阅读说明：本技术 镗管机床可调镗头 (Adjustable boring head of boring machine tool ) 是由 张振江 高卓 孟华 李国胜 于 2020-04-22 设计创作，主要内容包括：本公开提供了一种镗管机床可调镗头,属于机械加工设备技术领域。将安装组件中安装主体固定在镗杆,矩形安装缺口由一个矩形底面及三个垂直矩形底面的侧壁构成。第一丝杆第一端转动连接在矩形底面上,第二端螺纹插设在滑动块上,滑动块沿第一丝杆的轴向可滑动地设置在矩形安装缺口内。第一驱动组件使第一丝杆转动,第一丝杆转动带动滑动块转动,矩形安装缺口对滑动块周向限位,滑动块带动刀杆一同沿第一丝杆的轴向移动,以调整刀杆的位置。距离测量器则用于测量刀杆在第一丝杆的轴向上的移动距离,对刀杆的移动距离进行监测与量化,避免出现刀杆移动过度导致刀杆上的刀片切削管状工件过深的情况出现。(The utility model provides an adjustable boring head of boring machine tool, belongs to machining equipment technical field. The mounting main body in the mounting assembly is fixed on the boring bar, and the rectangular mounting notch is formed by a rectangular bottom surface and three side walls vertical to the rectangular bottom surface. The first end of the first screw rod is rotatably connected to the bottom surface of the rectangle, the second end thread is inserted into the sliding block, and the sliding block is slidably arranged in the rectangular mounting notch along the axial direction of the first screw rod. First drive assembly makes first lead screw rotate, and first lead screw rotates and drives the sliding block and rotate, and the rectangle installation breach is spacing to sliding block circumference, and the sliding block drives the cutter arbor together along the axial displacement of first lead screw to the position of adjustment cutter arbor. The distance measurer is used for measuring the moving distance of the cutter bar in the axial direction of the first screw rod, monitoring and quantifying the moving distance of the cutter bar, and the situation that the cutter bar moves excessively to cause the cutter blade on the cutter bar to cut the tubular workpiece too deeply is avoided.)

1. The adjustable boring head of the pipe boring machine is characterized by comprising:

the mounting assembly (1) comprises a boring bar (11) and a mounting body (12), wherein the mounting body (12) is fixed on the boring bar (11), the mounting body (12) is provided with a rectangular mounting notch (121), and the rectangular mounting notch (121) is composed of a rectangular bottom surface (121a) and three side walls (121b) vertical to the rectangular bottom surface (121 a);

the adjusting and measuring assembly (2) comprises a first screw rod (21), a sliding block (22), a cutter bar (23) and a distance measuring device (24), wherein the first end of the first screw rod (21) is rotatably connected to the rectangular bottom surface (121a), the second end thread of the first screw rod (21) is inserted in the sliding block (22), the sliding block (22) is slidably arranged in the rectangular mounting notch (121) along the axial direction of the first screw rod (21), the projection of the sliding block (22) on the plane of the rectangular bottom surface (121a) coincides with the rectangular bottom surface (121a), and the distance measuring device (24) is used for measuring the moving distance of the cutter bar (23) in the axial direction of the first screw rod (21);

the first driving assembly (3), the first driving assembly (3) is arranged on the mounting main body (12), and the first driving assembly (3) is used for driving the first screw rod (21) to rotate.

2. The adjustable boring head of the boring machine tool as claimed in claim 1, wherein the sliding block (22) is provided with a rectangular limiting groove (221), the adjusting and measuring assembly (2) further comprises a second lead screw, a first end of the second lead screw is rotatably connected in the rectangular limiting groove (221), the second lead screw is coaxial with the first lead screw (21), a second end of the second lead screw is inserted in the cutter bar (23), the cutter bar (23) is slidably arranged in the rectangular limiting groove (221) along the axial direction of the second lead screw, the cutter bar (23) extends out of the rectangular limiting groove (221), and the projection of the rectangular limiting groove (221) is coincident with the projection of the cutter bar (23) on a plane perpendicular to the axial line of the second lead screw,

the adjustable boring head of the pipe boring machine further comprises a second driving assembly (4) which is arranged on the mounting body (12) and used for driving the second screw rod to rotate.

3. The adjustable boring head of the boring machine tool as claimed in claim 2, characterized in that the part of the tool bar (23) outside the rectangular limiting groove (221) is provided with a measuring plate (232), the distance measuring device (24) is a dial indicator, and the detecting head of the dial indicator is connected to the measuring plate (232).

4. The adjustable boring head of the boring machine tool as claimed in claim 2, wherein the rectangular limiting groove (221) is provided with a guide groove (222), the guide groove (222) extends along the length direction of the rectangular limiting groove (221), and the cutter bar (23) is provided with a guide protrusion (233) which is correspondingly inserted into the guide groove (222).

5. The adjustable boring head of the boring machine as claimed in any one of claims 1 to 4, characterized in that the first drive assembly (3) comprises a first worm gear (31), a first worm (32) and a first drive element (33), the first worm gear (31) is coaxially fixed on the first screw (21), the first worm (32) is meshed with the first worm gear (31), and the first drive element (33) is arranged on the mounting body (12) and is used for driving the first worm (32).

6. The adjustable boring head of a boring machine according to claim 5, characterized in that the mounting body (12) has a semi-annular groove (12a) thereon, and the first driving member (33) is an annular plate coaxially fixed to the first worm (32), the annular plate being coaxially supported within the semi-annular groove (12 a).

7. The adjustable boring head of a boring machine as claimed in claim 5, characterized in that one of the side walls (121b) of the rectangular mounting notch (121) has a support protrusion (122), the support protrusion (122) is located between the sliding block (22) and the rectangular bottom surface (121a), and the first screw (21) is inserted on the support protrusion (122).

8. The adjustable boring head of a boring machine according to claim 7, characterized in that the first worm wheel (31) is located between the support protrusion (122) and the rectangular bottom surface (121 a).

9. The adjustable boring head of the boring machine tool as claimed in any one of claims 1 to 4, wherein the boring bar (11) is provided with a through hole (11a), the mounting body (12) is inserted into the through hole (11a), and the mounting body (12) and the boring bar (11) are fixed through a connecting piece (14).

10. The adjustable boring head of a boring machine according to claim 9, characterized in that the through hole (11a) is a rectangular hole, the mounting body (12) is in a rectangular parallelepiped shape, and the mounting body (12) is in clearance fit with the rectangular hole.

Technical Field

The disclosure relates to the technical field of machining equipment, in particular to an adjustable boring head of a boring pipe machine tool.

Background

The tube boring machine tool is mainly used for machining grooves in tubular workpieces with large apertures, when the tube boring machine tool machines the tubular workpieces, a boring head is arranged on a main shaft of the tube boring machine tool, and a cutter arranged on the boring head is in direct contact with the tubular workpieces for machining. When the cutter performs one-time cutting in the depth direction on the groove on the tubular workpiece, the position of the cutter on the boring head needs to be adjusted to ensure that the cutter can contact the tubular workpiece and perform the next-time cutting in the depth direction on the groove.

In the related art, the position of the tool relative to the boring head is usually manually adjusted to ensure that the tool can further process the tubular workpiece. However, the position of the cutter relative to the boring head is adjusted manually, so that the cutting depth of the cutter is difficult to ensure, the too-deep position adjustment of the cutter is easy to occur, the side wall or the bottom surface of the groove on the tubular workpiece is rough due to the too-deep cutting of the tubular workpiece by the cutter, and the quality of the finally obtained groove is affected.

Disclosure of Invention

The embodiment of the disclosure provides an adjustable boring head of a pipe boring machine, which can ensure the quality of a groove machined on a tubular part. The technical scheme is as follows:

the disclosed embodiment provides an adjustable boring head of a pipe boring machine, which comprises:

the mounting assembly comprises a boring bar and a mounting main body, the mounting main body is fixed on the boring bar, a rectangular mounting notch is formed in the mounting main body, and the rectangular mounting notch is composed of a rectangular bottom surface and three side walls vertical to the rectangular bottom surface;

the adjusting and measuring assembly comprises a first screw rod, a sliding block, a cutter bar and a distance measuring device, wherein the first end of the first screw rod is rotatably connected to the rectangular bottom surface, the second end of the first screw rod is inserted into the sliding block, the sliding block is slidably arranged in the rectangular mounting notch along the axial direction of the first screw rod, the projection of the sliding block on the plane of the rectangular bottom surface is superposed with the rectangular bottom surface, and the distance measuring device is used for measuring the moving distance of the cutter bar in the axial direction of the first screw rod;

the first driving assembly is arranged on the mounting main body and used for driving the first screw rod to rotate.

Optionally, a rectangular limiting groove is formed in the sliding block, the adjusting and measuring assembly further comprises a second lead screw, a first end of the second lead screw is rotatably connected in the rectangular limiting groove, the second lead screw is coaxial with the first lead screw, a second end thread of the second lead screw is inserted in the cutter bar, the cutter bar is slidably arranged in the rectangular limiting groove along the axial direction of the second lead screw, the cutter bar extends out of the rectangular limiting groove, and the projection of the rectangular limiting groove coincides with the projection of the cutter bar on a plane perpendicular to the axis of the second lead screw,

the adjustable boring head of the pipe boring machine further comprises a second driving assembly arranged on the mounting main body and used for driving the second screw rod to rotate.

Optionally, a measuring plate is arranged on a portion of the cutter bar outside the rectangular limiting groove, the distance measuring device is a dial indicator, and a probe of the dial indicator is connected to the measuring plate.

Optionally, the rectangular limiting groove is provided with a guide groove, the guide groove extends along the length direction of the rectangular limiting groove, and the cutter bar is provided with a guide protrusion which is correspondingly inserted into the guide groove.

Optionally, the first driving assembly includes a first worm wheel, a first worm and a first driving member, the first worm wheel is coaxially fixed on the first lead screw, the first worm is engaged with the first worm wheel, and the first driving member is disposed on the mounting body and is used for driving the first worm.

Optionally, the mounting body has a semi-annular groove thereon, the first driving member is an annular plate, the annular plate is coaxially fixed on the first worm, and the annular plate is coaxially supported in the semi-annular groove.

Optionally, a support protrusion is arranged on one side wall of the rectangular installation notch, the support protrusion is located between the sliding block and the rectangular bottom surface, and the first screw rod is inserted into the support protrusion.

Optionally, the first worm gear is located between the support protrusion and the rectangular bottom surface.

Optionally, the boring bar is provided with a through hole, the mounting body is inserted into the through hole, and the mounting body and the boring bar are fixed through a connecting piece.

Optionally, the through hole is a rectangular hole, the mounting body is in a cuboid shape, and the mounting body is in clearance fit with the rectangular hole.

The beneficial effects brought by the technical scheme provided by the embodiment of the disclosure at least comprise:

the boring bar in the mounting assembly is coaxially mounted on a main shaft of a boring pipe machine, the mounting main body is fixed on the boring bar, a rectangular mounting notch in the mounting main body can be used as a mounting part of other components, and the rectangular mounting notch is formed by a rectangular bottom surface and side walls perpendicular to the rectangular bottom surface. The first end of a first screw rod in the adjusting and measuring assembly is rotatably connected to the rectangular bottom surface, the second end thread of the first screw rod is inserted into a sliding block, the sliding block is slidably arranged in the rectangular installation notch along the axial direction of the first screw rod, and the projection of the sliding block on the plane of the rectangular bottom surface coincides with the rectangular bottom surface. When the position of cutter arbor is adjusted to needs, can be through setting up the first drive assembly that is used for driving first lead screw pivoted in the installation main part, make first lead screw rotate, first lead screw rotates and drives the sliding block and rotates, but because the sliding block sets up in rectangle installation breach along the axial slidable of first lead screw in, and the projection and the coincidence of rectangle bottom surface of sliding block on rectangle bottom surface place plane, the three lateral wall of rectangle installation breach realizes circumference spacing to the sliding block, consequently, the sliding block can not rotate, but the cutter arbor that drives on the sliding block is together along the axial displacement of first lead screw, with the position of adjustment cutter arbor. The distance measurer is used for measuring the moving distance of the cutter bar in the axial direction of the first screw rod, monitoring and quantifying the moving distance of the cutter bar, the condition that the cutter bar moves excessively to cause the cutter blade on the cutter bar to cut the tubular workpiece too deeply is avoided, and the quality of the finally obtained groove is ensured.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present disclosure, the drawings used in the description of the embodiments will be briefly introduced below, it is obvious that the drawings in the following description are only some embodiments of the present disclosure, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive efforts,

FIG. 1 is a schematic structural diagram of an adjustable boring head of a pipe boring machine provided by an embodiment of the disclosure;

FIG. 2 is a schematic view of the tool bar and the sliding block provided in the embodiment of the present disclosure;

FIG. 3 is a sectional view taken along A-A of an adjustable boring head of a pipe boring machine provided by an embodiment of the disclosure;

FIG. 4 is a side view of a boring bar provided by embodiments of the present disclosure;

fig. 5 is a schematic structural diagram of a slider provided in the embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the present disclosure more apparent, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of an adjustable boring head of a pipe boring machine provided in an embodiment of the present disclosure, and as can be seen with reference to fig. 1, an embodiment of the present disclosure provides an adjustable boring head of a pipe boring machine, where the adjustable boring head of a pipe boring machine includes:

the mounting assembly 1 comprises a boring bar 11 and a mounting body 12, wherein the mounting body 12 is fixed on the boring bar 11, the mounting body 12 is provided with a rectangular mounting notch 121, and the rectangular mounting notch 121 is composed of a rectangular bottom surface 121a and three side walls 121b vertical to the rectangular bottom surface 121 a.

The adjusting and measuring assembly 2, the adjusting and measuring assembly 2 includes a first screw rod 21, a sliding block 22, a cutter bar 23 and a distance measuring device 24, a first end of the first screw rod 21 is rotatably connected to the rectangular bottom surface 121a, a second end thread of the first screw rod 21 is inserted in the sliding block 22, the sliding block 22 is slidably disposed in the rectangular mounting notch 121 along the axial direction of the first screw rod 21, a projection of the sliding block 22 on the plane where the rectangular bottom surface 121a is located coincides with the rectangular bottom surface 121a, and the distance measuring device 24 is used for measuring a moving distance of the cutter bar 23 in the axial direction of the first screw rod 21.

The first driving assembly 3, the first driving assembly 3 is arranged on the mounting body 12, and the first driving assembly 3 is used for driving the first screw rod 21 to rotate.

The boring bar 11 in the mounting assembly 1 is coaxially mounted on the spindle of the boring machine tool, the mounting body 12 is fixed on the boring bar 11, the rectangular mounting notch 121 in the mounting body 12 can be used as a mounting part for other components, and the rectangular mounting notch 121 is composed of a rectangular bottom surface 121a and side walls 121b perpendicular to the rectangular bottom surface 121 a. The first end of the first screw 21 in the adjustment and measurement assembly 2 is rotatably connected to the rectangular bottom surface 121a, the second end of the first screw 21 is inserted into the sliding block 22, the sliding block 22 is slidably disposed in the rectangular mounting notch 121 along the axial direction of the first screw 21, and the projection of the sliding block 22 on the plane of the rectangular bottom surface 121a coincides with the rectangular bottom surface 121 a. When the position of the tool bar 23 needs to be adjusted, the first screw rod 21 is rotated by the first driving assembly 3 arranged on the mounting body 12 and used for driving the first screw rod 21 to rotate, the first screw rod 21 rotates to drive the sliding block 22 to rotate, but because the sliding block 22 is slidably arranged in the rectangular mounting notch 121 along the axial direction of the first screw rod 21, the projection of the sliding block 22 on the plane where the rectangular bottom surface 121a is located coincides with the rectangular bottom surface 121a, and the three side walls 121b of the rectangular mounting notch 121 realize circumferential limit on the sliding block 22, the sliding block 22 cannot rotate, but drives the tool bar 23 on the sliding block 22 to move along the axial direction of the first screw rod 21 together, so as to adjust the position of the tool bar 23. The distance measurer 24 is used for measuring the moving distance of the cutter bar 23 in the axial direction of the first screw rod 21, monitoring and quantifying the moving distance of the cutter bar 23, avoiding the situation that the cutter bar 23 moves excessively to cause the cutter blade on the cutter bar 23 to cut the tubular workpiece too deeply, and ensuring the quality of the finally obtained groove.

In addition, in the structure of the adjustable boring head of the boring machine tool, the limit of the sliding block 22 is realized through the rectangular mounting notch 121, the limit structure is simple, and the sliding block 22 and other structures can be conveniently disassembled and assembled.

Referring to fig. 1, the tool bar 23 further has a blade mounting opening 231.

The insert mounting opening 231 in the tool bar 23 may facilitate the mounting of the insert.

Referring to fig. 1, in one implementation provided by the present disclosure, the insert 26 may be mounted on the insert mounting opening 231, and the cutting edge 261 of the insert 26 is flush with the axis 21a of the first lead screw 21.

The cutting edge 261 of the blade 26 is flush with the axis 21a of the first screw rod 21, and the blade 26 is not easy to shake when being subjected to force along the axial direction of the first screw rod 21, so that stable work of the blade 26 is ensured to be reduced.

Referring to fig. 1, the first driving assembly 3 may include a first worm wheel 31, a first worm 32 and a first driving member 33, the first worm wheel 31 is coaxially fixed on the first lead screw 21, the first worm 32 is engaged with the first worm wheel 31, and the first driving member 33 is disposed on the mounting body 12 and is used for driving the first worm 32.

The first driving assembly 3 includes a first worm wheel 31, a first worm 32 and a first driving member 33, the first worm wheel 31 is coaxially fixed on the first lead screw 21, the first worm 32 is engaged with the first worm wheel 31, the first driving member 33 is disposed on the mounting body 12 and is used for driving the first worm 32, and the driving of the first lead screw 21 is easy to realize.

Optionally, the lead angle of the first worm 32 is smaller than the friction angle of the first worm 32.

The lead angle of the first worm 32 is smaller than the friction angle of the first worm 32, so that the self-locking effect between the first worm 32 and the first worm wheel 31 can be ensured, the situation that the sliding block 22 and the cutter bar 23 move due to the play of the first worm 32 and the first worm wheel 31 is avoided, and the cutter bar 23 can stably work and be adjusted.

Referring to fig. 1, the mounting body 12 may have a semi-annular groove 12a formed therein, and the first driving member 33 may be an annular plate coaxially fixed to the first worm 32 and coaxially supported in the semi-annular groove 12 a.

The mounting body 12 can be provided with a semi-annular groove 12a, the first driving member 33 is an annular plate, the annular plate is coaxially fixed on the first worm 32, the annular plate is coaxially supported in the semi-annular groove 12a, the semi-annular groove 12a on the mounting body 12 can support the annular plate, and a worker can also drive the first worm 32 to rotate by stirring the annular plate so as to control the first screw rod 21 to rotate, so that the position of the cutter bar 23 can be adjusted conveniently.

Optionally, the annular plate may have a plurality of striking webs thereon.

The arrangement of a plurality of shifting rib plates on the annular plate can facilitate the force application of workers and the shifting of the annular plate.

Optionally, a plurality of striking rib plates on the annular plate can be arranged at equal angular intervals along the circumferential direction of the annular plate. The rotation of the annular plate is convenient to control.

For example, one side wall 121b of the rectangular mounting notch 121 may have a supporting protrusion 122 thereon, the supporting protrusion 122 is located between the sliding block 22 and the rectangular bottom surface 121a, and the first lead screw 21 is inserted on the supporting protrusion 122.

One side wall 121b of the rectangular installation notch 121 is provided with a supporting protrusion 122, the supporting protrusion 122 is located between the sliding block 22 and the rectangular bottom surface 121a, the first screw rod 21 is inserted into the supporting protrusion 122, and the supporting protrusion 122 can support the first screw rod 21 and prevent the first screw rod 21 from moving in the radial direction.

Referring to fig. 1, the first worm wheel 31 may be located between the support protrusion 122 and the rectangular bottom surface 121 a.

The first worm wheel 31 can be located between the supporting protrusion 122 and the rectangular bottom surface 121a, and both the supporting protrusion 122 and the rectangular bottom surface 121a can support the first worm wheel 31 on the first lead screw 21, so that both the first lead screw 21 and the first worm wheel 31 on the first lead screw 21 can be ensured to work stably.

Referring to fig. 1, the bearing 13 is disposed between the first lead screw 21 and the rectangular bottom surface 121 a.

The bearing 13 between the first screw 21 and the rectangular bottom surface 121a can rotatably support the first screw 21 and also can facilitate the rolling installation of the first screw 21.

Exemplarily, the bearing 13 may also be disposed between the first lead screw 21 and the support protrusion 122.

The bearing 13 between the first screw 21 and the supporting protrusion 122 can also rotatably support the first screw 21, and can also facilitate the rolling installation of the first screw 21.

It should be noted that, in other implementation manners provided by the present disclosure, the first driving element 33 may also be configured as a motor or the like, which is not limited by the present disclosure.

It should be noted that, in other implementation manners provided by the present disclosure, the first driving mechanism may also be configured to be in gear transmission, the driving element is engaged with the gear, the gear is coaxially fixed with the first lead screw 21, and rotation of the first lead screw 21 may also be implemented, which is not limited by the present disclosure.

Referring to fig. 1, the sliding block 22 may have a rectangular limiting groove 221, the adjustment and measurement assembly 2 may further include a second lead screw 25, a first end of the second lead screw 25 is rotatably connected in the rectangular limiting groove 221, the second lead screw 25 is coaxial with the first lead screw 21, a second end thread of the second lead screw 25 is inserted on the cutter bar 23, the cutter bar 23 is slidably disposed in the rectangular limiting groove 221 along an axial direction of the second lead screw 25, the cutter bar 23 extends out of the rectangular limiting groove 221, and on a plane perpendicular to an axis of the second lead screw 25, a projection of the rectangular limiting groove 221 coincides with a projection of the cutter bar 23.

The adjustable boring head of the pipe boring machine further comprises a second driving assembly 4 arranged on the mounting body 12 and used for driving the second screw rod 25 to rotate.

The sliding block 22 is provided with a rectangular limiting groove 221, the adjusting and measuring assembly 2 further comprises a second lead screw 25, a first end of the second lead screw 25 is rotatably connected in the rectangular limiting groove 221, the second lead screw 25 is coaxial with the first lead screw 21, a second end thread of the second lead screw 25 is inserted in the cutter bar 23, the cutter bar 23 is slidably arranged in the rectangular limiting groove 221 along the axial direction of the second lead screw 25, the cutter bar 23 extends out of the rectangular limiting groove 221, and on a plane perpendicular to the axis of the second lead screw 25, the projection of the rectangular limiting groove 221 is overlapped with the projection of the cutter bar 23. The second driving assembly 4, which is arranged on the mounting body 12 and is used for driving the second lead screw 25 to rotate, is controlled to drive the second lead screw 25 to rotate, the cutter bar 23 is limited by the rectangular limiting groove 221, the second lead screw 25 directly drives the cutter bar 23 to move axially, and the distance measurer 24 measures the moving distance of the cutter bar 23. The first screw rod 21 and the second screw rod 25 can be respectively matched with the first driving assembly 3 and the second driving assembly 4 to realize the movement of the cutter bar 23, and finally, the axial movement of the cutter bar 23 is measured through the distance measurer 24, so that the movement control of the cutter bar 23 can be facilitated. The whole body is also convenient for dismounting the knife bar 23 and the sliding block 22.

Referring to fig. 1, the portion of the tool bar 23 outside the rectangular position-limiting groove 221 may have a measuring plate 232, the distance measuring device 24 is a dial indicator, and the probe of the dial indicator is connected to the measuring plate 232.

The portion of the tool bar 23 outside the rectangular stop slot 221 may have a measuring plate 232, the distance measuring device 24 is a dial indicator and the probe of the dial indicator is attached to the measuring plate 232. The dial indicator can be convenient for measure and display the moving distance of the cutter bar 23, and is convenient for monitoring and controlling the position of the cutter bar 23 by a worker. And adopt the percentage table and measure the cooperation of board 232 to measure the mode of the displacement of cutter arbor 23, the cost is also lower, easily the holistic realization of scheme.

Alternatively, the dial indicator may be provided on the slide block 22, with the measuring plate 232 on the tool bar 23 and the distance measuring device 24 being a dial indicator.

The measuring plate 232 is located on the cutter bar 23, the dial indicator is located on the sliding block 22, the dial indicator measures the axial moving distance of the cutter bar 23 relative to the sliding block 22 on the second screw rod 25 after the second screw rod 25 rotates, the integral moving distance of the cutter bar 23 and the sliding block 22 is not measured when the first screw rod 21 rotates, and the accuracy of the dial indicator can be guaranteed.

It should be noted that, the portion of the tool bar 23 located outside the rectangular limiting groove 221 may have a measuring plate 232, the distance measuring device 24 is a dial indicator disposed on the sliding block 22, and when a detecting head of the dial indicator is connected to the measuring plate 232, a person skilled in the art can control the sliding block 22 and the tool bar 23 to move through the first lead screw 21 and the first driving assembly 3 before the adjustable boring head of the boring machine tool actually cuts, so as to ensure that the tool bar 23 and the blade and other structures on the tool bar 23 can contact the tubular part. After cutting, the position of the knife bar 23 is adjusted by only the second lead screw 25 and the second driving assembly 4. The first screw rod 21 is adjusted integrally, and the second screw rod 25 is adjusted finely, so that the cutter bar 23 can be moved accurately.

Optionally, the measurement accuracy of the dial indicator is accurate to a thousandth.

The measuring accuracy of the dial indicator is accurate to the thousandth position, the dial indicator can be guaranteed to be accurate in number indication, the possibility of over-cutting of the cutter bar 23 is reduced, and the machining quality of the cutter on the cutter bar 23 to the tubular part is guaranteed.

In other implementations provided by the present disclosure, the measurement plate 232 may also be disposed on the sliding block 22, and the dial indicator is mounted on the mounting body 12, which is not limited by the present disclosure.

Alternatively, in other implementations provided by the present disclosure, the distance measuring device 24 may also be a displacement sensor, and the display panel is used to display the moving distance of the knife bar 23, which is not limited by the present disclosure.

Fig. 2 is a schematic view illustrating the fit between the cutter bar and the sliding block according to the embodiment of the disclosure, and as can be seen from fig. 2, the rectangular limiting groove 221 may have a guide groove 222 thereon, the guide groove 222 extends along the length direction of the rectangular limiting groove 221, and the cutter bar 23 has a guide protrusion 233 correspondingly inserted into the guide groove 222.

The rectangular limiting groove 221 is provided with a guide groove 222 extending along the length direction of the rectangular limiting groove 221, the cutter bar 23 is provided with a guide protrusion 233 correspondingly inserted into the guide groove 222, the guide groove 222 is matched with the guide protrusion 233, the rectangular limiting groove 221 can further limit the cutter bar 23 in the circumferential direction, the cutter bar 23 is prevented from rotating, the guide protrusion 233 and the guide groove 222 can also play a role in guiding and positioning to a certain extent, and the cutter bar 23 is convenient to mount.

Referring to fig. 2, the rectangular limiting groove 221 may have a limiting groove bottom 221a and four limiting groove sidewalls 221b perpendicular to each other, the limiting groove bottom 221a is rectangular, and the four limiting groove sidewalls 221b are perpendicular to the limiting groove bottom 221 a. The guide groove 222 may be provided on one of the stopper groove sidewalls 221 b.

Alternatively, two opposite side walls 221b of the rectangular limiting groove 221 may be provided with a guide groove 222, and the cutter bar 23 has two guide protrusions 233 corresponding to the two guide grooves 222.

Two opposite limiting groove side walls 221b of the rectangular limiting groove 221 are respectively provided with a guide groove 222, and the cutter bar 23 is provided with two guide protrusions 233 corresponding to the two guide grooves 222, so that the cutter bar 23 can be quickly positioned and mounted on the sliding block 22, and the limiting effect on the cutter bar 23 is better.

Referring to fig. 2, the sliding block 22 may have a dovetail groove protrusion 224 thereon, the dovetail groove protrusion 224 extends in the axial direction of the first lead screw 21, and one side wall 121b of the rectangular mounting notch 121 has a dovetail groove 123 corresponding to the dovetail groove protrusion 224.

The dovetail groove protrusion 224 and the dovetail groove 123 cooperate to guide and restrict rotation of the sliding block 22, thereby ensuring stable operation of the sliding block 22.

For example, the mounting body 12 may further include an escape opening 124 corresponding to the metrology plate 232. Facilitating the mounting of the knife bar 23 as a whole.

For example, the second driving assembly 4 may include a second worm wheel 41, a second worm 42 and a second driving member 43, the second worm wheel 41 is coaxially fixed on the second lead screw 25, the second worm 42 is engaged with the second worm wheel 41, and the second driving member 43 is disposed on the mounting body 12 and is used for driving the second worm 42.

The second driving assembly 4 includes a second worm wheel 41, a second worm 42 and a second driving element 43, the second worm wheel 41 is coaxially fixed on the second lead screw 25, the second worm 42 is engaged with the second worm wheel 41, the second driving element 43 is disposed on the mounting body 12 and is used for driving the second worm 42, and the driving of the second lead screw 25 is easy to realize.

Optionally, the lead angle of the second worm 42 is smaller than the friction angle of the second worm 42.

The lead angle of the second worm 42 is smaller than the friction angle of the second worm 42, so that the self-locking effect between the second worm 42 and the second worm wheel 41 can be ensured, the situation that the sliding block 22 and the cutter bar 23 move due to the play of the second worm 42 and the second worm wheel 41 is avoided, and the cutter bar 23 can stably work and be adjusted.

Illustratively, the structure of the second driving member 43 may be the same as that of the first driving member 33, so as to realize the rotation control of the second screw rod 25.

Alternatively, the sliding block 22 may have a mounting groove 223 thereon, the mounting groove 223 is spaced apart from the rectangular stopper groove 221 on the sliding block 22, the second lead screw 25 passes through the mounting groove 223, and the second worm wheel 41 is located in the mounting groove 223.

The sliding block 22 can be provided with a mounting groove 223, the mounting groove 223 and the rectangular limiting groove 221 are arranged on the sliding block 22 at intervals, the second lead screw 25 penetrates through the mounting groove 223, the second worm wheel 41 is located in the mounting groove 223, in the structure, the second lead screw 25 can be well supported by the sliding block 22, and the second worm wheel 41 can also be well matched with the second lead screw 25 to stably drive the second lead screw 25. The second driving assembly 4 needs to occupy a smaller installation space, so that the adjustable boring head of the boring and pipe milling machine is lower in cost.

Exemplarily, the mounting groove 223 includes at least two parallel opposite mounting groove sidewalls 223a, the second screw 25 passes through the two mounting groove sidewalls 223a, and the bearings 13 are disposed between the second screw 25 and the two mounting groove sidewalls 223 a.

The mounting groove 223 at least comprises two parallel opposite mounting groove side walls 223a, the second screw rod 25 passes through the two mounting groove side walls 223a, the bearings 13 are arranged between the second screw rod 25 and the two mounting groove side walls 223a, the bearings 13 can stably support the second screw rod 25 and realize the rolling of the second screw rod 25, and the stable work of the second screw rod 25 is ensured.

It should be noted that, in other implementations provided by the present disclosure, the structure of the second driving assembly 4 and the structure of the first driving assembly 3 may or may not be completely the same, and the present disclosure does not limit this.

Fig. 3 is a sectional view of the adjustable boring head of the pipe boring machine according to the embodiment of the disclosure, and referring to fig. 3, the boring bar 11 may have a through hole 11a, the mounting body 12 is inserted into the through hole 11a, and the mounting body 12 and the boring bar 11 are fixed by a connecting member 14.

The boring bar 11 is provided with a through hole 11a, the mounting body 12 is inserted into the through hole 11a, and the mounting body 12 and the boring bar 11 are fixed through a connecting piece 14, so that the stable connection between the mounting body 12 and the boring bar 11 can be ensured, and the mounting body 12 and the boring bar 11 are convenient to disassemble and assemble.

Illustratively, the mounting body 12 may have a rectangular parallelepiped shape, and the mounting body 12 has a mounting hole for engaging with the connecting member 14, and the connecting member 14 is inserted into the mounting hole and the boring bar 11.

The mounting body 12 may be rectangular, the mounting body 12 has a mounting hole matching with the connecting member 14, and the connecting member 14 is inserted into the mounting hole and the boring bar 11, so as to facilitate connection between the boring bar 11 and the mounting body 12.

Illustratively, the attachment 14 may be a bolt. The connection between the mounting body 12 and the boring bar 11 is facilitated.

In other implementations provided by the present disclosure, the connecting member 14 may also be configured as a screw, a bolt, or a connecting key, which is not limited by the present disclosure.

Fig. 4 is a side view of the boring bar according to the embodiment of the present disclosure, and as can be seen from fig. 4, the through hole 11a may be a rectangular hole, the mounting body 12 has a rectangular shape, and the mounting body 12 is in clearance fit with the rectangular hole.

The through hole 11a may be a rectangular hole, the mounting body 12 is in a rectangular shape, and the mounting body 12 is in clearance fit with the rectangular hole, so that stable mounting of the mounting body 12 in the boring bar 11 can be ensured, and play of the mounting body 12 is avoided.

Fig. 5 is a schematic structural diagram of the sliding block provided in the embodiment of the present disclosure, and as shown in fig. 5, the sliding block 22 may include a connecting end 22a and a mounting end 22b fixedly connected, the connecting end 22a is in threaded connection with the first lead screw 21, the mounting end 22b is connected with the tool bar 23, and a projection of the connecting end 22a on the rectangular bottom surface 121a is smaller than that of the mounting end 22 b.

The sliding block 22 can include a connecting end 22a and a mounting end 22b which are fixedly connected, the connecting end 22a is in threaded connection with the first screw rod 21, the mounting end 22b is connected with the cutter bar 23, and the projection of the connecting end 22a on the rectangular bottom surface 121a is smaller than that of the mounting end 22b, so that the manufacturing cost of the sliding block 22 can be reduced while the stable mounting of the first screw rod 21 and the cutter bar 23 can be ensured.

Optionally, the rectangular limiting groove 221 and the mounting groove 223 are both disposed at the mounting end 22 b. Ensuring the working strength of the slider 22.

The above description is intended to be exemplary only and not to limit the present disclosure, and any modification, equivalent replacement, or improvement made without departing from the spirit and scope of the present disclosure is to be considered as the same as the present disclosure.