CN113148606A

CN113148606A - Axle housing centering tilting mechanism

Info

Publication number: CN113148606A
Application number: CN202110231290.0A
Authority: CN
Inventors: 易春红; 吴云辉; 陶连松; 方强斌
Original assignee: Hangzhou Wheeler General Machinery Co ltd
Current assignee: Hangzhou Wheeler General Machinery Co ltd
Priority date: 2021-03-02
Filing date: 2021-03-02
Publication date: 2021-07-23

Abstract

The invention discloses an axle housing centering turnover mechanism which comprises a lifting part, a rotating part and a limiting part, wherein the lifting part is positioned below the whole body, the rotating part is arranged on the left side and the right side of the lifting part, the limiting part is arranged on one side of the rotating part, a workpiece is arranged between the limiting parts, a chain conveyor is arranged behind the rotating part, the compatible specification of the turnover mechanism can be correspondingly adjusted according to the specification type, the adjustment is convenient and rapid, and the space is reasonably optimized; the upset is simple, and the adjustment is simple, and rotation angle is accurate controllable, and the upset is efficient, and space utilization is showing and is improving, and very big reduction unnecessary space is extravagant, and the frame that overturns in the past accounts for the very big compression in space, only needs a product to promote the space and can overturn after improving, and the current technology of very big improvement is overturned in middle gesture, optimizes the production beat, improves production efficiency.

Description

Axle housing centering tilting mechanism

Technical Field

The invention relates to the technical field of automobiles, in particular to an axle housing centering and overturning mechanism which is applied to the requirements of the next processing procedure on the posture after the axle housing of a heavy truck is punched and formed, and the shell needs to be overturned and the posture needs to be changed.

Background

The upset technique of adoption on the existing market is with both sides arm, respectively has two cylinders to embrace to press from both sides above the arm, and the arm is fixed in the upset transmission shaft in the upset frame, and the motor drives the upset transmission shaft upset, and the upset occupation space is big, and the upset is inefficient, and the upset needs the very much time of cost moreover. In view of the defects in the prior art, the inventor feels that the axle housing is not perfect, and the axle housing centering and overturning mechanism is researched and overcome by paying attention to the inventor, so that the axle housing centering and overturning mechanism is researched and overcome by working experience of the axle housing centering and overturning mechanism for many years, the arms on two sides are clamped by the air cylinders, the axle housing centering and overturning mechanism is limited angularly, the whole axle housing centering and overturning mechanism is lifted by the air cylinders, the air cylinders push the racks, and the racks drive the gears to rotate, so that the whole clamping tool is driven to rotate.

The mechanism adopts a lifting mode, reduces the limitation of transverse overturning space, realizes the posture conversion by using smaller space, obviously improves the overturning efficiency, greatly reduces the overturning time, improves the production capacity, has wide range of compatible workpiece products, good compatibility and good universality, can adjust the overturning angle and can realize accurate overturning posture.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention discloses an axle housing centering and overturning mechanism which is realized by adopting the following technical scheme.

In the description of the present invention, it should be noted that the terms "inside", "below", "upper" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention usually place when using, and are only used for convenience of description and simplification of description, but do not indicate or imply that the devices or elements indicated must have a specific orientation, be constructed in a specific orientation or be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

The utility model provides an axle housing centering tilting mechanism, includes promotion portion, rotating part, spacing portion, promotion portion is located holistic below, the left and right sides of promotion portion is the rotating part, one side of rotating part is equipped with spacing portion, be equipped with the work piece between the spacing portion, the rear of rotating part is equipped with chain conveyor.

As a further improvement of the technology, the lifting part comprises a lifting cylinder, a stand column, a lifting beam and a limiting structure, the lifting cylinder is fixed on the beam through bolts, the beam is fixed on the stand column on two sides through bolts, the beam and the lifting cylinder are connected through a floating joint, the stand column is fixedly connected with a sliding rail through bolts, a sliding block is fixed on the beam, the sliding block is connected with the sliding rail in a sliding manner, and the cylinder and the beam are connected with each other.

As a further improvement of the technology, the rotating part further comprises a clamping structure and a rotating structure, the clamping structure further comprises a clamping cylinder, a sliding block, a guide rail, a first rotating installation seat, a second rotating installation seat, a clamping cylinder installation seat and a floating joint, the clamping cylinder is fixed on the clamping cylinder installation seat through a bolt, the clamping cylinder installation seat is fixed on the first rotating installation seat through a bolt, the guide rail is locked on the first rotating installation seat through a bolt, the guide rail is connected with the sliding block through a sliding manner, the sliding block is fixed on the second rotating installation seat through a bolt, the clamping cylinder is connected with the floating joint through a thread, the floating joint is fixed with the second rotating installation seat through a bolt, and the cylinder and the rotating installation seat are connected with each other.

As a further improvement of the technology, the rotating structure comprises a rotating cylinder, a rack fixing plate, a sliding rail, a sliding block, a rotating shaft, a gear, a workpiece clamping plate, a workpiece guide block, an angular limiting block, a sensor bracket, a photoelectric sensor and an angular limiting block; the workpiece guide block is fixed on a workpiece clamping plate through a bolt, the angular limiting block is fixed on the workpiece clamping plate through bolt connection and positioning through a pin bush, the workpiece clamping plate is fixed on a rotating shaft through bolt connection, the rotating shaft and a bearing are fixed on a rotating bearing seat in a clearance fit manner, the tail part of the angular limiting block is locked on the rotating shaft side by side through two round nuts, the rotating bearing seat is fixed on a second rotating fixed seat through bolt connection, a gear is connected through a flat key and is tightly pressed by an end cover, the bolt is fixed on the rotating shaft, a rotating cylinder is connected on a cylinder mounting seat through a bolt and is provided with a cylindrical pin at the bottom for positioning connection, the rotating cylinder is connected with a floating joint through a bolt, the floating joint is fixed on a rack mounting plate through a bolt, a slide rail is connected on the rack mounting plate through a bolt, the slide rail is connected with a slide block through sliding connection, and the slide block is connected on the first rotating fixed seat through a bolt, the rack is connected through a bolt, the cylindrical pin is limited, the rotary cylinder pushes the rack to move linearly, and the rack is meshed with the gear.

As a further improvement of the technology, the limiting part comprises a stop block, an adjusting fixing seat, an induction pin shaft, a photoelectric sensor, an induction block, an adjusting screw, a linear bearing, an induction bracket and a bearing fixing seat; the stop block is fixed on the stand column through a waist-shaped groove bolt, the bearing fixing seat is connected on the stop block through a bolt, the linear bearing is fixed on the stop block through a bolt, the induction block is connected on the induction pin shaft through a bolt, the induction pin shaft is connected with the linear bearing in a sliding mode, the photoelectric correlation switch is fixed on the induction support through a bolt, the induction support is fixed on the stop block through a bolt, and the adjusting fixing seat is fixed on the stand column through a bolt.

As a further improvement of the technology, the induction pin shaft is provided with a return spring.

The invention has the beneficial effects that:

according to the axle housing centering and overturning mechanism provided by the invention, the compatible specification of the overturning mechanism can be correspondingly adjusted according to the specification type, the adjustment is convenient and fast, and the space is reasonably optimized; the upset is simple, and the adjustment is simple, and rotation angle is accurate controllable, and the upset is efficient, and space utilization is showing and is improving, and very big reduction unnecessary space is extravagant, and the frame that overturns in the past accounts for the very big compression in space, only needs a product to promote the space and can overturn after improving, and the current technology of very big improvement is overturned in middle gesture, optimizes the production beat, improves production efficiency.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic structural view of the lifting portion of the present invention.

Fig. 3 is a schematic structural view of a rotating portion according to the present invention.

FIG. 4 is a schematic structural diagram of the limiting portion of the present invention.

Detailed Description

The invention will be described with reference to the accompanying drawings, which are only schematic in terms of their structural proportions and which may be specified according to actual requirements; it should be understood that the description is illustrative only and is not intended to limit the scope of the present disclosure. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present disclosure. All terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. It is noted that the terms used herein should be interpreted as having a meaning that is consistent with the context of this specification and should not be interpreted in an idealized or overly formal sense.

As shown in fig. 1, 2, 3 and 4, an axle housing centering and overturning mechanism comprises a lifting part 1, a rotating part 2 and a limiting part 3, wherein the lifting part 1 is positioned below the whole, the rotating part 2 is arranged on the left side and the right side of the lifting part 1, the limiting part 3 is arranged on one side of the rotating part 2, a workpiece 5 is arranged between the limiting parts 3, a chain conveyor 4 is arranged behind the rotating part 2, the lifting part 1 comprises lifting cylinders 1-4, upright columns 1-8, lifting cross beams 1-3 and limiting structures 1-1, the lifting cylinders 1-4 are fixed on cross beams 1-7 through bolts, the cross beams 1-7 are fixed on the upright columns 1-8 on the two sides through bolts, the cross beams 1-7 are connected with the lifting cylinders 1-4 through floating joints, the upright columns 1-8 are connected and fixed with sliding rails 1-11 through bolts, and sliding blocks 1-12 are fixed on the cross beams 1-7, the sliding block 1-12 is connected with the sliding rail 1-11 in a sliding manner, the air cylinder 1-4 and the beam 1-3 are connected with each other, the rotating part 2 further comprises a clamping structure and a rotating structure, the clamping structure further comprises a clamping air cylinder 2-4, a sliding block 2-17, a guide rail 2-2, a first rotating installation base 2-1, a second rotating installation base 2-8, a clamping air cylinder installation base 2-14 and a floating joint 2-13, the clamping air cylinder 2-4 is fixed on the clamping air cylinder installation base 2-14 through a bolt, the clamping air cylinder installation base 2-14 is fixed on the first rotating installation base 2-8 through a bolt, the guide rail 2-2 is locked on the first rotating installation base 2-1 through a bolt, the guide rail 2-2 is connected with the sliding block 2-17 in a sliding manner, the sliding block 2-17 is fixed on the second rotating installation base 2-8 through a bolt, the clamping cylinder 2-4 is connected with the floating joint 2-13 through threads, the floating joint 2-13 is fixed with the second rotary fixing seat 2-1 through bolts, the cylinder 2-4 is connected with the rotary fixing seat 2-8, and the rotary structure comprises a rotary cylinder 2-5, a rack 2-12, a rack fixing plate 2-18, a sliding rail 2-19, a sliding block 2-20, a rotary shaft 2-21, a gear 2-15, a workpiece clamping plate 2-22, a workpiece guide block 2-7, an angular limiting block 2-6, a sensor support 2-10, a photoelectric sensor 2-16 and an angular limiting block 2-6; the workpiece guide block 2-7 is fixed on the workpiece clamping plate 2-22 through a bolt, the angular limiting block 2-6 is fixed on the workpiece clamping plate 2-22 through a bolt connection and a pin bush positioning, the workpiece clamping plate 2-22 is fixed on the rotating shaft 2-21 through a bolt connection, the rotating shaft 2-21 and a bearing are fixed on the rotating bearing seat 2-23 in a clearance fit manner, the tail part of the rotating bearing seat is locked on the rotating shaft 2-21 side by side through two round nuts, the rotating bearing seat 2-23 is fixed on the second rotating fixing seat 2-1 through a bolt connection, the gear 2-15 is connected through a flat key and is tightly pressed by an end cover, the bolt is fixed on the rotating shaft 2-21, the rotating cylinder 2-5 is connected on the cylinder mounting seat 2-11 through a bolt and is provided with a cylindrical pin at the bottom for positioning connection, the rotating cylinder 2-5 is connected with the floating joint 2-24 through a bolt, the floating joint 2-24 is fixed on a rack mounting plate 2-18 through a bolt, a slide rail 2-19 is connected on the rack mounting plate 2-18 through a bolt, the slide rail 2-19 is connected with a slide block 2-20 through a sliding way, the slide block 2-20 is connected on a rotary fixing seat I2-8 through a bolt, a rack 2-12 is connected through a bolt, a cylindrical pin is used for limiting, a rotary cylinder 2-5 pushes the rack 2-12 to move linearly, the rack 2-12 is meshed with a gear 15, a limiting part 3 comprises a stop block 3-13, an adjusting fixing seat 3-1, an induction pin shaft 3-12, a photoelectric sensor 3-2, an induction block 3-11, an adjusting screw 3-7, a linear bearing 3-10, an induction support 3-3 and a bearing fixing seat 3-14; the stop block 3-13 is fixed on the upright post 1-8 through a waist-shaped groove bolt, the bearing fixing seat 3-14 is connected on the stop block 3-13 through a bolt, the linear bearing 3-10 is fixed on the stop block 3-13 through a bolt, the induction block 3-11 is connected on the induction pin shaft 3-12 through a bolt, the induction pin shaft 3-12 is connected with the linear bearing 3-10 in a sliding mode, the photoelectric correlation switch 3-2 is fixed on the induction support 3-3 through a bolt, the induction support 3-3 is fixed on the stop block 3-13 through a bolt, the adjusting fixing seat 3-1 is fixed on the upright post 1-8 through a bolt, and the induction pin shaft 3-12 is provided with a reset spring 3-9.

As shown in fig. 1, the present invention is integrally divided into three parts, a lifting part 1, a rotating part 2, a stopper part 3, a chain conveyor 4 and a workpiece 5.

As shown in figure 2, the lifting part 1 mainly comprises lifting cylinders 1-4, upright post parts 1-8, lifting cross beams 1-3, limiting structures 1-1 and the like, wherein the lifting cylinders 1-4 are fixed on the cross beams 1-7 through bolts, the cross beams 1-7 are fixed on the side upright posts 1-8 through bolts, the lifting cylinders 1-4 are connected with the cross beams 1-7 through floating joints, slide rails 1-11 are fixedly connected with the upright posts 1-8 on two sides through bolts, slide blocks 1-12 are fixed on the cross beams 1-7, the slide blocks 1-12 are connected with the slide rails 1-11 in a sliding manner, two slide blocks 1-12 are arranged on two sides respectively, and the air cylinders 1-4 push the cross beams 1-3 to lift.

As shown in fig. 3, the rotating portion further includes a clamping portion. The clamping part mainly comprises a clamping cylinder 2-4, a sliding block 2-17, a guide rail 2-2, a first rotary mounting seat 2-1, a second rotary mounting seat 2-8, a clamping cylinder mounting seat 2-14, a floating joint 2-13 and the like, wherein the clamping cylinder 2-4 is fixed on the clamping cylinder mounting seat 2-14 through bolts, the clamping cylinder mounting seat 2-14 is fixed on the first rotary mounting seat 2-8 through bolts, the guide rail 2-2 is locked on the first rotary mounting seat 2-1 through bolts, the guide rail 2-2 is connected with the sliding block 2-17 in a sliding manner, the sliding block 2-17 is connected and fixed on the second rotary mounting seat 2-8 through bolts, the clamping cylinder 2-4 is connected with the floating joint 2-13 through threads, the floating joint 2-13 is connected with the second rotary mounting seat 2-1, the rotary part mainly comprises a rotary cylinder 2-5, a rack 2-12, a rack fixing plate 2-18, a sliding rail 2-19, a sliding block 2-20, a rotary shaft 2-21, a gear 2-15, a workpiece clamping plate 2-22, a workpiece guide block 2-7, an angular limiting block 2-6, a sensor support 2-10, a photoelectric sensor 2-16, an angular limiting block 2-6 and the like. The workpiece guide blocks 2-7 are connected through bolts and fixed on the workpiece clamping plates 2-22; the angular limiting blocks 2-6 are connected through bolts, positioned by pin sleeves and fixed on the workpiece clamping plates 2-22; the workpiece clamping plates 2-22 are fixed on the rotating shafts 2-21 through bolt connection; the rotating shaft 2-21 and the bearing are fixed on the rotating bearing seat 2-23 in a clearance fit manner, the tail part of the rotating shaft is locked on the rotating shaft 2-21 side by side through two round nuts, the rotating bearing seat 2-23 is fixed on the second rotating fixing seat 2-1 through bolt connection, the gear 2-15 is connected through a flat key, an end cover is pressed tightly, and the bolt is fixed on the rotating shaft 2-21; the rotary cylinder 2-5 is connected to the cylinder mounting seat 2-11 through a bolt, the bottom of the rotary cylinder is connected with a cylindrical pin in a positioning mode, the rotary cylinder 2-5 is connected with the floating joint 2-24 through a bolt, the floating joint 2-24 is fixed to the rack mounting plate 2-18 through a bolt, the sliding rail 2-19 is connected with the sliding block 2-20 in a sliding mode, the sliding block 2-20 is connected to the first rotary fixing seat 2-8 through a bolt, the rack 2-12 is connected through a bolt, the cylindrical pin is limited, the rotary cylinder 2-5 pushes the rack 2-12 to move linearly, the rack 2-12 is meshed with the gear 2-15, the gear 2-15 rotates to drive the rotary shaft 2-21 to rotate, and the workpiece clamping plate 2-22 rotates.

As shown in fig. 4, the limiting part 3 mainly comprises a stop block 3-13, an adjusting fixing seat 3-1, an induction pin shaft 3-12, a photoelectric sensor 3-2, an induction block 3-11, a return spring 3-9, an adjusting screw 3-7, a linear bearing 3-10, an induction bracket 3-3, a bearing fixing seat 3-14, and the stop block 3-13 is fixed on the overturning upright post through a waist-shaped groove bolt; the bearing fixing seats 3-14 are connected to the stopping blocks 3-13 through bolts, and the linear bearings 3-10 are fixed to the stopping blocks 3-13 through bolts; the induction blocks 3-11 are connected to the induction pin shafts 3-12 through bolts, the induction pin shafts 3-12 are in sliding connection with the linear bearings 3-10, and the springs 3-9 are elastically reset to compress and slide; the photoelectric correlation switch 3-2 is fixed on the induction bracket 3-3 through a bolt, and the induction bracket 3-3 is fixed on the stop block 3-13 through a bolt; the adjusting fixing seat 3-1 is fixed on the overturning upright post through a bolt. Through the structure of telling, can be according to the width of work piece, the position of adjusting bolt to the back and forth position of adjusting the fender and stopping piece 3-13 makes the work piece center keep unchangeable, guarantees that the center of upset does not change.

While the present invention has been described in conjunction with the above embodiments, the present invention is not limited to the above embodiments but is limited only by the appended claims, and those skilled in the art can easily make modifications and variations thereto without departing from the true spirit and scope of the present invention.

Claims

1. The utility model provides an axle housing centering tilting mechanism, includes promotion portion (1), rotating part (2), spacing portion (3), its characterized in that: the lifting part (1) is located the holistic below, the left and right sides of lifting part (1) is rotating part (2), one side of rotating part (2) is equipped with spacing portion (3), be equipped with work piece (5) between spacing portion (3), the rear of rotating part (2) is equipped with chain conveyor (4).

2. The axle housing centering and overturning mechanism is characterized in that the lifting part (1) comprises lifting cylinders (1-4), vertical columns (1-8), lifting cross beams (1-3) and limiting structures (1-1), the lifting cylinders (1-4) are fixed on the cross beams (1-7) through bolts, the cross beams (1-7) are fixed on the vertical columns (1-8) on two sides through bolts, the cross beams (1-7) are connected with the lifting cylinders (1-4) through floating joints, the vertical columns (1-8) are fixedly connected with sliding rails (1-11) through bolts, sliding blocks (1-12) are fixed on the cross beams (1-7), and the sliding blocks (1-12) are connected with the sliding rails (1-11) in a sliding mode, the cylinders (1-4) and the beams (1-3) are connected with each other.

3. The axle housing centering and overturning mechanism is characterized in that the rotating part (2) further comprises a clamping structure and a rotating structure, the clamping structure further comprises a clamping cylinder (2-4), a sliding block (2-17), a guide rail (2-2), a first rotating mounting seat (2-1), a second rotating mounting seat (2-8), a clamping cylinder mounting seat (2-14) and a floating joint (2-13), the clamping cylinder (2-4) is fixed on the clamping cylinder mounting seat (2-14) through a bolt, the clamping cylinder mounting seat (2-14) is fixed on the first rotating mounting seat (2-8) through a bolt, the guide rail (2-2) is locked on the first rotating mounting seat (2-1) through a bolt, and the guide rail (2-2) is connected with the sliding block (2-17) through a sliding manner, the sliding blocks (2-17) are fixed on a second rotary mounting seat (2-8) through bolts, the clamping cylinders (2-4) are connected with the floating joints (2-13) through threads, the floating joints (2-13) are fixed with a second rotary fixing seat (2-1) through bolts, and the cylinders (2-4) are connected with the rotary fixing seats (2-8) mutually.

4. The axle housing centering and overturning mechanism is characterized in that the rotating structure comprises a rotating cylinder (2-5), a rack (2-12), a rack fixing plate (2-18), a sliding rail (2-19), a sliding block (2-20), a rotating shaft (2-21), a gear (2-15), a workpiece clamping plate (2-22), a workpiece guide block (2-7), an angular limiting block (2-6), a sensor bracket (2-10), a photoelectric sensor (2-16) and an angular limiting block (2-6); the workpiece guide block (2-7) is fixed on a workpiece clamping plate (2-22) through a bolt, the angular limiting block (2-6) is fixed on the workpiece clamping plate (2-22) through bolt connection and positioning through a pin bush, the workpiece clamping plate (2-22) is fixed on a rotating shaft (2-21) through bolt connection, the rotating shaft (2-21) and a bearing are fixed on a rotating bearing seat (2-23) in a clearance fit mode, the tail portion of the rotating shaft is locked on the rotating shaft (2-21) side by side through two round nuts, the rotating bearing seat (2-23) is fixed on a second rotating fixing seat (2-1) through bolt connection, a gear (2-15) is connected through a flat key and is compressed through an end cover, the bolt is fixed on the rotating shaft (2-21), the rotating cylinder (2-5) is connected on a cylinder mounting seat (2-11) through a bolt, and a cylindrical pin is arranged at the bottom of the rotating cylinder mounting seat (2-11) The positioning connection is realized, the rotary cylinder (2-5) is connected with the floating joint (2-24) through a bolt, the floating joint (2-24) is fixed on the rack mounting plate (2-18) through a bolt, the slide rail (2-19) is connected with the slide block (2-20) through a slide, the slide block (2-20) is connected on the rotary fixing seat I (2-8) through a bolt, the rack (2-12) is connected through a bolt, the cylindrical pin is limited, the rotary cylinder (2-5) pushes the rack (2-12) to move linearly, and the rack (2-12) is meshed with the gear (15).

5. The axle housing centering and overturning mechanism is characterized in that the limiting part (3) comprises a stopping block (3-13), an adjusting fixing seat (3-1), an induction pin shaft (3-12), a photoelectric sensor (3-2), an induction block (3-11), an adjusting screw (3-7), a linear bearing (3-10), an induction bracket (3-3) and a bearing fixing seat (3-14); the stop block (3-13) is fixed on an upright post (1-8) through a waist-shaped groove bolt, a bearing fixing seat (3-14) is connected on the stop block (3-13) through a bolt, a linear bearing (3-10) is fixed on the stop block (3-13) through a bolt, an induction block (3-11) is connected on an induction pin shaft (3-12) through a bolt, the induction pin shaft (3-12) is connected with the linear bearing (3-10) in a sliding mode, a photoelectric correlation switch (3-2) is fixed on an induction support (3-3) through a bolt, the induction support (3-3) is fixed on the stop block (3-13) through a bolt, and an adjusting fixing seat (3-1) is fixed on the upright post (1-8) through a bolt.

6. The axle housing centering and overturning mechanism is characterized in that a return spring (3-9) is arranged on the induction pin shaft (3-12).