CN218946409U - Boring machine tool mechanism - Google Patents

Abstract

The utility model relates to a boring machine tool mechanism, belongs to the technical field of boring processing, and solves the technical problem that fine scraps remain in a processing hole in the boring process. This boring machine tool mechanism includes workstation, three-jaw chuck, first sliding component, bore hole subassembly and air pump, three-jaw chuck slidable mounting is on one end of workstation, three-jaw chuck is used for fixed part, first sliding component slidable mounting is on the one end that three-jaw chuck was kept away from to the workstation, bore hole subassembly slidable mounting is on first sliding component, bore hole subassembly is used for boring the part, first sliding component is used for driving bore hole subassembly and slides, slip direction perpendicular to bore hole subassembly axis, have the intake duct in the bore hole subassembly, the air outlet of air pump is linked together with the one end of the intake duct of bore hole subassembly, the fine piece in the other end exhaust wind of intake duct is used for clearing up the processing hole.

Description

Boring machine tool mechanism

Technical Field

The utility model belongs to the technical field of boring processing, and particularly relates to a boring machine tool mechanism.

Background

The boring is a machining process of expanding a preformed hole on a workpiece to have a certain aperture, improving the hole shape precision and improving the surface roughness, certain scraps can be generated in the boring process, and some fine scraps can remain in the machined hole to influence the subsequent machining of the machined hole by a boring cutter.

Disclosure of Invention

The utility model provides a boring machine tool mechanism which is used for solving the technical problem that fine scraps remain in a machining hole in the boring process.

In order to achieve the above purpose, the present utility model is realized by the following technical scheme: the utility model provides a bore hole lathe mechanism includes workstation, three-jaw chuck, first sliding component, bore hole subassembly and air pump, three-jaw chuck slidable mounting is on one end of workstation, three-jaw chuck is used for fixed part, first sliding component slidable mounting is on the one end that three-jaw chuck was kept away from to the workstation, bore hole subassembly slidable mounting is on first sliding component, bore hole subassembly is used for boring the part, first sliding component is used for driving bore hole subassembly and slides, slip direction perpendicular to bore hole subassembly axis, have the intake duct in the bore hole subassembly, the air pump is installed on the bore hole subassembly, the air outlet of air pump is linked together with the one end of the intake duct of bore hole subassembly, the fine piece in the other end exhaust wind of intake duct is used for clearing up the processing hole.

Through the structure, the boring machine tool mechanism provided by the utility model can clean out the machining hole from fine scraps in the boring process, specifically, after the part is clamped and fixed by the three-jaw chuck, the first sliding component drives the boring component to slide along the first sliding direction, so that the boring component is coaxial with the machining hole, then, the three-jaw chuck slides towards the direction close to the boring component, so that the part is driven to approach towards the boring component, the boring component starts boring the part, in the boring process, air blown out from the air outlet of the air pump forms air flow, the air flow enters the cavity from the air inlet channel and then is blown out from the air blowing channel, and thus, the fine scraps enter the machining hole on the part, and further, the fine scraps are blown out from the machining hole.

Optionally, the method further comprises:

the material containing disc is detachably arranged on the three-jaw chuck, is positioned between the three-jaw chuck and the boring assembly and below the three-jaw chuck, and is used for containing fragments falling from the parts.

Optionally, the method further comprises:

one end of the first transparent cover is rotatably arranged at the top end of the three-jaw chuck, and the other end of the first transparent cover is positioned between the three-jaw chuck and the boring assembly;

and one ends of the two second transparent covers are respectively rotatably arranged on two opposite sides of the three-jaw chuck, and the other ends of the second transparent covers are positioned between the three-jaw chuck and the boring assembly.

Optionally, the first sliding assembly includes:

a first mounting plate slidably mounted on one end of the table;

the two first vertical plates are respectively arranged on two opposite sides of the first mounting plate, and one ends of the two first vertical plates, which are far away from the first mounting plate, extend upwards;

one end of the first screw rod is rotatably mounted on any one of the first vertical plates, and the other end of the first screw rod is rotatably mounted on the other first vertical plate;

the two first guide rails are respectively arranged on two opposite sides of the first mounting plate, the axes of the first guide rails are parallel to the axes of the first screw rods, and the first screw rods are positioned between the two first guide rails;

the first sliding plate is provided with sliding grooves on two sides and threaded holes, the first screw rod is in threaded connection with the threaded holes, the two first guide rails are respectively arranged in the two sliding grooves, when the first screw rod is rotated, the first sliding plate slides on the first screw rod and the two first guide rails, and the boring assembly is arranged on the first sliding plate;

the first driving motor is coaxially arranged at one end of the first screw rod and used for driving the first screw rod to rotate.

Optionally, the method further comprises:

the second sliding assembly is installed on one end, far away from the three-jaw chuck, of the workbench, the first mounting plate is installed on the second sliding assembly in a sliding mode, the axis of the first screw rod is perpendicular to the axis of the second sliding assembly, and the second sliding assembly is used for driving the first mounting plate to be close to and far away from the three-jaw chuck.

Optionally, the second sliding assembly includes:

the second mounting plate is mounted on one end, far away from the three-jaw chuck, of the workbench;

the two second vertical plates are respectively arranged on two opposite sides of the second mounting plate, and one ends of the two second vertical plates, which are far away from the second mounting plate, extend upwards;

one end of the second screw rod is rotatably mounted on any one of the second vertical plates, and the other end of the second screw rod is rotatably mounted on the other second vertical plate;

the two second guide rails are respectively arranged on two opposite sides of the second mounting plate, the axes of the second guide rails are parallel to the axes of the second screw rods, and the second screw rods are positioned between the two second guide rails;

the second sliding plate is provided with sliding grooves on two sides and threaded holes, the second screw rod is in threaded connection with the threaded holes, the two second guide rails are respectively arranged in the two sliding grooves, when the second screw rod is rotated, the second sliding plate slides on the second screw rod and the two second guide rails, and the first mounting plate is arranged on the second sliding plate;

the second driving motor is coaxially arranged at one end of the second screw rod and used for driving the second screw rod to rotate.

Optionally, the method further comprises:

the third sliding assembly is installed on one end, far away from the boring assembly, of the workbench, the three-jaw chuck is installed on the third sliding assembly in a sliding mode, and the third sliding assembly is used for driving the three-jaw chuck to be close to and far away from the boring assembly.

Optionally, the third sliding assembly comprises:

the third mounting plate is mounted on one end, far away from the boring assembly, of the workbench;

the two third vertical plates are respectively arranged on two opposite sides of the third mounting plate, and one ends of the two third vertical plates far away from the third mounting plate extend upwards;

one end of the third screw rod is rotatably mounted on any one of the third vertical plates, and the other end of the third screw rod is rotatably mounted on the other third vertical plate;

the two third guide rails are respectively arranged on two opposite sides of the third mounting plate, the axes of the third guide rails are parallel to the axes of the third screw rods, and the third screw rods are positioned between the two third guide rails;

the three-jaw chuck is arranged on the third sliding plate;

and the third driving motor is coaxially arranged at one end of the third screw rod and is used for driving the third screw rod to rotate.

Optionally, the boring assembly comprises:

the hollow shaft is rotatably arranged on the first sliding plate, the air inlet channel is positioned in the hollow shaft, and one end of the hollow shaft is communicated with the air outlet;

the boring cutter is arranged at one end of the hollow shaft, which is close to the three-jaw chuck, and is provided with an air outlet hole which is communicated with the other end of the hollow shaft;

and the fourth driving motor is arranged at one end, far away from the three-jaw chuck, of the hollow shaft and is used for driving the hollow shaft to rotate.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a boring machine tool mechanism according to an embodiment of the present utility model;

fig. 2 is a partial enlarged view at a point a of a schematic structural diagram of a boring machine tool mechanism according to an embodiment of the present utility model;

fig. 3 is a schematic structural diagram of a third sliding assembly according to an embodiment of the present utility model;

fig. 4 is a schematic structural diagram of a first sliding component and a second sliding component according to an embodiment of the present utility model.

In the figure:

1-a workbench;

2-three jaw chuck;

3-a first slide assembly; 31-a first mounting plate; 32-a first riser; 33-a first screw rod; 34-a first rail; 35-a first sliding plate; 36-a first drive motor;

4-boring assembly; 41-a hollow shaft; 42-boring a hole; 43-fourth drive motor;

5-a second slide assembly; 51-a second mounting plate; 52-a second riser; 53-a second screw rod; 54-a second rail; 55-a second slide plate; 56-a second drive motor;

6-a third slide assembly; 61-a third mounting plate; 62-a third riser; 63-a third screw rod; 64-a third rail; 65-a third slide plate; 66-a third drive motor;

7-an air pump;

8, a material containing disc;

9-a first transparent cover;

10-a second transparent cover;

11-parts.

Detailed Description

Embodiments of the present application are described in detail below with reference to the accompanying drawings.

In the description of the present application, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the present application and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present application.

The terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context. Examples:

certain scraps can be generated in the boring process, and some fine scraps can remain in the processing hole to influence the subsequent processing of the boring tool on the processing hole.

In order to solve the above-mentioned technical problems, the present embodiment provides a boring machine tool mechanism as shown in fig. 1, which includes a table 1, a three-jaw chuck 2, a first sliding assembly 3, a boring assembly 4, and an air pump 7.

In order to keep the mounting surface of the workbench 1 flat, the supporting leg of the workbench 1 is an adjustable supporting leg, the three-jaw chuck 2 is slidably mounted on one end of the workbench 1, the three-jaw chuck 2 is used for fixing a part 11, the first sliding component 3 is slidably mounted on one end of the workbench 1 far away from the three-jaw chuck 2, the boring component 4 is slidably mounted on the first sliding component 3, the boring component 4 is used for boring the part 11, the first sliding component 3 is used for driving the boring component 4 to slide in a first sliding direction, the first sliding direction is perpendicular to the axis of the boring component 4 and parallel to the mounting surface of the workbench 1, an air inlet channel is formed in the boring component 4, an air outlet of the air pump 7 is communicated with one end of the air inlet channel of the boring component 4, and air discharged from the other end of the air inlet channel is used for cleaning fine chips in a processing hole.

Through the structure, the boring machine tool mechanism provided by the embodiment can clean fine scraps out of a machining hole in the boring process. Specifically, after the part 11 is clamped and fixed by the three-jaw chuck 2, the first sliding component 3 drives the boring component 4 to slide along the first sliding direction, so that the boring component 4 is coaxial with the machining hole, then, the three-jaw chuck 2 slides along the second sliding direction perpendicular to the first sliding direction, so that the part 11 is driven to approach to the direction close to the boring component 4, the boring component 4 starts boring the part 11, in the boring process, air blown out from the air outlet of the air pump 7 forms air flow, and the air flow enters the cavity from the air inlet channel and is blown out from the air blowing channel, so that the air enters the machining hole on the part 11, and fine chips are blown out from the machining hole.

To facilitate collection of fine debris, an alternative implementation of this embodiment is as follows: as shown in fig. 1 and 3, the three-jaw chuck further comprises a material containing disc 8, wherein the material containing disc 8 is detachably arranged on the three-jaw chuck 2, is positioned between the three-jaw chuck 2 and the boring assembly 4 and is positioned below the three-jaw chuck 2, and the material containing disc 8 is used for containing chips falling from the part 11. Specifically, when the blind hole is bored, the air flow collides with the bottom of the blind hole and returns, so that fine scraps are driven to fly out from the opening of the blind hole and fall into the material containing disc 8 below the three-jaw chuck 2.

In order to keep fine debris from splashing around with the airflow, an alternative implementation of this embodiment is as follows: as shown in fig. 1 and 3, the three-jaw chuck further comprises a first transparent cover 9 and two second transparent covers 10, wherein the first transparent cover 9 and the two second transparent covers 10 are made of polymethyl methacrylate, one end of the first transparent cover 9 is rotatably installed at the top end of the three-jaw chuck 2, the other end of the first transparent cover 9 is located between the three-jaw chuck 2 and the boring assembly 4, one ends of the two second transparent covers 10 are rotatably installed at two opposite sides of the three-jaw chuck 2 respectively, and the other ends of the second transparent covers 10 are located between the three-jaw chuck 2 and the boring assembly 4. Specifically, as shown in fig. 3, when the part 11 needs to be fixed, one end of the first transparent cover 9, which is far away from the three-jaw chuck 2, is rotated in a direction away from the boring assembly 4, and one ends of the two second transparent covers 10, which are full of the three-jaw chucks 2, are rotated in a direction away from the boring assembly 4, so that space is reserved, and an operator can conveniently fix the part 11 by using the three-jaw chuck 2; when processing is to be performed, as shown in fig. 1, one end of the first transparent cover 9 away from the three-jaw chuck 2 is rotated in a direction approaching the boring assembly 4, and one ends of the two second transparent covers 10 are rotated in a direction approaching the boring assembly 4.

In order to align the axis of the tooling hole with the axis of the boring assembly 4, an alternative implementation of this embodiment is as follows: the first sliding assembly 3 comprises a first mounting plate 31, two first vertical plates 32, a first screw rod 33, two first guide rails 34, a first sliding plate 35 and a first driving motor 36, wherein the first mounting plate 31 is slidably mounted on one end of the workbench 1, the two first vertical plates 32 are respectively mounted on two opposite sides of the first mounting plate 31, one ends of the two first vertical plates 32 far away from the first mounting plate 31 extend upwards, one ends of the first screw rods 33 are rotatably mounted on any one of the first vertical plates 32, the other ends of the first screw rods 33 are rotatably mounted on the other first vertical plates 32, the two first guide rails 34 are respectively mounted on two opposite sides of the first mounting plate 31, the axis of the first guide rails 34 is parallel to the axis of the first screw rods 33, the first screw rods 33 are located between the two first guide rails 34, sliding grooves are respectively formed in two sides of the first sliding plate 35, the first screw rods 33 are in threaded connection with the threaded holes, the two first guide rails 34 are respectively mounted in the two sliding grooves, when the first screw rods 33 are rotated, the first sliding plate 35 and the first screw rods 33 are coaxially arranged on the first guide rails 33, and the first guide rails 33 are coaxially drive the first screw rods 33, and the first guide rails are coaxially rotate, and the first guide rails 33 are rotatably drive the first guide rails 35, and the first guide rails 33. Specifically, the first driving motor 36 drives the first screw 33 to rotate, thereby driving the first sliding plate 35 to slide in the first sliding direction.

In order to enable the first slider assembly 3 to be slidably mounted at one end of the table 1, an alternative implementation of this embodiment is as follows: the three-jaw chuck further comprises a second sliding component 5, the second sliding component 5 is arranged at one end, far away from the three-jaw chuck 2, of the workbench 1, the first mounting plate 31 is slidably arranged on the second sliding component 5, the axis of the first screw rod 33 is perpendicular to the axis of the second sliding component 5, and the second sliding component 5 is used for driving the first mounting plate 31 to slide along a third sliding direction. Specifically, the third sliding direction is parallel to the second sliding direction and also perpendicular to the first sliding direction

In order to be able to precisely control the sliding distance of the first sliding assembly 3 in the third sliding direction, an alternative implementation of this embodiment is as follows: the second sliding component 5 comprises a second mounting plate 51, two second vertical plates 52, a second screw rod 53, two second guide rails 54, a second sliding plate 55 and a second driving motor 56, wherein the second mounting plate 51 is mounted at one end of the workbench 1 far away from the three-jaw chuck 2, the two second vertical plates 52 are respectively mounted at two opposite sides of the second mounting plate 51, one end of the second vertical plate 52 far away from the second mounting plate 51 extends upwards, one end of the second screw rod 53 is rotatably mounted on any second vertical plate 52, the other end of the second screw rod 53 is rotatably mounted on the other second vertical plate 52, the two second guide rails 54 are respectively mounted at two opposite sides of the second mounting plate 51, the axis of the second guide rail 54 is parallel to the axis of the second screw rod 53, the second screw rod 53 is positioned between the two second guide rails 54, sliding grooves are respectively formed at two sides of the second sliding plate 55, the second screw rod 53 is in threaded connection with the threaded holes, the two second guide rails 54 are respectively mounted in the two sliding grooves, when the second screw rod 53 is rotated, the second guide rails 53 are coaxially arranged at the second guide rails 53, the second guide rails 53 are coaxially arranged at the second ends of the second mounting plate 53, the second guide rails 55 are rotatably driven by the second motor 53, and the second guide rails 55 are mounted at the second guide rails 53. Specifically, the second driving motor 56 drives the second screw 53 to rotate clockwise, thereby driving the second sliding plate 55 to move away from the three-jaw chuck 2; the second driving motor 56 drives the second screw 53 to rotate counterclockwise, thereby driving the second sliding plate 55 to approach the three-jaw chuck 2.

In order to enable the three-jaw chuck 2 to be slidably mounted at one end of the table 1, an alternative implementation of this embodiment is as follows: the three-jaw chuck 2 is slidably mounted on the third sliding component 6, and the third sliding component 6 is used for driving the three-jaw chuck 2 to slide along the second sliding direction.

In order to accurately control the sliding distance of the three-jaw assembly in the second sliding direction, an alternative implementation of this embodiment is as follows: the third sliding assembly 6 comprises a third mounting plate 61, two third vertical plates 62, a third screw rod 63, two third guide rails 64, a third sliding plate 65 and a third driving motor 66, wherein the third mounting plate 61 is mounted at one end of the workbench 1 far away from the boring assembly 4, the two third vertical plates 62 are respectively mounted at two opposite sides of the third mounting plate 61, one end of the two third vertical plates 62 far away from the third mounting plate 61 extends upwards, one end of the third screw rod 63 is rotatably mounted on any one of the third vertical plates 62, the other end of the third screw rod 63 is rotatably mounted on the other third vertical plate 62, the two third guide rails 64 are respectively mounted at two opposite sides of the third mounting plate 61, the axis of the third guide rail 64 is parallel to the axis of the third screw rod 63, the third screw rod 63 is positioned between the two third guide rails 64, sliding grooves are respectively formed at two sides of the third sliding plate 65, the third screw rod 63 is in threaded connection with the threaded holes, the two third guide rails 64 are respectively mounted in the two sliding grooves, when the third screw rod 63 is rotated, the third screw rod 63 is coaxially rotates, the third guide rails 63 and the third driving motor is coaxially mounted at the third screw rod 63 and the third guide rails 64, and the third driving motor is coaxially mounted at the third screw rod 63.

An alternative implementation of this embodiment is as follows: the boring assembly 4 comprises a hollow shaft 41 and a boring cutter 42 and a fourth driving motor 43, the hollow shaft 41 is rotatably arranged on the first sliding plate 35, an air inlet channel is arranged in the hollow shaft 41, one end of the hollow shaft 41 is communicated with an air outlet, the boring cutter 42 is arranged at one end of the hollow shaft 41, which is close to the three-jaw chuck 2, an air outlet hole is formed in the boring cutter 42, the air outlet hole is communicated with the other end of the hollow shaft 41, the fourth driving motor 43 is arranged at one end, far away from the three-jaw chuck 2, of the hollow shaft 41, and the fourth driving motor 43 is used for driving the hollow shaft 41 to rotate. Specifically, the fourth drive rotates the hollow shaft 41, thereby rotating the boring cutter 42; air blown out from the air outlet of the air pump 7 forms air flow, the air flow enters from one end of the air inlet channel, then enters the air outlet hole from the other end of the air inlet channel, and then is blown out from the air outlet hole, so that the air enters into the processing hole on the part 11, and fine scraps are blown out from the processing hole.

In summary, when boring the part 11, firstly, the end of the first transparent cover 9 away from the three-jaw chuck 2 is rotated in the direction away from the boring cutter 42, the ends of the two second transparent covers 10 away from the three-jaw chuck 2 are rotated in the direction away from the boring cutter 42, thereby freeing up space, the operator can fix the part 11 by using the three-jaw chuck 2, after fixing, the end of the first transparent cover 9 away from the three-jaw chuck 2 is rotated in the direction close to the boring cutter 42, the ends of the two second transparent covers 10 away from the three-jaw chuck 2 are rotated in the direction close to the boring cutter 42, so that fine chips do not splash along with air flow to influence the operation of the operator, then, the first driving motor 36 drives the first screw 33 to rotate, thereby driving the first sliding plate 35 to slide along the first sliding direction, so that the axis of the machining hole and the axis of the boring cutter 42 are in the same straight line, then, the fourth driving motor 43 drives the hollow shaft 41 to rotate, so as to drive the boring cutter 42 to rotate, the second driving motor 56 drives the second screw rod 53 to rotate anticlockwise, so as to drive the second sliding plate 55 to be close to the three-jaw chuck 2, so as to drive the first sliding mechanism to be close to the three-jaw chuck 2, so as to drive the hollow shaft 41 to be close to the three-jaw chuck 2, so as to drive the boring cutter to be close to the part 11, and machine the part 11, then, the air pump 7 sucks air, then, the air blown out by the air pump 7 forms an air flow, the air flow enters from one end of the air inlet channel, then enters the air outlet hole from the other end of the air inlet channel, then, is blown out from the air outlet hole, when the machining hole is a through hole, tiny fragments can be blown out from one end of the through hole away from the air outlet, when the machining hole is a blind hole, the air flow is bumped at the bottom of the blind hole, thereby drive tiny piece fly out from the blind hole mouth and fall into the flourishing charging tray 8 of three-jaw chuck 2 below, after the bore hole is accomplished, two driving motor drive second lead screw 53 clockwise rotation, thereby drive second sliding plate 55 keep away from three-jaw chuck 2, thereby drive first sliding mechanism keep away from three-jaw chuck 2, thereby drive hollow shaft 41 keep away from three-jaw chuck 2, and then drive the boring cutter and keep away from part 11, afterwards, fourth driving motor 43 stops rotating, thereby drive the boring cutter stop rotating, and then accomplish the bore hole to part 11, therefore this boring machine tool mechanism has solved the technical problem that tiny piece remains in the processing hole in the bore hole in-process.

The above description is merely an embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present utility model, and it is intended to cover the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (9)

1. A boring machine tool mechanism, comprising:

a work table;

the three-jaw chuck is slidably arranged on one end of the workbench and is used for fixing a part;

a first sliding assembly slidably mounted on an end of the table remote from the three-jaw chuck;

the boring assembly is slidably mounted on the first sliding assembly and is used for boring a part, the first sliding assembly is used for driving the boring assembly to slide, the sliding direction of the boring assembly is perpendicular to the axis of the boring assembly, and an air inlet channel is formed in the boring assembly;

the air pump is installed on the boring assembly, the air outlet of the air pump is communicated with one end of an air inlet channel of the boring assembly, and air exhausted from the other end of the air inlet channel is used for cleaning fine scraps in a machining hole.

2. A boring machine tool mechanism as claimed in claim 1, further comprising:

the material containing disc is detachably arranged on the three-jaw chuck, is positioned between the three-jaw chuck and the boring assembly and below the three-jaw chuck, and is used for containing fragments falling from the parts.

3. A boring machine tool mechanism as claimed in claim 2, further comprising:

one end of the first transparent cover is rotatably arranged at the top end of the three-jaw chuck, and the other end of the first transparent cover is positioned between the three-jaw chuck and the boring assembly;

and one ends of the two second transparent covers are respectively rotatably arranged on two opposite sides of the three-jaw chuck, and the other ends of the second transparent covers are positioned between the three-jaw chuck and the boring assembly.

4. A boring machine tool mechanism according to claim 3, wherein the first slide assembly comprises:

a first mounting plate slidably mounted on one end of the table;

the two first vertical plates are respectively arranged on two opposite sides of the first mounting plate, and one ends of the two first vertical plates, which are far away from the first mounting plate, extend upwards;

one end of the first screw rod is rotatably mounted on any one of the first vertical plates, and the other end of the first screw rod is rotatably mounted on the other first vertical plate;

the two first guide rails are respectively arranged on two opposite sides of the first mounting plate, the axes of the first guide rails are parallel to the axes of the first screw rods, and the first screw rods are positioned between the two first guide rails;

the first sliding plate is provided with sliding grooves on two sides and threaded holes, the first screw rod is in threaded connection with the threaded holes, the two first guide rails are respectively arranged in the two sliding grooves, when the first screw rod is rotated, the first sliding plate slides on the first screw rod and the two first guide rails, and the boring assembly is arranged on the first sliding plate;

the first driving motor is coaxially arranged at one end of the first screw rod and used for driving the first screw rod to rotate.

5. A boring machine tool mechanism according to claim 4, further comprising:

the second sliding assembly is installed on one end, far away from the three-jaw chuck, of the workbench, the first mounting plate is installed on the second sliding assembly in a sliding mode, the axis of the first screw rod is perpendicular to the axis of the second sliding assembly, and the second sliding assembly is used for driving the first mounting plate to be close to and far away from the three-jaw chuck.

6. A boring machine tool mechanism according to claim 5, wherein the second slide assembly comprises:

the second mounting plate is mounted on one end, far away from the three-jaw chuck, of the workbench;

the two second vertical plates are respectively arranged on two opposite sides of the second mounting plate, and one ends of the two second vertical plates, which are far away from the second mounting plate, extend upwards;

one end of the second screw rod is rotatably mounted on any one of the second vertical plates, and the other end of the second screw rod is rotatably mounted on the other second vertical plate;

the two second guide rails are respectively arranged on two opposite sides of the second mounting plate, the axes of the second guide rails are parallel to the axes of the second screw rods, and the second screw rods are positioned between the two second guide rails;

the second sliding plate is provided with sliding grooves on two sides and threaded holes, the second screw rod is in threaded connection with the threaded holes, the two second guide rails are respectively arranged in the two sliding grooves, when the second screw rod is rotated, the second sliding plate slides on the second screw rod and the two second guide rails, and the first mounting plate is arranged on the second sliding plate;

the second driving motor is coaxially arranged at one end of the second screw rod and used for driving the second screw rod to rotate.

7. A boring machine tool mechanism according to claim 6, further comprising:

the third sliding assembly is installed on one end, far away from the boring assembly, of the workbench, the three-jaw chuck is installed on the third sliding assembly in a sliding mode, and the third sliding assembly is used for driving the three-jaw chuck to be close to and far away from the boring assembly.

8. A boring machine tool mechanism according to claim 7, wherein the third slide assembly comprises:

the third mounting plate is mounted on one end, far away from the boring assembly, of the workbench;

the two third vertical plates are respectively arranged on two opposite sides of the third mounting plate, and one ends of the two third vertical plates far away from the third mounting plate extend upwards;

one end of the third screw rod is rotatably mounted on any one of the third vertical plates, and the other end of the third screw rod is rotatably mounted on the other third vertical plate;

the two third guide rails are respectively arranged on two opposite sides of the third mounting plate, the axes of the third guide rails are parallel to the axes of the third screw rods, and the third screw rods are positioned between the two third guide rails;

the three-jaw chuck is arranged on the third sliding plate;

and the third driving motor is coaxially arranged at one end of the third screw rod and is used for driving the third screw rod to rotate.

9. A boring machine tool mechanism according to claim 8, wherein the boring assembly comprises:

the hollow shaft is rotatably arranged on the first sliding plate, the air inlet channel is positioned in the hollow shaft, and one end of the hollow shaft is communicated with the air outlet;

the boring cutter is arranged at one end of the hollow shaft, which is close to the three-jaw chuck, and is provided with an air outlet hole which is communicated with the other end of the hollow shaft;

and the fourth driving motor is arranged at one end, far away from the three-jaw chuck, of the hollow shaft and is used for driving the hollow shaft to rotate.

Images