CN111188502A - A adjust bearing structure for operation is pricked to reinforcing bar - Google Patents

Abstract

The invention discloses an adjusting and supporting structure for steel bar wire binding operation, which comprises a support plate and telescopic rods, wherein a first device plate is arranged on the side edge of the support plate, the telescopic rods which are horizontally distributed are installed on the central line of the front surface of the support plate, one end of each telescopic rod is fixedly connected with the surface of the side edge of a second device plate, a second supporting ring is arranged on the outer side of the second device plate, the center of the second device plate is rotatably connected with a second operating rod, the outer end of the second operating rod is connected with a second handle, and the outer surface of the second supporting ring is connected with the outer end of the second adjusting rod. This an adjust bearing structure for reinforcing bar is pricked silk operation through the structural design of first device board and second device board, can follow four edges and carry out the support that stabilizes to reinforcing bar itself and fix, can utilize the motor drive of the first device board of multiunit to rotate simultaneously and make things convenient for the staff to carry out the efficient and prick the silk operation, and structural design is more reasonable.

Description

A adjust bearing structure for operation is pricked to reinforcing bar

Technical Field

The invention relates to the technical field of building construction, in particular to an adjusting and supporting structure for steel bar wire binding operation.

Background

In the construction process, how guarantee that building structure intensity is enough safe very important, among the current building structure, it is filling concrete in framework of steel reinforcement to use comparatively extensively, and framework of steel reinforcement's formation, then need use several reinforcing bar cooperation hoop of steel reinforcement to use, utilize the bundle silk to consolidate connection processing to node connection between them, there is corresponding equipment to carry out automated processing preparation to large-scale framework of steel reinforcement among the existing equipment, but use more extensive medium-sized or small-size framework of steel reinforcement then to need staff's manual operation processing, in order to ensure framework of steel reinforcement's preparation efficiency, can use corresponding bearing structure to support the reinforcing bar, but current bearing structure has following problem when in-service use:

1. the length of a single steel bar forming the steel bar framework is long, and the two-limb hoop which is widely used needs four independent steel bars to be respectively connected to four corners of the steel bar hoop, and the steel bar can be bent downwards under the gravity and elasticity of the steel bar when being horizontally placed, so that the wire binding operation is very difficult, and a worker needs to repeatedly adjust the position of the steel bar;

2. a complete framework of steel reinforcement needs to use several hoop in the skeleton texture, and several hoop all need manually to prick the silk operation, consequently needs the manual not stop framework of steel reinforcement that turns over of staff, and the whole weight of framework of steel reinforcement is great, and the actual operation is got up very inconveniently.

Disclosure of Invention

The invention aims to provide an adjusting and supporting structure for steel bar binding operation, which aims to solve the problems that the length of a single steel bar forming a steel bar framework is long, a double-limb hoop widely used needs four independent steel bars to be respectively connected to four corners of the steel bar hoop, and the steel bar is difficult to bind and operate due to downward bending caused by the gravity and elasticity of the steel bar when the steel bar is horizontally placed; a complete framework of steel reinforcement needs to use the several hoop of steel reinforcement in the skeleton texture, and the several hoop of steel reinforcement all needs manual the operation of pricking the silk, consequently needs the manual not stop framework of steel reinforcement that turns over of staff, and the whole weight of framework of steel reinforcement is great, the very inconvenient problem of actual operation getting up.

In order to achieve the purpose, the invention provides the following technical scheme: an adjusting and supporting structure for steel bar wire binding operation comprises a support plate and an expansion link, wherein a first device plate is arranged on the side of the support plate, a rotating shaft is installed at the center of the back of the first device plate and is rotatably connected to the top end of a vertical beam, the bottom end of the vertical beam is fixed to the outer end of a cross beam, the inner end of the cross beam is fixedly welded to the surface of the support plate, a motor is installed on the support plate and is connected with a motor shaft which is horizontally distributed in the support plate, first bevel gears are installed on the motor shaft, vertical shafts which are vertically distributed are rotatably installed in the vertical beam, the top end of each vertical shaft is connected with the rotating shaft through 2 third bevel gears which are meshed with each other, a first operating rod and a first supporting ring are arranged on the outer side of the first device plate and are connected with a sleeve through a first adjusting rod, and the tail end of the sleeve is integrally connected to the corner of the side of the first device plate, the lower half section of the first operating rod is vertically rotatably installed on the inner side of the first device plate, the top end of the first operating rod is connected with a first handle, a wheel shaft which is horizontally distributed is installed at the inner center of the first device plate, a horizontally distributed telescopic rod is installed on the front center line of the support plate, one end of the telescopic rod is fixedly connected with the surface of the side of the second device plate, a second supporting ring is arranged on the outer side of the second device plate, the center of the second device plate is rotatably connected with the second operating rod, the outer end of the second operating rod is connected with a second handle, and the outer surface of the second supporting ring is connected with the outer end of the second adjusting rod.

Preferably, the number of the first bevel teeth is two, the conical surfaces of the 2 first bevel teeth on the motor shaft are in the same direction, and the first bevel teeth are meshed with the first bevel teeth on the transverse shaft.

Preferably, the transverse shaft is rotatably arranged inside the cross beam, and the right end of the transverse shaft is connected with the vertical shaft through 2 meshed second conical teeth.

Preferably, the first supporting ring and the first adjusting rod are distributed in four equal angles relative to the center of the first device plate, and the opening of the 4 first supporting rings is distributed upwards.

Preferably, the wheel shaft is provided with a vertically distributed worm wheel, the side of the worm wheel is meshed with the worm, the worm is fixed on the first operating rod, and the wheel shaft is provided with a driving block.

Preferably, the driving block is of a square structure, the edge of the front face of the driving block is rotatably connected with one end of the connecting rod, the other end of the connecting rod is rotatably connected to the bottom end of the first adjusting rod, and the connecting rods are distributed at equal angles.

Preferably, the second supporting rings and the first supporting rings are horizontally and correspondingly distributed, and the opening of the 4 second supporting rings is distributed towards the outer side.

Preferably, the second adjusting rod is connected to the corner of the second device plate in a sliding mode through a spring, the tail end of the second adjusting rod extends into the arc-shaped groove, the arc-shaped groove is formed in the side surface of the guide plate in an equal angle mode, and the guide plate is vertically fixed to the second operating rod.

Compared with the prior art, the invention has the beneficial effects that: according to the adjusting and supporting structure for the steel bar wire binding operation, through the structural design of the first device plate and the second device plate, the steel bars can be stably supported and fixed from four corners, meanwhile, the motors of the multiple groups of first device plates can be used for driving rotation to facilitate efficient wire binding operation of workers, and the structural design is more reasonable;

1. the structural design of the second device plate is convenient for the second adjusting rod and the second supporting ring to synchronously extend and retract through the driving of the second operating rod, so that the reinforcing steel bar is tightly supported from the middle part of the reinforcing steel bar framework, and the phenomenon that the reinforcing steel bar bends downwards is avoided;

2. due to the design of the transverse shafts, the vertical shafts and the multiple groups of bevel gear structures, the operation of the motor is conveniently utilized to integrally rotate the multiple first device plates for supporting the reinforcing steel bars, and workers can conveniently perform wire binding operation on different nodes at different positions;

3. due to the structural design of the wheel shaft and the driving block, a user can conveniently adjust the positions of the first supporting ring and the first adjusting rod by rotating the first handle, stable placement of reinforcing steel bars is ensured, the self-locking mechanism formed by the worm and the gear can also avoid retraction of the positions of the supporting ring and the adjusting rod, and the whole subsequent framework can be conveniently taken out.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic side view of the present invention;

FIG. 3 is a schematic view of a top cross-sectional structure of the present invention;

FIG. 4 is a left side view of the motor shaft of the present invention;

FIG. 5 is a schematic diagram of a right side cross-sectional view of a first device board according to the present invention;

FIG. 6 is a right side cross-sectional view of a second device plate according to the present invention.

In the figure: 1. a mounting plate; 2. a first device board; 3. a rotating shaft; 4. erecting a beam; 5. a cross beam; 6. an electric motor; 7. a motor shaft; 8. a first bevel gear; 9. a horizontal axis; 10. a second taper tooth; 11. a vertical axis; 12. a third bevel gear; 13. a first ring; 14. a first operating lever; 15. a first adjusting lever; 16. a sleeve; 17. a first handle; 18. a wheel axle; 19. a worm gear; 20. a worm; 21. a drive block; 22. a connecting rod; 23. a telescopic rod; 24. a second device board; 25. a second ring; 26. a second operating lever; 27. a second adjusting lever; 28. a second handle; 29. a spring; 30. a guide plate; 31. an arc-shaped groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: an adjusting and supporting structure for steel bar wire binding operation comprises a support plate 1, a first device plate 2, a rotating shaft 3, a vertical beam 4, a cross beam 5, a motor 6, a motor shaft 7, a first bevel gear 8, a transverse shaft 9, a second bevel gear 10, a vertical shaft 11, a third bevel gear 12, a first supporting ring 13, a first operating rod 14, a first adjusting rod 15, a sleeve 16, a first handle 17, a wheel shaft 18, a worm wheel 19, a worm 20, a driving block 21, a connecting rod 22, a telescopic rod 23, a second device plate 24, a second supporting ring 25, a second operating rod 26, a second adjusting rod 27, a second handle 28, a spring 29, a guide plate 30 and an arc-shaped groove 31, wherein the first device plate 2 is arranged on the side of the support plate 1, the rotating shaft 3 is arranged in the center of the back of the first device plate 2, the rotating shaft 3 is rotatably connected to the top end of the vertical beam 4, the bottom end of the vertical beam 4 is fixed to the outer end of the cross beam 5, and the cross beam 5 is welded, the support plate 1 is provided with an electric motor 6, the electric motor 6 is connected with a motor shaft 7 which is horizontally distributed in the support plate 1, a first bevel gear 8 is arranged on the motor shaft 7, a vertical shaft 11 which is vertically distributed is rotatably arranged in the vertical beam 4, the top end of the vertical shaft 11 is connected with a rotating shaft 3 through 2 mutually meshed third bevel gears 12, a first operating rod 14 and a first supporting ring 13 are arranged on the outer side of the first device plate 2, the first supporting ring 13 is connected with a sleeve 16 through a first adjusting rod 15, the tail end of the sleeve 16 is integrally connected with the corner of the side of the first device plate 2, the lower half section of the first operating rod 14 is vertically rotatably arranged on the inner side of the first device plate 2, the top end of the first operating rod 14 is connected with a first handle 17, the inner center of the first device plate 2 is provided with a wheel shaft 18 which is horizontally distributed, a horizontally distributed telescopic rod 23 is arranged on the central line of the front surface of the support plate 1, one end of the telescopic rod 23 is fixedly connected with the lateral side surface of the second mounting plate 24, a second supporting ring 25 is arranged on the outer side of the second mounting plate 24, the center of the second mounting plate 24 is rotatably connected with a second operating rod 26, the outer end of the second operating rod 26 is connected with a second handle 28, and the outer surface of the second supporting ring 25 is connected with the outer end of a second adjusting rod 27.

Two first bevel gears 8 are arranged on a motor shaft 7, the conical surfaces of 2 first bevel gears 8 on the motor shaft 7 face in the same direction, the first bevel gears 8 are meshed with the first bevel gears 8 on a transverse shaft 9, the transverse shaft 9 is rotatably installed inside a transverse beam 5, the right end of the transverse shaft is connected with a vertical shaft 11 through 2 meshed second bevel gears 10, a motor 6 can correspondingly operate and drive the motor shaft 7 to be in a rotating state, the transverse shaft 9 can synchronously rotate in the transverse beam 5 under the meshing transmission action of the first bevel gears 8, and the vertical shaft 11 and the rotary shaft 3 can synchronously rotate under the meshing transmission action of the second bevel gears 10 and a third bevel gear 12, so that the first device plate 2 is driven to rotate together with a reinforcing steel bar, and workers can conveniently perform wire tying operation on connecting nodes at other positions.

The first supporting ring 13 and the first adjusting rod 15 are distributed with four equal angles about the center of the first device plate 2, the opening of the 4 first supporting rings 13 is distributed upward, the wheel shaft 18 is provided with a worm wheel 19 which is vertically distributed, the side of the worm wheel 19 is meshed with the worm 20, the worm 20 is fixed on the first operating rod 14, the wheel shaft 18 is provided with a driving block 21, the driving block 21 is in a square structure, the edge of the front surface of the driving block is rotatably connected with one end of a connecting rod 22, the other end of the connecting rod 22 is rotatably connected with the bottom end of the first adjusting rod 15, the connecting rod 22 is distributed with equal angles, the first handle 17 in figure 5 can be rotated, and the first operating rod 14 is driven to rotate synchronously, at the moment, the worm 20 in figure 5 can rotate synchronously, under the meshing transmission action of the worm wheel 20 and the worm wheel 19, the wheel shaft 18 can be driven to rotate synchronously in the first device plate 2, at this time, under the driving of the connecting rod 22, the first adjusting rod 15 will extend outwards by sliding inside the sleeve 16, and drive the first supporting ring 13 with the reinforcing steel bars to extend outwards synchronously.

The second supporting rings 25 and the first supporting rings 13 are horizontally and correspondingly distributed, the opening of the second supporting rings 25 is distributed towards the outside, the second adjusting rod 27 is connected at the corner of the second device plate 24 in a sliding way through a spring 29, the tail end of the second adjusting rod 27 extends into the arc-shaped groove 31, and the arc-shaped grooves 31 are opened on the side surface of the guide plate 30 at equal angles, while the guide plate 30 is vertically fixed to the second operating lever 26, the second handle 28 of fig. 1 is rotated to rotate the second operating lever 26 of fig. 6 synchronously, the second operating lever 26 is connected with the second device plate 24 through a damping bearing, the rotation of the second operating lever 26 drives the guide plate 30 of fig. 6 to rotate synchronously, therefore, under the guiding action of the arc-shaped groove 31 at the side of the guiding plate 30, the second adjusting rod 27 drives the second supporting ring 25 to synchronously extend outwards, so that the second supporting ring 25 can support the steel bar at the middle position tightly.

The working principle is as follows: under initial condition, telescopic link 23 is for shortening the state, and second device board 24 is located the position between first device board 2 and mounting panel 1, and the staff can place appointed quantity's bar hoop in advance on four appointed reinforcing bars, later erects the reinforcing bar whole in the device main part again, and the mode of erection is as follows:

the first mounting plate 2 and the first support rings 13 at the outer sides thereof are horizontally and correspondingly provided with two sets, so that workers can place four steel bars on the horizontally corresponding first support rings 13 one by one, at the moment, the steel bar hoops are hung on the steel bars, and the centers of the steel bars naturally droop under the action of the gravity of the steel bars and the first support rings 13, at the moment, a user can rotate the first handle 17 in fig. 5 and drive the first operating rod 14 to synchronously rotate, at the moment, the worm 20 in fig. 5 can synchronously rotate, under the meshing transmission action of the worm 20 and the worm wheel 19, the worm wheel 19 can drive the wheel shaft 18 to synchronously rotate in the first mounting plate 2, at the moment, under the drive of the connecting rod 22, the first adjusting rod 15 can extend outwards in a sliding manner in the sleeve 16 and drive the first support rings 13 with the steel bars to synchronously extend outwards, at the moment, under the limiting action of the steel bar hoops, the steel bars at the two side positions are braced to, the reinforcing steel bars can be automatically clamped at four inner corners of the reinforcing steel bar hoop, the clamping force of the reinforcing steel bar hoop and the external supporting acting force of the supporting rings can enable two ends of the reinforcing steel bars to keep a tight and stable state, then a user can adjust the length of the telescopic rod 23 in fig. 1 and 6, the second device plate 24 is located at the middle position of the four reinforcing steel bars, the second handle 28 in fig. 1 can be rotated, the second operating rod 26 in fig. 6 is driven to synchronously rotate, the second operating rod 26 is connected with the second device plate 24 through a damping bearing, the guide plate 30 in fig. 6 can be driven to synchronously rotate by the rotation of the second operating rod 26, therefore, under the guiding action of the arc-shaped groove 31 at the side of the guide plate 30, the second adjusting rod 27 can drive the second supporting ring 25 to synchronously extend outwards, and the second supporting ring 25 can support the reinforcing steel bars at the middle position;

after the above operations are completed, the distribution state of the steel bars is as shown by a dotted line in fig. 1, the wire binding operation can be started, after the wire binding of the steel bar hoop and the steel bar contact node far away from one side of the support plate 1 is completed, a user can reversely rotate the second handle 28 to separate the second supporting ring 25 from the steel bars, and correspondingly retract the telescopic rod 23, so that the motor 6 can correspondingly operate and drive the motor shaft 7 to be in a rotating state, under the meshing transmission action of the first bevel gear 8, the transverse shaft 9 can synchronously rotate in the transverse beam 5, and under the meshing transmission action of the second bevel gear 10 and the third bevel gear 12, the vertical shaft 11 and the rotating shaft 3 can synchronously rotate, so that the first device plate 2 is driven to rotate together with the steel bars, and the wire binding operation of connecting nodes at other positions is facilitated for workers.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides an adjust bearing structure for operation is pricked to reinforcing bar, includes mounting panel (1) and telescopic link (23), its characterized in that: the device is characterized in that a first device plate (2) is arranged on the side of the support plate (1), a rotating shaft (3) is installed at the center of the back of the first device plate (2), the rotating shaft (3) is rotatably connected to the top end of a vertical beam (4), the bottom end of the vertical beam (4) is fixed to the outer end of a cross beam (5), the inner end of the cross beam (5) is fixedly welded to the surface of the support plate (1), a motor (6) is installed on the support plate (1), the motor (6) is connected with a motor shaft (7) which is horizontally distributed in the support plate (1), a first conical tooth (8) is installed on the motor shaft (7), a vertical shaft (11) which is vertically distributed is rotatably installed in the vertical beam (4), the top end of the vertical shaft (11) is connected with the rotating shaft (3) through 2 third conical teeth (12) which are meshed with each other, a first operating rod (14) and a first supporting ring (13) are arranged on the outer side of the first device plate (2), the first supporting ring (13) is connected with the sleeve (16) through a first adjusting rod (15), the tail end of the sleeve (16) is integrally connected with the corner of the edge side of the first device plate (2), the lower half section of the first operating rod (14) is vertically and rotatably installed on the edge side of the interior of the first device plate (2), the top end of the first operating rod (14) is connected with a first handle (17), the center of the interior of the first device plate (2) is provided with a wheel shaft (18) which is horizontally distributed, a horizontally distributed telescopic rod (23) is installed on the center line of the front face of the support plate (1), one end of the telescopic rod (23) is fixedly connected with the surface of the edge side of the second device plate (24), the outer side of the second device plate (24) is provided with a second supporting ring (25), and the center of the second device plate (24) is rotatably connected with a second operating rod (26), and the outer end of the second operating rod (26) is connected with a second handle (28), and the outer surface of the second supporting ring (25) is connected with the outer end of the second adjusting rod (27).

2. An adjustable support structure for a rebar tying operation as claimed in claim 1, wherein: two first bevel gears (8) are arranged on the motor shaft (7), the conical surfaces of the 2 first bevel gears (8) on the motor shaft (7) face in the same direction, and the first bevel gears (8) are meshed with the first bevel gears (8) on the transverse shaft (9).

3. An adjustable support structure for a rebar tying operation as claimed in claim 2, wherein: the transverse shaft (9) is rotatably arranged in the transverse beam (5), and the right end of the transverse shaft is connected with the vertical shaft (11) through 2 meshed second conical teeth (10).

4. An adjustable support structure for a rebar tying operation as claimed in claim 1, wherein: the first supporting rings (13) and the first adjusting rods (15) are distributed in four equal angles relative to the center of the first device plate (2), and the opening of the first supporting rings (13) is distributed upwards.

5. An adjustable support structure for a rebar tying operation as claimed in claim 1, wherein: the wheel shaft (18) is provided with a worm wheel (19) which is vertically distributed, the side of the worm wheel (19) is meshed with a worm (20), the worm (20) is fixed on the first operating rod (14), and meanwhile, the wheel shaft (18) is provided with a driving block (21).

6. An adjustable support structure for a rebar tying operation as claimed in claim 1, wherein: the driving block (21) is of a square structure, the edge of the front face of the driving block is rotatably connected with one end of the connecting rod (22), the other end of the connecting rod (22) is rotatably connected to the bottom end of the first adjusting rod (15), and the connecting rod (22) is distributed at equal angles.

7. An adjustable support structure for a rebar tying operation as claimed in claim 1, wherein: the second supporting rings (25) and the first supporting rings (13) are horizontally and correspondingly distributed, and the opening parts of the 4 second supporting rings (25) are distributed towards the outer side.

8. An adjustable support structure for a rebar tying operation as claimed in claim 1, wherein: the second adjusting rod (27) is connected to the corner of the second device plate (24) in a sliding mode through a spring (29), the tail end of the second adjusting rod (27) extends into the arc-shaped groove (31), the arc-shaped groove (31) is formed in the side surface of the guide plate (30) in an equal angle mode, and meanwhile the guide plate (30) is vertically fixed to the second operating rod (26).

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