CN210061429U

CN210061429U - Numerical control sawing and milling machine

Info

Publication number: CN210061429U
Application number: CN201920463364.1U
Authority: CN
Inventors: 林善龙; 赵光俊
Original assignee: BINZHOU COSEN CNC EQUIPMENT TECHNOLOGY Co Ltd
Current assignee: BINZHOU COSEN CNC EQUIPMENT TECHNOLOGY Co Ltd
Priority date: 2019-04-08
Filing date: 2019-04-08
Publication date: 2020-02-14
Anticipated expiration: 2029-04-08

Abstract

The utility model relates to a numerical control sawing and milling machine, which comprises a processing host, a base unit, a mobile platform unit, a working platform unit and a feeding unit; a Z-axis motor is arranged on the processing host, and one end of the milling cutter is detachably clamped on an output shaft of the Z-axis motor; the mobile platform unit is arranged on the base unit and can move back and forth along the X-axis direction relative to the base unit; the working platform unit is arranged on the movable platform unit and can reciprocate along the Y-axis direction relative to the movable platform unit; the feeding unit is arranged on the working platform unit and can move back and forth along the axis A relative to the working platform unit; according to the technical scheme, multi-axis linkage and numerical control automatic feeding are realized, the machining precision and the machining efficiency are improved, the rejection rate is greatly reduced, accurate machining of round corners can be completed, and the application range of products is wide.

Description

Numerical control sawing and milling machine

Technical Field

The invention relates to the field of processing machines, in particular to a numerical control sawing and milling machine.

Background

The woodworking sawing and milling machine is a woodworking machine tool for processing wood by using a milling cutter rotating at high speed, the vertical woodworking sawing and milling machine is one of the woodworking sawing and milling machines, the milling cutter of the vertical woodworking sawing and milling machine is arranged on a vertical milling cutter shaft extending from a fixed workbench, a workpiece is tightly attached to a fixed workbench surface and a guide plate and is fed manually, a guide roller and a forming milling clamp can be used for forming and milling the side surface, and the workpiece can be clamped on a movable workbench for processing.

The vertical sawing and milling machine in the prior art mainly processes the wood manually by manually moving the wood after drawing lines according to the processing shape, and has the following defects:

1) the material to be processed is fed manually, the operation danger coefficient is high, and the number of the injury cases of operators is not few in the practical situation;

2) the processing quality of the product completely depends on the operation proficiency of an operator, the processing precision is extremely low, the size error is large, the rejection rate is high, and the precision requirement required by the actual product can be met by repairing and matching the product twice or even for many times;

3) the manual single-shaft feeding can only mill the side face, the milling processing of a round angle cannot be finished, and the accurate processing of a special-shaped shape is difficult to achieve.

Disclosure of Invention

The invention aims to solve the technical problem of making up the defects of the prior art and provides a numerical control sawing and milling machine which realizes numerical control automatic feeding and multi-shaft linkage and can finish accurate processing of a fillet.

To solve the technical problems, the technical scheme of the invention is as follows: a numerical control sawing and milling machine comprises a processing host, a base unit, a movable platform unit, a working platform unit and a feeding unit; a Z-axis motor is arranged on the processing host, and one end of the milling cutter is detachably clamped on an output shaft of the Z-axis motor; the mobile platform unit is arranged on the base unit and can move back and forth along the X-axis direction relative to the base unit; the working platform unit is arranged on the movable platform unit and can reciprocate along the Y-axis direction relative to the movable platform unit; the feeding unit is arranged on the working platform unit and can move back and forth along the axis A relative to the working platform unit; the Y axis is perpendicular to the X axis, the A axis is parallel to the Y axis, the Z axis is a rotating axis, the Z axis is perpendicular to the X axis, and the Z axis is perpendicular to the Y axis.

Furthermore, an X-axis linear guide mechanism and an X-axis driving mechanism are arranged on the base unit, the moving platform unit is fixedly connected with the movable part of the X-axis linear guide mechanism, and the X-axis driving mechanism is used for driving the moving platform unit to reciprocate in the X-axis direction; the movable platform unit is provided with a Y-axis linear guide mechanism, and the working platform unit is fixedly connected with the movable part of the Y-axis linear guide mechanism; the device comprises a working platform unit, a feeding unit, a pressing unit and a control unit, wherein the working platform unit is provided with a Y-axis driving mechanism, an A-axis linear guide mechanism and the pressing unit, the Y-axis driving mechanism is used for driving the working platform unit to move in the Y-axis releasing direction and back and forth, the pressing unit is used for pressing a plate to be processed, and the feeding unit is fixedly connected with the movable part of the A-axis linear guide mechanism; the feeding unit is provided with an A-axis driving mechanism, and the A-axis driving mechanism drives the feeding unit to move back and forth in the A-axis direction.

Further, the base unit includes base body, X axle straight line guiding mechanism includes a pair of X axle guide rail, be equipped with X axle slider on the X axle guide rail, drive plate A and drive plate B respectively with X axle slider fixed connection, X axle drive structure includes X axle rack, X axle gear and X axle motor, X axle guide rail with X axle rack all passes through the fix with screw on the base body, X axle motor with drive plate B fixed connection, the output shaft of X axle motor with X axle gear interference connection or key-type connection, X axle gear with X axle rack meshes, the moving platform unit with drive plate A with drive plate B passes through screw fixed connection.

Further, the moving platform unit comprises a moving platform body, the Y-axis linear guide mechanism comprises a pair of Y-axis guide rails, the Y-axis guide rails are fixedly connected to the moving platform body through screws, Y-axis sliding blocks are arranged on the Y-axis guide rails, and the working platform unit is fixedly connected with the Y-axis sliding blocks.

Furthermore, the working platform unit comprises a working platform main body, the Y-axis driving mechanism comprises a Y-axis rack, a Y-axis gear and a Y-axis motor, the Y-axis rack is fixedly connected to the mobile platform unit through a screw, the Y-axis motor is fixedly connected to the working platform main body through a screw, the Y-axis rack is meshed with the Y-axis gear, and the Y-axis gear is in interference connection or key connection with an output shaft of the Y-axis motor; the A-axis linear guide mechanism comprises an A-axis guide rail, the A-axis guide rail is fixedly connected to the working platform main body through screws, an A-axis sliding block is arranged on the A-axis guide rail, and the feeding unit is fixedly connected with the A-axis sliding block.

Further, the pay-off unit includes the crossbeam, be equipped with motor mounting bracket on the crossbeam, a axle actuating mechanism includes A axle rack, A axle gear and A axle motor, A axle motor passes through the fix with screw on the motor mounting bracket, A axle rack passes through screw fixed connection and is in on the work platform unit, A axle rack with A axle gear engagement, A axle gear with the output shaft interference connection or the key-type connection of A axle motor.

Furthermore, a pair of guide rails M are arranged on the working platform unit, the length direction of the guide rails M is perpendicular to the shaft A, a plurality of sliding blocks M are arranged on each guide rail M, two ends of a plurality of movable supporting pieces are fixed on the plurality of sliding blocks M through screws respectively, a skid is fixedly connected onto the movable supporting pieces through screws, and the skid is used for bearing materials to be processed.

Further, the feeding unit comprises a cross beam and a clamping mechanism; the guide rail N is fixedly connected to the cross beam through a screw, and a sliding block N is arranged on the guide rail N; clamping mechanism includes support, die clamping cylinder and movable rod, the movable rod includes root junction, intermediate junction and tip, the support pass through the screw with slider N connects, die clamping cylinder's cylinder body with the support is articulated, die clamping cylinder's piston rod with the movable rod intermediate junction is articulated, the movable rod the root junction with the support is articulated, the movable rod the tip is equipped with and presss from both sides the material blade, the end of hanging out of support is equipped with presss from both sides the flitch, press from both sides the material blade with it can press from both sides the tight material of waiting to process to press from both sides the flitch.

Furthermore, the pressing unit comprises a support frame, a plurality of air cylinder mounting frames are arranged on the support frame, a cylinder body of the pressing air cylinder is fixed on the air cylinder mounting frames, and a pressing foot is arranged at the end part of a piston rod of the pressing air cylinder.

Furthermore, a C-axis motor is arranged on the processing host, an extension bar is detachably clamped on an output shaft of the C-axis motor, and the output shaft of the C-axis motor is coaxial with the output shaft of the Z-axis motor and synchronously rotates; the lengthening bar is provided with a fixing hole, and the fixing hole is used for clamping the other end of the milling cutter.

Due to the adoption of the technical scheme, the numerical control sawing and milling machine provided by the invention can achieve the following beneficial effects: the multi-shaft linkage realizes numerical control automatic feeding, improves the processing precision and the processing efficiency, has greatly low rejection rate, can finish the accurate processing of a fillet, can finish the processing of a special-shaped shape according to the actual requirement, and has wide application range of products; the manual work participation has been avoided in the processing pay-off process, and the operative employee injury probability that significantly reduces effectively ensures operative employee's personal safety.

Drawings

FIG. 1 is an overall block diagram of an embodiment of the present invention;

fig. 2 is a perspective structural view of the processing machine 1 in the embodiment of the present invention;

fig. 3 is a perspective view of the base unit 2 in the embodiment of the present invention;

fig. 4 is a perspective view of another perspective of the base unit 2 in the embodiment of the present invention;

fig. 5 is a perspective view of the mobile platform unit 3 in the embodiment of the present invention;

fig. 6 is a perspective view of the work platform unit 4 in the embodiment of the present invention;

fig. 7 is a perspective structural view of the feeding unit 5 in the embodiment of the present invention;

fig. 8 is a perspective view of the pressing unit 6 in the embodiment of the present invention;

in the figure: 1-a processing host, 111-a base, 112-a second upright, 113-a first upright, 114-a cantilever, 115-a fixed plate A, 12-C axis motor, 13-an extension bar, 14-a milling cutter, 15-Z axis motor, 2-a base unit, 21-a base body, 22-X axis guide rail, 23-X axis rack, 24-a drive plate A, 25-a drive plate B, 26-X axis motor, 27-a fixed plate B, 3-a moving platform unit, 31-a moving platform body, 32-Y axis guide rail, 33-Y axis rack, 4-a working platform unit, 41-a working platform main body, 42-A axis rack, 43-Y axis motor, 44-A axis guide rail, 45-guide rail M, 46-a moving support, 47-skid, 48-fixed plate C, 49-positioning cylinder, 5-feeding unit, 51-cross beam, 52-A shaft motor, 53-motor mounting rack, 54-guide rail N, 55-clamping mechanism, 551-bracket, 552-clamping cylinder, 553-movable rod, 554-clamping blade, 555-clamping plate, 6-pressing unit, 61-supporting rack, 62-cylinder mounting rack, 63-pressing cylinder and 64-pressing foot.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Examples

A numerical control sawing and milling machine comprises a processing host machine 1, a base unit 2, a moving platform unit 3, a working platform unit 4 and a feeding unit 5.

The processing host computer 1 includes the frame, the frame includes base 111, first stand 113 is fixed at the rear end of base 111, fixed plate A115 is fixed at the front end of base 111, the one end of cantilever 114 is fixed in the upper end of first stand 113, be equipped with second stand 112 between first stand 113 and the fixed plate A115, second stand 112 and base 111 fixed connection, Z axle motor 15 is fixed on second stand 112, the one end detachably centre gripping of milling cutter 14 is on the output shaft of Z axle motor 15, C axle motor 12 is fixed at the end of hanging out of cantilever 114, the output shaft of C axle motor 12 is coaxial with the output shaft of Z axle motor 15, and synchronous rotation, detachably centre gripping extension bar 13 on the output shaft of C axle motor 12, be equipped with the fixed orifices on the extension bar 13, this fixed orifices is used for the other end of centre gripping milling cutter 14. When a thick plate is processed, the length of the milling cutter 14 is long, the stress force arm of the hanging end is long, and the cutter is easy to break, the motor 112 and the extension bar 13 are additionally arranged for clamping the hanging end of the milling cutter 14, so that the stress supporting points of the hanging end of the milling cutter 14 are increased, and the cutter breaking phenomenon caused by the overlong milling cutter 14 is greatly reduced; when the milling cutter 14 needs to be replaced, the shaft end of the C-axis motor 12 is only required to be loosened to clamp the extension bar 13, the extension bar 13 is pushed upwards for a proper distance, the extension bar 13 is separated from the overlapped part of the milling cutter 14, the extension bar 13 is taken down, the Z-axis motor 15 is loosened to clamp the milling cutter 14 to be replaced, and the milling cutter 14 to be replaced is taken out; the other mill 14 is then installed in the reverse process.

Base unit 2 includes base body 21, X axle linear guide mechanism and X axle actuating mechanism, X axle linear guide mechanism includes a pair of X axle guide rail 22, be equipped with X axle slider on the X axle guide rail 22, drive plate A24 and drive plate respectively with B25X axle slider fixed connection, X axle actuating mechanism includes X axle rack 23, X axle gear and X axle motor 26, X axle guide rail 22 and X axle rack 23 all pass through the fix with screw on base body 21, X axle motor 26 and drive plate B25 fixed connection, X axle motor 26's output shaft and X axle gear key-type connection, X axle gear and X axle rack 23 mesh, one side that base body 21 is close to processing host 1 is equipped with fixed plate B27, processing host 1's fixed plate A115 and fixed plate B27 pass through screw fixed connection.

The moving platform unit 3 comprises a moving platform body 31 and a Y-axis linear guide mechanism, the moving platform body 31 is fixedly connected with a drive plate A24 and a drive plate B25 through screws, the Y-axis linear guide mechanism comprises a pair of Y-axis guide rails 32, the Y-axis guide rails 32 are fixedly connected onto the moving platform body 31 through screws, and Y-axis sliding blocks are arranged on the Y-axis guide rails 32.

The working platform unit 4 comprises a working platform main body 41, a Y-axis driving mechanism, an A-axis linear guide mechanism and a pressing unit 6, the working platform main body 41 is fixedly connected with a Y-axis sliding block, the Y-axis driving mechanism comprises a Y-axis rack 33, a Y-axis gear and a Y-axis motor 43, the Y-axis rack 33 is fixedly connected to the moving platform body 31 through a screw, the Y-axis motor 43 is fixedly connected to the working platform main body 41 through a screw, the Y-axis rack 33 is meshed with the Y-axis gear, and the Y-axis gear is connected with an output shaft key of the Y-axis motor 43; the A-axis linear guide mechanism comprises an A-axis guide rail 44, the A-axis guide rail 44 is fixedly connected to the working platform main body 41 through a screw, and an A-axis sliding block is arranged on the A-axis guide rail 44; a pair of guide rails M45 are fixed to the front end and the rear end of the working platform main body 41 respectively by screws, the length direction of the guide rail M45 is perpendicular to the axis a, each guide rail M45 is provided with 3 sliding blocks M, two ends of 3 movable supporting members 46 are fixed to the sliding blocks M respectively by screws, a skid 47 is fixedly connected to the movable supporting members 46 by screws, the skid 47 is used for supporting a material to be processed, and the material of the skid 47 is phenolic plastic; the positioning cylinder 49 is fixedly connected to one side of the working platform main body 41 and used for positioning the material to be processed; work platform main part 41 is close to the both sides of the one end of processing host computer 1 and is equipped with fixed plate C48 respectively, compresses tightly unit 6 and includes support frame 61, and support frame 61 fixed connection is equipped with a plurality of cylinder mounting bracket 62 on fixed plate C48 on support frame 61, and the cylinder body that compresses tightly cylinder 63 is fixed on cylinder mounting bracket 62, and the tailpiece of the piston rod portion that compresses tightly cylinder 63 is equipped with presser foot 64.

The feeding unit 5 comprises a cross beam 51, an A-axis driving mechanism and a clamping mechanism 55, wherein two ends of the cross beam 51 are respectively provided with a motor mounting rack 53, and the motor mounting racks 53 are fixedly connected with an A-axis sliding block; the A-axis driving mechanism comprises an A-axis rack 42, an A-axis gear and an A-axis motor 52, the A-axis motor 52 is fixed on the motor mounting frame 53 through screws, the A-axis rack 42 is fixedly connected to the working platform main body 41 through screws, the A-axis rack 42 is meshed with the A-axis gear, and the A-axis gear is connected with an output shaft key of the A-axis motor 52; the guide rail N54 is fixedly connected to the cross beam 51 through a screw, and a slide block N is arranged on the guide rail N54; the number of the clamping mechanisms 55 is 2, each clamping mechanism 55 comprises a support 551, a clamping cylinder 552 and a movable rod 553, each movable rod 553 comprises a root joint, a middle joint and an end, each support 551 is connected with a sliding block N through a screw, the cylinder body of each clamping cylinder 552 is hinged to each support 551, the piston rod of each clamping cylinder 552 is hinged to the middle joint of each movable rod 553, the root joint of each movable rod 553 is hinged to each support 551, a material clamping blade 554 is arranged at the end of each movable rod 553, a material clamping plate 555 is arranged at the hanging end of each support 551, and the material clamping blades 554 and the material clamping plates 555 can clamp materials to be processed.

The Y axis is vertical to the X axis, the A axis is parallel to the Y axis, the Z axis is a rotating axis, the Z axis is vertical to the X axis, and the Z axis is vertical to the Y axis.

The positioning cylinder 49, the clamping cylinder 552 and the pressing cylinder 63 are connected into a gas circuit system through reversing valves, and the C-axis motor 12, the Z-axis motor 15, the X-axis motor 26, the Y-axis motor 43 and the A-axis motor 52 are connected with a control system.

The embodiment is actually a five-axis numerical control sawing and milling machine comprising a C axis, a Z axis, an X axis, a Y axis and an a axis, and the action principle of the embodiment is as follows:

1) adjusting the spacing between 3 skids 47 and the spacing between 2 clamping mechanisms 55 according to the breadth of the material to be processed;

2) placing the material to be processed on the skid 47 and the material clamping plate 555, enabling one side of the material to be processed to be close to the positioning cylinder 49, and controlling the action of the positioning cylinder 49 through the control system to realize the positioning of the material to be processed;

3) the control system controls the action of the clamping cylinder 552 to clamp the material to be processed by the material clamping blade 554 and the material clamping plate 555;

4) the control system controls the action of the A-axis motor 52 to drive the clamping mechanism 55 to push the material to be processed to the processing original point;

5) the control system controls the action of the pressing cylinder 63 to realize the pressing of the presser foot 64 on the material to be processed;

6) the linkage of an X axis, a Y axis, a Z axis and a C axis is controlled by a control system, so that the milling of the material to be processed is realized.

In the description of the present invention, words such as "inner", "outer", "upper", "lower", "front", "rear", etc., which indicate orientation or positional relationship, are used only for convenience in describing the present invention, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

The above description is only one embodiment of the present invention, and the scope of the present invention is not limited to the above embodiments, and it should be noted that, for those skilled in the art, several modifications and decorations can be made without departing from the spirit of the present invention.

Claims

1. The utility model provides a numerical control saw mills machine, includes processing host computer (1), characterized by: the device also comprises a base unit (2), a mobile platform unit (3), a working platform unit (4) and a feeding unit (5); a Z-axis motor (15) is arranged on the machining host (1), and one end of a milling cutter (14) is detachably clamped on an output shaft of the Z-axis motor (15); the mobile platform unit (3) is arranged on the base unit (2) and can move back and forth along the X-axis direction relative to the base unit (2); the working platform unit (4) is arranged on the moving platform unit (3) and can move back and forth along the Y-axis direction relative to the moving platform unit (3); the feeding unit (5) is arranged on the working platform unit (4) and can move back and forth along the axis A relative to the working platform unit (4); the Y axis is perpendicular to the X axis, the A axis is parallel to the Y axis, the Z axis is a rotating axis, the Z axis is perpendicular to the X axis, and the Z axis is perpendicular to the Y axis.

2. The numerical control saw mill of claim 1, wherein: an X-axis linear guide mechanism and an X-axis driving mechanism are arranged on the base unit (2), the moving platform unit (3) is fixedly connected with the movable part of the X-axis linear guide mechanism, and the X-axis driving mechanism is used for driving the moving platform unit (3) to reciprocate in the X-axis direction; a Y-axis linear guide mechanism is arranged on the movable platform unit (3), and the working platform unit (4) is fixedly connected with the movable part of the Y-axis linear guide mechanism; the working platform unit (4) is provided with a Y-axis driving mechanism, an A-axis linear guide mechanism and a pressing unit (6), the Y-axis driving mechanism is used for driving the working platform unit (4) to move backwards in the Y-axis releasing direction, the pressing unit (6) is used for pressing a plate to be processed, and the feeding unit (5) is fixedly connected with the movable part of the A-axis linear guide mechanism; and an A-axis driving mechanism is arranged on the feeding unit (5), and the A-axis driving mechanism drives the feeding unit (5) to reciprocate in the A-axis direction.

3. The numerical control saw mill of claim 2, wherein: the base unit (2) comprises a base body (21), the X-axis linear guide mechanism comprises a pair of X-axis guide rails (22), an X-axis sliding block is arranged on the X-axis guide rail (22), a driving plate A (24) and a driving plate B (25) are respectively and fixedly connected with the X-axis sliding block, the X-axis driving structure comprises an X-axis rack (23), an X-axis gear and an X-axis motor (26), the X-axis guide rail (22) and the X-axis rack (23) are fixed on the base body (21) through screws, the X-axis motor (26) is fixedly connected with the driving plate B (25), an output shaft of the X-axis motor (26) is in interference fit connection or key connection with the X-axis gear, the X-axis gear is meshed with the X-axis rack (23), and the moving platform unit (3) is fixedly connected with the driving plate A (24) and the driving plate B (25) through screws.

4. The numerical control saw mill of claim 2, wherein: moving platform unit (3) include moving platform body (31), Y axle straight line guiding mechanism includes a pair of Y axle guide rail (32), Y axle guide rail (32) are in through screw fixed connection on moving platform body (31), be equipped with Y axle slider on Y axle guide rail (32), work platform unit (4) with Y axle slider fixed connection.

5. The numerical control saw mill of claim 2, wherein: the working platform unit (4) comprises a working platform main body (41), the Y-axis driving mechanism comprises a Y-axis rack (33), a Y-axis gear and a Y-axis motor (43), the Y-axis rack (33) is fixedly connected to the moving platform unit (3) through a screw, the Y-axis motor (43) is fixedly connected to the working platform main body (41) through a screw, the Y-axis rack (33) is meshed with the Y-axis gear, and the Y-axis gear is in interference connection or key connection with an output shaft of the Y-axis motor (43); a axle straight line guiding mechanism includes A axle guide rail (44), A axle guide rail (44) pass through screw fixed connection and be in on work platform main part (41), be equipped with A axle slider on A axle guide rail (44), pay-off unit (5) with A axle slider fixed connection.

6. The numerical control saw mill of claim 2, wherein: pay-off unit (5) include crossbeam (51), be equipped with motor mounting bracket (53) on crossbeam (51), A axle actuating mechanism includes A axle rack (42), A axle gear and A axle motor (52), A axle motor (52) pass through the fix with screw on motor mounting bracket (53), A axle rack (42) are in through screw fixed connection work platform unit (4) is last, A axle rack (42) with A axle gear engagement, A axle gear with the output shaft interference of A axle motor (52) is connected or the key-type connection.

7. The numerical control saw mill of claim 2, wherein: be equipped with a pair of guide rail M (45) on work platform unit (4), the length direction of guide rail M (45) with A axle mutually perpendicular, every be equipped with a plurality of slider M on guide rail M (45), it is a plurality of through the fix with screw respectively at a plurality of both ends that remove support piece (46) on the slider M, skid (47) pass through screw fixed connection remove support piece (46) on, skid (47) are used for the bearing to treat the processing material.

8. The numerical control saw mill of claim 2, wherein: the feeding unit (5) comprises a cross beam (51) and a clamping mechanism (55); a guide rail N (54) is fixedly connected to the cross beam (51) through a screw, and a sliding block N is arranged on the guide rail N (54); the clamping mechanism (55) comprises a support (551), a clamping cylinder (552) and a movable rod (553), wherein the movable rod (553) comprises a root joint, a middle joint and an end part, the support (551) is connected with the slide block N through a screw, a cylinder body of the clamping cylinder (552) is hinged with the support (551), a piston rod of the clamping cylinder (552) is hinged with the middle joint of the movable rod (553), the root joint of the movable rod (553) is hinged with the support (551), the end part of the movable rod (553) is provided with a material clamping blade (554), a material clamping plate (555) is arranged at a hanging end of the support (551), and the material clamping blade (554) and the material clamping plate (555) can clamp a processing material.

9. The numerical control saw mill of claim 2, wherein: the pressing unit (6) comprises a supporting frame (61), a plurality of air cylinder mounting frames (62) are arranged on the supporting frame (61), a cylinder body of a pressing air cylinder (63) is fixed on the air cylinder mounting frames (62), and a pressing foot (64) is arranged at the end part of a piston rod of the pressing air cylinder (63).

10. The numerical control saw mill of claim 1, wherein: the machining host (1) is provided with a C-axis motor (12), an output shaft of the C-axis motor (12) is detachably clamped with an extension bar (13), and the output shaft of the C-axis motor (12) is coaxial with the output shaft of the Z-axis motor (15) and synchronously rotates; the lengthening bar (13) is provided with a fixing hole, and the fixing hole is used for clamping the other end of the milling cutter (14).