CN223718385U

CN223718385U - Milling mechanism of precise numerical control lathe

Info

Publication number: CN223718385U
Application number: CN202520088979.6U
Authority: CN
Inventors: 周大全
Original assignee: Wuxi Bonuo Technology Co ltd
Current assignee: Wuxi Bonuo Technology Co ltd
Priority date: 2025-01-15
Filing date: 2025-01-15
Publication date: 2025-12-26
Anticipated expiration: 2035-01-15

Abstract

The utility model belongs to the field of numerically controlled lathes, in particular to a milling mechanism of a precise numerically controlled lathe, which aims at the problems that scraps generated by the existing milling can scatter on the surface or the ground of the lathe and are inconvenient to clean manually; according to the utility model, scraps generated by processing can be shielded and guided, and discharged and collected through the discharge groove and the discharge channel, so that the energy of people is saved, the people can conveniently and rapidly install and detach the first baffle, and the people can conveniently load and unload a workpiece.

Description

Milling mechanism of precise numerical control lathe

Technical Field

The utility model relates to the technical field of numerically controlled lathes, in particular to a milling mechanism of a precise numerically controlled lathe.

Background

A numerical control lathe is one of the numerical control lathes that are widely used. The cutting tool is mainly used for cutting machining of inner and outer cylindrical surfaces of shaft parts or disc parts, inner and outer conical surfaces of any cone angle, complex rotation inner and outer curved surfaces, cylindrical threads, conical threads and the like, and can be used for grooving, drilling, reaming, boring and the like.

Milling is a mechanical processing method for processing the surface of an object by taking a milling cutter as a cutter, however, the traditional lathe has the following defects when milling:

1. the scraps generated by milling can be scattered on the surface or the ground of the lathe, and the scraps need to be cleaned manually, so that the machine is inconvenient.

Therefore, we propose a milling mechanism of a precision numerically controlled lathe.

Disclosure of utility model

The utility model aims to solve the defects that scraps generated by milling in the prior art can scatter on the surface or the ground of a lathe and are inconvenient to clean manually, and provides a milling mechanism of a precise numerical control lathe.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

A milling mechanism for a precision numerically controlled lathe, comprising:

The lathe comprises a lathe body, wherein one side of the lathe body is slidably connected with a lifting seat through a guide rail, one side of the lifting seat is slidably connected with a sliding seat through the guide rail, one side of the sliding seat is fixedly provided with a mounting seat, and the bottom of the mounting seat is fixedly provided with a milling cutter and a second baffle;

The surface of the lathe main body is provided with a discharge groove, the bottom of the discharge groove is communicated with a discharge channel which is obliquely arranged, one side of the discharge groove is fixedly penetrated with a fixing seat, the top end of the discharge groove is provided with a first baffle, and one side of the first baffle is provided with a yielding port;

The adjusting mechanism is arranged on one side of the lathe main body and used for adjusting the position of the mounting seat;

The clamping mechanism is arranged on one side of the fixed seat and used for clamping a workpiece;

The two positioning mechanisms are respectively arranged at two corners of the discharge groove and used for positioning the first baffle.

In one possible design, the adjusting mechanism comprises a first motor and a second motor, the first motor is fixedly arranged at the top end of the lathe body, a first screw rod is fixedly arranged at one end of an output shaft of the first motor, threads of the first screw rod penetrate through the lifting seat, the second motor is fixedly arranged at one side of the lifting seat, a second screw rod is fixedly arranged at one end of an output shaft of the second motor, and threads of the second screw rod penetrate through the sliding seat.

In a possible design, fixture includes the pivot, and the pivot rotates and runs through the top at the fixing base, and processing platform has been set firmly on the top of pivot, and a plurality of spouts have been seted up to the bottom of processing platform, all sliding connection has the clamp splice in a plurality of spouts, and a plurality of electric putter have been set firmly to the bottom of processing platform, and electric putter's output shaft and clamp splice are fixed mutually.

In one possible design, the clamping mechanism further comprises a third motor, the third motor is fixedly arranged on one side of the lathe body, one end of an output shaft of the third motor and the bottom end of the rotating shaft are fixedly provided with synchronous wheels, and the two synchronous wheels are in transmission connection through a synchronous belt.

In one possible design, the positioning mechanism comprises a first positioning block and a second positioning block, wherein the first positioning block and the second positioning block are both fixedly arranged on the surface of the lathe body, the second positioning block is L-shaped, and an L-shaped gap is formed between the first positioning block and the second positioning block and is used for being matched with the first baffle.

In one possible design, the two sides of the first positioning block and the two sides of the second positioning block are respectively provided with a ball groove, and the ball grooves are respectively provided with balls.

In one possible design, the top ends of the first positioning block and the second positioning block are provided with chamfers.

In the application, when the milling cutter is used, a workpiece to be processed is placed on a processing table, then an electric push rod is started to drive a clamping block to clamp the workpiece, then a first baffle is placed between a first positioning block and a second positioning block, then a third motor is started, under the action of a synchronous wheel and a synchronous belt, the third motor drives a rotating shaft and the processing table to rotate, the workpiece is driven to rotate, then the position of a mounting seat is adjusted by the first motor and the second motor, so that a milling cutter is close to the workpiece to mill, and scraps generated by milling fall into a discharge groove and are discharged through a discharge channel.

The milling mechanism of the precise numerical control lathe has the beneficial effects that scraps generated by processing can be shielded and guided through the arrangement of the first baffle, the second baffle, the discharge groove and the like, and discharged and collected through the discharge groove and the discharge channel, so that the energy of people is saved;

According to the milling mechanism of the precise numerical control lathe, through the arrangement of the positioning mechanism, people can conveniently and rapidly mount and dismount the first baffle, and people can conveniently load and unload a workpiece;

According to the utility model, scraps generated by processing can be shielded and guided, and discharged and collected through the discharge groove and the discharge channel, so that the energy of people is saved, the first baffle can be conveniently and rapidly installed and detached, and the work piece is conveniently loaded and unloaded by people.

Drawings

Fig. 1 is a schematic three-dimensional structure diagram of a milling mechanism of a precision numerically controlled lathe according to a first view angle;

fig. 2 is a schematic three-dimensional structure diagram of a milling mechanism of a precision numerically controlled lathe according to a second view angle;

Fig. 3 is a schematic structural diagram of a clamping mechanism of a milling mechanism of a precision numerically controlled lathe;

fig. 4 is a schematic structural diagram of a positioning mechanism of a milling mechanism of a precision numerically controlled lathe.

In the figure, 1, a lathe main body; 2, a lifting seat, 3, a sliding seat, 4, a first motor, 5, a second motor, 6, a mounting seat, 7, a milling cutter, 8, a first baffle, 9, a second baffle, 10, a discharge groove, 11, a positioning mechanism, 12, a fixing seat, 13, a third motor, 14, a rotating shaft, 15, a processing table, 16, a sliding groove, 17, a clamping block, 18, an electric push rod, 19, a synchronous wheel, 20, a first positioning block, 21, a second positioning block, 22, a ball, 23, a yielding port and 24, a discharge channel.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Embodiment 1 referring to fig. 1 to 4, a milling mechanism of a precision numerically controlled lathe includes:

The lathe comprises a lathe body 1, wherein one side of the lathe body 1 is slidably connected with a lifting seat 2 through a guide rail, one side of the lifting seat 2 is slidably connected with a sliding seat 3 through the guide rail, one side of the sliding seat 3 is fixedly provided with a mounting seat 6, and the bottom of the mounting seat 6 is fixedly provided with a milling cutter 7 and a second baffle 9 to prevent scraps from splashing;

The surface of the lathe main body 1 is provided with a discharge groove 10, the bottom of the discharge groove 10 is communicated with a discharge channel 24 which is obliquely arranged and can guide scraps to be discharged, one side of the discharge groove 10 is fixedly penetrated with a fixed seat 12, the top end of the discharge groove 10 is provided with a first baffle plate 8 for preventing scraps from splashing, one side of the first baffle plate 8 is provided with a yielding port 23 for yielding the lathe main body 1, and the first baffle plate 8 is convenient to mount and dismount;

The adjusting mechanism is arranged on one side of the lathe body 1 and used for adjusting the position of the mounting seat 6, the adjusting mechanism comprises a first motor 4 and a second motor 5, the first motor 4 is fixedly arranged at the top end of the lathe body 1, a first screw is fixedly arranged at one end of an output shaft of the first motor 4, threads of the first screw penetrate through the lifting seat 2, the lifting seat 2 can move in the vertical direction through driving of the first motor 4, the second motor 5 is fixedly arranged on one side of the lifting seat 2, a second screw is fixedly arranged at one end of an output shaft of the second motor 5, threads of the second screw penetrate through the sliding seat 3, and the sliding seat 3 can move in the horizontal direction through driving of the second motor 5;

The clamping mechanism is arranged on one side of the fixed seat 12 and used for clamping a workpiece, the clamping mechanism comprises a rotating shaft 14, the rotating shaft 14 rotates to penetrate through the top end of the fixed seat 12, a processing table 15 is fixedly arranged on the top end of the rotating shaft 14, a plurality of sliding grooves 16 are formed in the bottom of the processing table 15, clamping blocks 17 are slidably connected in the plurality of sliding grooves 16 and used for clamping the workpiece, a plurality of electric push rods 18 are fixedly arranged at the bottom of the processing table 15, an output shaft of each electric push rod 18 is fixed with each clamping block 17, the clamping blocks 17 can move in the corresponding sliding grooves 16 through the expansion and contraction of the corresponding electric push rods 18, the workpiece can be clamped and loosened, the clamping mechanism further comprises a third motor 13, the third motor 13 is fixedly arranged on one side of the lathe main body 1, one end of an output shaft of the third motor 13 and the bottom end of the rotating shaft 14 are fixedly provided with synchronous wheels 19, and the two synchronous wheels 19 are in transmission connection through a synchronous belt. By driving the third motor 13, the rotation of the rotating shaft 14 and the processing table 15 can be realized, thereby realizing the rotary processing of the workpiece;

The two positioning mechanisms 11 are respectively arranged at two corners of the discharge groove 10 and used for positioning the first baffle plate 8, the positioning mechanisms 11 comprise a first positioning block 20 and a second positioning block 21, the first positioning block 20 and the second positioning block 21 are fixedly arranged on the surface of the lathe body 1, the second positioning block 21 is L-shaped, and an L-shaped gap is formed between the first positioning block 20 and the second positioning block 21 and used for being matched with the first baffle plate 8. When the position of the first baffle plate 8 needs to be adjusted, the first baffle plate 8 is only required to be pulled out or inserted from the gap, and the device is very convenient.

Embodiment 2 a milling mechanism of a precision numerically controlled lathe modified on the basis of embodiment 1;

In another aspect of the present embodiment, both sides of the first positioning block 20 and both sides of the second positioning block 21 are provided with ball grooves, and a plurality of ball grooves are provided with balls 22. The arrangement of the balls 22 can reduce friction between the first baffle plate 8 and the positioning mechanism 11, so that the first baffle plate 8 can move more smoothly.

In another aspect of this embodiment, the top ends of the first positioning block 20 and the second positioning block 21 are each provided with a chamfer. The arrangement of the chamfer can guide the first baffle plate 8 to smoothly enter the gap, so that the installation and the disassembly are more convenient.

However, as well known to those skilled in the art, the working principles and wiring methods of the first motor 4, the second motor 5, the third motor 13 and the electric putter 18 are well known, which are all conventional means or common knowledge, and are not described herein in detail, and any optional matching can be performed by those skilled in the art according to their needs or convenience.

The foregoing is only a preferred 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, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims

1. The milling mechanism of the precise numerical control lathe is characterized by comprising:

the lathe comprises a lathe body (1), wherein one side of the lathe body (1) is slidably connected with a lifting seat (2) through a guide rail, one side of the lifting seat (2) is slidably connected with a sliding seat (3) through the guide rail, one side of the sliding seat (3) is fixedly provided with a mounting seat (6), and the bottom of the mounting seat (6) is fixedly provided with a milling cutter (7) and a second baffle (9);

A discharge groove (10) is formed in the surface of the lathe main body (1), a discharge channel (24) which is obliquely arranged is communicated with the bottom of the discharge groove (10), a fixing seat (12) is fixedly penetrated on one side of the discharge groove (10), a first baffle (8) is arranged at the top end of the discharge groove (10), and a yielding port (23) is formed in one side of the first baffle (8);

the adjusting mechanism is arranged on one side of the lathe body (1) and is used for adjusting the position of the mounting seat (6);

The clamping mechanism is arranged on one side of the fixed seat (12) and used for clamping a workpiece;

The two positioning mechanisms (11) are respectively arranged at two corners of the discharge groove (10) and used for positioning the first baffle (8).

2. The milling mechanism of the precise numerical control lathe according to claim 1, wherein the adjusting mechanism comprises a first motor (4) and a second motor (5), the first motor (4) is fixedly arranged at the top end of the lathe body (1), one end of an output shaft of the first motor (4) is fixedly provided with a first screw rod, threads of the first screw rod penetrate through the lifting seat (2), the second motor (5) is fixedly arranged on one side of the lifting seat (2), one end of an output shaft of the second motor (5) is fixedly provided with a second screw rod, and threads of the second screw rod penetrate through the sliding seat (3).

3. The milling mechanism of the precise numerical control lathe according to claim 2, wherein the clamping mechanism comprises a rotating shaft (14), the rotating shaft (14) rotates to penetrate through the top end of the fixed seat (12), a machining table (15) is fixedly arranged at the top end of the rotating shaft (14), a plurality of sliding grooves (16) are formed in the bottom of the machining table (15), clamping blocks (17) are slidably connected in the sliding grooves (16), a plurality of electric pushing rods (18) are fixedly arranged at the bottom of the machining table (15), and an output shaft of the electric pushing rods (18) is fixed with the clamping blocks (17).

4. The milling mechanism of the precise numerical control lathe according to claim 3, wherein the clamping mechanism further comprises a third motor (13), the third motor (13) is fixedly arranged on one side of the lathe body (1), one end of an output shaft of the third motor (13) and the bottom end of the rotating shaft (14) are fixedly provided with synchronous wheels (19), and the two synchronous wheels (19) are in transmission connection through a synchronous belt.

5. The milling mechanism of the precise numerical control lathe according to claim 4, wherein the positioning mechanism (11) comprises a first positioning block (20) and a second positioning block (21), the first positioning block (20) and the second positioning block (21) are both fixedly arranged on the surface of the lathe main body (1), the second positioning block (21) is L-shaped, and an L-shaped gap is formed between the first positioning block (20) and the second positioning block (21) and is used for being matched with the first baffle (8).

6. The milling mechanism of the precise numerical control lathe according to claim 5, wherein ball grooves are formed in both sides of the first positioning block (20) and both sides of the second positioning block (21), and balls (22) are arranged in the ball grooves.

7. The milling mechanism of the precise numerical control lathe according to claim 6, wherein the top ends of the first positioning block (20) and the second positioning block (21) are respectively provided with a chamfer.