JP2021030304A - High-speed bidirectional interlocking bender - Google Patents

Abstract

To disclose a high-speed bidirectional interlocking bender.SOLUTION: A high-speed bidirectional interlocking bender includes a main body. A conveyance space is installed in the main body, and a rotation space is installed on the right side of the conveyance space. A work space is installed under the rotation space, and a left space and a right space are installed above the main body. A lower space is installed under the conveyance space, and an inlet to which a reinforcement can be input is installed in a left wall of the conveyance space. The conveyance space and the work space are in communication via an inside hole, and an upper guide roller and lower guide roller which are capable of carrying the reinforcement are installed in the conveyance space. A hydraulic device capable of cutting is fixedly connected in the rotation space.SELECTED DRAWING: Figure 1

Description

The invention of the present application deals with the field of building construction equipment, and particularly relates to a high-speed bidirectional interlocking vendor.

In the construction of high-rise buildings, it is necessary to assemble steel frames with a large amount of reinforcing bars in order to improve the stability of the building. In steel frame construction, many reinforcing bar frames created by bending are used, and such reinforcing bar frames are basically obtained by bending four times. However, traditional bending work is mainly done manually, and the bent rebar is further cut with a hydraulic cutter to shorten it. In large-scale construction, such a method consumes a large amount of labor. We will provide high-speed interlocking vendors to improve construction efficiency and speed up the production of reinforcing bar frames.

Chinese Patent Application Publication No. 105562553

By providing a high-speed bidirectional interlocking vendor, the purpose is to solve the above problems and improve the practicality of the equipment.

The present invention is realized by the following technical solutions.

The high-speed bidirectional interlocking bender described in the present application includes a main body, a transport space is installed in the main body, a rotation space is installed on the right side of the transfer space, and a work space is installed below the rotation space. Is installed, a left space and a right space are installed above the main body, a lower space is installed below the transport space, and an entrance into which a reinforcing bar can be inserted is installed on the left wall of the transport space. The transport space and the work space are communicated with each other by a middle hole, and an upper guide roller and a lower guide roller capable of transporting reinforcing bars are installed in the transport space, and a hydraulic device capable of cutting is installed in the rotating space. Are fixedly connected, a transport belt capable of delivering reinforcing bars is installed in the work space, a shaft sleeve capable of bending is installed in the work space, and transmission can be performed in the rotating space. The motor is fixedly connected, the rear vertical axis and the right vertical axis are rotatably connected to the inner wall of the rotating space, the left gear is fixedly connected to the rear vertical axis, and the right vertical axis is connected. The right gear is fixedly connected to the motor, the output shaft is movably connected to the motor, the main fan-shaped gear is fixedly connected to the output shaft, and the main fan-shaped gear is the left gear and the right, respectively. By engaging with the gears intermittently, it enables bidirectional interlocking.

Further, a rear gear and a rear fan-shaped gear are fixedly connected below the rear vertical axis, the front gear meshes with the rear gear, and the front gear is rotatably connected with the upper wall of the rotating space. The front vertical axis is fixedly connected, and the front fan-shaped gear is fixedly connected to the lower end of the front vertical axis.

Further, a bending shaft extending in the working space is rotatably connected to the lower wall of the rotating space, a center gear is fixedly connected to the upper end of the bending shaft, and the center gear is the front fan-shaped gear. The shaft sleeve is intermittently meshed with the rear fan-shaped gear, the shaft sleeve is connected to the lower end of the bending shaft by a spline, and a holding groove is formed at the lower end of the shaft sleeve.

Further, an inner upper umbrella gear is fixedly connected to the lower end of the right vertical axis, the inner lower umbrella gear meshes with the inner upper umbrella gear, and the inner lower umbrella gear can rotate with the inner wall of the rotating space. The right horizontal axis connected to is fixedly connected, the cam is fixedly connected to the right horizontal axis, and the sliding rod extending to the work space is slidable on the lower wall of the rotating space. A stopper was fixedly connected to the sliding rod, a spring was fixedly connected below the stopper, and the lower end of the sliding rod was rotatably connected to the shaft sleeve. The thrust plates are fixedly connected.

Further, a hydraulic cutter extending to the work space is movably connected to the hydraulic device, and a cutting table is fixedly connected to the left wall of the work space.

Further, the right vertical axis extends to the right space and is fixedly connected to the lower right bevel gear, the upper right bevel gear meshes with the lower right bevel gear, and the upper right bevel gear is left in the right space. The upper horizontal axis rotatably connected to the wall is fixedly connected, the upper horizontal axis extends in the left space and is fixedly connected to the upper left bevel gear, and the upper left bevel gear is fixedly connected to the lower left bevel gear. The left lower vertical axis is rotatably connected to the lower wall of the left space, and the left vertical axis extends to the transport space and is fixed to the upper gear. Are connected.

Further, the lower cap gear meshes with the upper cap gear, and the upper transport shaft rotatably connected to the inner wall of the transport space is fixedly connected to the lower cap gear, and the upper transport shaft is fixedly connected to the upper guide. It was fixedly connected to the roller, the upper gear was fixedly connected to the upper transport shaft, the lower gear meshed with the upper gear, and the lower gear was rotatably connected to the inner wall of the transport space. The lower transport shaft is fixedly connected, and the lower transport shaft is fixedly connected to the lower guide roller.

Further, a rear bevel gear is fixedly connected to the lower transport shaft, an inner bevel gear meshes with the rear bevel gear, and the inner bevel gear is rotatably connected to the lower wall of the transport space. The vertical axis is fixedly connected, and the lower vertical axis extends in the lower space and is fixedly connected to the rear upper bevel gear.

Further, the rear lower gear is meshed with the rear upper gear, and the lower horizontal shaft rotatably connected to the right wall of the lower space is fixedly connected to the rear lower gear. Extends to the work space and is fixedly connected to the first bevel gear, the second bead gear meshes with the first bead gear, and the second bead gear is rotatably connected to the inner wall of the work space. The left shaft is fixedly connected to the left shaft, the left transport wheel movably connected to the transport belt is fixedly connected to the left shaft, and the right transport wheel is mobilably connected to the transport belt. A right shaft rotatably connected to the inner wall of the work space is fixedly connected to the right transport wheel.

The present invention has the following positive effects: The present invention enables continuous bending by intermittently meshing fan-shaped gears, and bidirectional interlocking by fan-shaped gears for bending and pinching and transporting a reinforcing bar. It is worthwhile to effectively improve the construction efficiency, perform the bending work fully automatically, save a large amount of labor, and spread it in the construction work as a highly efficient mechanical equipment.

In order to explain the present invention in detail with reference to FIGS. 1 to 4 below and to explain the present invention in a convenient manner, each direction described in the present application is defined as follows: FIG. Each of the described directions is based on the observation direction in FIG.

FIG. 1 is a schematic diagram of the overall configuration of the present invention. FIG. 2 is a schematic configuration of a cross section taken along the line AA in FIG. FIG. 3 is a schematic configuration of a BB cross section in FIG. FIG. 4 is a schematic configuration of a CC cross section in FIG.

As shown in FIGS. 1 to 4, the high-speed bidirectional interlocking bender described in the present application includes a main body 10, a transport space 20 is installed in the main body 10, and a transport space 20 is installed on the right side of the transport space 20. A rotating space 21 is installed, a working space 68 is installed below the rotating space 21, a left space 11 and a right space 17 are installed above the main body 10, and a lower space below the transport space 20. A space 44 is installed, an inlet 40 into which reinforcing bars can be inserted is installed on the left wall of the transport space 20, and the transport space 20 and the work space 68 are communicated with each other by a middle hole 41, and the transport space 20 is connected to the transport space 20. An upper guide roller 38 and a lower guide roller 42 capable of transporting reinforcing bars are installed, a hydraulic device 22 capable of cutting is fixedly connected in the rotating space 21, and reinforcing bars are placed in the working space 68. A transport belt 52 that can be sent out is installed, a shaft sleeve 55 that can be bent is installed in the work space 68, and a motor 24 that can transmit is fixedly connected in the rotation space 21. The rear vertical axis 23 and the right vertical axis 18 are rotatably connected to the inner wall of 21, the left gear 28 is fixedly connected to the rear vertical axis 23, and the right gear 27 is fixedly connected to the right vertical axis 18. The output shaft 25 is fixedly connected to the motor 24, the main fan-shaped gear 26 is fixedly connected to the output shaft 25, and the main fan-shaped gear 26 is connected to the left gear 28, respectively. By intermittently meshing with the right gear 27, interlocking in both directions is possible.

Preferably, the rear gear 34 and the rear fan-shaped gear 67 are fixedly connected below the rear vertical axis 23, the front gear 65 meshes with the rear gear 34, and the rotating space 21 is engaged with the front gear 65. The front vertical axis 64 rotatably connected to the upper wall is fixedly connected, and the front fan-shaped gear 66 is fixedly connected to the lower end of the front vertical axis 64.

Preferably, a bending shaft 37 extending to the working space 68 is rotatably connected to the lower wall of the rotating space 21, and a center gear 35 is fixedly connected to the upper end of the bending shaft 37 to form the center. The gear 35 intermittently meshes with the front fan-shaped gear 66 and the rear fan-shaped gear 67, the shaft sleeve 55 is connected by a spline to the lower end of the bending shaft 37, and a holding groove 56 is provided at the lower end of the shaft sleeve 55. It is formed.

Preferably, the inner upper cap gear 71 is fixedly connected to the lower end of the right vertical axis 18, the inner lower cap gear 72 meshes with the inner upper cap gear 71, and the rotation of the inner lower cap gear 72. The right horizontal shaft 30 rotatably connected to the inner wall of the space 21 is fixedly connected, the cam 29 is fixedly connected to the right horizontal shaft 30, and the work space is connected to the lower wall of the rotating space 21. The sliding rod 31 extending to 68 is slidably connected, the stopper 32 is fixedly connected to the sliding rod 31, and the spring 33 is fixedly connected below the stopper 32. A thrust plate 57 rotatably connected to the shaft sleeve 55 is fixedly connected to the lower end of the sliding rod 31.

Preferably, the hydraulic cutter 36 extending to the work space 68 is movably connected to the hydraulic device 22, and the cutting table 49 is fixedly connected to the left wall of the work space 68.

Preferably, the right vertical axis 18 extends to the right space 17 and is fixedly connected to the right lower bevel gear 16, and the upper right bevel gear 15 meshes with the lower right bevel gear 16 so that the upper right bevel gear 15 is engaged. The upper horizontal shaft 13 rotatably connected to the left wall of the right space 17 is fixedly connected to the right space 17, and the upper horizontal shaft 13 extends to the left space 11 and is fixedly connected to the upper left bevel gear 12. The left lower gear 14 meshes with the upper left gear 12, and the left vertical axis 19 rotatably connected to the lower wall of the left space 11 is fixedly connected to the lower left gear 14. The left vertical axis 19 extends to the transport space 20 and is fixedly connected to the upper gear 58.

Preferably, the lower gear 59 meshes with the upper gear 58, and the upper transport shaft 39 rotatably connected to the inner wall of the transport space 20 is fixedly connected to the lower gear 59. The transport shaft 39 is fixedly connected to the upper guide roller 38, the upper gear 60 is fixedly connected to the upper transport shaft 39, the lower gear 61 meshes with the upper gear 60, and the lower gear 61 engages with the lower gear 61. Is fixedly connected to the lower transport shaft 43 rotatably connected to the inner wall of the transport space 20, and the lower transport shaft 43 is fixedly connected to the lower guide roller 42.

Preferably, the rear bevel gear 62 is fixedly connected to the lower transport shaft 43, the inner bevel gear 63 meshes with the rear bevel gear 62, and the inner bevel gear 63 is connected to the lower wall of the transport space 20. The rotatably connected lower vertical axis 45 is fixedly connected, and the lower vertical axis 45 extends to the lower space 44 and is fixedly connected to the rear upper bevel gear 46.

Preferably, the rear lower gear 47 meshes with the rear upper gear 46, and the lower horizontal shaft 48 rotatably connected to the right wall of the lower space 44 is fixedly connected to the rear lower gear 47. The lower horizontal shaft 48 extends to the work space 68 and is fixedly connected to the first cap gear 69, and the second cap gear 70 meshes with the first cap gear 69 to form the second cap gear 70. Is fixedly connected to the left shaft 50 rotatably connected to the inner wall of the work space 68, and the left transport wheel 51 rotatably connected to the transport belt 52 is fixedly connected to the left shaft 50. The right transport wheel 53 is rotatably connected to the transport belt 52, and the right shaft 54 rotatably connected to the inner wall of the work space 68 is fixedly connected to the right transport wheel 53. ..

The fixed connection method described in the present application includes, but is not limited to, fixing with bolts and welding.

The operating procedure of the present invention is as follows.

1. At the time of work, a reinforcing bar is inserted from the inlet 40, the motor 24 is started to rotate the output shaft 25, and the main fan-shaped gear 26 rotates in conjunction with the rotation.

2. When the main fan-shaped gear 26 meshes with the right gear 27, the right vertical axis 18 rotates in conjunction with the inner upper umbrella gear 71, and the inner lower umbrella gear 72 rotates in conjunction with the right gear 27. The right horizontal shaft 30 is rotated, the cam 29 is rotated in conjunction with the rotation rod 31, and the sliding rod 31 is lowered by coming into contact with the sliding rod 31, and the thrust plate 57 is lowered in conjunction with the sliding rod 31. , The shaft sleeve 55 is lowered.

3. The lower right bevel gear 16 rotates in conjunction with each other to rotate the upper right bevel gear 15, the upper left bevel gear 12 is rotated in conjunction with each other, the lower left bevel gear 14 is rotated, and the left vertical axis 19 is rotated. Rotates in conjunction with each other, the upper bevel gear 58 is rotated, the lower bevel gear 59 is rotated in conjunction with each other, the upper transport shaft 39 is rotated, and the upper guide roller 38 is rotated in conjunction with the above. The lower gear 61 is rotated, the lower transport shaft 43 is rotated in conjunction with the rotation, and the lower guide roller 42 is rotated to move the reinforcing bar to the right and enter the holding groove 56.

4. Further, the lower vertical axis 45 rotates in conjunction with the rear upper umbrella gear 46, the rear lower umbrella gear 47 rotates in conjunction with the lower horizontal shaft 48, and the second lower horizontal axis 48 rotates. The one umbrella gear 69 rotates in conjunction with each other to rotate the second umbrella gear 70, and the upper left transfer wheel 51 rotates in conjunction with the second umbrella gear 70 to move the transfer belt 52.

5. When the main fan-shaped gear 26 meshes with the left gear 28, the rear vertical axis 23 rotates in conjunction with each other to rotate the rear gear 34 and the rear fan-shaped gear 67, and the rear fan-shaped gear 67 rotates. By meshing with the center gear 35, the shaft sleeve 55 is rotated 90 degrees, and the rear fan-shaped gear 67 does not mesh with the center gear 35, and then the main fan-shaped gear 26 does not mesh with the left gear 28.

6. Next, the main fan-shaped gear 26 meshes with the right gear 27 again, the cam 29 does not come into contact with the sliding rod 31, the stopper 32 is raised by the spring 33, and the holding groove 56 is a reinforcing bar. Reinforcing bars continue to move to the right.

7. After the reinforcing bar is bent four times, the motor 24 is stopped and the hydraulic device 22 is activated to allow the hydraulic cutter 36 to cut the reinforcing bar downward, whereby a complete reinforcing bar frame can be obtained.

The above examples are merely for explaining the technical idea and features of the present invention, and are intended to allow engineers in the field to understand and implement the present invention, and are not intended to limit the present invention. However, any modifications, equivalent substitutions and improvements made under the significance and principles of the invention should be included in the scope of protection of the invention.

Claims (9)

Including the main body
A transport space is installed in the main body, a rotating space is installed on the right side of the transport space, a work space is installed below the rotating space, and a left space and a right space are installed above the main body. Is installed, a lower space is installed below the transport space, an entrance into which reinforcing bars can be inserted is installed on the left wall of the transport space, and the transport space and the work space are communicated with each other by a middle hole. An upper guide roller and a lower guide roller capable of transporting reinforcing bars are installed in the transport space, a hydraulic device capable of cutting is fixedly connected in the rotating space, and reinforcing bars are placed in the work space. A transport belt that can be sent is installed,
A shaft sleeve that can be bent is installed in the work space, a motor that can transmit is fixedly connected in the rotation space, and a rear vertical axis and a right vertical axis are connected to the inner wall of the rotation space. Rotatably connected, the left gear is fixedly connected to the rear vertical axis, the right gear is fixedly connected to the right vertical axis, and the output shaft is movably connected to the motor. A main fan-shaped gear is fixedly connected to the output shaft, and the main fan-shaped gear is intermittently meshed with the left gear and the right gear, respectively, thereby enabling bidirectional interlocking. Two-way interlocking vendor. A rear gear and a rear fan-shaped gear are fixedly connected below the rear vertical axis, the front gear meshes with the rear gear, and the front gear is rotatably connected with the upper wall of the rotating space. The high-speed bidirectional interlocking bender according to claim 1, wherein the front vertical axis is fixedly connected, and a front fan-shaped gear is fixedly connected to the lower end of the front vertical axis. A bending shaft extending to the working space is rotatably connected to the lower wall of the rotating space, a center gear is fixedly connected to the upper end of the bending shaft, and the center gear is the front fan-shaped gear and the said. The first aspect of claim 1, wherein the shaft sleeve is intermittently meshed with the rear fan-shaped gear, the shaft sleeve is connected to the lower end of the bent shaft by a spline, and a holding groove is formed at the lower end of the shaft sleeve. High-speed bidirectional interlocking vendor. An inner upper cap gear is fixedly connected to the lower end of the right vertical axis, an inner lower cap gear meshes with the inner upper cap gear, and the inner lower cap gear is rotatably connected to the inner wall of the rotating space. The right horizontal axis is fixedly connected, the cam is fixedly connected to the right horizontal axis, and the sliding rod extending to the work space is slidably connected to the lower wall of the rotating space. A stopper is fixedly connected to the sliding rod, a spring is fixedly connected below the stopper, and a thrust plate rotatably connected to the shaft sleeve at the lower end of the sliding rod. The high-speed bidirectional interlocking vendor according to claim 1, wherein the gears are fixedly connected. The first aspect of claim 1, wherein a hydraulic cutter extending in the work space is movably connected to the hydraulic device, and a cutting table is fixedly connected to the left wall of the work space. High-speed bidirectional interlocking vendor. The right vertical axis extends to the right space and is fixedly connected to the lower right bevel gear, the upper right bevel gear meshes with the lower right bevel gear, and the upper right bead gear is connected to the left wall of the right space. The rotatably connected upper horizontal shaft is fixedly connected, the upper horizontal shaft extends in the left space and is fixedly connected to the upper left bevel gear, and the left lower bevel gear meshes with the upper left bevel gear. A left vertical axis rotatably connected to the lower wall of the left space is fixedly connected to the left lower bevel gear, and the left vertical axis extends to the transport space and is fixedly connected to the upper bevel gear. The high-speed bidirectional interlocking vendor according to claim 1, wherein they are linked. The lower cap gear meshes with the upper cap gear, and the upper transport shaft rotatably connected to the inner wall of the transport space is fixedly connected to the lower cap gear, and the upper transport shaft is fixedly connected to the upper guide roller. The upper gear is fixedly connected to the upper transport shaft, the lower gear meshes with the upper gear, and the lower gear is rotatably connected to the inner wall of the transport space. The high-speed bidirectional interlocking bender according to claim 6, wherein the shaft is fixedly connected, and the lower transport shaft is fixedly connected to the lower guide roller. A rear bevel gear is fixedly connected to the lower transport shaft, an inner bevel gear meshes with the rear bevel gear, and the lower vertical axis is rotatably connected to the lower wall of the transport space to the inner bevel gear. 7. The high-speed bidirectional interlocking bender according to claim 7, wherein the lower vertical axis extends in the lower space and is fixedly connected to the rear upper bevel gear. The rear lower gear is meshed with the rear upper gear, and the lower horizontal shaft rotatably connected to the right wall of the lower space is fixedly connected to the rear lower gear, and the lower horizontal shaft is the same. The left that extends to the work space and is fixedly connected to the first bevel gear, the second bead gear meshes with the first bead gear, and the second bead gear is rotatably connected to the inner wall of the work space. The shafts are fixedly connected, the left shaft is fixedly connected to the left transport wheel mobilably connected to the transport belt, the right transport wheel is mobilably connected to the transport belt, and the right The high-speed bidirectional interlocking bender according to claim 8, wherein a right shaft rotatably connected to the inner wall of the work space is fixedly connected to the transport wheel.

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