CN117620284A - Numerical control milling planer for numerical control machining center - Google Patents

Abstract

The invention discloses a numerical control planer type milling machine for a numerical control machining center, and relates to the technical field of planer type milling machines. This numerical control milling planer for numerical control machining center, in the course of working, two main shaft positions are fixed unchangeable relatively, and X is to only being driven by an X to servo motor, therefore the synchronism when having guaranteed two main shafts and removed, both effectual assurance two work piece processing position's uniformity has improved the precision of processing greatly, through starting transverse motor drive transverse screw rotation, make second screw thread piece and second workstation remove left or right, thereby play the effect of adjusting single work piece X on the second workstation to, can adjust the relative position between right side work piece and the left side work piece, compensate that two main shaft X to the relative position fixed unchangeable made, make the processing origin of two work pieces respectively with the relative coordinate between two cutters unanimous all the time.

Description

Numerical control milling planer for numerical control machining center

Technical Field

The invention relates to the technical field of planer milling machines, in particular to a numerical control planer milling machine for a numerical control machining center.

Background

The planer type milling machine is a large metal processing machine tool for milling a workpiece, is named as a planer type milling machine, is similar to a planer type milling machine in structural shape, is provided with a cross beam and a stand column supporting workbench, is generally used for processing large workpieces such as ship parts, wind power equipment, railway vehicle parts and the like, wherein the planer type milling machine tool with double main shafts is provided with two independent main shafts, can process two workpieces at the same time, has the advantages of high efficiency, high precision and multiple working procedures, is an ideal choice for processing the large workpieces and complex processes, and is widely applied.

In the prior art, when the double-spindle planer type milling machine is used for machining, the positions of two workpieces are fixed after being clamped, and the milling machine is generally provided with two X-axis servo motors for respectively controlling the movement of the two spindles, so that the milling operation of two different positions can be simultaneously carried out, but the technology has very high requirements on the synchronism of the two motors in work, and even if a high-precision control system and a feedback mechanism are adopted, the position deviation of the two spindles can be caused due to small errors, so that the machining precision of the milling machine is reduced.

So we propose a numerical control planer milling machine for numerical control machining center in order to solve the above mentioned problems.

Disclosure of Invention

The invention aims to provide a numerical control planer type milling machine for a numerical control machining center, which aims to solve the problems that the synchronization of two motors in operation is very high, even if a high-precision control system and a feedback mechanism are adopted, a small error can cause the position deviation of two main shafts, and the machining precision of the milling machine is reduced.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a numerical control milling planer for numerical control machining center, includes the base, the top fixed mounting of base has a plurality of evenly distributed's first slide rail, a plurality of all slide between the surface of first slide rail is provided with Y to the slider, the top fixed mounting of Y to the slider has the slip table, the top of slip table is close to left position symmetry fixed mounting has the supporting shoe, two fixed mounting has first workstation between the top of supporting shoe, the right surface fixed mounting of slip table has transverse motor, transverse motor's output shaft fixed mounting has transverse screw, the position that transverse screw surface is close to the distal end is provided with first supporting seat, first supporting seat fixed mounting is at the top of slip table, the position threaded connection that transverse screw surface is close to the proximal end has the second thread piece, the top fixedly connected with second workstation of second thread piece, the height of first workstation is the same with the second workstation, the bottom of second workstation is close to the position of front and back both sides is all fixed mounting has transverse slider, the inside slip of transverse slider is provided with transverse slide rail, transverse rail's fixed mounting is at the top of transverse slide table.

Preferably, the rear surface of base is close to the position fixed mounting in the middle has Y to servo motor, Y to servo motor's output fixed mounting has Y to the lead screw, the surface threaded connection of Y to the lead screw has first screw thread piece, first screw thread piece fixed mounting is in the bottom of slip table.

Preferably, the stand columns are fixedly installed on the outer surfaces of the left side and the right side of the base, the cross beam is fixedly installed between the tops of the two stand columns, the X-direction servo motor is fixedly installed on the right surface of the cross beam, the output end of the X-direction servo motor penetrates through the outer surface of the cross beam in a sliding mode and extends to the other side, the X-direction screw rod is fixedly installed at the output end of the X-direction servo motor, the second supporting seat is arranged at a position, close to the far end, of the outer surface of the X-direction screw rod, and the second supporting seat is fixedly installed on the inner wall of the cross beam.

Preferably, the position of the outer surface of the X-direction screw rod, which is close to the proximal end, is in threaded connection with a third threaded block, a sliding plate is fixedly arranged on the front surface of the third threaded block, a top sliding block is fixedly arranged at the inner top of the sliding plate, a top sliding rail is slidably arranged in the top sliding block, the top sliding rail is fixedly arranged at the top of the cross beam, an X-direction sliding block is symmetrically and fixedly arranged on the inner wall of one side of the sliding plate, an X-direction sliding rail is slidably arranged in the inner side of the X-direction sliding block, and the X-direction sliding rail is fixedly arranged on the front surface of the cross beam.

Preferably, the front surface of slide symmetry is provided with the spout, the inside slip of spout is provided with the lift arm, the front surface fixed mounting of lift arm has spindle motor, spindle motor's outside is provided with the cutter in a complete set.

Preferably, the top of slide symmetry has seted up the screw hole, four guiding holes have been seted up to the position that the top of slide is located the screw hole front side.

Preferably, the top fixed mounting of lift arm has the support, the surface of support is close to the position fixed mounting of rear side has Z to servo motor, Z to servo motor's output slip runs through the surface of support and extends to the below, Z to servo motor's output fixed mounting has Z to the lead screw, Z is corresponding with the screw hole.

Preferably, guide rods are fixedly arranged on the outer surfaces of the left side and the right side of the support, and the guide rods correspond to the guide holes.

Preferably, the notch is seted up on the right surface of first workstation, the left surface fixed mounting of second workstation has first fender bits board, the surface of first fender bits board is close to the inside of distal end slide setting at the notch, the top of slip table is close to the position of front and back both sides and all fixed mounting has the second fender bits board.

Preferably, the position that the interior top of slide is located top slider rear side is provided with the pressure sensor, the top of crossbeam is located the position fixed mounting of pressure sensor below has the horizontal piece, one of them one side surface fixed mounting of stand has the PLC controller, the outside of PLC controller is supporting to be equipped with bee calling organ, the PLC controller is electric connection with pressure sensor and bee calling organ.

Compared with the prior art, the invention has the beneficial effects that:

1. in the machining process, the positions of the two main shafts are relatively fixed and unchanged, and the X direction is driven by only one X direction servo motor, so that the synchronism of the two main shafts in moving is ensured, the consistency of the machining positions of the two workpieces is effectively ensured, the machining precision is greatly improved, the transverse screw rod is driven by the transverse motor to rotate, the second threaded block and the second workbench move leftwards or rightwards through starting, the effect of adjusting the X direction of a single workpiece on the second workbench is achieved, the relative position between the right workpiece and the left workpiece can be adjusted, the compensation made by the fact that the relative position of the X direction of the two main shafts is fixed is made up, and the machining origin of the two workpieces is consistent with the relative coordinates between the two cutters all the time.

2. Through setting up first fender bits board and second fender bits board, can let the iron fillings that processing produced drop on second fender bits board and first fender bits board, avoid the iron fillings to gather inside the device, be convenient for follow-up clearance and processing, keep work area's clean and tidy and good operational environment, avoid the accurate part of iron fillings entering device simultaneously, influence machining precision and positioning accuracy.

3. When the sliding plate moves in the X direction, the two pressure sensors located at the rear side also move synchronously, when the sliding plate inclines due to the abrasion loss generated during the movement in the X direction, one of the pressure sensors touches the surface of the horizontal block, after the pressure sensors touch the horizontal block, signals are sent to the PLC, the PLC starts through a set program control buzzer, abnormal signals of a worker can be reminded, the machine is stopped in time, the accuracy of the milling machine is effectively monitored, and the problem of processing precision reduction is avoided.

Drawings

FIG. 1 is a perspective view of a numerical control planer type milling machine for a numerical control machining center;

FIG. 2 is another perspective view of a numerical control planer type milling machine for a numerical control machining center;

FIG. 3 is a schematic diagram of a base structure of a numerical control planer type milling machine for a numerical control machining center;

FIG. 4 is a schematic diagram of a sliding table structure of a numerical control planer type milling machine for a numerical control machining center;

FIG. 5 is a schematic diagram of a second workbench of the numerical control planer type milling machine for a numerical control machining center;

FIG. 6 is a schematic diagram of a column structure of a numerical control planer type milling machine for a numerical control machining center;

FIG. 7 is a schematic diagram of a slide plate structure of a numerical control planer type milling machine for a numerical control machining center;

fig. 8 is a schematic diagram of a lifting arm structure of a numerical control planer type milling machine for a numerical control machining center.

In the figure:

1. a base; 11. a first slide rail; 2. a Y-direction servo motor; 21. y-direction screw rod; 3. a sliding table; 31. a transverse slide rail; 32. a support block; 33. a first threaded block; 34. a Y-direction sliding block; 35. a first chip blocking plate; 4. a transverse motor; 41. a transverse screw rod; 42. a first support base; 5. a first work table; 51. a notch; 52. a second work table; 53. a second chip baffle; 54. a second threaded block; 55. a transverse slide block; 6. a column; 61. a PLC controller; 62. a buzzer; 63. a cross beam; 64. a horizontal block; 65. a top slide rail; 66. an X-direction slide rail; 7. an X-direction servo motor; 71. x-direction screw rod; 72. a second support base; 8. a slide plate; 81. a threaded hole; 82. a guide hole; 83. a chute; 84. a third threaded block; 85. a top slider; 86. an X-direction sliding block; 87. a pressure sensor; 9. a lifting arm; 91. a spindle motor; 92. a cutter; 93. a bracket; 94. a guide rod; 10. a Z-direction servo motor; 101. z-direction screw rod.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-8, the present invention provides the following technical solutions: the utility model provides a numerical control milling planer for numerical control machining center, including base 1, the top fixed mounting of base 1 has a plurality of evenly distributed's first slide rail 11, all slide between the surface of a plurality of first slide rail 11 and be provided with Y to slider 34, Y is to the top fixed mounting of slider 34 has slip table 3, the top of slip table 3 is close to left side position symmetry fixed mounting has supporting shoe 32, fixed mounting has first workstation 5 between the top of two supporting shoes 32, the right surface fixed mounting of slip table 3 has transverse motor 4, transverse motor 4's output shaft fixed mounting has transverse screw 41, transverse screw 41 surface is provided with first supporting seat 42 near the position of distal end, first supporting seat 42 fixed mounting is at the top of slip table 3, transverse screw 41 surface is close to the position threaded connection of proximal end has second thread block 54, the top fixedly connected with second workstation 52 of second thread block 54, the height of first workstation 5 is the same with second workstation 52, the bottom of second workstation 52 is close to the front and back both sides position all fixed mounting has transverse slider 55, the inside slip of transverse slider 55 is provided with transverse slide rail 31, the fixed mounting at the top of slip table 3.

As shown in fig. 1, 2, 3 and 4, a Y-direction servo motor 2 is fixedly installed on the rear surface of the base 1 near the middle, a Y-direction screw rod 21 is fixedly installed at the output end of the Y-direction servo motor 2, a first thread block 33 is in threaded connection with the outer surface of the Y-direction screw rod 21, the first thread block 33 is fixedly installed at the bottom of the sliding table 3, the Y-direction screw rod 21 is driven to rotate by starting the Y-direction servo motor 2, and when the Y-direction screw rod 21 rotates, the first thread block 33 is matched to convert the rotary motion of the Y-direction screw rod 21 into linear motion, so that the sliding table 3 is driven to move forwards or backwards, the first workbench 5 and the second workbench 52 synchronously move forwards or backwards, and the Y-direction distance between a workpiece and a cutter 92 can be changed.

As shown in fig. 1, fig. 2, fig. 6 and fig. 7, the outer surfaces of the left and right sides of the base 1 are fixedly provided with the upright posts 6, a cross beam 63 is fixedly arranged between the tops of the two upright posts 6, the right surface of the cross beam 63 is fixedly provided with an X-direction servo motor 7, the output end of the X-direction servo motor 7 slides through the outer surface of the cross beam 63 and extends to the other side, the output end of the X-direction servo motor 7 is fixedly provided with an X-direction screw 71, the position, close to the far end, of the outer surface of the X-direction screw 71 is provided with a second supporting seat 72, the second supporting seat 72 is fixedly arranged on the inner wall of the cross beam 63, the upright posts 6 play a role in supporting the cross beam 63 through the arrangement of the upright posts 6 on the base 1, and the position, close to the upper end, of the upright posts 6 become larger gradually and are arranged in a triangle shape, so that the contact area between the upright posts 6 and the cross beam 63 is increased, and the stability of the cross beam 63 is improved.

As shown in fig. 1, fig. 2, fig. 6 and fig. 7, the position of the outer surface of the X-directional screw rod 71 close to the proximal end is in threaded connection with a third threaded block 84, the front surface of the third threaded block 84 is fixedly provided with a slide plate 8, the inner top of the slide plate 8 is fixedly provided with a top sliding block 85, the inner sliding of the top sliding block 85 is provided with a top sliding rail 65, the top sliding rail 65 is fixedly arranged at the top of the cross beam 63, one side inner wall of the slide plate 8 is symmetrically and fixedly provided with an X-directional sliding block 86, the inner sliding of the X-directional sliding block 86 is provided with an X-directional sliding rail 66, the X-directional sliding rail 66 is fixedly arranged on the front surface of the cross beam 63, and the X-directional screw rod 71 rotates, and is matched with the third threaded block 84 to convert the rotary motion of the X-directional screw rod 71 into linear motion, so as to drive the slide plate 8 to move leftwards or rightwards, thereby drive the lifting arm 9 and the spindle motor 91 to synchronously move leftwards or rightwards, the X-directional distance between the tool 92 and a workpiece can be changed, the slide plate 8 slides on the top sliding rail 65, and at the same time, the X-directional sliding block 86 slides on the top sliding rail 66, the side, the X-directional sliding block 86 slides on the top, the slide rail 66 on the X-directional sliding rail 66, the slide, and the X-directional sliding rail 66 on the slide rail 66, on the X-directional sliding rail 66, and the slide rail 8, on the slide rail, and on the slide rail.

As shown in fig. 1, fig. 2, fig. 7 and fig. 8, the front surface of the sliding plate 8 is symmetrically provided with a sliding groove 83, the inside of the sliding groove 83 is slidably provided with a lifting arm 9, the front surface of the lifting arm 9 is fixedly provided with a spindle motor 91, a cutter 92 is arranged outside the spindle motor 91 in a matching manner, accurate positioning and accurate guiding of the lifting arm 9 can be achieved through the sliding groove 83, the accuracy of the movement track and the position when the lifting arm 9 moves up and down is ensured, the cutter 92 can be driven to rotate by starting the spindle motor 91, the rotating speed of the cutter 92 is set according to workpiece parameters to be processed, and therefore the effect of cutting workpieces is achieved.

As shown in fig. 1, 2 and 7, the top of the sliding plate 8 is symmetrically provided with threaded holes 81, the top of the sliding plate 8 is located at the front side of the threaded holes 81 and provided with four guide holes 82, motion transmission and conversion can be achieved through matching of the threaded holes 81 and the Z-direction screw rod 101, the rotational motion of the Z-direction screw rod 101 in the threaded holes 81 can be converted into linear motion, and the guide holes 82 are arranged to limit and guide the guide rods 94.

As shown in fig. 1, 2 and 8, a bracket 93 is fixedly installed at the top of the lifting arm 9, a Z-direction servo motor 10 is fixedly installed at a position, close to the rear side, of the outer surface of the bracket 93, an output end of the Z-direction servo motor 10 penetrates through the outer surface of the bracket 93 in a sliding manner and extends to the lower side, a Z-direction screw rod 101 is fixedly installed at the output end of the Z-direction servo motor 10, the Z-direction screw rod 101 corresponds to a threaded hole 81, the function of installing the Z-direction servo motor 10 is achieved through the arrangement of the bracket 93, the positions of the Z-direction servo motor 10 and the lifting arm 9 are relatively fixed through the bracket 93, the Z-direction screw rod 101 can be driven to rotate through the actuation of the Z-direction servo motor 10, and the lifting arm 9 moves upwards or downwards through the cooperation of the threaded hole 81, so that the Z-direction distance between a cutter 92 and a workpiece can be changed.

As shown in fig. 1, 2 and 7, guide rods 94 are fixedly mounted on the outer surfaces of the left and right sides of the support 93, the guide rods 94 correspond to the guide holes 82, when the lifting arm 9 moves up and down, the guide rods 94 are inserted into the guide holes 82, so that the lifting arm 9 can be ensured to maintain accurate positions and directions in the moving process, and the stability of the lifting arm 9 during moving is greatly improved.

As shown in fig. 1, fig. 2, fig. 4 and fig. 5, the notch 51 is formed in the right surface of the first workbench 5, the first chip blocking plate 35 is fixedly mounted on the left surface of the second workbench 52, the position, close to the far end, of the outer surface of the first chip blocking plate 35 is slidably arranged in the notch 51, the second chip blocking plate 53 is fixedly mounted at the position, close to the front side and the rear side, of the top of the sliding table 3, the first chip blocking plate 35 and the second chip blocking plate 53 are arranged, scrap iron generated during processing can fall on the second chip blocking plate 53 and the first chip blocking plate 35, scrap iron is prevented from accumulating in the device, subsequent cleaning and processing are facilitated, clean and good working environment of a working area is maintained, meanwhile, the scrap iron is prevented from entering precise parts of the device, machining precision and positioning precision are affected, when the second workbench 52 moves left and right, the first chip blocking plate 35 slides in the notch 51, and the problem that the first chip blocking plate 35 and the first workbench 5 interfere is avoided.

As shown in fig. 1, fig. 2, fig. 6 and fig. 7, the position of the inner top of the slide plate 8, which is located at the rear side of the top sliding block 85, is provided with a pressure sensor 87, the position of the top of the cross beam 63, which is located below the pressure sensor 87, is fixedly provided with a horizontal block 64, one side outer surface of one upright post 6 is fixedly provided with a PLC controller 61, the outside of the PLC controller 61 is provided with a buzzer 62 in a matching manner, the PLC controller 61 is electrically connected with the pressure sensor 87 and the buzzer 62, the pressure sensor 87 and the horizontal block 64 are close to a fitting state, but do not fit, the slide plate 8 moves in the X direction, simultaneously, the two pressure sensors 87 located at the rear side also move synchronously, when the slide plate 8 tilts due to the abrasion loss generated in the X direction, one of the pressure sensors 87 contacts the surface of the horizontal block 64, after the pressure sensors 87 and the horizontal block 64 contact, signals are sent to the PLC controller 61, and the PLC controller 61 is provided with a program control buzzer 62 to remind a worker of abnormal signal, and the worker to start up the buzzer 62, so that the precision of the machine is effectively monitored and the precision of the machine is reduced, and the problem of machining is avoided is effectively avoided.

The application method and the working principle of the device are as follows: when in use, firstly, two clamps are respectively arranged on the first workbench 5 and the second workbench 52, workpieces are clamped on the clamps, then the spindle motor 91 is started to drive the cutter 92 to rotate, the Y-direction servo motor 2 is started to drive the Y-direction screw rod 21 to rotate according to workpiece parameters required to be processed, the sliding table 3 is driven to move forwards or backwards through the first thread block 33, so that the first workbench 5 and the second workbench 52 synchronously move, the Y-direction distance between the workpieces and the cutter 92 can be changed, the X-direction servo motor 7 is started to drive the X-direction screw rod 71 to rotate, the sliding plate 8 is driven to move leftwards or rightwards through the third thread block 84, the lifting arm 9 and the spindle motor 91 are driven to synchronously move, the X-direction distance between the cutter 92 and the workpieces can be changed, the Z-direction servo motor 10 is started to drive the Z-direction screw rod 101 to rotate, friction is generated between the Z-direction screw rod 101 and the threaded hole 81, thereby the lifting arm 9 ascends or descends in the chute 83, the Z-direction distance between the cutter 92 and the workpiece can be changed, the distance between the workpiece and the cutter 92 is changed from three dimensions according to the requirement, and the double spindles are matched, so that the effect of simultaneously processing two workpieces is achieved, in the processing process, the positions of the two spindles are relatively fixed, and the X direction is only driven by one X-direction servo motor 7, so that the synchronism of the movement of the two spindles is ensured, the consistency of the processing positions of the two workpieces is effectively ensured, the processing precision is greatly improved, the transverse motor 4 is started to drive the transverse screw 41 to rotate, the second threaded block 54 and the second workbench 52 are enabled to move leftwards or rightwards, the effect of adjusting the X direction of a single workpiece on the second workbench 52 is achieved, the relative position between the workpiece on the right side and the workpiece on the left side can be adjusted, make up the compensation that two main shaft X are fixed and be made to the relative position of orientation for the relative coordinate between two work pieces's processing origin and two cutters 92 respectively is unanimous all the time, the iron fillings that processing produced can drop on second fender bits board 53 and first fender bits board 35, can avoid the iron fillings to gather inside the device, difficulty and consuming time of clearance and maintenance have been reduced, avoid the precision part of iron fillings entering device simultaneously, influence machining precision and positioning accuracy, slide 8 is when carrying out X to remove, two pressure sensor 87 that are located the rear side also can remove simultaneously, when X produces the wearing and tearing volume when removing and lead to slide 8 to take place the slope, make one of them pressure sensor 87 touch the surface of horizontal piece 64, after pressure sensor 87 and horizontal piece 64 touch, will send the signal to PLC controller 61, PLC controller 61 opens through setting up program control buzzer 62, can remind the staff abnormal signal, in time shut down and maintain, make the precision of milling machine obtain effective monitoring, avoid the problem that the machining precision descends.

The wiring diagrams of the Y-direction servo motor 2, the transverse motor 4, the PLC controller 61, the buzzer 62, the X-direction servo motor 7, the pressure sensor 87 and the spindle motor 91 in the present invention are common knowledge in the art, the working principle thereof is a known technology, and the model thereof is selected to be a proper model according to actual use, so the control mode and wiring arrangement will not be explained in detail for the Y-direction servo motor 2, the transverse motor 4, the PLC controller 61, the buzzer 62, the X-direction servo motor 7, the pressure sensor 87 and the spindle motor 91.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (10)

1. The utility model provides a numerical control milling planer for numerical control machining center, includes base (1), its characterized in that: the utility model discloses a sliding table, including base (1) and sliding seat, the top fixed mounting of base (1) has a plurality of evenly distributed's first slide rail (11), a plurality of all slide between the surface of first slide rail (11) is provided with Y to slider (34), the top fixed mounting of Y to slider (34) has slip table (3), the top of slip table (3) is close to left side position symmetry fixed mounting has supporting shoe (32), two between the top of supporting shoe (32) fixed mounting has first workstation (5), the right surface fixed mounting of slip table (3) has transverse motor (4), the output shaft end fixed mounting of transverse motor (4) has transverse screw (41), the position that the surface of transverse screw (41) is close to the distal end is provided with first supporting seat (42), first supporting seat (42) fixed mounting is at the top of slip table (3), the position screw thread connection that the surface of transverse screw (41) is close to the proximal end has second screw thread piece (54), the top fixed connection of second screw thread piece (54) has second workstation (52), the output shaft end fixed mounting of transverse motor (4), the output shaft end of transverse motor (4) has transverse screw (52) outside the position that the outside of slip table (55), the transverse sliding rail (31) is fixedly arranged at the top of the sliding table (3).

2. The numerical control planer type milling machine for a numerical control machining center according to claim 1, wherein: the Y-direction servo motor (2) is fixedly arranged at the position, close to the middle, of the rear surface of the base (1), a Y-direction screw rod (21) is fixedly arranged at the output end of the Y-direction servo motor (2), a first thread block (33) is connected with the outer surface of the Y-direction screw rod (21) in a threaded manner, and the first thread block (33) is fixedly arranged at the bottom of the sliding table (3).

3. The numerical control planer type milling machine for a numerical control machining center according to claim 1, wherein: the utility model discloses a motor vehicle seat, including base (1), stand (6) are all fixed mounting to the left and right sides surface of base (1), two fixed mounting has crossbeam (63) between the top of stand (6), the right surface fixed mounting of crossbeam (63) has X to servo motor (7), the output of X to servo motor (7) slides the surface of running through crossbeam (63) and extends to the opposite side, the output fixed mounting of X to servo motor (7) has X to lead screw (71), the outer surface of X to lead screw (71) is provided with second supporting seat (72) near the position of distal end, second supporting seat (72) fixed mounting is on the inner wall of crossbeam (63).

4. A numerically controlled planer type milling machine for a numerically controlled machining center as claimed in claim 3, wherein: the X is to the position threaded connection that the surface of lead screw (71) is close to the proximal end has third screw thread piece (84), the preceding fixed surface of third screw thread piece (84) installs slide (8), the interior top fixed mounting of slide (8) has top slider (85), the inside slip of top slider (85) is provided with top slide rail (65), top slide rail (65) fixed mounting is at the top of crossbeam (63), one side inner wall symmetry fixed mounting of slide (8) has X to slider (86), the inside slip of X to slider (86) is provided with X to slide rail (66), X is to slide rail (66) fixed mounting at the front surface of crossbeam (63).

5. The numerical control planer type milling machine for a numerical control machining center according to claim 4, wherein: the front surface symmetry of slide (8) is provided with spout (83), the inside slip of spout (83) is provided with lift arm (9), the front surface fixed mounting of lift arm (9) has spindle motor (91), the outside of spindle motor (91) is provided with cutter (92) in a matched manner.

6. The numerical control planer type milling machine for a numerical control machining center according to claim 4, wherein: threaded holes (81) are symmetrically formed in the top of the sliding plate (8), and four guide holes (82) are formed in the position, located on the front side of the threaded holes (81), of the top of the sliding plate (8).

7. The numerical control planer type milling machine for a numerical control machining center according to claim 5, wherein: the lifting device is characterized in that a support (93) is fixedly arranged at the top of the lifting arm (9), a Z-direction servo motor (10) is fixedly arranged at the position, close to the rear side, of the outer surface of the support (93), the output end of the Z-direction servo motor (10) penetrates through the outer surface of the support (93) in a sliding mode and extends to the lower portion, a Z-direction screw rod (101) is fixedly arranged at the output end of the Z-direction servo motor (10), and the Z-direction screw rod (101) corresponds to the threaded hole (81).

8. The numerical control planer type milling machine for a numerical control machining center according to claim 7, wherein: guide rods (94) are fixedly arranged on the outer surfaces of the left side and the right side of the support (93), and the guide rods (94) correspond to the guide holes (82).

9. The numerical control planer type milling machine for a numerical control machining center according to claim 8, wherein: notch (51) have been seted up on the right surface of first workstation (5), the left surface fixed mounting of second workstation (52) has first fender bits board (35), the surface of first fender bits board (35) is close to the inside of distal end sliding setting in notch (51), the top of slip table (3) is close to the position of both sides all fixed mounting has second fender bits board (53).

10. A numerically controlled planer type milling machine for a numerically controlled machining center as claimed in claims 3 and 4, wherein: the position that the interior top of slide (8) is located top slider (85) rear side is provided with pressure sensor (87), the top of crossbeam (63) is located the position fixed mounting of pressure sensor (87) below has horizontal piece (64), one of them one side surface fixed mounting of stand (6) has PLC controller (61), the outside of PLC controller (61) is supporting to be equipped with bee calling organ (62), PLC controller (61) are electric connection with pressure sensor (87) and bee calling organ (62).