CN117299878A - Be used for titanium alloy pipe processing orthopedic device - Google Patents

Abstract

The invention relates to an orthopedic device for titanium alloy tube processing, comprising: the base correcting component comprises a correcting head with a telescopic function and a connecting block connected to the top of the correcting head, and the connecting block slides back and forth along the length direction of the base; the two rotating rollers are respectively connected to the inner sides of the two side plates; the rotary roller fixing part is fixedly connected with the inner wall of the side plate, the fixing part of the rotary driving motor is connected with the rotary roller fixing part, and the rotary part is connected with the driving roller; the two follow-up rollers are connected to the top of the bottom plate and are respectively arranged close to the inner sides of the two side plates, and the follow-up rollers are positioned below the rotating rollers and comprise two first V-shaped grooves and two bearings rotatably connected between the two first V-shaped grooves; the auxiliary supporting component is arranged between the two follow-up rollers and comprises an auxiliary supporting table connected to the top of the bottom plate and a second V-shaped groove arranged on the top of the auxiliary supporting table; the contact type displacement detector comprises a fixed rod piece and a displacement sensor. The invention improves the accuracy in correction.

Description

Be used for titanium alloy pipe processing orthopedic device

Technical Field

The invention relates to the technical field of titanium alloy tube production, in particular to an orthopedic device for titanium alloy tube processing.

Background

At present, small-caliber thick-wall pipes are widely applied to national life, and a straightener is an indispensable device on a fine straight pipe production line and has the functions of eliminating pipe bending generated in the production process and reducing pipe ovality. Along with the rapid development of national economy, the market demand for high-precision pipes is also increasing, in particular to pipes for underground coal mine hydraulic supports and petroleum oil pumps, etc. However, the precision requirement of the pipe is hardly met by the straightening machine commonly used in the market.

Disclosure of Invention

Therefore, the invention aims to solve the technical problem of poor correction precision in the prior art.

In order to solve the technical problems, the invention provides an orthopedic device for titanium alloy tube processing, comprising:

the base is a shell structure with openings at the top and the front side, and comprises two side plates, a back plate and a bottom plate;

the correcting assembly comprises a correcting head with a telescopic function and a connecting block connected to the top of the correcting head, wherein the connecting block is connected to the backboard in a sliding manner and slides back and forth along the length direction of the base;

the two rotating rollers are respectively connected to the inner sides of the two side plates; the rotary roller comprises a rotary roller fixing part, a rotary driving motor and a driving roller, wherein the rotary roller fixing part is fixedly connected with the inner wall of the side plate;

the two follow-up rollers are connected to the top of the bottom plate and are respectively arranged close to the inner sides of the two side plates, the follow-up rollers are positioned below the rotating rollers and comprise two first V-shaped grooves and two bearings rotatably connected between the two first V-shaped grooves, and the axes of the bearings are arranged in parallel with the axial direction of the first V-shaped grooves;

the auxiliary supporting assembly is arranged between the two follow-up rollers and comprises an auxiliary supporting table connected to the top of the bottom plate and a second V-shaped groove arranged on the top of the auxiliary supporting table;

the contact type displacement detector is connected to the top of the bottom plate and located on one side of the auxiliary supporting component, and comprises a fixed rod piece and a displacement sensor arranged at the top end of the fixed rod piece.

In one embodiment of the invention, the connecting block is slidably connected to the back plate through a sliding assembly, and the sliding assembly comprises a power part, a screw rod and a sliding block; the power portion is fixedly connected with the base, one end of the screw rod is connected with the power portion, the other end of the screw rod is rotationally connected with the side plate, the sliding block is provided with a threaded hole, the threaded hole is in threaded connection with the screw rod, and the sliding block is fixedly connected with the connecting block.

In one embodiment of the invention, there are two slide assemblies, one above and one below the connection block.

In one embodiment of the invention, the sliding assembly further comprises an auxiliary supporting shaft, two ends of the auxiliary supporting shaft are respectively connected with the two side plates, the auxiliary supporting shaft is positioned between the two sliding assemblies, the connecting block is provided with a connecting hole, and the connecting hole and the auxiliary supporting shaft form a sliding pair.

In one embodiment of the invention, the top of the correction head is provided with a telescopic cylinder, the telescopic end of the telescopic cylinder is connected with the correction head, and the fixed end of the telescopic cylinder is connected with the connecting block.

In one embodiment of the invention, the auxiliary supporting tables are a plurality of, and the auxiliary supporting tables are arranged between the two follow-up rollers at intervals along the length direction of the base.

In one embodiment of the invention, the plurality of contact type displacement detectors are respectively arranged between two adjacent auxiliary supporting tables and between the auxiliary supporting tables and the auxiliary supporting assembly.

In one embodiment of the invention, both side plates are provided with through holes at positions below the rotating rollers; the orthopedic device also comprises two transmission components, wherein the two transmission components are symmetrically arranged at the inner sides of the two side plates; the transmission assembly comprises two transmission parts, the two transmission parts are symmetrically arranged on the front side and the rear side of the through hole, each transmission part comprises a fixing piece, a rotary power part and a transmission roller, the fixing pieces are fixed on the inner wall of the side plate, the fixed ends of the rotary power parts are fixedly connected with the fixing pieces, the rotary parts are connected with the transmission rollers, and the power parts are arranged in the transmission rollers.

In one embodiment of the invention, the rotating part of the rotating power part is connected with an L-shaped connecting rod, the free end of the L-shaped connecting rod is connected with a rotating shaft, and the transmission roller is rotatably connected on the rotating shaft.

In one embodiment of the invention, the number of the L-shaped connecting rods is two, the two L-shaped connecting rods are respectively connected with the upper end and the lower end of the rotating part, and the rotating shaft is connected between the two L-shaped connecting rods.

Compared with the prior art, the technical scheme of the invention has the following advantages:

according to the correction device for the titanium alloy tube processing, the data feedback is carried out through the contact type displacement detector in the correction process of the downward pressing of the correction head, so that the contact type displacement detector can detect the displacement change of the titanium alloy tube and feed back the data when the titanium alloy tube rotates, and the movable correction head is pressed down at the position with the maximum displacement range, thereby improving the correction accuracy, reducing the production cost and simplifying the production process; in addition, the invention is always in a full-automatic control state in the processing process, does not need manual intervention, can realize that one person controls a plurality of devices to operate, and improves the working efficiency.

Drawings

In order that the invention may be more readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof that are illustrated in the appended drawings, in which

FIG. 1 is a schematic illustration of a configuration of an orthopedic device for titanium alloy tube machining in accordance with a preferred embodiment of the present invention;

FIG. 2 is a schematic illustration of a rotating roller for use in the titanium alloy tube working orthopedic device shown in FIG. 1;

FIG. 3 is a schematic view of a follower roller for use in the titanium alloy tube working orthopedic device shown in FIG. 1;

FIG. 4 is a schematic illustration of a drive section for use in the titanium alloy tube working orthopedic device shown in FIG. 1.

Description of the specification reference numerals: 100. a base; 110. a through hole;

200. a corrective component; 210. correcting the head; 220. a connecting block; 230. a telescopic cylinder;

300. rotating the roller; 310. rotating the roller fixing member; 311. a mounting groove; 312. a connecting shaft; 320. a rotary drive motor; 330. a drive roller;

400. a follower roller; 410. a first V-groove; 420. a bearing;

500. an auxiliary support assembly; 510. an auxiliary support table; 520. a second V-groove;

600. a contact displacement detector;

700. a titanium alloy tube;

800. a sliding assembly; 810. an auxiliary support shaft;

900. a transmission assembly; 910. a transmission part; 911. a fixing member; 912. a rotary power unit; 913. a transmission roller; 914. an L-shaped connecting rod; 915. a rotating shaft.

Detailed Description

The invention will be further described in connection with the accompanying drawings and specific examples which are set forth so that those skilled in the art will better understand the invention and will be able to practice it, but the examples are not intended to be limiting of the invention.

Referring to fig. 1-4, the invention provides an orthopedic device for titanium alloy tube processing, comprising: the base 100 is a shell structure with openings at the top and the front side, and the base 100 comprises two side plates, a back plate and a bottom plate;

the straightening assembly 200 comprises a straightening head 210 with a telescopic function and a connecting block 220 connected to the top of the straightening head 210, wherein the connecting block 220 is connected to the back plate in a sliding manner, and the connecting block 220 slides back and forth along the length direction of the base 100;

two rotating rollers 300 respectively connected to the inner sides of the two side plates; the rotary roller 300 comprises a rotary roller fixing part 310, a rotary driving motor 320 and a driving roller 330, wherein the rotary roller fixing part 310 is fixedly connected with the inner wall of the side plate, the fixing part of the rotary driving motor 320 is connected with the rotary roller fixing part 310, the rotating part is connected with the driving roller 330, and a power part is arranged in the driving roller 330; in some embodiments, the bottom of the rotating roller fixing member 310 is provided with a mounting groove 311, the fixing portion of the rotating portion is connected to both side walls of the mounting groove 311, the rotating portion of the rotating portion is connected to a connecting shaft 312, the connecting shaft 312 is connected to the driving roller 330, and the axis of the driving roller 330 coincides with the axis of the connecting shaft 312.

The two follower rollers 400 are connected to the top of the bottom plate and are respectively arranged close to the inner sides of the two side plates, the follower rollers 400 are positioned below the rotating rollers 300 and comprise two first V-shaped grooves 410 and two bearings 420 rotatably connected between the two first V-shaped grooves 410, and the axes of the bearings 420 are arranged in parallel with the axial direction of the first V-shaped grooves 410; in some embodiments, the titanium alloy tube 700 is positioned above the first V-groove 410,1-5 mm after being placed on the bearing 420, which reduces friction when the titanium alloy tube 700 rotates so that the rotating rollers 300 drive the titanium alloy tube 700 to operate together.

An auxiliary supporting assembly 500 disposed between the two follower rollers 400 and including an auxiliary supporting table 510 connected to the top of the bottom plate and a second V-shaped groove 520 disposed on the top of the auxiliary supporting table 510; in some embodiments, the plane of the second V-groove 520 is 5mm below the plane of the first V-groove 410 of the follower roller 400, which may act as a stop during the depression of the movable orthotic head 210.

The contact type displacement detector 600 is connected to the top of the base plate and located at one side of the auxiliary supporting assembly 500, and the contact type displacement detector 600 includes a fixed rod and a displacement sensor disposed at the top end of the fixed rod.

Before straightening, the two ends of the titanium alloy tube 700 are first installed between the rotating roller 300 and the follower roller 400, and the rotation of the titanium alloy tube 700 can be achieved by the rotating roller 300. During the orthopedic process, the movable orthotic head 210 presses down on the convex portion of the titanium alloy tube 700, and during the pressing down, the titanium alloy tube 700 touches the contact displacement detector 600 and the displacement data is fed back and collected. High-precision orthopedic processing of the pipe fitting is achieved through detection of the rotation and displacement detector of the titanium alloy pipe 700. That is, the present application can correct the titanium alloy tube 700 through the data feedback of the contact displacement detector 600 during the machining process, thereby improving the correction accuracy.

The rotation driving motor 320 of the rotation roller 300 is operated and drives the driving roller 330 to move upward when the titanium alloy tube 700 is moved, so that a space is left for taking and putting the titanium alloy tube 700 in and out from the front side (at this time, the two driving parts 910 are opened, and the driving parts 910 are described below). The rotary driving motor 320 of the rotary roller 300 drives the driving roller 330 to move downwards to be tangent with the surface of the titanium alloy tube 700 during the correction operation, and the driving roller 330 is internally provided with the driving motor so as to drive the titanium alloy tube 700 to rotate around the axis of the driving motor.

Therefore, in the process of pressing and correcting the correction head 210, the data feedback is performed through the contact displacement detector 600, so that the contact displacement detector 600 can detect the displacement change and feed back the data when the titanium alloy tube 700 rotates, and the movable correction head 210 is pressed down at the position with the maximum displacement range, thereby improving the accuracy in the correction process, reducing the production cost and simplifying the production process; in addition, the invention is always in a full-automatic control state in the processing process, does not need manual intervention, can realize that one person controls a plurality of devices to operate, and improves the working efficiency.

Further, the connection block 220 is slidably connected to the back plate through a sliding assembly 800, and the sliding assembly 800 includes a power part, a screw rod and a slider; the power portion is fixedly connected with the base 100, one end of the screw rod is connected with the power portion, the other end of the screw rod is rotatably connected with the side plate, the sliding block is provided with a threaded hole, the threaded hole is in threaded connection with the screw rod, and the sliding block is fixedly connected with the connecting block 220. In some embodiments, the power portion is a steering engine through which power is provided to the rotation of the lead screw.

Specifically, the reciprocating movement of the connecting block 220 is realized through the cooperation of the screw rod and the sliding block, and the embodiment is simple in structure, stable and reliable.

Further, there are two sliding assemblies 800, and the two sliding assemblies 800 are respectively located above and below the connection block 220.

Specifically, the two slide assemblies 800 make the reciprocating movement of the connection block 220 more stable.

Further, the sliding assembly 800 further includes an auxiliary supporting shaft 810, two ends of the auxiliary supporting shaft 810 are respectively connected with the two side plates, the auxiliary supporting shaft 810 is located between the two sliding assemblies 800, the connecting block 220 is provided with a connecting hole, and the connecting hole and the auxiliary supporting shaft 810 form a sliding pair.

Specifically, the auxiliary supporting shaft 810 plays a role of guiding and supporting the reciprocating movement of the connection block 220.

Further, a telescopic cylinder 230 is arranged at the top of the correction head 210, a telescopic end of the telescopic cylinder 230 is connected with the correction head 210, and a fixed end is connected with the connecting block 220. In some embodiments, the telescoping cylinder 230 is a cylinder.

Specifically, the telescopic cylinder 230 in the present embodiment expands and contracts the correction head 210 to perform correction. Simple structure and stable and reliable operation.

Further, the number of auxiliary supporting tables 510 is plural, and the plurality of auxiliary supporting tables 510 are disposed between the two follower rollers 400 at intervals along the longitudinal direction of the base 100.

In particular, the plurality of auxiliary support stands 510 provide more stable and uniform support for the titanium alloy tube 700.

Further, the number of the contact type displacement detectors 600 is plural, and the plurality of the contact type displacement detectors 600 are respectively disposed between two adjacent auxiliary supporting tables 510 and between the auxiliary supporting tables 510 and the auxiliary supporting assembly 500.

In particular, the plurality of contact displacement detectors 600 may monitor a plurality of points of the titanium alloy tube 700 such that corrective data collection is more accurate.

Further, both side plates are provided with through holes 110 at positions below the rotating roller 300; the orthopedic device further comprises two transmission assemblies 900, wherein the two transmission assemblies 900 are symmetrically arranged on the inner sides of the two side plates; the transmission assembly 900 includes two transmission portions 910, the two transmission portions 910 are symmetrically disposed on the front and rear sides of the through hole 110, the transmission portions 910 include a fixing member 911, a rotating power portion 912 and a transmission roller 913, the fixing member 911 is fixed on the inner wall of the side plate, the fixed end of the rotating power portion 912 is fixedly connected with the fixing member 911, the rotating portion is connected with the transmission roller 913, the transmission roller 913 is internally provided with a power portion, for example, the transmission roller 913 is internally provided with a driving motor, and the driving motor drives the transmission roller 913 to rotate to move and transport the titanium alloy tube 700 to the working position.

Specifically, the through hole 110 and the transmission assembly 900 are provided in this embodiment, such that when the length of the titanium alloy tube 700 is greater than the distance between the two side plates, one end of the titanium alloy tube 700 is inserted into the through hole 110 of one side plate, and the other end of the titanium alloy tube 700 is inserted through the through hole 110 of the other side plate and protrudes out of the side plate. And the two transmission rollers 913 are driven to rotate by the rotary power parts 912 of the two transmission parts 910 to clamp the titanium alloy tube 700, and the displacement of the titanium alloy tube 700 from one end to the other end is realized by the rotation of the transmission rollers 913. This can correct the titanium alloy tube 700 having a longer specification, and further improve the application range. Therefore, the invention realizes the axial conveying and preliminary correction of the long tube through the transmission assembly 900, and realizes the sectional high-precision correction of the long tube through the further correction processing of the correction device.

Further, the rotating part of the rotating power part 912 is connected with an L-shaped connecting rod 914, the free end of the L-shaped connecting rod 914 is connected with a rotating shaft 915, and the transmission roller 913 is rotatably connected on the rotating shaft 915.

Further, there are two L-shaped links 914, the two L-shaped links 914 are respectively connected to the upper and lower ends of the rotating portion, and the rotating shaft 915 is connected between the two L-shaped links 914.

Specifically, the two L-shaped links 914 and the shaft 915 form a closed space, so that the structural heel is stable and reliable.

Taking a titanium alloy tube 700 with a length of 20m and a diameter of 0.5m as an example, the control process using the present invention comprises the following specific steps:

(1) The rotary driving motor 320 drives the driving roller 330 to rotate and lift, the transmission assembly 900 starts to transport the titanium alloy tube 700, the titanium alloy tube 700 above the follow-up roller 400 is primarily corrected, and the rotary roller 300 is pressed down and fixed;

(2) The rotation driving roller 330 drives the titanium alloy tube 700 to rotate, and the contact displacement detector 600 feeds back the displacement difference extreme value of the titanium alloy tube 700 in the rotation process;

(3) Repeating the step (2) for five times, averaging the five data fed back by the plurality of contact displacement detectors 600, comparing the three averages, and pressing the correction head 210 to the limit position of the auxiliary support table 510 at the position of the contact displacement detector 600 corresponding to the maximum value;

(4) Repeating the steps (2) and (3) until the extreme value fed back by the contact displacement detectors 600 is less than 1mm, and completing the correction.

(5) Repeating steps (1) - (4) until the orthopedic is completed.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations and modifications of the present invention will be apparent to those of ordinary skill in the art in light of the foregoing description. It is not necessary here nor is it exhaustive of all embodiments. And obvious changes and modifications which are extended therefrom are still within the scope of the invention.

Claims (10)

1. An orthopedic device for titanium alloy tube processing, characterized in that: comprising the following steps:

the base is a shell structure with openings at the top and the front side, and comprises two side plates, a back plate and a bottom plate;

the correcting assembly comprises a correcting head with a telescopic function and a connecting block connected to the top of the correcting head, wherein the connecting block is connected to the back plate in a sliding manner, and the connecting block slides back and forth along the length direction of the base;

the two rotating rollers are respectively connected to the inner sides of the two side plates; the rotary roller comprises a rotary roller fixing part, a rotary driving motor and a driving roller, wherein the rotary roller fixing part is fixedly connected with the inner wall of the side plate, a fixing part of the rotary driving motor is connected with the rotary roller fixing part, a rotating part is connected with the driving roller, and a power part is arranged in the driving roller;

the two follow-up rollers are connected to the top of the bottom plate and are respectively arranged close to the inner sides of the two side plates, the follow-up rollers are positioned below the rotating rollers and comprise two first V-shaped grooves and two bearings rotatably connected between the two first V-shaped grooves, and the axes of the bearings are parallel to the axial direction of the first V-shaped grooves;

the auxiliary supporting assembly is arranged between the two follow-up rollers and comprises an auxiliary supporting table connected to the top of the bottom plate and a second V-shaped groove arranged on the top of the auxiliary supporting table;

the contact type displacement detector is connected to the top of the bottom plate and located on one side of the auxiliary supporting component, and comprises a fixed rod piece and a displacement sensor arranged at the top end of the fixed rod piece.

2. The orthopedic device for titanium alloy tube working as defined in claim 1, wherein: the connecting block is connected to the back plate in a sliding way through a sliding component, and the sliding component comprises a power part, a screw rod and a sliding block; the power portion with base fixed connection, the one end of lead screw with power portion is connected, the other end with the curb plate rotates to be connected, the slider is equipped with the screw hole, the screw hole with lead screw threaded connection, the slider with connecting block fixed connection.

3. The orthopedic device for titanium alloy tube working as defined in claim 2, wherein: the number of the sliding assemblies is two, and the two sliding assemblies are respectively positioned above and below the connecting block.

4. The orthopedic device for titanium alloy tube working as defined in claim 3, wherein: the sliding assembly further comprises an auxiliary supporting shaft, two ends of the auxiliary supporting shaft are respectively connected with the two side plates, the auxiliary supporting shaft is located between the two sliding assemblies, the connecting block is provided with a connecting hole, and the connecting hole and the auxiliary supporting shaft form a sliding pair.

5. The orthopedic device for titanium alloy tube working as defined in claim 1, wherein: the top of correcting the head is equipped with flexible jar, flexible end of flexible jar with correct the head and be connected, the stiff end with the connecting block is connected.

6. The orthopedic device for titanium alloy tube working as defined in claim 1, wherein: the auxiliary supporting tables are multiple, and the auxiliary supporting tables are arranged between the two follow-up rollers at intervals along the length direction of the base.

7. The orthopedic device for titanium alloy tube working as defined in claim 1, wherein: the contact type displacement detectors are multiple, and the contact type displacement detectors are respectively arranged between two adjacent auxiliary support tables and between the auxiliary support tables and the auxiliary support assembly.

8. The orthopedic device for titanium alloy tube working as defined in claim 1, wherein: the two side plates are provided with through holes at the positions below the rotating rollers; the orthopedic device further comprises two transmission components, wherein the two transmission components are symmetrically arranged on the inner sides of the two side plates; the transmission assembly comprises two transmission parts, the two transmission parts are symmetrically arranged on the front side and the rear side of the through hole, each transmission part comprises a fixing piece, a rotary power part and a transmission roller, the fixing pieces are fixed on the inner wall of the side plate, the fixed ends of the rotary power parts are fixedly connected with the fixing pieces, the rotary parts are connected with the transmission rollers, and the transmission rollers are internally provided with power parts.

9. The orthopedic device for titanium alloy tube working as defined in claim 8, wherein:

the rotating part of the rotating power part is connected with an L-shaped connecting rod, the free end of the L-shaped connecting rod is connected with a rotating shaft, and the transmission roller is rotationally connected to the rotating shaft.

10. The orthopedic device for titanium alloy tube working as defined in claim 9, wherein: the two L-shaped connecting rods are respectively connected with the upper end and the lower end of the rotating part, and the rotating shaft is connected between the two L-shaped connecting rods.