CN214079364U - Anchor ring inner hole conical surface machining device - Google Patents

Abstract

The utility model discloses an anchor ring inner hole conical surface processing device, including the taper hole processing rotating device that graduated shaft clamping device and the clamping end that corresponds graduated shaft clamping device set up, taper hole processing rotating device includes the biax mobile device, installs straight hole processing rotating device and taper hole processing rotating device on the biax mobile device, and the rotation axis parallel arrangement of straight hole processing rotating device and taper hole processing rotating device, and the processing end coaxial of straight hole processing rotating device is provided with the straight hole drill bit, and the processing end slip of taper hole processing rotating device is provided with eccentric oblique boring cutter; the straight hole processing rotating device and the taper hole processing rotating device are driven by the rotation driving device to synchronously rotate; the utility model discloses when improving the volume machining efficiency of anchorage zone taper hole, the slope setting through the eccentric mounting to eccentric oblique boring cutter and the edge of a knife makes the taper hole one-time processing target in place, avoids the machining error that bore hole processing brought many times, effectively guarantees the formation of anchorage zone taper hole quality.

Description

Anchor ring inner hole conical surface machining device

Technical Field

The utility model belongs to the technical field of taper hole processingequipment, concretely relates to anchor ring hole conical surface processingequipment.

Background

The anchorage circle is one of the anchor tools commonly used in the building field, and when being processed, the anchorage circle usually needs to be processed with a taper hole in the interior, and the taper hole of the anchorage circle usually requires higher forming quality. The traditional method for processing the inner taper hole of the anchor ring is to directly carry out taper hole boring operation on the anchor ring through a special taper hole boring cutter, and due to the large boring amount, the boring cutter is easy to damage, and a final taper hole can be obtained only by carrying out boring procedures for multiple times; the conventional process of boring the taper hole by pre-drilling and then boring by a boring cutter is also available, but due to the limitation of the boring cutter, the final taper hole can be obtained by boring for multiple times. The process of boring many times not only causes machining efficiency low, and the positioning error that the location caused many times in the process of boring many times also can influence the shaping quality of final anchor ring inner cone hole simultaneously, carries out the taper hole through traditional mode and processes the back, still needs to carry out surface treatment to the inner cone hole of anchor ring usually.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an anchor ring hole conical surface processingequipment realizes that drilling boring taper hole goes on in step in succession, when having improved anchor ring taper hole machining efficiency, through the edge of a knife slope and the eccentric settings of eccentric oblique boring cutter for taper hole bore hole operation once targets in place, avoids the positioning error that bore hole brought many times, effectively ensures the shaping quality in final taper hole.

The utility model discloses a following technical scheme realizes:

a conical surface processing device for an inner hole of an anchor ring comprises an indexing shaft clamping device and a conical hole processing rotating device arranged corresponding to a clamping end of the indexing shaft clamping device, wherein the conical hole processing rotating device comprises a double-shaft moving device, a straight hole processing rotating device and a conical hole processing rotating device are arranged on the double-shaft moving device, rotating axes of the straight hole processing rotating device and the conical hole processing rotating device are arranged in parallel, a straight hole drill bit is coaxially arranged at a processing end of the straight hole processing rotating device, and an eccentric inclined boring cutter is slidably arranged at a processing end of the conical hole processing rotating device; and the straight hole processing rotating device and the taper hole processing rotating device are driven by the rotation driving device to synchronously rotate.

The method comprises the steps that firstly, a straight hole drill bit is driven to drill holes on an anchor ring through a straight hole machining rotating device, then an eccentric inclined boring cutter is moved to a machining station through the movement of a double-shaft moving device, the eccentric inclined boring cutter is driven to rotate through a taper hole machining rotating device, the eccentric inclined boring cutter is enabled to machine the taper hole in place at one time through the inclination angle and the eccentricity of the edge of the eccentric inclined boring cutter, the positioning error caused by repeated machining is avoided, and the forming quality of the final taper hole is effectively guaranteed.

In order to better realize the utility model discloses, furtherly, straight hole processing rotating device's processing end is provided with first mounting groove, the installation sleeve is equipped with to the card in the first mounting groove, the straight hole drill bit has been clamped to the one end that the installation sleeve is close to dividing shaft clamping device.

In order to better realize the utility model discloses, furtherly, the inside fluid passage that is provided with of straight hole drill bit, the one end that straight hole drill bit is close to biax mobile device is provided with the outage that communicates with fluid passage.

For better realization the utility model discloses, furtherly, taper hole processing rotating device's processing end is provided with the second mounting groove, slidable mounting has a mounting base in the second mounting groove, install cutter mounting base on one side that mounting base is close to dividing shaft clamping device, cutter mounting base has clamped eccentric oblique boring cutter on one side that is close to dividing shaft clamping device.

In order to better realize the utility model, furthermore, a plurality of base locking threaded holes are arranged on the bottom surface of the second mounting groove, and base locking holes are arranged on the mounting base corresponding to the locking threaded holes; the tool mounting device is characterized in that a plurality of tool seat locking threaded holes are formed in one side, close to the indexing shaft clamping device, of the mounting base, and tool seat locking holes are formed in the tool mounting base corresponding to the tool seat locking threaded holes.

In order to better realize the utility model discloses, furtherly, the one end that eccentric oblique boring cutter is close to biax mobile device is provided with the edge of a knife of slope, the middle part of the edge of a knife is provided with the chip removal recess.

In order to better realize the utility model, furthermore, the rotation driving device comprises a rotation driving motor, a driving gear, a driven gear, a first toothed belt wheel, a second toothed belt wheel and a transmission toothed belt, the driving gear is sleeved on an output shaft of the driving motor, and the driven gear meshed with the driving gear is sleeved on a rotating shaft of the taper hole processing rotating device; the rotary shaft of the taper hole processing rotating device is further sleeved with a first toothed belt wheel, the rotary shaft of the straight hole processing rotating device is sleeved with a second toothed belt wheel, and the first toothed belt wheel is in transmission connection with the second toothed belt wheel through a transmission toothed belt.

In order to better realize the utility model discloses, furtherly, biax mobile device includes that X is to mobile device, Y to the mobile device, Y is to sliding along Y to the mobile device, and Y is provided with X to the mobile device to sliding along perpendicular X to Y to the top of mobile device, X is provided with straight hole processing rotating device and taper hole processing rotating device to the top of mobile device.

In order to better realize the utility model, the device further comprises a supporting base, the double-shaft moving device is fixedly arranged at one end of the top of the supporting base, and the straight hole processing rotating device and the taper hole processing rotating device are arranged at the other end of the top of the supporting base side by side; the top of the supporting base is provided with a downward-inclined discharging inclined plane.

For better realization the utility model discloses, furtherly, still including corresponding row's material hopper of arranging material inclined plane bottom setting.

Compared with the prior art, the utility model, following advantage and beneficial effect have:

(1) the utility model discloses a set up straight hole processing rotating device and taper hole processing rotating device side by side to drive the system hole drill bit through straight hole processing rotating device and establish the through-hole on the anchor ring first, effectively reduced the processingquantity of follow-up boring taper hole; then, the taper hole machining rotating device drives the eccentric inclined boring cutter to rotate to carry out taper hole boring operation on the through hole of the anchor ring, and due to the arrangement of the inclination angle and the eccentricity of the cutter edge of the eccentric inclined boring cutter, the eccentric inclined boring cutter machines the taper hole in place at one time, so that the positioning error caused by repeated boring machining is avoided, the taper hole machining efficiency is greatly improved, and the final anchor ring taper hole forming quality is further ensured;

(2) the utility model discloses a rotation drive arrangement drives straight hole processing rotating device in step and rotates with the taper hole processing rotating device is synchronous for straight hole processing rotating device is synchronous with the rotational speed of taper hole processing rotating device, avoids the taper hole machining error because the difference in rotation speed causes when drilling straight hole and boring taper hole process conversion, further guarantees the shaping quality of anchor ring taper hole.

Drawings

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

FIG. 2 is a schematic view of the installation of a straight hole machining rotating device and a taper hole machining rotating device;

FIG. 3 is an enlarged schematic view of an eccentric inclined boring tool;

FIG. 4 is an enlarged schematic view of a straight hole drill bit;

fig. 5 is a schematic view of the transmission connection between the straight hole processing rotating device and the taper hole processing rotating device.

Wherein: 1-an indexing shaft clamping device; 2-an inner taper hole processing device; 21-a biaxial movement device; 22-straight hole processing rotating device; 23-a taper hole processing rotating device; 24-straight hole drill bits; 25-eccentric inclined boring cutter; 26-a rotational drive; 27-a support base; 221-mounting the sleeve; 231-a mounting base; 232-a tool mounting base; 261-a drive motor; 262-a drive gear; 263-driven gear; 264-a first toothed pulley; 265-second toothed pulley; 266-drive toothed belt.

Detailed Description

Example 1:

the anchor ring inner hole conical surface processing device of the embodiment comprises a dividing shaft clamping device 1 and an inner conical hole processing device 2 arranged corresponding to a clamping end of the dividing shaft clamping device 1, wherein the inner conical hole processing device 2 comprises a double-shaft moving device 21, a straight hole processing rotating device 22 and a conical hole processing rotating device 23 are installed on the double-shaft moving device 21, rotating axes of the straight hole processing rotating device 22 and the conical hole processing rotating device 23 are arranged in parallel, a straight hole drill bit 24 is coaxially arranged at a processing end of the straight hole processing rotating device 22, and an eccentric inclined boring cutter 25 is slidably arranged at a processing end of the conical hole processing rotating device 23; the straight hole machining rotating device 22 and the taper hole machining rotating device 23 are driven to rotate synchronously by a rotation driving device 26.

The double-shaft moving device 21 can move in the X direction and the Y direction, the X direction and the Y direction are in the same horizontal plane and are perpendicular to each other, the straight hole machining rotating device 22 and the taper hole machining rotating device 23 are arranged on the top of the double-shaft moving device 21 side by side along the Y direction, and the axis of the straight hole machining rotating device 22 and the axis of the taper hole machining rotating device 23 are both parallel to the X axis. The indexing shaft clamping device 1 is arranged on one side of the straight hole machining rotating device 22 and the taper hole machining rotating device 23 along the X direction, and the indexing shaft clamping device 1 is used for clamping and fixing an anchor ring to be machined. The double-shaft moving device 21 moves along the X direction, namely, the straight hole processing rotating device 22 and the taper hole processing rotating device 23 are driven to be close to or far away from the double-shaft moving device 21; the double-shaft moving device 21 moves along the Y direction to drive the straight hole machining rotating device 22 and the taper hole machining rotating device 23 to perform position switching on machining stations corresponding to the clamping ends of the double-shaft moving device 21, and therefore the process switching of drilling and taper hole boring is achieved.

The processing end of the straight hole processing rotating device 22 is coaxially provided with a straight hole drill 24, and the straight hole processing rotating device 22 is driven by the rotation driving device 26 to rotate, so as to drive the straight hole drill 24 to rotate, thereby realizing the drilling operation on the workpiece. After drilling is finished, the double-shaft moving device 21 moves away from the indexing shaft clamping device 1 along the X direction, and the straight hole drill 24 retracts. Then the double-shaft moving device 21 moves along the Y direction, the taper hole machining rotating device 23 is switched to a machining station corresponding to the clamping end of the indexing shaft clamping device 1, then the double-shaft moving device 21 moves along the X direction to be close to the indexing shaft clamping device 1 until the eccentric inclined boring cutter 25 at the machining end of the taper hole machining rotating device 23 is in contact with the inner hole of the workpiece, and taper hole boring operation is carried out. Through the eccentric distance of the eccentric inclined boring cutter 25 and the arrangement of the inclination angle of the cutter edge of the eccentric inclined boring cutter 25, the one-time boring of the taper hole is realized, multiple boring processing is avoided, the boring processing efficiency of the taper hole is improved, and meanwhile, the positioning error of the multiple boring processing is avoided, so that the boring precision of the taper hole is improved, and the forming quality of the inner control surface of the taper hole is effectively ensured. And repeating the steps to realize continuous and efficient machining of the anchor ring taper hole.

Further, the indexing shaft clamping device 1 is an indexing shaft three-jaw chuck.

Example 2:

the present embodiment is further optimized based on embodiment 1, as shown in fig. 2, a first mounting groove is provided at the processing end of the straight hole processing rotating device 22, a mounting sleeve 221 is clamped in the first mounting groove, and a straight hole drill 24 is clamped at one end of the mounting sleeve 221 close to the indexing shaft clamping device 1.

The clamping connection is carried out in the first mounting groove to form a mounting sleeve 221, one end, close to the indexing shaft clamping device 1, of the mounting sleeve 221 is coaxially provided with a mounting clamping groove, one end of the straight-hole drill bit 24 is provided with a clamping block corresponding to the mounting clamping groove, and the straight-hole drill bit 24 is convenient to mount and replace the mounting sleeve 221. Meanwhile, according to the drilling depth requirements of anchors of different specifications, the installation sleeves 221 of different lengths can be conveniently replaced and installed in the first installation groove, so that the distance between the straight-hole drill bit 24 and the indexing shaft clamping device 1 can be adjusted, the straight-hole drill bits 24 of different specifications can be replaced differently, and the cost is saved.

Other parts of this embodiment are the same as embodiment 1, and thus are not described again.

Example 3:

the present embodiment is further optimized based on the above embodiment 1 or 2, as shown in fig. 4, a liquid channel is provided inside the straight-hole drilling head 24, and a liquid drainage hole communicated with the liquid channel is provided at one end of the straight-hole drilling head 24 close to the biaxial movement device 21.

A through hole is coaxially arranged inside the rotating shaft of the straight hole processing rotating device 22, one end of the through hole is connected with the opening end of the liquid channel inside the straight hole drill 24, and the other end of the through hole is connected with the supply end of the cooling liquid supply equipment. The cooling liquid enters the liquid channel inside the straight-hole drill bit 24 through the through hole inside the rotating shaft of the straight-hole processing rotating device 22 and is finally sprayed out of the liquid discharge hole at the processing end of the straight-hole drill bit 24, so that the drill bit is cooled and lubricated during drilling operation, and the straight-hole drill bit 24 is prevented from being damaged due to overheating.

The rest of this embodiment is the same as embodiment 1 or 2, and therefore, the description thereof is omitted.

Example 4:

the present embodiment is further optimized on the basis of any one of the above embodiments 1 to 3, as shown in fig. 2, the processing end of the taper hole processing rotating device 23 is provided with a second mounting groove, a mounting base 231 is slidably mounted in the second mounting groove, a tool mounting base 232 is mounted on one side of the mounting base 231 close to the indexing shaft clamping device 1, and an eccentric inclined boring tool 25 is clamped on one side of the tool mounting base 232 close to the indexing shaft clamping device 1.

The second mounting groove is arranged along the Z direction of the horizontal plane where the X direction and the Y direction are perpendicular to each other, a mounting base 231 is slidably mounted in the second mounting groove along the Z direction, and the eccentric distance of the cutter mounting base 232 is adjusted by adjusting the mounting position of the mounting base 231.

A clamping groove is formed in one side, close to the indexing shaft clamping device 1, of the cutter mounting base 232, and a clamping head connected with the clamping groove in a clamping mode is arranged at one end of the eccentric inclined boring cutter 25, so that the eccentric inclined boring cutter 25 can be conveniently mounted and replaced on the cutter mounting base 232.

Other parts of this embodiment are the same as any of embodiments 1 to 3, and thus are not described again.

Example 5:

the present embodiment is further optimized on the basis of any one of the above embodiments 1 to 4, wherein a plurality of base locking threaded holes are formed on the bottom surface of the second mounting groove, and base locking holes are formed in the mounting base 231 corresponding to the locking threaded holes; a plurality of tool seat locking threaded holes are formed in one side, close to the indexing shaft clamping device 1, of the mounting base 231, and tool seat locking holes are formed in the tool mounting base 232 and correspond to the tool seat locking threaded holes.

After the adjustment of the mounting base is completed along the Z-direction, the fastening bolt is screwed in the aligned base locking threaded hole and the base locking hole, so that the position of the mounting base 231 in the second mounting groove is fixed, and the final eccentricity is fixed.

The easy mounting of the tool mount 232 on the mounting base 231 is achieved by screwing fastening bolts into the aligned tool holder locking threaded holes and tool holder locking holes.

Other parts of this embodiment are the same as any of embodiments 1 to 4, and thus are not described again.

Example 6:

the present embodiment is further optimized on the basis of any one of the above embodiments 1 to 5, as shown in fig. 3, one end of the eccentric inclined boring tool 25 close to the double-shaft moving device 21 is provided with an inclined knife edge, and the middle part of the knife edge is provided with a chip removal groove.

The inclination angle of the knife edge is equal to the inclination angle of the inner hole conical surface to be processed of the anchor ring, the inner hole surface of the anchor ring conical hole is processed by setting the inclination angle of the knife edge, the problem that the conical hole needs to be bored for many times in the traditional boring is solved by matching the eccentricity of the cutter mounting base, the one-time processing of the conical hole is realized, and the problem that the final precision of the conical hole is not enough due to errors of multiple positioning is solved.

Other parts of this embodiment are the same as any of embodiments 1 to 5, and thus are not described again.

Example 7:

the present embodiment is further optimized on the basis of any one of the embodiments 1 to 6, as shown in fig. 5, the rotation driving device 26 includes a rotation driving motor 261, a driving gear 262, a driven gear 263, a first toothed belt wheel 264, a second toothed belt wheel 265, and a transmission toothed belt 266, the driving gear 262 is sleeved on an output shaft of the driving motor 261, and the driven gear 263 engaged with the driving gear 262 is sleeved on a rotating shaft of the taper hole processing rotating device 23; a first toothed belt wheel 264 is further sleeved on the rotating shaft of the taper hole machining rotating device 23, a second toothed belt wheel 265 is sleeved on the rotating shaft of the straight hole machining rotating device 22, and the first toothed belt wheel 264 and the second toothed belt wheel 265 are in transmission connection through a transmission toothed belt 266.

The driving motor 261 drives the driving gear 262 to rotate, and then drives the driven gear 263 to rotate, the driven gear 263 drives the rotating shaft of the taper hole processing rotating device 23 to rotate, and then drives the first toothed belt wheel 264 to rotate, the first toothed belt wheel 264 drives the second toothed belt wheel 265 to rotate through the transmission toothed belt 266, and the second toothed belt wheel 265 drives the rotating shaft of the straight hole processing rotating device 22 to synchronously rotate. The rotation synchronism of the rotating shaft of the straight hole processing rotating device 22 and the rotating shaft of the taper hole processing rotating device 23 is effectively ensured, on the premise that the rotating speed of the rotating shaft of the straight hole processing rotating device 22 is the same as that of the rotating shaft of the taper hole processing rotating device 23, the processing error caused between the straight hole processing and the taper hole processing conversion due to the rotation speed difference can be effectively avoided, and the forming precision of the final taper hole is effectively ensured.

Other parts of this embodiment are the same as any of embodiments 1 to 6, and thus are not described again.

Example 8:

the present embodiment is further optimized on the basis of any one of the above embodiments 1 to 7, where the dual-axis moving device 21 includes an X-direction moving device and a Y-direction moving device, the Y-direction moving device slides along the Y-direction, the top of the Y-direction moving device is provided with the X-direction moving device along the X-direction perpendicular to the Y-direction, and the top of the X-direction moving device is provided with a straight hole machining rotating device 22 and a tapered hole machining rotating device 23.

The X-direction moving device comprises an X-direction base, an X-direction sliding rail and an X-direction driving device, the X-direction base is arranged on the X-direction sliding rail in a sliding mode through a sliding block, and meanwhile the X-direction driving device is arranged at the bottom of the X-direction base and used for driving the X-direction base to slide along the X-direction sliding rail.

Furthermore, the X-direction driving device is any one of a linear screw driving device, a linear air cylinder, a linear oil cylinder and a gear rack linear driving device.

The Y-direction moving device comprises a Y-direction base, a Y-direction sliding rail and a Y-direction driving device, the Y-direction sliding rail is arranged at the top of the X-direction base along the Y direction, the Y-direction base is arranged on the Y-direction sliding rail in a sliding mode through a sliding block, and meanwhile the Y-direction driving device is arranged at the bottom of the Y-direction base and used for driving the Y-direction base to slide along the Y-direction sliding rail.

Furthermore, the Y-direction driving device is any one of a linear screw driving device, a linear air cylinder, a linear oil cylinder and a gear rack linear driving device.

Other parts of this embodiment are the same as any of embodiments 1 to 7, and thus are not described again.

Example 9:

the present embodiment is further optimized on the basis of any one of the above embodiments 1 to 8, and as shown in fig. 1, the present embodiment further includes a supporting base 27, the double-axis moving device 21 is fixedly disposed at one end of the top of the supporting base 27, and the straight hole processing rotating device 22 and the tapered hole processing rotating device 23 are disposed side by side at the other end of the top of the supporting base 27; the top of the supporting base 27 is provided with a downward-inclined discharging inclined plane, and the bottom of the discharging inclined plane is correspondingly provided with a discharging hopper.

The drill chip that produces in the course of working drops at the top of supporting base 27 and along arranging the material inclined plane landing to the row of hopper in, can realize the collection to the drill chip, avoids drill chip pollution work area.

Other parts of this embodiment are the same as any of embodiments 1 to 8, and thus are not described again.

The above is only the preferred embodiment of the present invention, not to the limitation of the present invention in any form, all the technical matters of the present invention all fall into the protection scope of the present invention to any simple modification and equivalent change of the above embodiments.

Claims (10)

1. The anchor ring inner hole conical surface machining device is characterized by comprising an indexing shaft clamping device (1) and an inner conical hole machining device (2) arranged corresponding to a clamping end of the indexing shaft clamping device (1), wherein the inner conical hole machining device (2) comprises a double-shaft moving device (21), a straight hole machining rotating device (22) and a conical hole machining rotating device (23) are installed on the double-shaft moving device (21), rotating axes of the straight hole machining rotating device (22) and the conical hole machining rotating device (23) are arranged in parallel, a straight hole drill bit (24) is coaxially arranged at a machining end of the straight hole machining rotating device (22), and an eccentric inclined boring cutter (25) is slidably arranged at a machining end of the conical hole machining rotating device (23); the straight hole machining rotating device (22) and the taper hole machining rotating device (23) are driven by the rotating driving device (26) to synchronously rotate.

2. An anchor ring inner hole conical surface machining device as claimed in claim 1, wherein the machining end of the straight hole machining rotating device (22) is provided with a first installation groove, a mounting sleeve (221) is clamped in the first installation groove, and a straight hole drill bit (24) is clamped at one end of the mounting sleeve, which is close to the indexing shaft clamping device (1).

3. An anchor ring inner hole conical surface machining device as claimed in claim 2, wherein a liquid channel is arranged inside the straight hole drill bit (24), and a liquid drainage hole communicated with the liquid channel is arranged at one end, close to the double-shaft moving device (21), of the straight hole drill bit (24).

4. An anchor ring inner hole conical surface machining device as claimed in claim 1, wherein the machining end of the conical hole machining rotating device (23) is provided with a second installation groove, a mounting base (231) is slidably installed in the second installation groove, a cutter mounting base (232) is installed on one side, close to the indexing shaft clamping device (1), of the mounting base (231), and an eccentric inclined boring cutter (25) is clamped on one side, close to the indexing shaft clamping device (1), of the cutter mounting base (232).

5. The anchor ring inner hole conical surface machining device as claimed in claim 4, wherein a plurality of base locking threaded holes are formed in the groove bottom surface of the second mounting groove, and base locking holes are formed in the mounting base corresponding to the locking threaded holes; the tool holder is characterized in that a plurality of tool holder locking threaded holes are formed in one side, close to the indexing shaft clamping device (1), of the mounting base, and tool holder locking holes are formed in the tool mounting base (232) corresponding to the tool holder locking threaded holes.

6. The anchor ring inner hole conical surface machining device as claimed in claim 4 or 5, wherein one end of the eccentric inclined boring cutter (25) close to the double-shaft moving device (21) is provided with an inclined cutter edge, and a chip removal groove is formed in the middle of the cutter edge.

7. The anchor ring inner hole conical surface processing device as claimed in any one of claims 1-5, wherein the rotary driving device (26) comprises a rotary driving motor (261), a driving gear (262), a driven gear (263), a first toothed belt wheel (264), a second toothed belt wheel (265) and a transmission toothed belt (266), the driving gear (262) is sleeved on an output shaft of the driving motor (261), and the driven gear (263) meshed with the driving gear (262) is sleeved on a rotating shaft of the conical hole processing rotating device (23); the rotating shaft of the taper hole processing rotating device (23) is further sleeved with a first toothed belt wheel (264), the rotating shaft of the straight hole processing rotating device (22) is sleeved with a second toothed belt wheel (265), and the first toothed belt wheel (264) is in transmission connection with the second toothed belt wheel (265) through a transmission toothed belt (266).

8. An anchor ring inner hole conical surface machining device according to any one of claims 1-5, characterized in that the double-shaft moving device (21) comprises an X-direction moving device and a Y-direction moving device, the Y-direction moving device slides along the Y direction, the top of the Y-direction moving device is provided with the X-direction moving device along the X direction vertical to the Y direction, and the top of the X-direction moving device is provided with a straight hole machining rotating device (22) and a conical hole machining rotating device (23).

9. An anchor ring inner hole conical surface machining device according to any one of claims 1-5, characterized by further comprising a supporting base (27), wherein the double-shaft moving device (21) is fixedly arranged at one end of the top of the supporting base (27), and the straight hole machining rotating device (22) and the taper hole machining rotating device (23) are arranged side by side at the other end of the top of the supporting base (27); the top of the supporting base (27) is provided with a downward-inclined discharging inclined plane.

10. The anchor ring inner hole conical surface machining device as claimed in claim 9, further comprising a discharge hopper arranged corresponding to the bottom of the discharge slope.

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