CN220278875U - Numerical control machine tool body structure with chip removal function - Google Patents

Abstract

The utility model provides a numerical control machine tool body structure with a chip removal function, which comprises a machine tool body, wherein the machine tool body comprises an X-axis machine tool body and a Y-axis machine tool body, a plurality of first chip removal mechanisms are arranged on the X-axis machine tool body, a plurality of second chip removal mechanisms are arranged on the Y-axis machine tool body, and the first chip removal mechanisms comprise an X-axis chip removal groove, an X-axis screw rod and a first driving motor; the second chip removal mechanism comprises a Y-axis chip removal groove, a Y-axis screw rod and a second driving motor; the X axial bed body top is provided with the trapezoidal guiding gutter that communicates with X axial junk groove, Y axial junk groove output and trapezoidal guiding gutter intercommunication, and metal piece will be ground into metal powder and by outside the output lathe bed, avoid metal piece to block up X axial junk groove, Y axial junk groove, realized the automatic emission of metal piece, make things convenient for metal piece's processing to retrieve, save the labour, ensure the normal production of lathe.

Description

Numerical control machine tool body structure with chip removal function

Technical Field

The utility model relates to the technical field of numerical control machine tools, in particular to a numerical control machine tool body structure with a chip removal function.

Background

The numerical control machine 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. When the numerical control machine tool processes parts, cooling liquid needs to be sprayed to parts processing positions, metal scraps can flow onto the lathe bed of the machine tool along with the cooling liquid, the metal scraps cannot be automatically discharged from the lathe bed, more and more metal scraps can be accumulated, workers are required to frequently clean the metal scraps, normal production and processing of the machine tool are affected, production efficiency is reduced, and labor force is increased.

Disclosure of Invention

The utility model aims to solve the problem of providing a numerical control machine tool body structure with a chip removal function, which can realize automatic discharge of metal chips, save labor force and ensure normal production of a machine tool.

The numerical control machine tool body structure with the chip removal function comprises a machine body, wherein the machine body comprises an X-axis machine body arranged along the X-axis direction and a Y-axis machine body arranged along the Y-axis direction, a plurality of first chip removal mechanisms are arranged on the X-axis machine body in parallel, a plurality of second chip removal mechanisms are arranged on the Y-axis machine body in parallel, and the first chip removal mechanisms comprise X-axis chip removal grooves penetrating through the top of the X-axis machine body along the X-axis direction, X-axis screw rods rotatably connected between two ends of the X-axis chip removal grooves, and a first driving motor arranged on one end face of the X-axis chip removal grooves and in driving connection with the X-axis screw rods; the second chip removing mechanism comprises a Y-axis chip removing groove penetrating through the top of the Y-axis bed body along the Y-axis direction, a Y-axis screw rod rotatably connected between two ends of the Y-axis chip removing groove, and a second driving motor arranged on one end face of the Y-axis chip removing groove and in driving connection with the Y-axis screw rod; the top of the X-axis bed body is provided with a trapezoid diversion trench communicated with the X-axis chip removal trench, and the output end of the Y-axis chip removal trench is communicated with the trapezoid diversion trench.

Preferably, the center of the top of the X-axis bed body is provided with an X-axis sliding step, and two sides of the X-axis sliding step are symmetrically provided with first chip removal mechanisms, and a trapezoidal guide groove is adjacent to the side wall of the X-axis sliding step; two Y-axis sliding steps are arranged on the top of the Y-axis bed body in parallel, second chip removal mechanisms are arranged on two sides of each Y-axis sliding step, and a first diversion inclined plane extending to the Y-axis chip removal groove is arranged on the side wall of each Y-axis sliding step.

Preferably, two X-axis guide rail base plates are arranged at the top of the X-axis sliding step in parallel, and two second guide inclined planes extending to the trapezoid guide grooves are symmetrically arranged at the end face of the X-axis sliding step.

The beneficial effects of the utility model are as follows: the utility model provides a numerical control machine tool body structure with a chip removal function, wherein an X-axis lathe body is used for installing a spindle mechanism, a Y-axis lathe body is used for installing a material seat mechanism, metal chips generated during part machining fall on the X-axis lathe body and the Y-axis lathe body along with cooling liquid, the metal chips on the X-axis lathe body flow into the X-axis chip removal groove along with the cooling liquid, the metal chips on the Y-axis lathe body flow into the Y-axis chip removal groove along with the cooling liquid, a second driving motor drives a Y-axis screw to rotate in the Y-axis chip removal groove, the metal chips falling into the Y-axis chip removal groove are conveyed to the X-axis chip removal groove side under the action of the Y-axis screw and are ground, the metal chips falling into the X-axis chip removal groove are conveyed to the output end side of the X-axis chip removal groove under the action of the X-axis screw and are ground, the metal chips are ground into metal powder and are prevented from blocking the X-axis chip removal groove and Y-axis chip removal groove, automatic emission of metal labor is realized, the metal chips are conveniently processed, normal production of the machine tool is ensured, and normal recovery of the metal chips are saved.

Drawings

Fig. 1 illustrates an outline structure of the present utility model.

Fig. 2 illustrates a partially enlarged structural view of the portion a in fig. 1 according to the present utility model.

Fig. 3 illustrates a top view of the present utility model.

Reference numerals illustrate: the X-axis bed body 10, the trapezoid guide groove 11, the X-axis sliding step 12, the X-axis guide rail backing plate 13, the second guide inclined plane 14, the Y-axis bed body 20, the Y-axis sliding step 21, the first guide inclined plane 22, the first chip removing mechanism 30, the X-axis chip removing groove 31, the X-axis screw 32, the first driving motor 33, the second chip removing mechanism 40, the Y-axis chip removing groove 41, the Y-axis screw 42 and the second driving motor 43.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present disclosure. It will be apparent that the described embodiments are some, but not all, of the embodiments of the present disclosure.

All other embodiments, which can be made by one of ordinary skill in the art without the need for inventive faculty, are intended to be within the scope of the present disclosure, based on the described embodiments of the present disclosure.

Reference is made to fig. 1-3.

The utility model provides a numerical control machine tool body structure with a chip removal function, which comprises a machine tool body, wherein the machine tool body comprises an X-axis machine tool body 10 arranged along an X-axis direction and a Y-axis machine tool body 20 arranged along a Y-axis direction, a plurality of first chip removal mechanisms 30 are arranged on the X-axis machine tool body 10 in parallel, a plurality of second chip removal mechanisms 40 are arranged on the Y-axis machine tool body 20 in parallel, the first chip removal mechanisms 30 comprise X-axis chip removal grooves 31 penetrating through the top of the X-axis machine tool body 10 along the X-axis direction, X-axis screw rods 32 rotatably connected between two ends of the X-axis chip removal grooves 31, and a first driving motor 33 arranged on one end face of the X-axis chip removal grooves 31 and in driving connection with the X-axis screw rods 32; the second chip removing mechanism 40 comprises a Y-axis chip removing groove 41 penetrating through the top of the Y-axis bed body 20 along the Y-axis direction, a Y-axis screw 42 rotatably connected between two ends of the Y-axis chip removing groove 41, and a second driving motor 43 arranged on one end surface of the Y-axis chip removing groove 41 and in driving connection with the Y-axis screw 42; the top of the X-axis bed body 10 is provided with a trapezoid diversion trench 11 communicated with the X-axis chip removal trench 31, and the output end of the Y-axis chip removal trench 41 is communicated with the trapezoid diversion trench 11.

The working principle of the machine tool is that the X-axis lathe body 10 is used for installing a spindle mechanism, the Y-axis lathe body 20 is used for installing a material seat mechanism, metal scraps generated during part machining fall on the X-axis lathe body 10 and the Y-axis lathe body 20 along with cooling liquid, the metal scraps on the X-axis lathe body 10 flow into the X-axis scraps 31 along with the cooling liquid, the metal scraps on the Y-axis lathe body 20 flow into the Y-axis scraps 41 along with the cooling liquid, the Y-axis screw 42 is driven to rotate in the Y-axis scraps 41 through the second driving motor 43, the metal scraps falling into the Y-axis scraps 41 are conveyed to the X-axis scraps 31 side under the action of the Y-axis screw 42 and are ground, metal powder slurry output from the Y-axis scraps 41 enters the X-axis scraps 31 through the trapezoid guide groove 11, the first driving motor 33 drives the X-axis screw 32 to rotate in the X-axis scraps 31, the metal scraps falling into the X-axis scraps 31 are conveyed to the output end side of the X-axis scraps 31 along with the cooling liquid flowing into the Y-axis scraps 41, the metal scraps are ground, the metal scraps are automatically conveyed to the output side of the X-axis scraps to the Y-axis scraps 31 side under the action of the X-axis screw 32, the metal scraps are prevented from being blocked by the metal scraps, the metal scraps are automatically conveyed to the Y-axis scraps and the metal scraps are discharged to the side of the machine tool body, and the normal machine tool is guaranteed, and the metal scraps are conveniently discharged, and the metal scraps are conveniently is recycled, and the metal scraps are processed, and the metal scraps are conveniently.

Based on the above embodiment, the top center of the X-axis bed 10 is provided with the X-axis sliding step 12, and the two sides of the X-axis sliding step 12 are symmetrically provided with the first chip removing mechanism 30, and the trapezoidal diversion trench 11 is adjacent to the side wall of the X-axis sliding step 12; two Y-axis sliding steps 21 are arranged on the top of the Y-axis bed body 20 in parallel, second chip removal mechanisms 40 are arranged on two sides of the Y-axis sliding steps 21, and first diversion inclined planes 22 extending to Y-axis chip removal grooves 41 are arranged on the side walls of the Y-axis sliding steps 21. The metal scraps and the cooling liquid falling on the X-axial sliding steps 12 enter the X-axial junk slots 31 on two sides through the trapezoidal guide grooves 11 on two sides, the metal scraps and the cooling liquid falling on the Y-axial sliding steps 21 enter the Y-axial junk slots 41 through the guide of the first guide inclined planes 22, the rapid discharge of the metal scraps and the cooling liquid can be realized, and the discharging efficiency is improved.

Based on the above embodiment, two X axial guide rail backing plates 13 are arranged on the top of the X axial sliding step 12 in parallel, two second guide inclined planes 14 extending to the trapezoid guide grooves 11 are symmetrically arranged at the end face of the X axial sliding step 12, and metal chips and cooling liquid falling on the X axial sliding step 12 flow into the trapezoid guide grooves 11 under the guidance of the second guide inclined planes 14, so that the effect of guiding is achieved, and the rapid discharge of the metal chips and the cooling liquid is realized.

The above embodiments are merely illustrative of the preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model, and various modifications and improvements made by those skilled in the art to the technical solution of the present utility model should fall within the scope of protection defined by the claims of the present utility model without departing from the spirit of the design of the present utility model.

Claims (3)

1. The numerical control machine tool body structure with the chip removal function comprises a machine body and is characterized in that the machine body comprises an X-axis machine body arranged along the X-axis direction and a Y-axis machine body arranged along the Y-axis direction, a plurality of first chip removal mechanisms are arranged on the X-axis machine body in parallel, a plurality of second chip removal mechanisms are arranged on the Y-axis machine body in parallel, and the first chip removal mechanisms comprise X-axis chip removal grooves penetrating through the top of the X-axis machine body along the X-axis direction, X-axis screw rods rotatably connected between two ends of the X-axis chip removal grooves, and a first driving motor arranged on one end face of the X-axis chip removal grooves and in driving connection with the X-axis screw rods; the second chip removal mechanism comprises a Y-axis chip removal groove penetrating through the top of the Y-axis bed body along the Y-axis direction, a Y-axis screw rod rotatably connected between two ends of the Y-axis chip removal groove, and a second driving motor arranged on one end face of the Y-axis chip removal groove and in driving connection with the Y-axis screw rod; the X-axis bed body top is provided with a trapezoid guide groove communicated with the X-axis chip groove, and the output end of the Y-axis chip groove is communicated with the trapezoid guide groove.

2. The numerical control machine tool body structure with the chip removal function according to claim 1, wherein an X-axis sliding step is arranged at the center of the top of the X-axis machine tool body, the first chip removal mechanisms are symmetrically arranged on two sides of the X-axis sliding step, and the trapezoid diversion trench is adjacent to the side wall of the X-axis sliding step; two Y-axis sliding steps are arranged on the top of the Y-axis bed body in parallel, the second chip removal mechanisms are arranged on two sides of the Y-axis sliding steps, and a first diversion inclined plane extending to the Y-axis chip removal grooves is arranged on the side wall of the Y-axis sliding steps.

3. The numerical control machine tool body structure with the chip removal function according to claim 2, wherein two X-axis guide rail base plates are arranged on the top of the X-axis sliding step in parallel, and two second guide inclined planes extending to the trapezoid guide grooves are symmetrically arranged at the end face of the X-axis sliding step.