CN108817485B

CN108817485B - Numerical control milling machine tool suitable for automatic operation

Info

Publication number: CN108817485B
Application number: CN201811104571.4A
Authority: CN
Inventors: 黄杰
Original assignee: Dongguan Zhisheng Intelligent Machinery Technology Co ltd
Current assignee: Dongguan Zhisheng Intelligent Machinery Technology Co ltd
Priority date: 2018-09-21
Filing date: 2018-09-21
Publication date: 2023-08-25
Anticipated expiration: 2038-09-21
Also published as: CN108817485A

Abstract

The invention discloses a numerical control milling machine tool suitable for automatic operation, which comprises a frame, wherein buffer mechanisms are fixedly arranged at four corners of the lower part of the frame, a door-shaped frame is arranged at the upper part of the frame, and a milling head is arranged at the upper part of the door-shaped frame in a sliding manner; a processing table extending along the Y axis is arranged on the frame below the door-shaped frame, wherein the rear part of the processing table protrudes out of the frame for a certain distance, and the rear part of the processing table is connected with an automatic feeding and discharging mechanism; wherein, the processing platform includes the processing platform base member of fixed mounting in the frame. According to the invention, the Y-axis of the numerical control milling machine tool is lengthened, the workbench moves to the rear of the machine tool when the workpiece is required to be automatically replaced after machining, and the automatic feeding and discharging device can be installed and operated at the rear of the machine tool, so that the debugging and maintenance of the machine tool are completely unaffected. In addition, the invention also provides a buffer mechanism, and the machine tool can be buffered and damped through the buffer mechanism, so that the influence of mechanical vibration on the machining precision of the machine tool is avoided.

Description

Numerical control milling machine tool suitable for automatic operation

Technical field:

the invention relates to the technical field of machine tool equipment, in particular to a numerical control milling machine tool suitable for automatic operation.

The background technology is as follows:

the common numerical control machining center loads and unloads workpieces from the front or side protective door, and an automation device is additionally arranged at the parts during automatic loading and unloading, but the parts are inlets for debugging and maintaining the machine tool, and the additionally arranged automation device brings inconvenience to the debugging and maintaining of the machine tool. In addition, the running automation device has a certain danger, personnel are not allowed to approach, and the observation of the running process of the machine tool is also influenced.

The invention comprises the following steps:

the invention aims to overcome the defects of the prior art and provides a numerical control milling machine tool suitable for automatic operation.

The technical solution of the invention is as follows:

a numerical control milling machine tool suitable for automatic operation comprises a frame, wherein buffer mechanisms are fixedly arranged at four corners of the lower part of the frame, a door-shaped frame is arranged at the upper part of the frame, and a milling processing head is slidably arranged at the upper part of the door-shaped frame; a processing table extending along the Y axis is arranged on the frame below the door-shaped frame, wherein the rear part of the processing table protrudes out of the frame for a certain distance, and the rear part of the processing table is connected with an automatic feeding and discharging mechanism; wherein, the processing platform includes the processing platform base member of fixed mounting in the frame, and the middle part of processing platform base member is provided with rectangular cell body, and the both sides of rectangular cell body are formed with Y axle slide rail, and the upper portion of Y axle slide rail slides and is provided with Y axle slider, and the upper end of Y axle slider is provided with the frock tool.

The buffer mechanism comprises a buffer main body, wherein the buffer main body is of a barrel-shaped structure, an opening of the buffer main body is upward, a central opening is formed in the bottom wall of the buffer main body, a lower bracket is clamped in the central opening, a fixing ring is arranged on the outer side of the lower bracket, and the fixing ring limits the lower bracket on the bottom wall of the buffer main body; an annular groove is formed in the outer wall of the buffer main body, a supporting arm is inserted in the annular groove, an annular sealing ring is arranged between the supporting arm and the annular groove, and a reinforcing plate is arranged between the supporting arm and the buffer main body; the upper part of the outer end of the bracket arm is inserted with an elastic block, and the elastic block is further inserted with a gland positioned on the upper side; a cavity is formed between the gland and the bracket arm, and a plate spring connected with the elastic block and the outer wall of the buffer main body is arranged in the cavity; a buffer spring is fixed on the lower bracket, the upper end of the buffer spring passes through a central hole of the gland and is connected with the upper bracket, a guide cylinder is arranged between the upper bracket and the gland, the outer edge of the upper end of the guide cylinder is pressed by the upper bracket and the gland, and the lower end of the guide cylinder extends downwards to form a limiting mechanism of the buffer spring; the lower end surface of the gland is fixedly connected with an annular pressing ring, the outer circumference of the annular pressing ring is contacted with the inner wall of the buffer main body, and the inner circumference of the annular pressing ring is contacted with the lower end of the guide cylinder; the lower end of the annular pressing ring is also provided with an elastic lug which is used for contacting with the bottom wall of the buffering main body to buffer and damp.

Two first screw supports are fixedly arranged at two ends of the strip groove body, a Y-axis screw is rotatably arranged on the first screw supports, a Y-axis sliding block is in threaded connection with the Y-axis screw, and one end of the Y-axis screw is fixedly connected with an output shaft of a Y-axis motor.

The door-shaped frame comprises two upright posts fixedly arranged above the frame, upper end cross beams are fixedly arranged at the upper ends of the two upright posts, an X-axis moving mechanism is arranged on the upper end cross beams, and a milling processing head is arranged on the X-axis moving mechanism.

The X-axis moving mechanism comprises two X-axis sliding rails fixedly arranged at the front side of the upper end cross beam, milling heads are slidably arranged on the two X-axis sliding rails, an X-axis screw rod which is arranged in parallel with the X-axis sliding rails is arranged between the two X-axis sliding rails, and the X-axis screw rod is in threaded connection with a mounting block which is fixedly connected with the milling heads; further, two ends of the X-axis screw are rotatably supported through the second screw support, and one end of the X-axis screw is fixedly connected with an output shaft of the X-axis motor.

The milling head comprises a mounting plate, a clamping block matched with the two X-axis sliding rails is arranged on the back surface of the mounting plate, a vertical sliding groove is formed in the front end of the mounting plate, a lifting sliding block is arranged in the vertical sliding groove in a sliding mode, and the lifting sliding block is driven to lift by a lifting motor; the upper part of the lifting slide block is provided with a processing head fixing seat, and a milling cutter head is detachably fixed on the processing head fixing seat.

The frame includes lower part support and upper portion support frame, and wherein, upper portion support frame fixed mounting is provided with the flange in the upper end of lower part support, the side of upper portion support frame is fixed.

The front of the processing table is provided with a feeding trolley independent of the machine tool, and the feeding trolley comprises a carriage and travelling wheels positioned at the lower part of the carriage.

An electric cabinet is arranged in the lower support and is electrically connected with the processing table and the milling processing head.

The invention has the beneficial effects that: according to the invention, the Y-axis of the numerical control milling machine tool is lengthened, the workbench moves to the rear of the machine tool when the workpiece is required to be automatically replaced after machining, and the automatic feeding and discharging device can be installed and operated at the rear of the machine tool, so that the debugging and maintenance of the machine tool are completely unaffected. In addition, the invention also provides a buffer mechanism, and the machine tool can be buffered and damped through the buffer mechanism, so that the influence of mechanical vibration on the machining precision of the machine tool is avoided.

Description of the drawings:

FIGS. 1-3 are schematic views of the structure of the present invention from different viewing angles;

fig. 4 is a cross-sectional view of the cushioning mechanism.

The specific embodiment is as follows:

in order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to the appended drawings.

As shown in fig. 1-4, a numerical control milling machine tool suitable for automatic operation comprises a frame 1, wherein buffer mechanisms 2 are fixedly arranged at four corners of the lower part of the frame 1, a door-shaped frame is arranged at the upper part of the frame 1, and a milling head is slidably arranged at the upper part of the door-shaped frame; a processing table 3 extending along the Y axis is arranged on the frame 1 below the door-shaped frame, wherein the rear part of the processing table 3 protrudes from the frame 1 for a certain distance, and the rear part of the processing table 3 is connected with an automatic feeding and discharging mechanism;

the processing table 3 includes a processing table base body fixedly installed on the frame 1, a long groove body is arranged in the middle of the processing table base body, Y-axis sliding rails 30 are formed on two sides of the long groove body, a Y-axis sliding block 32 is slidably arranged on the upper portion of the Y-axis sliding rail 30, and a tool fixture (not shown in the figure) is arranged at the upper end of the Y-axis sliding block 32.

Two first screw supports 310 are fixedly arranged at two ends of the long-strip groove body, a Y-axis screw 311 is rotatably arranged on the first screw supports 310, a Y-axis sliding block 32 is in threaded connection with the Y-axis screw 311, and one end of the Y-axis screw 311 is fixedly connected with an output shaft of the Y-axis motor 31.

The door-shaped frame comprises two upright posts 42 fixedly arranged above the frame 1, an upper end cross beam 41 is fixedly arranged at the upper ends of the two upright posts 42, an X-axis moving mechanism is arranged on the upper end cross beam 41, and a milling head is arranged on the X-axis moving mechanism.

The X-axis moving mechanism comprises two X-axis sliding rails 413 fixedly arranged on the front side of the upper end beam 41, milling heads are slidably arranged on the two X-axis sliding rails 413, an X-axis screw 412 which is arranged parallel to the X-axis sliding rails 413 is arranged between the two X-axis sliding rails 413, an installation block 432 is connected to the X-axis screw 412 in a threaded manner, and the installation block 432 is fixedly connected with the milling heads; further, both ends of the X-axis screw 412 are rotatably supported by the second screw support 411, and one end of the X-axis screw 412 is fixedly connected with an output shaft of the X-axis motor.

The milling head comprises a mounting plate 43, a clamping block 431 matched with two X-axis sliding rails 413 is arranged on the back surface of the mounting plate 43, a vertical sliding groove (not shown in the figure) is arranged at the front end of the mounting plate 43, a lifting sliding block 441 is arranged in the vertical sliding groove in a sliding manner, and the lifting sliding block 441 is driven to lift by a lifting motor 45; the upper part of the lifting slide block 441 is provided with a processing head fixing seat 44, and a milling cutter head 46 is detachably fixed on the processing head fixing seat 44.

The frame 1 comprises a lower bracket 11 and an upper bracket 10, wherein the upper bracket 10 is fixedly arranged at the upper end of the lower bracket 11, and a flange (not shown in the figure) is fixedly arranged on the side surface of the upper bracket 10.

Due to the arrangement of the flange structure, the processing waste can be shielded to a certain extent, and the processing waste is prevented from splashing.

A feeding trolley 5 independent of the machine tool is arranged in front of the processing table 3, and the feeding trolley 5 comprises a carriage 50 and a travelling wheel 51 positioned at the lower part of the carriage 50.

An electric cabinet (not shown) is arranged in the lower support 11 and is electrically connected with the machining table 3 and the milling head.

The buffer mechanism comprises a buffer main body 202, wherein the buffer main body 202 is of a barrel-shaped structure, an opening of the buffer main body 202 is upwards arranged, a central opening 205 is formed in the bottom wall of the buffer main body 202, a lower bracket 206 is clamped in the central opening 205, a fixing ring 223 is arranged on the outer side of the lower bracket 206, and the fixing ring 223 limits the lower bracket 206 on the bottom wall of the buffer main body 202; an annular groove 204 is formed in the outer wall of the buffer main body 202, a supporting arm 216 is inserted into the annular groove 204, an annular sealing ring 203 is arranged between the supporting arm 216 and the annular groove 204, and a reinforcing plate 221 is arranged between the supporting arm 216 and the buffer main body 202; the upper part of the outer end of the bracket arm 216 is inserted with an elastic block 218, and the elastic block 218 is further inserted with a gland 215 positioned on the upper side; a cavity 217 is formed between the gland 215 and the bracket 216, and a plate spring 219 for connecting an elastic block 218 and the outer wall of the buffer main body 202 is arranged in the cavity 217; a buffer spring 208 is fixed on the lower bracket 206, the upper end of the buffer spring 208 passes through a central hole of a gland 215 and is connected with the upper bracket 201, wherein a guide cylinder 212 is arranged between the upper bracket 201 and the gland 215, the outer edge of the upper end of the guide cylinder 212 is pressed by the upper bracket 201 and the gland 215, and the lower end of the guide cylinder 212 extends downwards to form a limiting mechanism of the buffer spring 208; the lower end surface of the gland 215 is fixedly connected with an annular pressing ring 213, the outer circumference of the annular pressing ring 213 is contacted with the inner wall of the buffer main body 202, and the inner circumference of the annular pressing ring 213 is contacted with the lower end of the guide cylinder 212; the lower end of the annular pressing ring 213 is further provided with an elastic bump 214, and the elastic bump 214 is used for contacting the bottom wall of the buffer body 202 to buffer and absorb shock.

In the machining process, as the Y-axis of the digital milling machine tool is lengthened, the workbench moves to the rear of the machine tool when the workpiece is required to be automatically replaced after machining is finished, and the automatic feeding and discharging device can be installed to operate at the rear of the machine tool, so that the debugging and maintenance of the machine tool are not affected completely; the milling head can move in the X-axis and Z-axis directions, and further moves in combination with the Y-axis of the workbench, so that the workpiece can be precisely machined. In addition, the invention also provides a buffer mechanism, and the machine tool can be buffered and damped through the buffer mechanism, so that the influence of mechanical vibration on the machining precision of the machine tool is avoided.

The examples are presented to illustrate the invention and are not intended to limit the invention. Modifications to the described embodiment may occur to those skilled in the art without departing from the spirit and scope of the invention, and the scope of the invention is therefore set forth in the appended claims.

Claims

1. A numerical control milling machine tool suitable for automated operation, characterized in that: the milling machine comprises a frame (1), wherein buffer mechanisms (2) are fixedly arranged at four corners of the lower part of the frame (1), a door-shaped frame is arranged at the upper part of the frame (1), and a milling head is slidably arranged at the upper part of the door-shaped frame; a processing table (3) extending along the Y axis is arranged on the frame (1) below the door-shaped frame, wherein the rear part of the processing table (3) protrudes out of the frame (1) for a certain distance, and the rear part of the processing table (3) is connected with an automatic feeding and discharging mechanism; the machining table (3) comprises a machining table base body fixedly installed on the frame (1), a long groove body is arranged in the middle of the machining table base body, Y-axis sliding rails (30) are formed on two sides of the long groove body, Y-axis sliding blocks (32) are arranged on the upper parts of the Y-axis sliding rails (30) in a sliding mode, and tool jigs are arranged at the upper ends of the Y-axis sliding blocks (32); two first screw supports (310) are fixedly arranged at two ends of the strip groove body, a Y-axis screw (311) is rotatably arranged on the first screw supports (310), a Y-axis sliding block (32) is in threaded connection with the Y-axis screw (311), and one end of the Y-axis screw (311) is fixedly connected with an output shaft of a Y-axis motor (31); the door-shaped frame comprises two upright posts (42) fixedly arranged above the frame (1), upper end cross beams (41) are fixedly arranged at the upper ends of the two upright posts (42), X-axis moving mechanisms are arranged on the upper end cross beams (41), and milling heads are arranged on the X-axis moving mechanisms; the buffering mechanism comprises a buffering main body (202), the buffering main body (202) is of a barrel-shaped structure, an opening of the buffering main body is upward, a central opening (205) is formed in the bottom wall of the buffering main body (202), a lower bracket (206) is clamped in the central opening (205), a fixing ring (223) is arranged on the outer side of the lower bracket (206), and the fixing ring (223) limits the lower bracket (206) on the bottom wall of the buffering main body (202); an annular groove (204) is formed in the outer wall of the buffer main body (202), a supporting arm (216) is inserted into the annular groove (204), an annular sealing ring (203) is arranged between the supporting arm (216) and the annular groove (204), and a reinforcing plate (221) is arranged between the supporting arm (216) and the buffer main body (202); an elastic block (218) is inserted at the upper part of the outer end of the bracket arm (216), and the elastic block (218) is further inserted with a gland (215) positioned at the upper side; a cavity (217) is formed between the gland (215) and the bracket arm (216), and a plate spring (219) which is connected with an elastic block (218) and the outer wall of the buffer main body (202) is arranged in the cavity (217); a buffer spring (208) is fixed on the lower bracket (206), the upper end of the buffer spring (208) passes through a central hole of the gland (215) and is connected with the upper bracket (201), a guide cylinder (212) is arranged between the upper bracket (201) and the gland (215), the outer edge of the upper end of the guide cylinder (212) is pressed by the upper bracket (201) and the gland (215), and the lower end of the guide cylinder (212) downwards extends to form a limiting mechanism of the buffer spring (208); the lower end surface of the gland (215) is fixedly connected with an annular pressing ring (213), the outer circumference of the annular pressing ring (213) is contacted with the inner wall of the buffer main body (202), and the inner circumference of the annular pressing ring (213) is contacted with the lower end of the guide cylinder (212); the lower end of the annular pressing ring (213) is also provided with an elastic lug (214), and the elastic lug (214) is used for contacting with the bottom wall of the buffer main body (202) to buffer and absorb shock;

the X-axis moving mechanism comprises two X-axis sliding rails (413) fixedly arranged on the front side of the upper end cross beam (41), milling heads are slidably arranged on the two X-axis sliding rails (413), an X-axis screw rod (412) which is parallel to the X-axis sliding rails (413) is arranged between the two X-axis sliding rails (413), an installation block (432) is connected onto the X-axis screw rod (412) in a threaded manner, and the installation block (432) is fixedly connected with the milling heads; further, two ends of the X-axis screw rod (412) are rotatably supported through a second screw rod support (411), and one end of the X-axis screw rod (412) is fixedly connected with an output shaft of the X-axis motor;

the front of the processing table (3) is provided with a feeding trolley (5) independent of a machine tool, and the feeding trolley (5) comprises a carriage (50) and a travelling wheel (51) positioned at the lower part of the carriage (50).

2. A numerically controlled milling machine adapted for automated operation as claimed in claim 1, wherein: the milling head comprises a mounting plate (43), a clamping block (431) matched with two X-axis sliding rails (413) is arranged on the back surface of the mounting plate (43), a vertical sliding groove is formed in the front end of the mounting plate (43), a lifting sliding block (441) is arranged in the vertical sliding groove in a sliding mode, and the lifting sliding block (441) is driven to lift through a lifting motor (45); the upper part of the lifting slide block (441) is provided with a processing head fixing seat (44), and a milling cutter head (46) is detachably fixed on the processing head fixing seat (44).

3. A numerically controlled milling machine adapted for automated operation as claimed in claim 1, wherein: the frame (1) comprises a lower support (11) and an upper support (10), wherein the upper support (10) is fixedly arranged at the upper end of the lower support (11), and a flange is fixedly arranged on the side surface of the upper support (10).

4. A numerically controlled milling machine adapted for automated operation as claimed in claim 1, wherein: an electric cabinet is arranged in the lower support (11), and is electrically connected with the processing table (3) and the milling processing head.