CN112122926A - Processing equipment of nasal bone chisel - Google Patents

Abstract

The invention relates to the technical field of medical processing equipment, in particular to processing equipment for a nasal bone chisel, which comprises: the device comprises a transverse moving mechanism, a middle supporting assembly, an end rotating mechanism, a longitudinal moving mechanism and a sliding table, wherein the middle supporting assembly is arranged at the output end of the transverse moving mechanism; the thread cutting mechanism is arranged beside the longitudinal moving mechanism, and the technical scheme can be used for cutting the lug and the external thread of the cutter handle, so that the production efficiency is improved, and the product quality is ensured.

Description

Processing equipment of nasal bone chisel

Technical Field

The invention relates to the technical field of medical processing equipment, in particular to processing equipment for a nasal bone chisel.

Background

Medical instruments refer to instruments, devices, appliances, in-vitro diagnostic reagents and calibrators, materials and other similar or related items used directly or indirectly on the human body, including the required computer software.

The effects are obtained mainly by physical means, not by pharmacological, immunological or metabolic means, or they are involved but only as an aid.

For the purpose of diagnosis, prevention, monitoring, treatment, or amelioration of a disease; diagnosis, monitoring, treatment, mitigation, or functional compensation of injury; examination, replacement, regulation or support of a physiological structure or physiological process; support or maintenance of life; controlling pregnancy; by examining a sample from a human body, information is provided for medical or diagnostic purposes.

Chinese patent: CN201720160469.0 discloses nasal bone chisel convenient to change cutting edge, including sword handle and handle of a knife, the sword handle passes through connecting pipe and handle of a knife threaded connection, the one end fixedly connected with cutting edge portion of sword handle, the other end of sword handle is provided with first external screw thread portion, and its tip fixed surface is connected with first lug, the one end of handle of a knife is provided with second external screw thread portion, and its tip fixed surface is connected with the second lug, inside the being provided with respectively in both ends of connecting pipe with first external screw thread portion and second external screw thread portion threaded connection's internal thread portion, the inside slip chamber that is provided with in center of connecting pipe, and the inside slip of slip chamber is provided with the block rubber. This nasal bone chisel convenient to change cutting edge can change the cutting edge portion through the effect of connecting pipe at any time more cutting edge handle, and is very convenient, and fixed firm, need not to change the handle of a knife, has practiced thrift the resource.

However, no processing equipment for the cutter handle in the patent exists at present, so that the processing equipment for the nasal bone chisel needs to be provided, the cutter handle can be subjected to bump cutting and external thread cutting, the production efficiency is improved, and the product quality is guaranteed.

Disclosure of Invention

In order to solve the technical problem, the technical scheme provides the processing equipment for the nasal bone chisel, and the lug cutting and the external thread cutting can be carried out on the cutter handle, so that the production efficiency is improved, and the product quality is ensured.

In order to achieve the above purposes, the technical scheme adopted by the invention is as follows:

a nasal chisel machining apparatus, comprising:

the transverse moving mechanism is used for driving the cutter handle to transversely move;

the middle supporting component is arranged at the output end of the transverse moving mechanism and is used for supporting the middle end part of the cutter handle;

the end rotating mechanism is arranged at the output end of the transverse moving mechanism and is used for driving the end of the cutter handle to rotate;

the longitudinal moving mechanism and the sliding table are symmetrically arranged at two ends of the transverse moving mechanism, two ends of the transverse moving mechanism are respectively connected with output ends of the longitudinal moving mechanism and the sliding table, and the longitudinal moving mechanism is used for driving the transverse moving mechanism to longitudinally move along the sliding table;

the lug cutting mechanism is arranged beside the longitudinal moving mechanism and is used for cutting a lug at the end part of the cutter handle;

and the thread cutting mechanism is arranged beside the longitudinal moving mechanism and is used for cutting out external threads at the end part of the cutter handle.

Preferably, the lateral moving mechanism includes:

the top of the bottom plate is provided with a sliding rail and a rack;

the sliding plate is arranged at the top of the bottom plate, a sliding block is arranged at the bottom of the sliding plate, and the sliding plate is connected with the sliding rail in a sliding mode through the sliding block;

the transverse moving driving assembly is arranged at the top of the bottom plate, the output end of the transverse moving driving assembly is connected with the rack, and the transverse moving driving assembly is used for driving the sliding plate to move along the sliding rail.

Preferably, the traverse driving assembly includes:

the first servo motor is arranged at the top of the bottom plate;

the linkage rod penetrates through the bottom plate and is rotatably connected with the bottom plate, and the stress end of the linkage rod is connected with the output end of the first servo motor;

and the gear is sleeved at the output end of the linkage rod and is fixedly connected with the output end of the linkage rod, and the gear is meshed with the rack.

Preferably, the intermediate support assembly comprises:

the support frame is arranged at the output end of the transverse moving mechanism and is fixedly connected with the output end of the transverse moving mechanism;

the fixing ring is arranged at the top of the support frame and is fixedly connected with the support frame, and a channel is arranged at the inner edge of the fixing ring;

the ball, the ball has a plurality ofly, and a plurality of balls all set up in the inner edge of solid fixed ring and encircle the setting.

Preferably, the end rotating mechanism includes:

the three-jaw chuck is used for clamping and fixing the end part of the cutter handle;

one end of the driving rod is fixedly supported with the non-working part of the three-jaw chuck;

the bearing seat is arranged at the output end of the transverse moving mechanism and is rotatably connected with the driving rod;

and the second servo motor is arranged at the output end of the transverse moving mechanism and is fixedly connected with the output end of the transverse moving mechanism, and the output end of the second servo motor is connected with the other end of the driving rod.

Preferably, the longitudinal moving mechanism includes:

a first base;

the first synchronizing wheel and the second synchronizing wheel are respectively arranged at two ends of the first base, are rotatably connected with the first base and are in transmission connection through a synchronous belt;

the working block is connected with the first base in a sliding mode, the stress end of the working block is connected with the synchronous belt, and the working block is fixedly connected with one end of the transverse moving mechanism;

and the third servo motor is arranged on the first base, and the output end of the third servo motor is connected with the stressed end of the first synchronous wheel.

Preferably, the slide table includes:

a second base;

the two guide rods are arranged on the second base and fixedly connected with the second base;

and the longitudinal moving block is sleeved on the two guide rods respectively, is connected with the two guide rods in a sliding manner, and is fixedly connected with one end of the transverse moving mechanism.

Preferably, the cam cutting mechanism comprises:

the first upright post frame is provided with a top plate;

the first cylinder is arranged at the bottom of the top plate;

the first push plate is arranged at the output end of the first cylinder and fixedly connected with the first cylinder, a first limiting rod is arranged at the top of the first push plate, and the top end of the first limiting rod penetrates through the top plate and is in sliding connection with the top plate;

the first cutter is arranged at the bottom of the first push plate.

Preferably, the thread cutting mechanism includes:

the second upright post frame is arranged beside the longitudinal moving mechanism;

the linear driver is arranged on the second upright post frame;

the back plate is arranged at the output end of the linear driver;

the second cylinder is arranged at the bottom of the back plate;

the second push plate is arranged at the output end of the second cylinder, a second limiting rod is arranged at the top of the second push plate, and the top end of the second limiting rod penetrates through the top plate and is in sliding connection with the top plate;

and the second cutter is arranged at the bottom of the second push plate.

Preferably, the linear actuator includes:

the third base is arranged on the second upright post frame;

the threaded rod is arranged on the third base and is rotatably connected with the third base;

the movable plate is connected with the third base in a sliding mode and is in threaded connection with the threaded rod;

and the fourth servo motor is arranged on the third base, and the output end of the fourth servo motor is connected with the stress end of the threaded rod.

Compared with the prior art, the invention has the beneficial effects that: the worker penetrates the middle support assembly and inserts the knife handle into the output end of the end rotating mechanism, the middle of the knife handle is supported at the moment, the knife handle rotates in the middle, the end rotating mechanism starts to work, the output end of the end rotating mechanism clamps the end part of the knife handle, then the transverse moving mechanism starts to work, the output end of the transverse moving mechanism drives the middle support assembly and the end rotating mechanism to approach the output end of the lug cutting mechanism, the middle support assembly and the end rotating mechanism drive the knife handle to move to the output end of the lug cutting mechanism, one end of the knife handle is positioned at the output end of the lug cutting mechanism at the moment, the output end of the end rotating mechanism drives the knife handle to rotate, meanwhile, the lug cutting mechanism starts to work, the output end of the lug cutting mechanism descends until the outer edge of the end part, then the transverse moving mechanism starts to work again, the output end of the transverse moving mechanism drives the middle supporting component and the end rotating mechanism to be away from the lug cutting mechanism, the middle supporting component and the end rotating mechanism drive the tool shank to be away from the output end of the lug cutting mechanism, the longitudinal moving mechanism starts to work, the output end of the longitudinal moving mechanism drives the transverse moving mechanism to move along the sliding table, so that the tool shank and the output end of the thread cutting mechanism are in a coaxial state at the moment, then the transverse moving mechanism starts to work, the output end of the transverse moving mechanism drives the middle supporting component and the end rotating mechanism to be close to the output end of the thread cutting mechanism, the tool shank is close to the output end of the thread cutting mechanism, then the thread cutting mechanism starts to work, the output end of the thread cutting mechanism starts to descend to the outer edge of the end part of the tool shank, and the output end of the thread cutting mechanism performs external thread cutting on the outer edge of the tool shank;

through the arrangement of the equipment, the lug cutting and the external thread cutting can be carried out on the cutter handle, the production efficiency is improved, and the product quality is ensured.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of the lateral shifting mechanism of the present invention;

FIG. 3 is a side view of the lateral movement mechanism of the present invention;

FIG. 4 is a front view of the mid-support assembly of the present invention;

FIG. 5 is a schematic perspective view of an end-rotating mechanism of the present invention;

FIG. 6 is a schematic perspective view of the longitudinal movement mechanism of the present invention;

FIG. 7 is a schematic perspective view of a slide table according to the present invention;

FIG. 8 is a schematic perspective view of a bump cutting mechanism according to the present invention;

FIG. 9 is a perspective view of the thread cutting mechanism of the present invention;

fig. 10 is a schematic perspective view of the linear actuator of the present invention.

The reference numbers in the figures are:

1-a lateral movement mechanism; 1 a-a bottom plate; 1a 1-slide; 1a 2-rack; 1 b-a skateboard; 1b1 — slide; 1 c-a traverse driving assembly; 1c1 — first servomotor; 1c 2-trace; 1c 3-gear;

2-a middle support assembly; 2 a-a support frame; 2 b-a fixed ring; 2 c-a ball;

3-an end rotation mechanism; 3 a-a three-jaw chuck; 3 b-a drive rod; 3 c-bearing seat; 3 d-a second servo motor;

4-a longitudinal movement mechanism; 4 a-a first base; 4 b-a first synchronizing wheel; 4 c-a second synchronizing wheel; 4 d-working is fast; 4 e-a third servo motor;

5-a sliding table; 5 a-a second base; 5 b-a guide bar; 5 c-longitudinal moving block;

6-a bump cutting mechanism; 6 a-a first post frame; 6a 1-top plate; 6 b-a first cylinder; 6 c-a first push plate; 6c 1-first stop bar; 6 d-first tool;

7-a thread cutting mechanism; 7 a-a second post frame; 7 b-linear drive; 7b 1-third base; 7b 2-threaded rod; 7b 3-movable plate; 7b 4-fourth servomotor; 7 c-a back plate; 7 d-a second cylinder; 7 e-a second push plate; 7 f-a second tool;

8-knife handle.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

Referring to fig. 1, a nasal osteotome machining apparatus includes:

the transverse moving mechanism 1 is used for driving the cutter handle to transversely move;

the middle supporting component 2 is arranged at the output end of the transverse moving mechanism 1, and the middle supporting component 2 is used for supporting the middle end part of the cutter handle;

the end rotating mechanism 3 is arranged at the output end of the transverse moving mechanism 1, and the end rotating mechanism 3 is used for driving the end of the cutter handle to rotate;

the longitudinal moving mechanism 4 and the sliding table 5 are symmetrically arranged at two ends of the transverse moving mechanism 1, two ends of the transverse moving mechanism 1 are respectively connected with output ends of the longitudinal moving mechanism 4 and the sliding table 5, and the longitudinal moving mechanism 4 is used for driving the transverse moving mechanism 1 to longitudinally move along the sliding table 5;

the lug cutting mechanism 6 is arranged beside the longitudinal moving mechanism 4, and the lug cutting mechanism 6 is used for cutting a lug at the end part of the cutter handle;

the thread cutting mechanism 7 is arranged beside the longitudinal moving mechanism 4, and the thread cutting mechanism 7 is used for cutting an external thread at the end part of the cutter handle;

the worker penetrates the middle support assembly 2 and inserts the knife handle into the output end of the end rotating mechanism 3, the middle of the knife handle is supported at the moment, the knife handle rotates in the middle, the end rotating mechanism 3 starts to work, the output end of the end rotating mechanism 3 clamps the end of the knife handle, then the transverse moving mechanism 1 starts to work, the output end of the transverse moving mechanism 1 drives the middle support assembly 2 and the end rotating mechanism 3 to approach the output end of the bump cutting mechanism 6, the middle support assembly 2 and the end rotating mechanism 3 drive the knife handle to move to the output end of the bump cutting mechanism 6, one end of the knife handle is positioned at the output end of the bump cutting mechanism 6 at the moment, the output end of the end rotating mechanism 3 drives the knife handle to rotate, meanwhile, the bump cutting mechanism 6 starts to work, the output end of the bump cutting mechanism 6 descends until, at the moment, a lug is cut at the end part of the cutter handle, then the transverse moving mechanism 1 starts to work again, the output end of the transverse moving mechanism 1 drives the middle supporting component 2 and the end rotating mechanism 3 to be far away from the lug cutting mechanism 6, the middle supporting component 2 and the end rotating mechanism 3 drive the cutter handle to be far away from the output end of the lug cutting mechanism 6, the longitudinal moving mechanism 4 starts to work, the output end of the longitudinal moving mechanism 4 drives the transverse moving mechanism 1 to move along the sliding table 5, so that the cutter handle and the output end of the thread cutting mechanism 7 are in a coaxial state at the moment, then the transverse moving mechanism 1 starts to work, the output end of the transverse moving mechanism 1 drives the middle supporting component 2 and the end rotating mechanism 3 to be close to the output end of the thread cutting mechanism 7, the cutter handle is close to the output end of the thread cutting mechanism 7, then, and the output end of the thread cutting mechanism 7 performs external thread cutting on the outer edge of the tool shank.

As shown in fig. 2, the lateral movement mechanism 1 includes:

the top of the bottom plate 1a is provided with a sliding rail 1a1 and a rack 1a 2;

the sliding plate 1b is arranged at the top of the bottom plate 1a, the bottom of the sliding plate 1b is provided with a sliding block 1b1, and the sliding plate 1b is connected with the sliding rail 1a1 in a sliding manner through a sliding block 1b 1;

the transverse moving driving assembly 1c is arranged at the top of the bottom plate 1a, the output end of the transverse moving driving assembly 1c is connected with the rack 1a2, and the transverse moving driving assembly 1c is used for driving the sliding plate 1b to move along the sliding rail 1a 1;

the transverse moving mechanism 1 starts to work, the transverse moving driving assembly 1c starts to work, the output end of the transverse moving driving assembly 1c starts to rotate, the transverse moving driving assembly 1c drives the sliding plate 1b to transversely move along the sliding rail 1a1, the rack 1a2 is used for being connected with the output end of the transverse moving driving assembly 1c, and the slider 1b1 is used for being connected with the sliding rail 1a1 in a sliding mode.

The traverse driving assembly 1c shown in FIG. 3 includes:

a first servo motor 1c1 disposed on the top of the base plate 1 a;

the linkage rod 1c2, the linkage rod 1c2 penetrates the bottom plate 1a and is rotatably connected with the bottom plate, and the stress end of the linkage rod 1c2 is connected with the output end of the first servo motor 1c 1;

the gear 1c3 and the gear 1c3 are sleeved at the output end of the linkage rod 1c2 and are fixedly connected with the output end, and the gear 1c3 is meshed with the rack 1a 2;

the traverse driving assembly 1c starts to work, the first servo motor 1c1 starts to work, the output end of the first servo motor 1c1 drives the linkage rod 1c2 to rotate, the linkage rod 1c2 drives the gear 1c3 to rotate, and since the gear 1c3 is meshed with the rack 1a2, when the gear 1c3 rotates, the linkage rod 1c2 drives the sliding plate 1b to move along the sliding rail 1a1 in the reverse direction.

The intermediate support assembly 2 as shown in fig. 4 comprises:

the supporting frame 2a is arranged at the output end of the transverse moving mechanism 1 and is fixedly connected with the output end;

the fixing ring 2b is arranged at the top of the support frame 2a and is fixedly connected with the support frame, and a channel is arranged at the inner edge of the fixing ring 2 b;

a plurality of balls 2c, wherein the balls 2c are arranged on the inner edge of the fixed ring 2b and are arranged in a surrounding way;

when the staff runs through the fixing ring 2b with the hilt, and the end of the hilt is at the output end of the end rotating mechanism 3, the middle part of the hilt is supported by the balls 2c, the hilt can be rotated by the balls 2c, the fixing ring 2b is used for supporting the balls 2c, and the support frame 2a is used for supporting the fixing ring 2 b.

As shown in fig. 5, the end-turning mechanism 3 includes:

the three-jaw chuck 3a is used for clamping and fixing the end part of the cutter handle;

one end of the driving rod 3b is fixedly supported with the non-working part of the three-jaw chuck 3 a;

the bearing seat 3c is arranged at the output end of the transverse moving mechanism 1, and the bearing seat 3c is rotatably connected with the driving rod 3 b;

the second servo motor 3d is arranged at the output end of the transverse moving mechanism 1 and is fixedly connected with the output end of the transverse moving mechanism, and the output end of the second servo motor 3d is connected with the other end of the driving rod 3 b;

the three-jaw chuck 3a starts to work, the three-jaw chuck 3a clamps one end of the tool shank tightly and fixedly, the output end of the second servo motor 3d drives the driving rod 3b to rotate, the driving rod 3b drives the three-jaw chuck 3a to rotate, the three-jaw chuck 3a drives the end part of the tool shank to rotate, and the bearing seat 3c is used for fixing and supporting.

The longitudinal movement mechanism 4 shown in fig. 6 includes:

a first base 4 a;

the first synchronizing wheel 4b and the second synchronizing wheel 4c are respectively arranged at two ends of the first base 4a, the first synchronizing wheel 4b and the second synchronizing wheel 4c are rotatably connected with the first base 4a, and the first synchronizing wheel 4b and the second synchronizing wheel 4c are in transmission connection through a synchronous belt;

the working block 4d is connected with the first base 4a in a sliding mode, the stress end of the working block 4d is connected with the synchronous belt, and the working block 4d is fixedly connected with one end of the transverse moving mechanism 1;

the third servo motor 4e is arranged on the first base 4a, and the output end of the third servo motor 4e is connected with the stress end of the first synchronous wheel 4 b;

the longitudinal movement mechanism 4 begins to work, and the third servo motor 4e begins to work, and the output of third servo motor 4e drives first synchronizing wheel 4b and rotates, and first synchronizing wheel 4b passes through the fast 4d longitudinal movement of hold-in range drive work, and second synchronizing wheel 4c is used for supporting the hold-in range and the cooperation rotates, and first base 4a is used for the fixed stay.

The slide table 5 shown in fig. 7 includes:

a second base 5 a;

two guide rods 5b are arranged, the two guide rods 5b are arranged on the second base 5a, and the two guide rods 5b are fixedly connected with the second base 5 a;

the longitudinal moving blocks 5c are respectively sleeved on the two guide rods 5b, the longitudinal moving blocks 5c are respectively connected with the two guide rods 5b in a sliding manner, and the guide rods 5b are fixedly connected with one end of the transverse moving mechanism 1;

the second base 5a is used for fixed support, the two guide rods 5b are used for supporting the longitudinal moving block 5c and sliding in a matched mode, and the longitudinal moving block 5c is used for supporting one end of the transverse moving mechanism 1 and moving in a matched mode.

The cam cutting mechanism 6 shown in fig. 8 includes:

a first column frame 6a, wherein a top plate 6a1 is arranged on the first column frame 6 a;

a first cylinder 6b provided at the bottom of the top plate 6a 1;

the first push plate 6c is arranged at the output end of the first air cylinder 6b and is fixedly connected with the output end of the first air cylinder 6b, a first limiting rod 6c1 is arranged at the top of the first push plate 6c, and the top end of the first limiting rod 6c1 penetrates through the top plate 6a1 and is connected with the top plate in a sliding mode;

a first cutter 6d provided at the bottom of the first push plate 6 c;

the bump cutting mechanism 6 starts to work, the first air cylinder 6b starts to work, the output end of the first air cylinder 6b pushes the first push plate 6c to descend, the first push plate 6c drives the first cutter 6d to descend until the first cutter 6d contacts the outer edge of the end part of the cutter handle, the bump at the end part of the cutter handle is cut out due to the fact that the cutter handle is in a rotating state, the first upright post frame 6a and the top plate 6a1 are used for fixing and supporting, and the first limiting rod 6c1 is used for preventing the first push plate 6c from rotating.

The screw cutting mechanism 7 shown in fig. 9 includes:

a second upright post frame 7a arranged beside the longitudinal moving mechanism 4;

a linear actuator 7b provided on the second column frame 7 a;

a back plate 7c disposed at an output end of the linear driver 7 b;

a second cylinder 7d provided at the bottom of the back plate 7 c;

the second push plate 7e is arranged at the output end of the second air cylinder 7d, a second limiting rod is arranged at the top of the second push plate 7e, and the top end of the second limiting rod penetrates through the top plate 6a1 and is in sliding connection with the top plate;

a second cutter 7f disposed at the bottom of the second push plate 7 e;

the thread cutting mechanism 7 starts to work, the output end of the second air cylinder 7d pushes the second push plate 7e to descend until the second cutter 7f contacts the outer edge of the end part of the cutter handle, the cutter handle is rotating at the moment, and the output end of the linear driver 7b drives the second cutter 7f to move in a small range to cut external threads.

The linear actuator 7b shown in fig. 10 includes:

a third base 7b1 provided on the second column frame 7 a;

a threaded rod 7b2 disposed on the third base 7b1 and rotatably connected thereto;

a movable plate 7b3, the movable plate 7b3 being slidably connected with the third base 7b1, and the movable plate 7b3 being threadedly connected with the threaded rod 7b 2;

the fourth servo motor 7b4 is arranged on the third base 7b1, and the output end of the fourth servo motor 7b4 is connected with the force bearing end of the threaded rod 7b 2;

the linear driver 7b starts to work, the output end of the fourth servo motor 7b4 drives the threaded rod 7b2 to rotate, the threaded rod 7b2 drives the movable plate 7b3 to move transversely in a small range, the movable plate 7b3 drives the second cutter 7f, and the third base 7b1 is used for fixed support.

The working principle of the invention is as follows: firstly, a worker penetrates the tool shank through the fixing ring 2b, the end part of the tool shank is positioned at the output end of the three-jaw chuck 3a, the middle part of the tool shank is supported by the balls 2c, the tool shank can rotate through the arrangement of the balls 2c, the three-jaw chuck 3a starts to work to clamp and fix one end of the tool shank, then the transverse moving mechanism 1 starts to work, the transverse moving driving assembly 1c starts to work, the first servo motor 1c1 starts to work, the output end of the first servo motor 1c1 drives the linkage rod 1c2 to rotate, the linkage rod 1c2 drives the gear 1c3 to rotate, as the gear 1c3 is meshed with the rack 1a2, when the gear 1c3 rotates, the linkage rod 1c2 drives the sliding plate 1b to approach the projection cutting mechanism 6 along the sliding rail 1a1, the sliding plate 1b drives the output end of the projection cutting mechanism 6 to move, and the other end of the tool shank is positioned at the output end, the output end of the second servo motor 3d drives the driving rod 3b to rotate, the driving rod 3b drives the three-jaw chuck 3a to rotate, the three-jaw chuck 3a drives the end part of the tool shank to rotate, meanwhile, the lug cutting mechanism 6 starts to work, the first air cylinder 6b starts to work, the output end of the first air cylinder 6b pushes the first push plate 6c to descend, the first push plate 6c drives the first tool 6d to descend until the first tool 6d contacts the outer edge of the end part of the tool shank, as the tool shank is in a rotating state at the moment, the lug at the end part of the tool shank is cut out, then the transverse moving mechanism 1 starts to work again, the output end of the transverse moving mechanism 1 drives the middle supporting component 2 and the end part rotating mechanism 3 to be far away from the lug cutting mechanism 6, the middle supporting component 2 and the end part rotating mechanism 3 drive the tool shank, the third servo motor 4e starts to work, the output end of the third servo motor 4e drives the first synchronous wheel 4b to rotate, the first synchronous wheel 4b drives the working block 4d and the thread cutting mechanism 7 to be in a coaxial state through the synchronous belt, then the transverse moving mechanism 1 starts to work, the output end of the transverse moving mechanism 1 drives the middle supporting component 2 and the end rotating mechanism 3 to be close to the output end of the thread cutting mechanism 7, the tool shank is close to the output end of the thread cutting mechanism 7, then the thread cutting mechanism 7 starts to work, the output end of the second air cylinder 7d pushes the second push plate 7e to start to descend until the second tool 7f contacts the outer edge of the end of the tool shank, the tool shank is rotating at the moment, and the output end of the linear driver 7b drives the second tool 7f to move within a small range to cut the outer thread.

The device realizes the functions of the invention through the following steps, thereby solving the technical problems provided by the invention:

firstly, a worker penetrates a cutter handle through the middle supporting component 2 and inserts the cutter handle into the output end of the end rotating mechanism 3;

secondly, clamping the end part of the cutter handle by the output end of the end part rotating mechanism 3;

step three, the transverse moving mechanism 1 starts to work, the output end of the transverse moving mechanism 1 drives the cutter handle to move to the output end of the bump cutting mechanism 6, at the moment, one end of the cutter handle is positioned at the output end of the bump cutting mechanism 6,

fourthly, the output end of the end rotating mechanism 3 drives the cutter handle to rotate;

step five, 6, starting to work, descending the output end of the bump cutting mechanism 6 until the outer edge of the end part of the cutter handle cuts the outer edge of the cutter handle, and cutting the bump at the end part of the cutter handle;

sixthly, the transverse moving mechanism 1 starts to work again, and the output end of the transverse moving mechanism 1 drives the cutter handle to be far away from the lug cutting mechanism 6;

seventhly, the longitudinal moving mechanism 4 starts to work, and the output end of the longitudinal moving mechanism 4 drives the transverse moving mechanism 1 to move along the sliding table 5, so that the tool shank and the output end of the thread cutting mechanism 7 are in a coaxial state at the moment;

step eight, the output end of the transverse moving mechanism 1 drives the middle supporting component 2 and the end rotating mechanism 3 to be close to the output end of the thread cutting mechanism 7, and the tool shank is close to the output end of the thread cutting mechanism 7;

and ninthly, starting the thread cutting mechanism 7 to work, enabling the output end of the thread cutting mechanism 7 to descend to the outer edge of the end part of the tool shank, and cutting the outer thread of the outer edge of the tool shank by the output end of the thread cutting mechanism 7.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. A nasal chisel machining apparatus, comprising:

the transverse moving mechanism (1), the transverse moving mechanism (1) is used for driving the cutter handle to transversely move;

the middle supporting component (2) is arranged at the output end of the transverse moving mechanism (1), and the middle supporting component (2) is used for supporting the middle end part of the cutter handle;

the end rotating mechanism (3) is arranged at the output end of the transverse moving mechanism (1), and the end rotating mechanism (3) is used for driving the end of the cutter handle to rotate;

the device comprises a longitudinal moving mechanism (4) and a sliding table (5), wherein the longitudinal moving mechanism (4) and the sliding table (5) are symmetrically arranged at two ends of a transverse moving mechanism (1), two ends of the transverse moving mechanism (1) are respectively connected with output ends of the longitudinal moving mechanism (4) and the sliding table (5), and the longitudinal moving mechanism (4) is used for driving the transverse moving mechanism (1) to longitudinally move along the sliding table (5);

the bump cutting mechanism (6) is arranged beside the longitudinal moving mechanism (4), and the bump cutting mechanism (6) is used for cutting a bump at the end part of the cutter handle;

and the thread cutting mechanism (7) is arranged beside the longitudinal moving mechanism (4), and the thread cutting mechanism (7) is used for cutting out an external thread at the end part of the cutter handle.

2. A nasal osteotome machining apparatus according to claim 1, wherein the lateral movement mechanism (1) comprises:

the top of the bottom plate (1 a) is provided with a sliding rail (1 a 1) and a rack (1 a 2);

the sliding plate (1 b) is arranged at the top of the bottom plate (1 a), the bottom of the sliding plate (1 b) is provided with a sliding block (1 b 1), and the sliding plate (1 b) is connected with the sliding rail (1 a 1) in a sliding mode through a sliding block (1 b 1);

the transverse moving driving assembly (1 c) is arranged at the top of the bottom plate (1 a), the output end of the transverse moving driving assembly (1 c) is connected with the rack (1 a 2), and the transverse moving driving assembly (1 c) is used for driving the sliding plate (1 b) to move along the sliding rail (1 a 1).

3. A nasal osteotome machining apparatus according to claim 2, wherein the traverse drive assembly (1 c) comprises:

a first servo motor (1 c 1) arranged on the top of the bottom plate (1 a);

the linkage rod (1 c 2), the linkage rod (1 c 2) penetrates through the bottom plate (1 a) and is rotatably connected with the bottom plate, and the stress end of the linkage rod (1 c 2) is connected with the output end of the first servo motor (1 c 1);

the gear (1 c 3), the gear (1 c 3) is located the output of trace (1 c 2) and is connected with it fixedly to gear (1 c 3) and rack (1 a 2) meshing.

4. A nasal chisel machining apparatus as claimed in claim 1, wherein the central support assembly (2) comprises:

the support frame (2 a) is arranged at the output end of the transverse moving mechanism (1) and is fixedly connected with the output end;

the fixing ring (2 b) is arranged at the top of the support frame (2 a) and is fixedly connected with the support frame, and a channel is arranged at the inner edge of the fixing ring (2 b);

the ball (2 c), ball (2 c) have a plurality ofly, and a plurality of ball (2 c) all set up in the inner edge of solid fixed ring (2 b) and encircle the setting.

5. A nasal chisel machining apparatus as claimed in claim 1, wherein the end rotation mechanism (3) comprises:

the three-jaw chuck (3 a), the three-jaw chuck (3 a) is used for clamping and fixing the end part of the tool shank;

one end of the driving rod (3 b) is fixedly supported with the non-working part of the three-jaw chuck (3 a);

the bearing seat (3 c) is arranged at the output end of the transverse moving mechanism (1), and the bearing seat (3 c) is rotatably connected with the driving rod (3 b);

and the second servo motor (3 d) is arranged at the output end of the transverse moving mechanism (1) and is fixedly connected with the output end of the transverse moving mechanism, and the output end of the second servo motor (3 d) is connected with the other end of the driving rod (3 b).

6. A nasal chisel machining apparatus according to claim 1, wherein the longitudinal moving mechanism (4) comprises:

a first base (4 a);

the first synchronizing wheel (4 b) and the second synchronizing wheel (4 c) are respectively arranged at two ends of the first base (4 a), the first synchronizing wheel (4 b) and the second synchronizing wheel (4 c) are rotatably connected with the first base (4 a), and the first synchronizing wheel (4 b) and the second synchronizing wheel (4 c) are in transmission connection through a synchronous belt;

the working block (4 d) is connected with the first base (4 a) in a sliding mode, the stress end of the working block (4 d) is connected with the synchronous belt, and the working block (4 d) is fixedly connected with one end of the transverse moving mechanism (1);

and the third servo motor (4 e) is arranged on the first base (4 a), and the output end of the third servo motor (4 e) is connected with the stress end of the first synchronous wheel (4 b).

7. A nasal chisel machining apparatus according to claim 1, wherein the slide table (5) includes:

a second base (5 a);

two guide rods (5 b), wherein the two guide rods (5 b) are arranged on the second base (5 a), and the two guide rods (5 b) are fixedly connected with the second base (5 a);

the longitudinal moving blocks (5 c) are respectively sleeved on the two guide rods (5 b), the longitudinal moving blocks (5 c) are connected with the two guide rods (5 b) in a sliding mode, and the guide rods (5 b) are fixedly connected with one end of the transverse moving mechanism (1).

8. A nasal chisel machining apparatus according to claim 1, wherein the cam cutting mechanism (6) comprises:

a first upright post frame (6 a), wherein a top plate (6 a 1) is arranged on the first upright post frame (6 a);

a first cylinder (6 b) provided at the bottom of the top plate (6 a 1);

the first push plate (6 c) is arranged at the output end of the first air cylinder (6 b) and is fixedly connected with the first air cylinder, a first limiting rod (6 c 1) is arranged at the top of the first push plate (6 c), and the top end of the first limiting rod (6 c 1) penetrates through the top plate (6 a 1) and is in sliding connection with the top plate;

and the first cutter (6 d) is arranged at the bottom of the first push plate (6 c).

9. A nasal chisel machining apparatus according to claim 1, wherein the thread cutting mechanism (7) comprises:

the second upright post frame (7 a) is arranged beside the longitudinal moving mechanism (4);

a linear actuator (7 b) provided on the second column frame (7 a);

a back plate (7 c) arranged at the output end of the linear driver (7 b);

a second cylinder (7 d) disposed at the bottom of the back plate (7 c);

the second push plate (7 e) is arranged at the output end of the second air cylinder (7 d), a second limiting rod is arranged at the top of the second push plate (7 e), and the top end of the second limiting rod penetrates through the top plate (6 a 1) and is in sliding connection with the top plate;

and the second cutter (7 f) is arranged at the bottom of the second push plate (7 e).

10. A nasal chisel machining apparatus according to claim 9, wherein the linear driver (7 b) comprises:

a third base (7 b 1) provided on the second column frame (7 a);

a threaded rod (7 b 2) arranged on the third base (7 b 1) and rotatably connected with the third base;

a movable plate (7 b 3), the movable plate (7 b 3) is connected with the third base (7 b 1) in a sliding way, and the movable plate (7 b 3) is connected with the threaded rod (7 b 2) in a threaded way;

and the fourth servo motor (7 b 4) is arranged on the third base (7 b 1), and the output end of the fourth servo motor (7 b 4) is connected with the force bearing end of the threaded rod (7 b 2).

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