CN111496537A

CN111496537A - Three-head milling integrated processing equipment

Info

Publication number: CN111496537A
Application number: CN202010457968.2A
Authority: CN
Inventors: 陈邦友
Original assignee: Huizhou Youcheng Precision Technology Co ltd
Current assignee: Huizhou Youcheng Precision Technology Co ltd
Priority date: 2020-05-26
Filing date: 2020-05-26
Publication date: 2020-08-07

Abstract

The invention relates to a three-head milling integrated processing device, which comprises: the device comprises a rack, two cutter head mechanisms, a horizontal numerical control machine tool, a bearing mechanism and a movement mechanism; the two cutter head mechanisms and the horizontal numerical control machine tool are respectively and fixedly connected with the rack; each cutter head mechanism comprises a cutter head; the movement mechanism comprises a first driver and a guide rail, the guide rail is arranged on the rack, the first driver is in driving connection with the bearing mechanism, the bearing mechanism is arranged on the guide rail in a sliding mode, the two cutter discs are arranged on two sides of the guide rail respectively, the horizontal numerical control machine tool is arranged on one side of the two cutter disc mechanisms, and the horizontal numerical control machine tool is arranged on one side of the guide rail. The bearing mechanism is used for bearing a die, the cutter head mechanism and the horizontal numerical control machine tool are fixed together through the rack, and the die on the bearing mechanism can move between the cutter head mechanism and the horizontal numerical control machine tool through the movement of the bearing mechanism on the guide rail, so that the die can be automatically conveyed to the horizontal numerical control machine tool for milling after being cut by the double-head cutter head, and the production efficiency is effectively improved.

Description

Three-head milling integrated processing equipment

Technical Field

The invention relates to the technical field of milling, in particular to a three-head milling integrated processing device.

Background

The die machining needs to be conducted through cutting of the double-head cutter disc and milling of the milling equipment, the existing double-head cutter disc and the milling equipment are two independent devices, after the die is cut through the double-head cutter disc, a worker needs to manually place the die into the milling equipment for milling, more time needs to be consumed in the process, labor needs to be consumed, and the production efficiency is low.

Disclosure of Invention

Based on this, it is necessary to provide a three-head milling integrated processing device.

A three-head milling integrated processing equipment comprises: the device comprises a rack, two cutter head mechanisms, a horizontal numerical control machine tool, a bearing mechanism and a movement mechanism;

the two cutter head mechanisms and the horizontal numerical control machine tool are respectively and fixedly connected with the rack;

each cutter head mechanism comprises a cutter head, and the two cutter heads are arranged oppositely;

the motion mechanism comprises a first driver and a guide rail, the guide rail is arranged on the rack, the first driver is in driving connection with the bearing mechanism, the bearing mechanism is arranged on the guide rail in a sliding mode, the bearing mechanism is used for bearing a processed die, the two cutterheads are arranged on two sides of the guide rail respectively, the horizontal type numerical control machine tool is arranged on one side of the cutterhead mechanism, and the horizontal type numerical control machine tool is arranged on one side of the guide rail.

In one embodiment, the horizontal numerically-controlled machine tool comprises a milling assembly, a support column, a cutter taking rod and a cutter magazine, wherein the support column is fixedly connected with the frame, the milling assembly is arranged on one side of the guide rail, the milling assembly and the cutter magazine are respectively connected with the support column, the cutter taking rod is rotatably arranged on the support column, one end of the cutter taking rod is movably abutted to the milling assembly, the other end of the cutter taking rod is movably abutted to the cutter magazine, one end of the cutter taking rod is used for grabbing a cutter on the milling assembly and rotating the cutter taking rod to the cutter magazine, the grabbed cutter is placed into the cutter magazine, or the grabbed cutter on the cutter magazine is grabbed and rotated to the milling assembly, and the grabbed cutter is installed to the milling assembly.

In one embodiment, the milling assembly is slidably disposed on the supporting column, and a sliding direction of the milling assembly on the supporting column is perpendicular to a sliding direction of the carrying mechanism on the guide rail.

In one embodiment, the tool magazine is disc-shaped, and the tool magazine is rotatably arranged on the supporting column.

In one embodiment, the bearing mechanism comprises a sliding seat, a rotating seat, a second driver and a pressing assembly, the first driver is in driving connection with the sliding seat, the sliding seat is slidably disposed on the guide rail, the second driver is disposed on the sliding seat, the second driver rotates with the rotating seat, the rotating seat is rotatably disposed on the sliding seat, the pressing assembly is movably disposed on the sliding seat, and the pressing assembly is used for pressing the mold onto the rotating seat.

In one embodiment, the pressing assembly comprises a supporting frame and a pressing driver, the supporting frame is arranged on the sliding seat, the pressing driver is arranged on the supporting frame, and a power output end of the pressing driver is used for pressing the die on the rotating seat.

In one embodiment, the bearing mechanism further comprises a bearing table, and the bearing table is arranged on the rotating seat.

In one embodiment, the second drive comprises a servo motor.

In one embodiment, the first driver comprises a driving motor and a screw rod, the driving motor is in driving connection with the screw rod, the bearing mechanism is provided with a screw hole, the screw rod is arranged in the screw hole in a penetrating mode, and the screw rod is in threaded connection with the side wall of the screw hole.

In one embodiment, each of the cutter head mechanisms further comprises a third driver, the third driver is in driving connection with one of the cutter heads, and the third driver is used for driving the cutter head to rotate.

The invention has the beneficial effects that: the bearing mechanism is used for bearing a mold, the cutter head mechanism and the horizontal numerical control machine tool are fixed together through the rack, and the mold on the bearing mechanism can move between the cutter head mechanism and the horizontal numerical control machine tool through the movement of the bearing mechanism on the guide rail, so that the mold can be automatically conveyed to the horizontal numerical control machine tool for milling after being cut by the double-head cutter head, the mold does not need to be manually placed into milling equipment for milling, and the production efficiency is effectively improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic structural view of a three-head milling and machining apparatus according to an embodiment;

FIG. 2 is a schematic structural diagram of another direction of the three-head milling integrated processing device according to an embodiment;

fig. 3 is a schematic structural diagram of another state of the three-head milling and machining integrated apparatus according to the embodiment.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 3, a three-head milling and machining apparatus 10 according to an embodiment of the present invention includes: the device comprises a frame 100, two cutter head mechanisms 200, a horizontal numerical control machine 300, a bearing mechanism 400 and a movement mechanism 500; the two cutter head mechanisms 200 and the horizontal numerical control machine 300 are respectively and fixedly connected with the rack 100; each cutter head mechanism 200 comprises a cutter head 210, and the two cutter heads 210 are arranged oppositely; the moving mechanism 500 includes a first driver (not shown) and a guide rail 510, the guide rail 510 is disposed on the frame 100, the first driver is in driving connection with the bearing mechanism 400, the bearing mechanism 400 is slidably disposed on the guide rail 510, the bearing mechanism 400 is used for bearing a processed mold, two the cutterheads 210 are disposed on two sides of the guide rail 510, the horizontal numerical control machine 300 is disposed on one side of the cutterhead mechanism 200, and the horizontal numerical control machine 300 is disposed on one side of the guide rail 510.

Specifically, the cutterhead mechanism 200 and the horizontal numerical control machine 300 are fixed by the frame 100 so that they can be close to each other, the guide rail 510 extends along the direction of the cutterhead mechanism 200 toward the horizontal numerical control machine 300, the bearing mechanism 400 is used for bearing a mold to be machined, please refer to fig. 1 to 3, the bearing mechanism 400 slides on the guide rail 510, and then the mold on the bearing mechanism 400 can be conveyed from the cutterhead mechanism 200 to the horizontal numerical control machine 300. The first driver drives the carriage 400 to move linearly on the guide rail 510.

A cutter head mechanism 200 is disposed on one side of the guide rail 510, and another cutter head mechanism 200 is disposed on the other side of the guide rail 510, so that two cutter heads 210 can be disposed at intervals and are located on both sides of the guide rail 510, and the cutter heads 210 are used for cutting the mold on the bearing mechanism 400, so that the mold can be cut by the two cutter heads 210 when the mold is located between the two cutter heads 210, as shown in fig. 3. The horizontal numerical control machine 300 is provided with a cutter facing the die on the bearing mechanism 400, the cutter on the horizontal numerical control machine 300 is used for milling the die on the bearing mechanism 400, and after the die is cut by the cutter disc 210, the die moves to the horizontal numerical control machine 300 along with the bearing mechanism 400, so that the horizontal numerical control machine 300 can mill the die.

In the above embodiment, the bearing mechanism 400 is used for bearing a mold, the cutter head mechanism 200 and the horizontal numerical control machine 300 are fixed together by the frame 100, and the mold on the bearing mechanism 400 can move between the cutter head mechanism 200 and the horizontal numerical control machine 300 by the movement of the bearing mechanism 400 on the guide rail 510, so that the mold can be automatically conveyed to the horizontal numerical control machine 300 for milling after being cut by the double-head cutter head 210, the mold does not need to be manually placed into the milling equipment 10 for milling, and the production efficiency is effectively improved.

In this application, two blade disc mechanisms 200 mill the mould through two blade discs 210 for the mould is milled and is required shape, and horizontal digit control machine tool 300 carries out processing such as accurate drilling, milling, chamfer to the mould, makes the mould obtain accurate processing. The two cutter head mechanisms and the horizontal numerical control machine 300 are respectively provided with a cutter which is equivalent to three cutters for processing a mold, so that three heads of the three-head milling integrated processing equipment are respectively two cutter heads and a cutter of the horizontal numerical control machine 300. In one embodiment, the three-head milling integrated processing device can also be called a cutting and milling integrated processing device.

In order to adapt to the machining of different dies and to adapt to different milling requirements, in one embodiment, as shown in fig. 1 and fig. 2, the horizontal numerical control machine 300 includes a milling assembly 310, a supporting column 320, a tool-taking bar 330 and a tool magazine 340, the supporting column 320 is fixedly connected to the machine frame 100, the milling assembly 310 is disposed on one side of the guide rail 510, the milling assembly 310 and the tool magazine 340 are respectively connected to the supporting column 320, the tool-taking bar 330 is rotatably disposed on the supporting column 320, one end of the tool-taking bar 330 is movably abutted to the milling assembly 310, the other end of the tool-taking bar 330 is movably abutted to the tool magazine 340, one end of the tool-taking bar 330 is used for taking a tool on the milling assembly 310 and rotating to the tool magazine 340, and putting the taken tool into the tool magazine 340 or for taking a tool on the tool magazine 340, and rotated to the milling assembly 310 to mount the grasped tool into the milling assembly 310.

In this embodiment, a plurality of tools of different models are loaded on the tool magazine 340, and are used for replacing the tools on the milling assembly 310, so that the tools on the milling assembly 310 can be replaced according to different models of molds, and different milling requirements can be adapted. Specifically, when changing the cutter, the first end of getting cutter arbor 330 takes off the cutter of tool magazine 340, and the second end of getting cutter arbor 330 takes off the cutter on horizontal digit control machine tool 300, and afterwards, the cutter of first end rotates to horizontal digit control machine tool 300 and installs, and the cutter of second end loads on tool magazine 340 to realize the change of cutter, and then the processing of the different mould of adaptation, the different demands that mill of adaptation.

In this embodiment, get the both ends of cutter arbor 330 and be provided with respectively and get the sword groove, get the shape in sword groove and match with the shape of the handle of a knife of cutter, like this, get the sword groove and can get the cutter clamp, realize the change of cutter. And because the tool magazine 340 rotates and sets up on support column 320 for different positions on the cutter can rotate to get the position that cutter bar 330 got the cutter, and make the position of vacancy on the tool magazine 340 can rotate to get the position that cutter bar 330 corresponds, be convenient for get cutter bar 330 and install the cutter on tool magazine 340.

In order to replace a tool on the milling assembly 310, in one embodiment, the milling assembly 310 is provided with a mounting hole, a clamping assembly (not shown) and a pop-up assembly (not shown) are arranged in the mounting hole, the pop-up assembly includes a spring, the clamping assembly is used for clamping the tool, the pop-up assembly is used for popping up the tool when the tool needs to be replaced, so that the tool can be clamped by the tool taking rod 330, when the tool is mounted, the tool taking rod 330 aligns the tool with the mounting hole, the tool taking rod drives the tool to move towards the inner side of the mounting hole, so that the tool is inserted into the mounting hole and clamped and fixed by the clamping assembly. It should be understood that the clamping assembly and the ejection assembly of the milling assembly can be implemented by the prior art, and are not described in the present embodiment in a cumbersome manner.

In order to achieve milling of multiple positions of the mold, in one embodiment, the milling assembly 310 is slidably disposed on the supporting column 320, and a sliding direction of the milling assembly 310 on the supporting column 320 is perpendicular to a sliding direction of the carrying mechanism 400 on the guide rail 510.

For convenience of understanding, in this embodiment, a sliding direction of the bearing mechanism 400 on the guide rail 510 is defined as a horizontal direction, so that a sliding direction of the milling assembly 310 on the support column 320 is a vertical direction, when the mold needs to mill different positions in the milling process, the milling assembly 310 moves in the vertical direction, different positions of the mold in the vertical direction can be milled, and when the bearing mechanism 400 slides on the guide rail 510, the mold is driven to move in the horizontal direction, so that different positions of the mold in the horizontal direction are aligned to a cutter of the milling assembly 310, and further different positions of one surface of the mold facing the milling assembly 310 are all milled.

In order to drive the milling assembly 310 to move on the supporting column 320, in an embodiment, the horizontal numerical control machine 300 further includes a fourth driver (not shown), the fourth driver includes a fourth driving motor and a screw rod, the fourth driving motor is in driving connection with the screw rod, the milling assembly 310 includes a sliding block, a driving hole is formed in the sliding block, a side wall of the driving hole is in threaded connection with the screw rod, and the sliding block is slidably disposed on the supporting column 320, so that the milling assembly 310 can move on the supporting column 320 through the driving of the fourth driving motor and the transmission of the screw rod.

In order to realize the replacement of the tool, in one embodiment, as shown in fig. 2, the tool magazine 340 is a disc shape, and the tool magazine 340 is rotatably disposed on the supporting column 320. In this embodiment, each tool is disposed at the edge of the disc-shaped tool magazine 340, so that the tool can be conveniently taken by the tool taking bar 330.

In one embodiment, the axial direction of the tool magazine 340 and the axial direction of the tool of the horizontal numerical control machine 300 are parallel to each other, and the axial direction of the disk of the tool magazine 340 and the axial direction of the tool of the horizontal numerical control machine 300 are parallel to each other, which facilitates the taking of the tool.

In an embodiment, the axial direction of the tool magazine 340 is perpendicular to the axial direction of the tool of the horizontal numerical control machine 300, and the axial direction of the disk of the tool magazine 340 is perpendicular to the axial direction of the tool of the horizontal numerical control machine 300, in this embodiment, the tool magazine 340 is provided with a push-out assembly, the push-out assembly is used for pushing out the tool and rotating the tool to a direction parallel to the axial direction of the tool of the horizontal numerical control machine 300, the push-out assembly can be implemented by using the prior art, it should be understood that the tool magazine 340, the installation structure of the tool magazine 340 in the tool, the structure of the push-out assembly, and the rotation structure of the tool magazine 340 on the supporting column 320 in the above embodiments can be implemented by using the prior art.

In order to place the mold on the carrying mechanism 400 for processing, in one embodiment, as shown in fig. 1 to 3, the carrying mechanism 400 includes a sliding seat 410, a rotating seat 420, a second driver, and a pressing assembly 430, the first driver is in driving connection with the sliding seat 410, the sliding seat 410 is slidably disposed on the guide rail 510, the second driver is disposed on the sliding seat 410, the second driver rotates with the rotating seat 420, the rotating seat 420 is rotatably disposed on the sliding seat 410, the pressing assembly 430 is movably disposed on the sliding seat 410, and the pressing assembly 430 is configured to press the mold onto the rotating seat 420.

In this embodiment, the sliding seat 410 is configured to slide on the guide rail 510, the sliding seat 410 drives the rotating seat 420 to move, and the rotating seat 420 is configured to carry a mold, so that the sliding seat 410 slides along the guide rail 510, so that the mold can move to the milling assembly 310 from between the two cutter discs 210, and the second driver is configured to drive the rotating seat 420 to rotate, so that when the mold is placed on the rotating seat 420, the mold can rotate along with the rotating seat 420, so that different surfaces of the mold can face the milling assembly 310, and the milling assembly 310 can mill different surfaces of the mold respectively. The pressing assembly 430 is used for pressing the die onto the rotating base 420, so that when the die is used for cutting and milling, the die can be fixed on the rotating base 420, the die is prevented from moving in machining, the machining precision of the die is higher, and the effect is better.

In order to press the mold against the rotary base 420, in one embodiment, as shown in fig. 1 to 3, the pressing assembly 430 includes a support frame 431 and a pressing driver 432, the support frame 431 is disposed on the sliding base 410, the pressing driver 432 is disposed on the support frame 431, and a power output end of the pressing driver 432 is used to press the mold against the rotary base 420.

In this embodiment, the supporting frame 431 is fixed on the sliding seat 410 to support the downward-pressing driver 432, when the downward-pressing driver 432 works, the power output end of the downward-pressing driver 432 abuts against the mold, and the mold is pressed tightly on the rotating seat 420 by the power of the downward-pressing driver 432, so that the mold is pressed tightly.

In order to better place the mold, in one embodiment, as shown in fig. 1, the supporting mechanism 400 further includes a supporting platform 440, and the supporting platform 440 is disposed on the rotating base 420. In this embodiment, the plummer 440 is detachably disposed on the rotating seat 420, and the plummer 440 is matched with the mold in shape, so that the plummer 440 with different types and sizes can be mounted on the rotating seat 420 to adapt to the processing of molds with different types.

In order to precisely control the rotation of the rotary base 420 so that the mold can be precisely oriented toward the horizontal type numerically controlled machine tool 300, in one embodiment, the second driver includes a servo motor. In this embodiment, a cavity is formed inside the sliding seat 410, the servo motor is disposed in the cavity, a transmission hole is formed at the top of the cavity, a power output shaft of the servo motor passes through the transmission hole to be drivingly connected with the rotating seat 420,

in order to drive the carrying mechanism 400 to move on the guide rail 510, in one embodiment, the first driver includes a driving motor and a screw rod, the driving motor is in driving connection with the screw rod, the carrying mechanism 400 has a screw hole, the screw rod is inserted into the screw hole, and the screw rod is in threaded connection with a side wall of the screw hole.

In this embodiment, set up the cavity in the sliding seat 410, the lateral wall and the spiro union portion of cavity are connected, and the spiro union portion is seted up the screw, and the through-hole that is used for letting the lead screw pass is still seted up to the lateral wall at the both ends of cavity, and the lead screw is on a parallel with guide rail 510, and like this, driving motor works, and the drive lead screw rotates to drive sliding seat 410 along the axial motion of lead screw, and then make sliding seat 410 can move along guide rail 510.

In one embodiment, each of the cutter head mechanisms 200 further includes a third driver 230, the third driver 230 is in driving connection with one of the cutter heads 210, and the third driver 230 is configured to drive the cutter head 210 to rotate. In this embodiment, the third driver 230 is a motor, and the driving of the motor enables the cutter head 210 to rotate at a high speed, so that the cutter head 210 can cut the mold. Regarding the connection structure of motor and blade disc, can adopt prior art to realize, for example, the motor passes through the gear train and is connected with the blade disc drive, like this, can make the blade disc can high-speed rotation, realizes the cutting.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. The utility model provides a three mills integrative process equipment which characterized in that includes: the device comprises a rack, two cutter head mechanisms, a horizontal numerical control machine tool, a bearing mechanism and a movement mechanism;

2. The three-head milling integrated processing equipment as claimed in claim 1, wherein the horizontal numerical control machine tool comprises a milling assembly, a support column, a cutter taking rod and a tool magazine, the support column is fixedly connected with the frame, the milling assembly is arranged on one side of the guide rail, the milling assembly and the tool magazine are respectively connected with the support column, the tool taking bar is rotationally arranged on the support column, one end of the cutter taking bar is movably abutted with the milling assembly, the other end of the cutter taking bar is movably abutted with the tool magazine, one end of the cutter taking rod is used for grabbing the cutter on the milling assembly, rotating the cutter to the cutter base and placing the grabbed cutter into the cutter base, or the tool magazine is used for grabbing tools on the tool magazine and rotating the tools to the milling assembly, and the grabbed tools are installed into the milling assembly.

3. The three-head milling integrated processing equipment according to claim 2, wherein the milling assembly is slidably arranged on the supporting column, and the sliding direction of the milling assembly on the supporting column is perpendicular to the sliding direction of the bearing mechanism on the guide rail.

4. The three-head milling integrated processing equipment as claimed in claim 2, wherein the tool magazine is disc-shaped, and the tool magazine is rotatably arranged on the support column.

5. The three-head milling integrated processing equipment according to claim 1, wherein the bearing mechanism comprises a sliding seat, a rotating seat, a second driver and a pressing assembly, the first driver is in driving connection with the sliding seat, the sliding seat is slidably disposed on the guide rail, the second driver is disposed on the sliding seat, the second driver and the rotating seat rotate, the rotating seat is rotatably disposed on the sliding seat, the pressing assembly is movably disposed on the sliding seat, and the pressing assembly is used for pressing a mold onto the rotating seat.

6. The three-head milling integrated processing equipment as claimed in claim 4, wherein the pressing assembly comprises a support frame and a pressing driver, the support frame is arranged on the sliding seat, the pressing driver is arranged on the support frame, and a power output end of the pressing driver is used for pressing a die on the rotating seat.

7. The three-head milling and machining integrated equipment according to claim 4, wherein the bearing mechanism further comprises a bearing table, and the bearing table is arranged on the rotating seat.

8. The three-head milling integrated processing device according to claim 4, wherein the second driver comprises a servo motor.

9. The three-head milling and machining integrated equipment according to claim 1, wherein the first driver comprises a driving motor and a screw rod, the driving motor is in driving connection with the screw rod, the bearing mechanism is provided with a screw hole, the screw rod penetrates through the screw hole, and the screw rod is in threaded connection with the side wall of the screw hole.

10. The three-head milling and machining integrated apparatus according to any one of claims 1 to 9, wherein each of the cutter head mechanisms further includes a third driver, the third driver being in driving connection with one of the cutter heads, the third driver being configured to drive the cutter head to rotate.