CN216757750U - Pipe bending machine - Google Patents

Abstract

The utility model discloses a pipe bending machine which comprises a pushing component and a bent pipe component, wherein the pushing component is provided with a clamp capable of linearly moving in a reciprocating manner on a straight path, the bent pipe component is positioned in the moving direction of the clamp, the pipe bending machine is provided with a feeding component, the feeding component comprises a lifting translation carrying assembly and a stepping type conveying assembly, the lifting translation carrying assembly is provided with a gas claw, and the stepping type conveying assembly comprises a grouped conveying unit, a single conveying unit, a transverse translation unit and a rack. The pipe bender realizes replacing a manual mode to carry out automatic feeding operation by configuring a feeding function, reduces the labor intensity of personnel, improves the operation safety and improves the working efficiency of feeding operation.

Description

Pipe bending machine

Technical Field

The utility model relates to a pipe bender.

Background

In the field of industrial manufacturing, more and more process steps are performed by machines instead of by human beings, which are basically capable of being semi-automated. This is inseparable from the policy guidance of robot replacement in recent years, and has accelerated and deepened industrialization as a whole. The oil pipe production industry used on the diesel engine belongs to labor intensive industry, and the production process has multiple process steps and high labor intensity. Particularly, the bending operation of the straight semi-finished oil pipe has high labor intensity and high operation precision requirement, so that the working efficiency of the pipe bending operation is extremely low under the condition of completely manual operation. At present, full-automatic pipe bending operation is realized through a numerical control pipe bending machine, only manual operation for loading and unloading is needed, and other operations for bending pipe materials are completed on the pipe bending machine. From the whole production process, although the pipe bender solves the automation problem of the pipe bending step, the step of mounting the pipe to be processed on the pipe bender is still not automated. In the feeding stage, the distance between workers and equipment is very close, certain potential safety hazards exist, and particularly, the risk that the workers are injured cannot be avoided under the condition of misoperation. Therefore, the problems of high labor intensity and high potential safety hazard exist in the feeding ring section in the existing production process.

Disclosure of Invention

The utility model aims to solve the technical problem of how to finish feeding the pipe bender by automatic equipment, thereby obtaining the pipe bender matched with the feeding function.

In order to solve the technical problems, the utility model adopts the following technical scheme: the pipe bender comprises a pushing component and a pipe bending component, wherein the pushing component is provided with a clamp capable of performing reciprocating linear motion on a straight path, the pipe bending component is positioned in the motion direction of the clamp, the pipe bender is provided with a feeding component, the feeding component comprises a lifting translation carrying component and a stepping conveying component, the lifting translation carrying component is provided with a gas claw, the stepping conveying component comprises a grouped conveying unit, a single conveying unit, a transverse translation unit and a rack, the transverse translation unit comprises a support plate I and a translation cylinder, the support plate I is movably arranged on the rack through a guide rail, the translation cylinder is arranged on the rack, a piston rod of the translation cylinder is connected with the support plate I, the translation cylinder drives the support plate I to perform linear reciprocating motion in the horizontal direction on the rack, at least two support plates I which are distributed in parallel are arranged on the rack, be equipped with equidistant distribution's recess I and equidistant distribution's recess II on backup pad I, equidistant distribution's recess I and equidistant distribution's recess II distribute in succession in backup pad I, conveying unit includes backup pad II, lifting cylinder I in groups, lifting cylinder I is installed in the frame, backup pad II is installed on lifting cylinder I's piston rod and lifting cylinder I drive backup pad II straight reciprocating motion in vertical direction, be equipped with two parallel distribution's backup pad II in the frame, backup pad I is on a parallel with backup pad II, backup pad II all is located between backup pad I and backup pad II is located between the position that is equipped with recess I in the backup pad I, be equipped with equidistant distribution's recess III on backup pad II, the cross section of recess III and the cross section of recess I all are triangle-shaped isosceles, single conveying unit includes that backup pad III isosceles, The lifting cylinder II is installed on a rack, the support plate III is installed on a piston rod of the lifting cylinder II and drives the support plate III to do linear reciprocating motion in the vertical direction, two support plates III which are distributed in parallel are arranged on the rack, the support plate I is parallel to the support plate III, the support plate III is located between the support plates I, the support plate III is located between the positions, provided with the grooves II, of the support plate I, grooves IV which are distributed at equal intervals are arranged on the support plate III, the cross sections of the grooves IV and the cross sections of the grooves II are right-angled triangles, the opening width of the grooves I, the opening width of the grooves II, the opening width of the grooves III and the opening width of the grooves IV are the same, the interval of the grooves III on the support plate II is the same as that of the grooves I on the support plate I, and the interval of the grooves IV on the support plate III is the same as that of the grooves II on the support plate I, the pneumatic claw is characterized in that the grooves I and the grooves III are arranged in a matrix mode, the grooves II and the grooves IV are arranged in a staggered mode, and the moving range of the pneumatic claw extends into the area between the grooves II and the front of the clamp.

The pushing component is positioned in the conveying direction of the conveying component, and the conveying component is used for storing the pipe materials and outputting the pipe materials in a single mode. The tube materials are conveyed above the position of the grouped conveying units in a grouped manner on the stepping conveying assembly in a stepping movement manner, and when the grouped tube materials are conveyed above the position of the single conveying unit, the tube materials are close to the air claw in a one-by-one manner and are taken away by the air claw. The pneumatic claw on the lifting translation carrying assembly finally places the pipe material on the pushing component to complete the feeding operation. In the technical scheme, the materials are conveyed in groups and then conveyed in single piece, so that the energy consumption can be reduced, the key point is that the requirement on the working precision of the lifting translation carrying assembly can be reduced, and the lifting translation carrying assembly can participate in the work only by keeping a few extreme positions; the problem that the air claw clamps the pipe materials at positions which are far away from the material loading position one by one, and a plurality of air claw stop positions are needed to be arranged is solved, and the problem of software programming and structural design is solved. After the pipe materials all enter towards a fixed position one by one, the gas claw only needs to stop at a fixed position, and the feeding station is set to be at another stop position, so that the structure and the procedure can be simplified, and the lifting translation carrying assembly can be ensured to stably and reliably operate for a long time.

The storage function of step-by-step conveying component concentrates and is embodied in the position department that is equipped with recess I in the backup pad I above the position of conveying unit place in groups, and the function of step-by-step conveying component's with single mode output pipe material concentrates and is embodied in the position department that is equipped with recess II in the backup pad I above single conveying unit position. When the occupation ratio of the storage function and the function of outputting the pipes in a single mode in the stepping type conveying assembly is comprehensively measured, the time of a worker contacting the pipe bender in the feeding stage is greatly reduced and the energy consumption required by the work of the stepping type conveying assembly is obviously reduced after the storage function is strengthened on the premise of keeping the function of outputting the pipes in the single mode. From this, the length that is equipped with the position of recess I in this technical scheme the backup pad I is greater than the length that is equipped with the position of recess II in the backup pad I. This strengthens the memory function. In order to better identify the output position of the pipe material and increase the convenience degree in the adjustment process, the width of one groove II adjacent to the groove I is larger than the widths of other grooves II, the number of the grooves I is integral multiple of the number of the grooves II, and therefore the debugging work of grouped conveying operation and the debugging work of pipe material clamping operation by the gas claw can be carried out under the condition that the naked eyes can distinguish.

In the technical scheme, the lifting and translating carrying assembly has the capability of carrying in a three-dimensional space, and specifically comprises a longitudinal translating unit, a lifting and translating linear unit, a transverse translating unit and an air claw, wherein the transverse translating unit is mounted on the longitudinal translating unit and drives the transverse translating unit to do linear reciprocating motion in the horizontal direction, the lifting and translating linear unit is mounted on the transverse translating unit and drives the lifting and translating linear unit to do linear reciprocating motion in the horizontal direction, the air claw is mounted on the lifting and translating linear unit and drives the air claw to do linear reciprocating motion in the vertical direction, the direction of the linear reciprocating motion of the air claw on the lifting and translating linear unit is perpendicular to the direction of the linear reciprocating motion of the lifting and translating linear unit on the transverse translating unit, and the direction of the linear reciprocating motion of the lifting and translating unit on the transverse translating unit, The direction of the linear reciprocating motion of the pneumatic claw on the lifting linear unit is perpendicular to the direction of the linear reciprocating motion of the transverse translation unit on the longitudinal translation unit. By adopting the structure, the length of the conveying path can be reduced, and the pipe material transfer can be completed by the shortest conveying path; in addition, higher working efficiency can be obtained based on a shorter conveying path, and the efficiency of the feeding operation is promoted to be further improved.

The utility model adopts the technical scheme that: the pipe bender realizes replacing manual mode to carry out automatic feeding operation through configuration material loading function, reduces personnel intensity of labour, improves the security of operation, improves the work efficiency of material loading operation.

Drawings

The present invention will be described in more detail with reference to the accompanying drawings and embodiments.

FIG. 1 is a perspective view of a pipe bender according to the present invention;

FIG. 2 is a schematic view of a step-by-step delivery assembly of a bending machine of the present invention;

FIG. 3 is a schematic view of a step-by-step delivery assembly of the bending machine of the present invention;

FIG. 4 is a schematic view of a step-by-step delivery assembly of a bending machine according to the present invention;

FIG. 5 is a schematic view of a step-by-step delivery assembly IV of a bending machine according to the present invention;

FIG. 6 is a schematic view of a step-by-step conveyor assembly of the bending machine of the present invention;

FIG. 7 is a schematic view VI of the step-by-step delivery assembly of the bending machine of the present invention;

fig. 8 is a schematic diagram vii of the operation of the step-by-step conveying assembly of the pipe bender of the present invention.

Detailed Description

As shown in fig. 1, the tube bender is provided with a pushing member 1, a bending member 2 and a feeding member.

The feeding part is used for outputting pipe materials to the pushing part 1 one by one. The pushing member 1 is provided with a jig which is linearly movable to and fro in a straight path, the bent pipe member 2 is located in the moving direction of the jig, and the jig grips the pipe material and places the pipe material in the bent pipe member 2. The pipe bending unit 2 is used for bending a pipe material to bend the pipe material into a desired configuration.

The feeding means comprise a lifting-translating handling assembly 3 and a step-by-step conveyor assembly 4.

The lifting translation carrying assembly 3 comprises a longitudinal translation unit, a lifting linear unit, a transverse translation unit and an air claw.

The longitudinal translation unit comprises a base I, an objective table I and a cylinder. I fixed mounting of base is on propelling movement part 1, and objective table I passes through the guide rail and installs at I top of base with the sliding mode, and objective table I can be linear sliding motion on base I. The cylinder body fixed mounting of cylinder is on base I, and the piston rod and the I connection of objective table of cylinder can drive I motion of objective table after the piston rod of cylinder is flexible. The moving direction of the objective table I on the base I is the horizontal direction and the moving direction is parallel to the conveying direction of the stepping conveying assembly 4, and the objective table I can be driven to do linear reciprocating motion after a piston rod of the air cylinder stretches out and draws back.

The transverse translation unit comprises a base II, an objective table II and a motor. And the base II is fixedly arranged on the objective table I of the longitudinal translation unit. The objective table II with a horizontal translation sheet is installed at the top of the base II in a sliding mode through a guide rail, and the objective table II can do linear sliding motion on the base II. The motor is fixedly installed on the base II, a gear is arranged on an output shaft of the motor, a rack is arranged on the objective table II, the gear is meshed with the rack, and the motor can drive the objective table II to move after being started. The moving direction of the objective table II on the base II is the horizontal direction, and the objective table II can be driven to do linear reciprocating motion after the motor rotates forwards and backwards.

The lifting linear unit comprises an objective table III and a motor, the objective table III is installed on the objective table II in a sliding mode through a guide rail, the motor is fixedly installed on the objective table II, a gear is arranged on an output shaft of the motor, a rack is arranged on the objective table III, the gear is meshed with the rack, and the motor can drive the objective table III to move after being started. The moving direction of the objective table III on the objective table II is vertical, and the objective table III can be driven to do linear reciprocating motion after the motor rotates forwards and backwards. The gas claw is fixedly arranged on the object stage III.

The longitudinal translation unit can drive the transverse translation unit to do linear reciprocating motion in the horizontal direction, and the horizontal motion direction is marked as X. The transverse translation unit can drive the lifting linear unit to do linear reciprocating motion in the horizontal direction, and the horizontal motion direction is marked as Z. The lifting linear unit drives the air claw to do linear reciprocating motion in the vertical direction, and the vertical motion direction is marked as Y. The movement direction X is vertical to the movement direction Z; the motion direction X and the motion direction Z are both horizontal directions, so the motion directions are both vertical to the motion direction Y, namely the linear reciprocating motion direction of the lifting linear unit on the transverse translation unit and the linear reciprocating motion direction of the gas claw on the lifting linear unit are both vertical to the linear reciprocating motion direction of the transverse translation unit on the longitudinal translation unit. Therefore, the air claw can move in a three-dimensional space under the common drive of the longitudinal translation unit, the lifting linear unit and the transverse translation unit. The moving range of the air claw can extend into the front of the clamp so as to assemble the pipe materials on the clamp to the pushing component 1.

The step-by-step conveying assembly 4 comprises a group conveying unit, a single conveying unit, a transverse translation unit and a rack. The group conveying unit, the single conveying unit and the transverse translation unit are all arranged on the frame.

Horizontal translation unit includes backup pad I5 and translation cylinder 6, and backup pad I5 passes through guide rail movable mounting in the frame, and translation cylinder 6's cylinder body fixed mounting is in the frame, and translation cylinder 6's piston rod is connected with backup pad I5 and translation cylinder 6 drive backup pad I5 is the straight reciprocating motion on the horizontal direction in the frame. Two parallel supporting plates I5 are arranged on the frame, and each supporting plate I5 is provided with a corresponding translation cylinder 6; the two supporting plates I5 synchronously move in the same direction. The length of the support plate I5 is long, and the pushing component 1 extends along the length of the support plate I5. Be equipped with equidistant distribution's recess I7 and equidistant distribution's recess II 8 on backup pad I5, recess I7 continuous distribution is in the partly of backup pad I5, recess II 8 continuous distribution is in the other part of backup pad I5, so equidistant distribution's recess I7 and equidistant distribution's recess II 8 continuous distribution on backup pad I5. Wherein, the opening width of one groove II 8 next to the groove I7 is larger than the width of the other grooves II 8. As shown in fig. 2, in the initial state, the translation cylinder 6 is contracted, and the support plate i 5 is located on the side away from the pushing member 1.

Conveying unit in groups includes backup pad II 9, lifting cylinder I10. The cylinder body of lifting cylinder I10 is installed in the frame, and I10 drive backup pad II 9 of lifting cylinder II 9 and straight reciprocating motion in vertical direction is still equipped with the guide pillar on II 9 of backup pad to the piston rod of installing in lifting cylinder I10, guide pin bushing sliding connection and play the guide effect in guide pillar and the frame. Be equipped with two parallel distribution's backup pad II 9 in the frame, backup pad I5 is on a parallel with backup pad II 9, and two backup pads II 9 all are located between backup pad I5 and backup pad II 9 is located and is equipped with between the position of recess I7 on backup pad I5. Be equipped with equidistant distribution's recess III 11 on backup pad II 9, the cross section of recess III 11 and the cross section of recess I7 all are isosceles triangle. As shown in FIG. 2, the lifting cylinder I10 is contracted in the initial state, and the height of the support plate II 9 is smaller than that of the support plate I5.

The single conveying unit comprises a supporting plate III 12 and a lifting air cylinder II 13. The cylinder body of lifting cylinder II 13 is installed in the frame, and supporting plate III 12 is installed on the piston rod of lifting cylinder II 13 and lifting cylinder II 13 drive supporting plate III 12 is at the straight reciprocating motion of vertical direction, still is equipped with the guide pillar on supporting plate III 12, guide pin bushing sliding connection in guide pillar and the frame and play the guide effect. Be equipped with two parallel distribution's backup pad III 12 in the frame, backup pad I5 is on a parallel with backup pad III 12, and backup pad III 12 all is located between backup pad I5 and between the position that III 8 of recess were equipped with in backup pad I5 to backup pad III 12 is located the backup pad. Grooves IV 14 distributed at equal intervals are formed in the supporting plate III 12, and the cross sections of the grooves IV 14 and the cross sections of the grooves II 8 are right-angled triangles. The opening width of the groove I7, the opening width of the groove II 8, the opening width of the groove III 11 and the opening width of the groove IV 14 are the same; the interval of the groove III 11 on the support plate II 9 is the same as the interval of the groove I7 on the support plate I5, and the interval of the groove IV 14 on the support plate III 12 is the same as the interval of the groove II 8 on the support plate I5. As shown in fig. 2, the lifting cylinder ii 13 is contracted in the initial state, and the height of the support plate iii 12 is smaller than that of the support plate i 5.

The grooves I7 and the grooves III 11 are arranged in a matrix mode, so that the pipe materials can be embedded into the grooves I7 and the grooves III 11 at the same time; the grooves II 8 and the grooves IV 14 are arranged in a staggered mode, the bottom of any one groove II 8 is opposite to the position between the bottoms of the two adjacent grooves IV 14, and the pipe can only fall into one of the grooves II 8 and the grooves IV 14. The range of motion of the gas claw can extend into the area between the grooves II 8 at the end of the support plate I5.

The length that is equipped with the position of recess I7 on backup pad I5 is greater than the length that is equipped with the position of recess II 8 on backup pad I5, and this just makes backup pad I5 can place many pipes in recess I7. In addition, the number of the grooves I7 is integral multiple of the number of the grooves II 8, and the number of the grooves IV 14 and the number of the grooves III 11 are the same as the number of the grooves II 8.

As shown in figure 2, when in use, pipe materials are placed on the support plate I5, the pipe materials are straight, and two ends of each pipe material are embedded into two grooves I7 in the horizontal direction; then, the translation cylinder 6 extends to push the support plate i 5 to move towards the position of the pushing component 1, so that the spatial position of the tube material is changed and is closer to the position of the pushing component 1, as shown in fig. 3. A lifting cylinder I10 on the grouped conveying unit lifts the supporting plate II 9 until the pipe materials are embedded into the groove III 11 and break away from the supporting plate I5. At the same time, the individual conveyor units are also brought into operation, moving synchronously with the group of conveyor units, as shown in fig. 4. The supporting plate iii 12 of the single conveying unit is driven to ascend by the elevating cylinder ii 13. The tip part between the two grooves IV 14 extends into the bottom of the groove I7, the cross section of the pipe material is circular, the tip part between the two grooves IV 14 supports one side of the bottom of the pipe material and deviates from the bottommost part, the pipe material slides into the groove IV 14 along the direction of the position of the pushing component 1 by means of the self gravity of the pipe material, and then the pipe material is separated from the support plate I5 and is positioned on the support plate III 12.

As shown in fig. 5, the translation cylinder 6 of the transverse translation unit is contracted, and the support plate i 5 is restored to the initial state; then, the lifting cylinder I10 puts down the support plate II 9 until the pipe material returns to the groove I7, and the pipe material is separated from the support plate II 9 and returns to the initial state; meanwhile, the part of the supporting plate I5 provided with the groove II 8 is just positioned below the supporting plate III 12, the pointed part between the two grooves II 8 supports one side of the bottom of the pipe material after the supporting plate III 12 descends, deviates from the bottommost part, and slides into the groove II 8 along the direction of the position of the pushing component 1 by means of the self gravity of the pipe material, so that the pipe material is separated from the supporting plate III 12 and is positioned in the groove II 8 of the supporting plate I5. At this time, as shown in fig. 6, the relative position of the tube material on the support plate i 5 has changed to become closer to the position of the pushing member 1. In the process, a plurality of pipes are conveyed to move forwards to form a group, and a plurality of pipes can be conveyed in groups in each stepping movement. At this time, when exactly one pipe is placed in the groove II 8 at the end of the support plate I5, the air claw moves to the position and grabs the pipe to be sent to the position of the clamp.

After conveying unit in groups transferred into many pipes to II 8 of recess of backup pad I5, conveying unit in groups can not transfer the pipe into II 8 of recess before the pipe material in II 8 of recess is not totally exported. Then entering the stage of conveying the pipe materials one by a single conveying unit. As shown in fig. 7, the pipe material enters the groove ii 8, the rear support plate i 5 is located at a position close to the pushing component 1, the groove ii 8 and the groove iv 14 are in a staggered position, and the support plate iii 12 of a single conveying unit is driven by the lifting cylinder ii 13 to move up and down. After the supporting plate III 12 rises, the pointed part between the two grooves IV 14 extends into the bottom of the groove II 8, the cross section of the pipe material is circular, the pointed part between the two grooves IV 14 supports one side of the bottom of the pipe material and deviates from the bottommost part, the pipe material slides into the groove IV 14 along the direction of the position of the pushing component 1 by means of the self gravity of the pipe material, and then the pipe material is separated from the supporting plate I5 and is positioned on the supporting plate III 12. As shown in figure 8, when the supporting plate III 12 descends, the sharp part between the two grooves II 8 supports one side of the bottom of the pipe material and deviates from the bottommost part, and the pipe material slides into the groove II 8 along the direction of the position of the pushing component 1 by the self-gravity of the pipe material, so that the pipe material is separated from the supporting plate III 12 and is positioned on the supporting plate I5. After the above operation, the tube material advances by the width of the groove II 8. The supporting plate III 12 drives the pipe materials in the groove II 8 to synchronously advance by the width of the groove II 8 in the lifting process. When the pipe material was arranged in the recess II 8 that is located the tip of backup pad I5, the gas claw moved this moment and snatched the pipe material and send the anchor clamps position to, transfer the pipe material to recess II 8 in groups after accomplishing the automatic feeding operation of the pipe material that is in recess II 8.

Claims (3)

1. A pipe bender, including propelling movement part (1), elbow subassembly (2), propelling movement part (1) is equipped with the anchor clamps of reciprocal linear motion on straight path, elbow subassembly (2) are located the direction of motion of anchor clamps, its characterized in that: the pipe bender is provided with a feeding part, the feeding part comprises a lifting and translation carrying assembly (3) and a stepping type conveying assembly (4), a gas claw is arranged on the lifting and translation carrying assembly (3), the stepping type conveying assembly (4) comprises a grouped conveying unit, a single conveying unit, a transverse translation unit and a rack, the transverse translation unit comprises a support plate I (5) and a translation cylinder (6), the support plate I (5) is movably installed on the rack through a guide rail, the translation cylinder (6) is installed on the rack, a piston rod of the translation cylinder (6) is connected with the support plate I (5) and the translation cylinder (6) drives the support plate I (5) to do linear reciprocating motion in the horizontal direction on the rack, at least two support plates I (5) which are distributed in parallel are arranged on the rack, grooves I (7) which are distributed at equal intervals and grooves II (8) which are distributed at equal intervals are arranged on the support plate I (5), the conveying unit comprises a supporting plate I (5), a group of conveying units and lifting cylinders I (10), wherein the supporting plate I (7) and the grooves II (8) are distributed at equal intervals and continuously distributed on the supporting plate I (5), the group of conveying units comprises a supporting plate II (9) and a lifting cylinder I (10), the lifting cylinder I (10) is installed on a rack, the supporting plate II (9) is installed on a piston rod of the lifting cylinder I (10) and drives the supporting plate II (9) to do linear reciprocating motion in the vertical direction, the rack is provided with two supporting plates II (9) distributed in parallel, the supporting plate I (5) is parallel to the supporting plate II (9), the supporting plates II (9) are located between the supporting plates I (5), the supporting plates II (9) are located between positions of the grooves I (7) on the supporting plate I (5), the supporting plates II (9) are provided with grooves III (11) distributed at equal intervals, the cross section of the groove III (11) and the cross section of the groove I (7) are all isosceles triangles, the single conveying unit comprises a support plate III (12) and a lifting cylinder II (13), the lifting cylinder II (13) is installed on a rack, the support plate III (12) is installed on a piston rod of the lifting cylinder II (13) and drives the support plate III (12) to do linear reciprocating motion in the vertical direction, the rack is provided with two support plates III (12) which are distributed in parallel, the support plate I (5) is parallel to the support plate III (12), the support plate III (12) is located between the support plates I (5), the support plate III (12) is located between the positions of the grooves II (8) on the support plate I (5), the support plate III (12) is provided with grooves IV (14) which are distributed at equal intervals, the cross section of the groove IV (14) and the cross section of the groove II (8) are all right-angled triangles, the opening width of recess I (7), the opening width of recess II (8), the opening width of recess III (11), the opening width of recess IV (14) all the same, the interval of recess I (7) on recess III (11) on backup pad II (9) is the same with backup pad I (5), the interval of recess IV (14) on backup pad III (12) is the same with the interval of recess II (8) on backup pad I (5), matrix arrangement between recess I (7) and recess III (11), staggered arrangement between recess II (8) and recess IV (14), the motion range of gas claw stretches into the place ahead of regional and anchor clamps between recess II (8).

2. The bender according to claim 1, wherein: the length of the position of being equipped with recess I (7) on backup pad I (5) is greater than the length of the position of being equipped with recess II (8) on backup pad I (5), and the width of recess II (8) adjacent with recess I (7) is greater than the width of other recess II (8), and the quantity of recess I (7) is the integral multiple of the quantity of recess II (8).

3. The bender according to claim 1, wherein: the lifting translation carrying assembly (3) comprises a longitudinal translation unit, a lifting linear unit, a transverse translation unit and an air claw, wherein the transverse translation unit is installed on the longitudinal translation unit and drives the transverse translation unit to do linear reciprocating motion in the horizontal direction, the lifting linear unit is installed on the transverse translation unit and drives the lifting linear unit to do linear reciprocating motion in the horizontal direction, the air claw is installed on the lifting linear unit and drives the air claw to do linear reciprocating motion in the vertical direction, the direction of the linear reciprocating motion of the air claw on the lifting linear unit is perpendicular to the direction of the linear reciprocating motion of the lifting linear unit on the transverse translation unit, and the directions of the linear reciprocating motion of the lifting linear unit on the transverse translation unit and the linear reciprocating motion of the air claw on the lifting linear unit are perpendicular to the directions of the linear reciprocating motion of the transverse translation unit on the longitudinal translation unit The direction of linear reciprocating motion.

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