CN213169791U - Feeding mechanism for seamless copper pipe ultrasonic flaw detection equipment - Google Patents

Abstract

The utility model discloses a feeding mechanism for seamless copper pipe ultrasonic inspection equipment, include: the carrier roller mechanism comprises a carrier roller mechanism rack, a set of adjusting carrier roller assemblies, a set of conveying device and a set of feeding pushing mechanism, wherein the material blocking wheel mechanism is arranged at the feeding end of the carrier roller mechanism rack, the adjusting carrier roller assemblies and the conveying device are alternately arranged on the carrier roller mechanism rack, and the feeding pushing mechanism is arranged between the adjusting carrier roller assemblies and the conveying device. The utility model discloses in a bearing roller and feeding mechanism for seamless copper pipe ultrasonic inspection equipment, its simple structure, reasonable in design adjusts the copper pipe through setting up adjustment bearing roller subassembly on the rack to carry it through conveyor and feeding push mechanism, guarantee the accurate nature of its pay-off, reduce the amount of labour, its transport efficiency of improvement that simultaneously also great.

Description

Feeding mechanism for seamless copper pipe ultrasonic flaw detection equipment

Technical Field

The utility model belongs to the technical field of the metal material processing, in particular to a feeding mechanism for seamless copper pipe ultrasonic inspection equipment.

Background

Ultrasonic flaw detection is a method for detecting the flaw of a part by using the characteristic that ultrasonic energy penetrates into the depth of a metal material and is reflected at the edge of an interface when the ultrasonic energy enters another section from the section.

With the rapid development of social economy, the modernization and the intellectualization of various industries are gradually realized, and the production of enterprises is also the same. Seamless copper pipe often carries out the quality to it and detects in the course of working, and traditional detection mostly relies on artifical the detection, and nevertheless artifical the detection totally relies on experience and sensation, has certain uncontrollable nature, and the condition of false retrieval, hourglass inspection can also appear in artifical the detection simultaneously, so not only can influence the efficiency that its detected, also can influence the quality that its detected simultaneously.

Even if some enterprises adopt instruments for detection, the feeding of some enterprises is still completed manually, a large amount of manpower is consumed, the feeding efficiency is influenced, and even if some enterprises adopt a feeding mechanism for feeding, the copper pipe is cylindrical, so that the copper pipe can deviate in the processing process, the detection quality of the copper pipe is influenced, and the existing detection technology of the seamless copper pipe is still to be improved.

SUMMERY OF THE UTILITY MODEL

Utility model purpose: in order to overcome the above not enough, the utility model aims at providing a feeding mechanism for seamless copper pipe ultrasonic inspection equipment, its simple structure, reasonable in design, easily production, degree of automation is high, reduces the hand labor volume, has improved work efficiency.

The technical scheme is as follows: in order to realize the above purpose, the utility model provides a feeding mechanism for seamless copper pipe ultrasonic inspection equipment, include: the carrier roller mechanism comprises a carrier roller mechanism rack, a set of adjusting carrier roller assemblies, a set of conveying device and a set of feeding pushing mechanism, wherein the material blocking wheel mechanism is arranged at the feeding end of the carrier roller mechanism rack, the adjusting carrier roller assemblies and the conveying device are alternately arranged on the carrier roller mechanism rack, and the feeding pushing mechanism is arranged between the adjusting carrier roller assemblies and the conveying device.

The utility model discloses in a feeding mechanism for seamless copper pipe ultrasonic inspection equipment, its simple structure, reasonable in design adjusts the copper pipe through setting up the adjustment riding wheel subassembly on the rack to carry it through conveyor and feeding push mechanism, guarantee the accurate nature of its pay-off, reduce the amount of labour, its transport efficiency of improvement that simultaneously also great.

The utility model discloses in be equipped with a set of stand and workstation frame in the bearing roller mechanism rack, the workstation frame is located on the stand, just the below of stand is equipped with the chassis with it syntropy.

The utility model discloses in be equipped with mounting panel, a set of mirror surface switch support, a set of debugging bearing roller axle, a set of debugging riding wheel and debugging actuating mechanism in the adjustment riding wheel subassembly, wherein, be equipped with bearing roller major axis and bearing roller minor axis in the debugging bearing roller axle, the mounting panel is located on the bearing roller mechanism rack, mirror surface switch support is located relatively on the mounting panel, is located and is equipped with the bearing frame on the mirror surface switch support, the bearing frame that corresponds is located respectively at the both ends of bearing roller major axis and bearing roller minor axis, just the one end of debugging bearing roller axle is equipped with single sprocket, the debugging riding wheel is located on the debugging bearing roller axle, the below of work bench is located to debugging actuating mechanism, and its output is equipped with double sprocket, double sprocket passes through the chain and is connected with. And a housing is arranged at the outer sides of the double-row chain wheel and the single-row chain wheel. The arrangement of the long shaft and the short shaft of the carrier roller in the adjusting carrier roller can adjust the copper pipe on the conveying device, so that the copper pipe can be better conveyed, and the conveying accuracy of the copper pipe is ensured.

The utility model discloses in be equipped with swivel mount seat, swivel mount, conveying roller subassembly, conveying roller slewing arm, a set of push rod and rotation actuating mechanism among the conveyor, the station that lies in conveyor on the bearing roller mechanism rack is equipped with a set of bearing frame, be equipped with the rotation axis between the bearing frame, the swivel mount seat is located on the rotation axis, the swivel mount is located on the swivel mount seat, conveying roller subassembly is located on the swivel mount, on the one end of conveying roller slewing arm is located on the swivel mount, the other end is located between two push rods to connect through the adapter sleeve, the below of work rack is located to the push rod, just the one end of push rod is passed through the axis of rotation and is connected with rotation actuating mechanism. The conveying device is arranged, the push rod is pushed through the arrangement of the rotation driving mechanism, the conveying roller rotary arm is driven through the push rod, and the rotary support and the rotary frame are driven to rotate under the driving of the conveying roller rotary arm, so that the copper pipe can be conveyed.

The utility model discloses in be equipped with in the conveying roller subassembly and carry axle, delivery wheel and transport actuating mechanism, the both ends of carrying the axle are passed through the bearing frame and are installed on the swivel mount, the delivery wheel is located and is carried epaxially, carry actuating mechanism and locate the one end of carrying the axle to be connected with the one end of carrying the axle through the shaft coupling. The conveying driving mechanism adopts a motor, and the motor is connected with the rotating frame base through a motor base.

The utility model discloses in be equipped with installation stand, push mechanism and propelling movement cylinder among the feeding push mechanism, the installation stand is located on the workstation frame, on two installation stands were located to push mechanism's one end, on the support frame was located to the other end, push cylinder locates the below of support frame to on being fixed in the chassis through the cylinder fixing base, just push cylinder's output passes through the connector and is connected with push mechanism.

The utility model discloses in be equipped with vertical push plate among the push mechanism, be equipped with the V type groove that is used for the copper pipe walking on vertical push plate.

The utility model discloses in carry the axle to adopt V type axle, the delivery wheel adopts V type wheel.

Above-mentioned technical scheme can find out, the utility model discloses following beneficial effect has:

1. the utility model discloses in a feeding mechanism for seamless copper pipe ultrasonic inspection equipment, its simple structure, reasonable in design adjusts the copper pipe through setting up the adjustment riding wheel subassembly on the rack to carry it through conveyor and feeding push mechanism, guarantee the accurate nature of its pay-off, reduce the amount of labour, its transport efficiency of improvement that simultaneously also great.

2. The utility model discloses in the setting of bearing roller major axis and bearing roller minor axis in the adjustment riding wheel lets it can adjust the copper pipe on the conveyor to carry out better transport to it, guarantee the accuracy of its transmission.

3. The utility model discloses in conveyor sets up, through the setting that rotates actuating mechanism, lets it promote the push rod, drives the conveying roller slewing arm through the push rod, drives rotatory support and swivel mount rotation under the drive of conveying roller slewing arm again to let it carry the copper pipe.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a top view of the present invention;

fig. 3 is a partial enlarged view of the conveying device of the present invention;

FIG. 4 is a partial enlarged view of the adjustable idler assembly of the present invention;

fig. 5 is a schematic structural view of the conveying device of the present invention;

fig. 6 is a schematic structural view of the middle feeding and pushing mechanism of the present invention.

Detailed Description

The invention will be further elucidated with reference to the drawings and the specific embodiments.

Examples

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, unless otherwise specified, "a plurality" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

A feeding mechanism for seamless copper pipe ultrasonic inspection equipment as shown in the figure includes: the roller mechanism comprises a roller mechanism rack 31, a group of adjusting roller assemblies 32, a group of conveying devices 33 and a group of feeding and pushing mechanisms 34, wherein the adjusting roller assemblies 32 and the conveying devices 33 are alternately arranged on the roller mechanism rack 31, and the feeding and pushing mechanisms 34 are arranged between the adjusting roller assemblies 32 and the conveying devices 33.

The carrier roller mechanism rack 31 is provided with a group of upright columns 311 and a working rack 312, the working rack 312 is arranged on the upright columns 311, and a bottom frame 313 is arranged below the upright columns 311 in the same direction.

Further, be equipped with mounting panel 321, a set of mirror surface switch support 322, a set of debugging bearing roller axle 323, a set of debugging riding wheel 324 and debugging actuating mechanism 325 in the adjustment riding wheel subassembly 32, wherein, be equipped with bearing roller major axis 3231 and bearing roller minor axis 3232 in the debugging bearing roller axle 323, mounting panel 321 is located on bearing roller mechanism rack 31, mirror surface switch support 322 is located on mounting panel 321 relatively, is located and is equipped with bearing frame 35 on mirror surface switch support 322, the both ends of bearing roller major axis 3231 and bearing roller minor axis 3232 are located respectively in corresponding bearing frame 35, just the one end of debugging bearing roller axle 323 is equipped with single-row sprocket 36, debugging riding wheel 324 is located on debugging bearing roller axle 323, debugging actuating mechanism 325 is located the below of work bench 312, and its output is equipped with double sprocket 37, double sprocket 37 is connected with single-row sprocket 36 through the chain. And a housing is arranged outside the double-row chain wheel 37 and the single-row chain wheel 36.

In addition, the conveying device 33 is provided with a rotating frame seat 331, a rotating frame 332, a conveying roller component 333, a conveying roller revolving arm 334, a group of push rods 335 and a revolving driving mechanism 336, a group of bearing seats 35 are arranged on the carrier roller mechanism rack 31 at the station of the conveying device 33, a revolving shaft 337 is arranged between the bearing seats 35, the rotating frame seat 331 is arranged on the revolving shaft 337, the rotating frame 332 is arranged on the rotating frame seat 331, the conveying roller component 333 is arranged on the rotating frame 332, one end of the revolving conveying roller arm 334 is arranged on the rotating frame 332, the other end of the revolving conveying roller arm is arranged between the two push rods 335 and is connected through a connecting sleeve 338, the push rod 335 is arranged below the working table 312, and one end of the push rod 335 is connected with the revolving driving mechanism 336 through a revolving.

Preferably, the transport roller assembly 333 includes a transport shaft 3331, a transport wheel 3332, and a transport driving mechanism 3333, both ends of the transport shaft 3331 are attached to the rotating frame 332 via bearing blocks 35, the transport wheel 3332 is provided on the transport shaft 3331, and the transport driving mechanism 3333 is provided at one end of the transport shaft 3331 and is connected to one end of the transport shaft 3331 via a coupling 3334. The conveying driving mechanism 3333 is a motor, and the motor is connected with the rotating frame base 331 through a motor base.

Further preferably, the feeding pushing mechanism 34 is provided with an installation column 341, a pushing mechanism 342, and a pushing cylinder 343, the installation column 341 is disposed on the working table frame 312, one end of the pushing mechanism 342 is disposed on the two installation columns 341, the other end is disposed on the supporting frame 344, the pushing cylinder 343 is disposed below the supporting frame 344 and is fixed on the bottom frame 313 through a cylinder fixing seat, and an output end of the pushing cylinder 343 is connected to the pushing mechanism 342 through a connector.

Further preferably, a longitudinal pushing plate 3421 is arranged in the pushing mechanism 342, and a V-shaped groove 3422 for copper tube walking is arranged on the longitudinal pushing plate 3421.

In this embodiment, the conveying shaft 3331 is a V-shaped shaft, and the conveying wheel 3332 is a V-shaped wheel.

Example 2

A feeding mechanism for seamless copper pipe ultrasonic inspection equipment as shown in the figure includes: the roller mechanism comprises a roller mechanism rack 31, a group of adjusting roller assemblies 32, a group of conveying devices 33 and a group of feeding and pushing mechanisms 34, wherein the adjusting roller assemblies 32 and the conveying devices 33 are alternately arranged on the roller mechanism rack 31, and the feeding and pushing mechanisms 34 are arranged between the adjusting roller assemblies 32 and the conveying devices 33.

The carrier roller mechanism rack 31 is provided with a group of upright columns 311 and a working rack 312, the working rack 312 is arranged on the upright columns 311, and a bottom frame 313 is arranged below the upright columns 311 in the same direction.

Further, be equipped with mounting panel 321, a set of mirror surface switch support 322, a set of debugging bearing roller axle 323, a set of debugging riding wheel 324 and debugging actuating mechanism 325 in the adjustment riding wheel subassembly 32, wherein, be equipped with bearing roller major axis 3231 and bearing roller minor axis 3232 in the debugging bearing roller axle 323, mounting panel 321 is located on bearing roller mechanism rack 31, mirror surface switch support 322 is located on mounting panel 321 relatively, is located and is equipped with bearing frame 35 on mirror surface switch support 322, the both ends of bearing roller major axis 3231 and bearing roller minor axis 3232 are located respectively in corresponding bearing frame 35, just the one end of debugging bearing roller axle 323 is equipped with single-row sprocket 36, debugging riding wheel 324 is located on debugging bearing roller axle 323, debugging actuating mechanism 325 is located the below of work bench 312, and its output is equipped with double sprocket 37, double sprocket 37 is connected with single-row sprocket 36 through the chain. And a housing is arranged outside the double-row chain wheel 37 and the single-row chain wheel 36.

In addition, the conveying device 33 is provided with a rotating frame seat 331, a rotating frame 332, a conveying roller component 333, a conveying roller revolving arm 334, a group of push rods 335 and a revolving driving mechanism 336, a group of bearing seats 35 are arranged on the carrier roller mechanism rack 31 at the station of the conveying device 33, a revolving shaft 337 is arranged between the bearing seats 35, the rotating frame seat 331 is arranged on the revolving shaft 337, the rotating frame 332 is arranged on the rotating frame seat 331, the conveying roller component 333 is arranged on the rotating frame 332, one end of the revolving conveying roller arm 334 is arranged on the rotating frame 332, the other end of the revolving conveying roller arm is arranged between the two push rods 335 and is connected through a connecting sleeve 338, the push rod 335 is arranged below the working table 312, and one end of the push rod 335 is connected with the revolving driving mechanism 336 through a revolving.

Preferably, the transport roller assembly 333 includes a transport shaft 3331, a transport wheel 3332, and a transport driving mechanism 3333, both ends of the transport shaft 3331 are attached to the rotating frame 332 via bearing blocks 35, the transport wheel 3332 is provided on the transport shaft 3331, and the transport driving mechanism 3333 is provided at one end of the transport shaft 3331 and is connected to one end of the transport shaft 3331 via a coupling 3334. The conveying driving mechanism 3333 is a motor, and the motor is connected with the rotating frame base 331 through a motor base.

The rotating frame base 331 is provided with a mounting base 3311 and a set of mounting ring 3312, and the mounting ring 3312 is disposed below the mounting base 3311 and sleeved on the rotating shaft 337.

A mounting seat body is arranged in the mounting seat 3311, a group of mounting lugs is arranged below the mounting seat body, and the mounting sleeve ring 3312 is arranged on the mounting lugs.

The rotating frame 332 is L-shaped and vertically disposed on the rotating frame base 331.

The conveying roller rotary arm 334 is internally provided with a rotary arm rod piece 3341, one end of the rotary arm rod piece 3341 is provided with an installation sleeve 3342, the other end of the rotary arm rod piece 3341 is provided with a connecting lug 3343, the installation sleeve 3342 is arranged on the rotating shaft 337 and is arranged between the two installation sleeve rings 3312, and the connecting lug 3343 is arranged between the two push rods 335 and is connected through a connecting sleeve 338.

A rotary arm body is arranged in the rotary arm rod piece 3341, and stiffening plates are arranged on two sides of the rotary arm body.

The rotation driving mechanism 336 is a cylinder, and the cylinder is fixed on the bottom frame 313 through a cylinder block.

Further preferably, the feeding pushing mechanism 34 is provided with an installation column 341, a pushing mechanism 342, and a pushing cylinder 343, the installation column 341 is disposed on the working table frame 312, one end of the pushing mechanism 342 is disposed on the two installation columns 341, the other end is disposed on the supporting frame 344, the pushing cylinder 343 is disposed below the supporting frame 344 and is fixed on the bottom frame 313 through a cylinder fixing seat, and an output end of the pushing cylinder 343 is connected to the pushing mechanism 342 through a connector.

Further preferably, a longitudinal pushing plate 3421 is arranged in the pushing mechanism 342, and a V-shaped groove 3422 for copper tube walking is arranged on the longitudinal pushing plate 3421.

In this embodiment, the conveying shaft 3331 is a V-shaped shaft, and the conveying wheel 3332 is a V-shaped wheel.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications can be made without departing from the principles of the present invention, and these modifications should also be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides a feeding mechanism for seamless copper pipe ultrasonic inspection equipment which characterized in that: the method comprises the following steps: idler mechanism rack (31), a set of adjustment idler subassembly (32), a set of conveyor (33) and a set of feeding push mechanism (34), adjustment idler subassembly (32) and conveyor (33) are located on idler mechanism rack (31) in the alternative, feeding push mechanism (34) are located between adjustment idler subassembly (32) and conveyor (33).

2. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 1, characterized in that: the carrier roller mechanism is characterized in that a group of upright columns (311) and a working table frame (312) are arranged in the carrier roller mechanism table frame (31), the working table frame (312) is arranged on the upright columns (311), and an underframe (313) is arranged below the upright columns (311) in the same direction with the upright columns.

3. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 1, characterized in that: the adjustable carrier roller assembly (32) is internally provided with a mounting plate (321), a set of mirror switch bracket (322), a set of debugging carrier roller shaft (323), a set of debugging carrier roller (324) and a debugging driving mechanism (325), wherein the debugging carrier roller shaft (323) is internally provided with a carrier roller long shaft (3231) and a carrier roller short shaft (3232), the mounting plate (321) is arranged on the carrier roller mechanism rack (31), the mirror switch bracket (322) is oppositely arranged on the mounting plate (321), a bearing seat (35) is arranged on the mirror switch bracket (322), two ends of the carrier roller long shaft (3231) and the carrier roller short shaft (3232) are respectively arranged in the corresponding bearing seats (35), one end of the debugging carrier roller shaft (323) is provided with a single-row chain wheel (36), the debugging carrier roller (324) is arranged on the debugging carrier roller shaft (323), the debugging driving mechanism (325) is arranged below the working rack (312), and the output end of the chain is provided with a double-row chain wheel (37), and the double-row chain wheel (37) is connected with the single-row chain wheel (36) through a chain.

4. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 2, characterized in that: the conveying device (33) is internally provided with a rotating frame seat (331), a rotating frame (332), a conveying roller component (333), a conveying roller rotating arm (334), a group of push rods (335) and a rotating driving mechanism (336), a group of bearing blocks (35) are arranged on the carrier roller mechanism rack (31) at the station of the conveying device (33), a rotating shaft (337) is arranged between the bearing seats (35), the rotating frame seat (331) is arranged on the rotating shaft (337), the rotating frame (332) is arranged on the rotating frame seat (331), the conveying roller assembly (333) is arranged on the rotating frame (332), one end of the conveying roller rotating arm (334) is arranged on the rotating frame (332), the other end is arranged between the two push rods (335), and is connected through a connecting sleeve (338), the push rod (335) is arranged below the working table frame (312), and one end of the push rod (335) is connected with a rotary driving mechanism (336) through a rotary shaft (339).

5. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 4, characterized in that: the conveying roller assembly (333) is provided with a conveying shaft (3331), a conveying wheel (3332) and a conveying driving mechanism (3333), two ends of the conveying shaft (3331) are installed on the rotating frame (332) through bearing seats (35), the conveying wheel (3332) is arranged on the conveying shaft (3331), and the conveying driving mechanism (3333) is arranged at one end of the conveying shaft (3331) and is connected with one end of the conveying shaft (3331) through a coupling (3334).

6. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 2, characterized in that: be equipped with installation stand (341), push mechanism (342) and propelling movement cylinder (343) in feeding push mechanism (34), install on workstation frame (312) stand (341), on two installation stand (341) are located to the one end of push mechanism (342), on support frame (344) is located to the other end, push cylinder (343) are located the below of support frame (344) to be fixed in on chassis (313) through the cylinder fixing base, just the output of push cylinder (343) passes through the connector and is connected with push mechanism (342).

7. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 6, characterized in that: a longitudinal pushing plate (3421) is arranged in the pushing mechanism (342), and a V-shaped groove (3422) for copper pipe walking is arranged on the longitudinal pushing plate (3421).

8. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 5, characterized in that: the conveying shaft (3331) adopts a V-shaped shaft, and the conveying wheel (3332) adopts a V-shaped wheel.

9. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 4, characterized in that: the rotary frame seat (331) is internally provided with an installation seat (3311) and a group of installation lantern rings (3312), and the installation lantern rings (3312) are relatively arranged below the installation seat (3311) and sleeved on the rotary shaft (337).

10. The feeding mechanism for the seamless copper pipe ultrasonic flaw detection equipment according to claim 4, characterized in that: be equipped with in conveying roller revolving arm (334) and revolve arm member (3341), the one end of revolving arm member (3341) is equipped with installation cover (3342), and the other end is equipped with engaging lug (3343), installation cover (3342) are located on rotation axis (337), and place between two installation lantern rings (3312), engaging lug (3343) are located between two push rods (335) to connect through adapter sleeve (338).

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