to the other end of the transmission assembly 122. It should be noted that, in the present embodiment, the number of the transmission assemblies 122 is the same as that of the carriages 125, the plurality of transmission assemblies 122 are sequentially and equally spaced, and the plurality of carriages 125 are correspondingly disposed on one side of the other transmission wheel of the transmission assemblies 122 facing the feeding mechanism 11. Of course, in other embodiments, the carriages 125 may not be provided in a one-to-one correspondence with the drive assemblies 122.

The auxiliary connecting shaft 126 is rotatably arranged at one end of the slide carriages 125 facing the feeding mechanism 11, and the axis of the auxiliary connecting shaft 126 is parallel to the length direction of the feeding bracket 121; a plurality of stop levers 127 are sequentially fixed to the sub connecting shaft 126 at intervals, and the stop levers 127 can rotate together with the sub connecting shaft 126; the telescopic end of the linear push rod 128 is fixedly connected with one of the stop levers 127, when the linear push rod 128 extends or shortens, one stop lever 127 rotates to drive the auxiliary connecting shaft 126 to rotate together, and finally all the stop levers 127 are driven to rotate synchronously. The blocking rod 127 has two states, one is a vertical state and the other is a horizontal state, when the blocking rod 127 is in the vertical state, the linear push rod 128 is in a contraction state, at this time, the blocking rod 127 exceeds the slide carriage 125, and the reinforcing steel bar slides from the slide carriage 125 and is blocked by the blocking plate to stay on the slide carriage 125. When the steel bars on the feeding mechanism 11 are sent away, the linear push rod 128 extends upwards to push the stop lever 127 to rotate around the auxiliary connecting shaft 126, one end of the stop lever 127 away from the linear push rod 128 rotates downwards relatively, when the stop lever is rotated to be lower than the slide carriage 125, the stopped steel bars slide down on the feeding mechanism 11, the linear push rod 128 contracts downwards after the steel bars slide down, and one end of the stop lever 127 away from the linear push rod 128 rotates upwards to stop new steel bars. It should be noted that the linear push rod 128 of the present embodiment is a pneumatic push rod, but a hydraulic push rod or an electric push rod may be adopted according to actual needs.

Further, each feed mechanism 12 also includes a plurality of pterygoid laminas 129, and a plurality of pterygoid laminas 129 all are L shape, and a plurality of pterygoid laminas 129 are fixed in material loading support 121 at regular intervals in proper order, and a hem of a plurality of pterygoid laminas 129 upwards sets up, and the height of a hem of a plurality of pterygoid laminas 129 exceeds the height of transmission assembly 122, and main connecting axle 124 rotates and sets up in a hem of a plurality of pterygoid laminas 129. One folding edge of the wing plate 129 is arranged upwards to block the reinforcing steel bars, so that the reinforcing steel bars are prevented from falling off from one side of the feeding mechanism 12 yard, which is away from the feeding support 111, and safety accidents are avoided.

Further, the feeding mechanism 11 includes a material blocking frame 113, and one material blocking frame 113 is disposed between every two adjacent rollers 112; the material blocking frame 113 is fixed on the feeding support 111 and comprises a bottom plate and two side plates; the length direction of the bottom plate is parallel to the length direction of the feeding support 111, the height of the bottom plate is not more than that of the roller 112, the two side plates are fixed on two sides of the length direction of the bottom plate, and the height of the two side plates is more than that of the roller 112. The material blocking frame 113 can enable the reinforcing steel bar blank to move forwards on the feeding mechanism 11 along the rolling anti-line of the roller 112, and avoids the disorder of the reinforcing steel bars.

The reinforcing steel bar conveyed by the feeding mechanism 11 enters the reinforcing steel bar shearing device 2, the reinforcing steel bar shearing device 2 adopted in the embodiment is a vertical reinforcing steel bar cutting machine, and the type of the reinforcing steel bar shearing device 2 can be a YQ-70 type vertical reinforcing steel bar cutting machine or other types of vertical reinforcing steel bar cutting machines. After the reinforcing steel bars pass through the reinforcing steel bar shearing device 2, the reinforcing steel bars are firstly blocked by the reinforcing steel bar bilateral turning device 3, and the reinforcing steel bars are cut after the size of the penetrating reinforcing steel bars is determined.

Referring to fig. 4 and 5, the reinforcing steel bar double-side upender 3 of the present embodiment includes an upender bracket 31, a plurality of rollers 32, a conveying motor, and two upender mechanisms 33. The stirring support 31 is a frame structure, and the upper part of the stirring support is a square frame. The rollers 32 are arranged at intervals in sequence along the length direction of the stirring bracket 31 and are rotatably connected to the frame of the stirring bracket 31, and the rollers 32 are sequentially connected through chain transmission, namely one end of one roller 32 and one end of another roller 32 adjacent to the one roller are driven through a chain, the other end of another roller 32 and the other end of another roller 32 adjacent to the other roller are driven through a chain, and the transmission is staggered until all the rollers 32 are in transmission connection. It should be noted that belt transmission can also be adopted among a plurality of rollers 32, the number of rollers 32 is set according to actual needs, and when the steel bar to be cut is longer, the feeding range of the material turning support 31 can be prolonged and more rollers 32 are set. The conveying motor is fixed in the middle of the feeding bracket 111, and the conveying motor and one roller 32 are connected through chain transmission or belt transmission according to actual requirements. When the conveying motor drives one roller 32 to rotate, the roller 32 on the whole feeding bracket 111 rotates.

Further, the two material turning mechanisms 33 are respectively arranged on two sides of the material turning support 31 in the length direction; each material turning mechanism 33 comprises a material turning shaft 331, a plurality of turning plates 332 and a material turning push rod, wherein the material turning shafts 331 of the two material turning mechanisms 33 are parallel to each other and are respectively connected to two side edges of the material turning support 31 in a rotating manner. In one material turning mechanism 33, a plurality of turning plates 332 are sequentially arranged at intervals along the length direction of the corresponding material turning shaft 331, one end of each of the plurality of turning plates 332 is fixedly connected with the material turning shaft 331, and the other end faces the other material turning shaft 331. The fixed end of the material turning push rod is hinged to the middle of the material turning support 31 and is located below the roller 32, and the telescopic end of the material turning push rod is hinged to one of the turning plates 332. The turning plate 332 can be controlled to swing between an overturning position and a furling position by the extension and the shortening of the turning push rod, the telescopic end of the turning push rod is shortened, the turning plate 332 is located at the furling position, the height of the turning plate 332 is not more than that of the roller 32, the telescopic end of the turning push rod is extended, the turning plate 332 connected with the turning push rod rotates around the turning shaft 331, and meanwhile, the turning shaft also rotates along with the turning push rod, so that all the turning plates 332 on the turning shaft are driven to rotate to be located at the unfolding position, the height of the other end of the turning plate 332 far exceeds that of the roller 32, steel bars on the roller 32 can be lifted by the turning plate 332, and steel bars falling into the steel bar double-side overturning device 3 from the bin 4 or the.

Further, the reinforcing steel bar bilateral turning device 3 further comprises a plurality of material blocking mechanisms 34, the material blocking mechanisms 34 are arranged along the length direction of the turning support 31 at intervals in sequence, and the distance from each material blocking mechanism 34 to the knife edge of the reinforcing steel bar shearing device 2 is set according to actual needs, such as 1m, 1.5m, 2m and the like, that is, after the reinforcing steel bars pass through the reinforcing steel bar shearing device 2, if the reinforcing steel bars of 2m need to be cut off, the material blocking mechanisms 34 located at the position of 2m can act to block the reinforcing steel bars, after the reinforcing steel bars abut against the material blocking mechanisms 34, the size that the reinforcing steel bars penetrate out of the reinforcing steel bar shearing device 2 is determined to be 2m, and then cutting is performed. Specifically, the material blocking mechanism 34 includes material blocking plates 341, slide rails 342 and material blocking push rods, the two slide rails 342 are vertically arranged on the material turning support 31, the two slide rails 342 both have sliding grooves, the sliding grooves of the two slide rails 342 are oppositely arranged, the material blocking push rods are vertically fixed on the material turning support 31 and located below the rollers 32, the telescopic ends of the material blocking push rods are fixedly connected with the material blocking plates 341, two side edges of the material blocking plates 341 are slidably arranged in the sliding grooves of the two slide rails 342, and the material blocking plates 341 can operatively pass through the space between two adjacent rollers 32. It should be noted that the material turning push rod and the material blocking push rod of the embodiment are both air pressure push rods, and of course, hydraulic push rods or electric push rods may also be adopted according to actual needs.

Referring to fig. 4 and 6, the steel bar grading blanking bin 4 of the present embodiment includes a plurality of blanking units 41, and the plurality of blanking units 41 are sequentially disposed along the length direction of the steel bar bilateral material turning device 3. And the interval between every two adjacent blanking units 41 is increased along the moving direction of the steel bar in sequence, because the size of the steel bar at the front section is small, the steel bar can be limited by a plurality of blanking units 41 to be placed neatly, so for the steel bar with small specification, the interval of the blanking units 41 needs to be set smaller, and for the steel bar with large specification, the interval of the blanking units 41 can be correspondingly increased.

Further, each blanking unit 41 comprises a first limiting rod 411, a second limiting rod 412, two fixing barrels 413, two movable plates 414 and a driving part, the first limiting rod 411 is fixed on one side of the reinforcing steel bar bilateral material overturning device 3, and the second limiting rod 412 is vertically arranged on one side of the first limiting rod 411, which deviates from the reinforcing steel bar bilateral material overturning device 3 in parallel. Two fixed barrels 413 are fixed between the first limiting rod 411 and the second limiting rod 412 at intervals in sequence, so that three bin openings are formed, and three reinforcing steel bars with different specifications can be separately arranged. The heights of the two fixed cylinders 413 are both smaller than the height of the first limiting rod 411 and the heights of the two fixed cylinders 413 are sequentially reduced along the direction away from the first limiting rod 411. The upper end of each fixed cylinder 413 is hinged with a movable plate 414. One end of a movable plate 414 close to the first limiting rod 411 is hinged to the upper end of a fixed cylinder 413 close to the first limiting rod 411, and the other end is operatively connected to the upper end of the first limiting rod 411. One end of the other movable plate 414 close to the second limiting rod 412 is hinged to the upper end of the other fixed cylinder 413 close to the second limiting rod 412, and the other end is operatively overlapped with the upper end of the one fixed cylinder 413 close to the first limiting rod 411. It is worth noting that the holding tank has all been seted up to the upper end of each fixed section of thick bamboo 413, and the opening of the both sides of holding tank is towards first gag lever post 411 and second gag lever post 412 respectively, so, when the movable rod overlap joint was in the upper end of fixed section of thick bamboo 413, the movable rod can not surpass the upper end of fixed section of thick bamboo 413, just can not cause the hindrance to rolling of reinforcing bar.

It should be noted that, the number of the fixed cylinders 413 and the movable plates 414 may be set according to actual needs, for example, only one fixed cylinder 413 and one movable plate 414 may be provided, so that the rebar grading blanking bin 4 is equivalent to only two bin openings, and if three fixed cylinders 413 and three movable plates 414 are provided, the rebar grading blanking bin 4 is equivalent to four bin openings. It is noted that each of the fixed cylinders 413 is provided therein with a driving member for driving the movable plate 414 to rotate around the hinge point of the movable plate 414 and the fixed cylinder 413. In this embodiment, the driving member is a pneumatic push rod, a hydraulic push rod or an electric push rod, the fixed end of the driving member is hinged to the bottom of the fixed cylinder 413, and the telescopic end of the driving member is hinged to the movable plate 414. When a reinforcing steel bar of a certain specification rolls down from the reinforcing steel bar bilateral turning device 3, the driving part in one fixed cylinder 413 close to the first limiting rod 411 drives the movable plate 414 close to the first limiting rod 411 to rotate so that one end of the movable plate 414 lapped on the upper end of the first limiting rod 411 is far away from the first limiting rod 411, the reinforcing steel bar falls between one fixed cylinder 413 close to the first limiting rod 411 and the first limiting rod 411, when a reinforcing steel bar of another specification rolls down, the driving part in one fixed cylinder 413 close to the first limiting rod 411 drives the movable plate 414 close to the first limiting rod 411 to rotate so that the movable plate 414 lapped on the upper end of the first limiting rod 411, and the driving part in another fixed cylinder 413 close to the second limiting rod 412 drives the movable plate 414 close to the second limiting rod 412 to rotate so that one end of the movable plate 414 lapped on another fixed cylinder 413 close to the second limiting rod 412 is far away from another fixed cylinder 413 close to the second limiting rod 412, because the height of the fixed cylinder 413 is less than that of the first limiting rod 411, the steel bars can continuously roll along the movable plate 414 close to the first limiting rod 411 until the steel bars fall between the two fixed cylinders 413, so that classified storage of the steel bars of another specification is realized, when the steel bars of a third specification need to be stored, the movable plates 414 on the two fixed cylinders 413 are lapped on corresponding rod pieces, and at the moment, the steel bars can roll along the two movable plates 414 between the second limiting rod 412 and the other fixed cylinder 413, so that storage of the steel bars of three different specifications is realized.

Certainly, the sheared steel bars can be turned over to the steel bar bending device 5 to be bent, the steel bar bending device 5 in the embodiment is a steel bar bending center, and the type of the steel bar bending device can adopt an LSW32 vertical double-head steel bar bending center or other types of steel bar bending centers. After the bars are turned over onto the bar bender 5, the bars can be bent into the desired shape using a bender head at the center of the bar bend.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the present invention.

Claims (5)

1. The utility model provides a bilateral stirring device of reinforcing bar which characterized in that includes:

a material turning support;

the turning support is arranged on the frame, and the turning support is arranged on the frame and is provided with a plurality of rollers;

the conveying motor is fixed on the material turning support, and the output end of the conveying motor is in transmission connection with one roller;

the two material turning mechanisms are respectively arranged on two sides of the material turning support in the length direction; each material turning mechanism comprises a material turning shaft, a plurality of turning plates and a material turning push rod, and the material turning shaft is rotatably connected to the material turning support; the plurality of turning plates are sequentially arranged at intervals along the length direction of the material turning shaft, and one end of each turning plate is fixedly connected with the material turning shaft; the material turning push rod is hinged to the material turning support and located below the roller, and the telescopic end of the material turning push rod is hinged to one turning plate; the turning plate is provided with an opening position and a furling position, and in the furling position, the height of the turning plate does not exceed the roller.

2. The bilateral reinforcing steel bar stirring device of claim 1, further comprising a material blocking mechanism, wherein the material blocking mechanism comprises material blocking plates and material blocking push rods, the material blocking push rods are vertically fixed to the stirring support and located below the rollers, telescopic ends of the material blocking push rods are fixedly connected with the material blocking plates, and the material blocking plates can penetrate between two adjacent rollers in an operable manner.

3. The bilateral reinforcing steel bar stirring device of claim 2, wherein the material blocking mechanism further comprises two slide rails vertically arranged on the stirring support, slide grooves of the two slide rails are oppositely arranged, and two side edges of the material blocking plate are slidably arranged in the slide grooves of the two slide rails.

4. The bilateral turn-down rig of reinforcing bar of claim 2, wherein there are a plurality of said material blocking mechanisms, and a plurality of said material blocking mechanisms are arranged along the length direction of said turn-down support at intervals in sequence.

5. The bilateral reinforcing steel bar overturning device according to any one of claims 1 to 4, wherein the conveying motor is connected with the roller through chain transmission, and the rollers are sequentially connected through the chain transmission.

Images