CN219853228U - Multi-axis linkage numerical control machine tool suitable for multi-product processing - Google Patents

Abstract

The utility model discloses a multi-axis linkage numerical control machine tool suitable for multi-product processing, which comprises a frame and a cutting knife group, wherein the cutting knife group is arranged on the frame through a plane track group, the plane track group comprises a knife rack plate and a connecting plate, two horizontal guide rails which are horizontally arranged are arranged on the frame, two vertical guide rails which are vertically arranged are arranged on the knife rack plate, at least two sliding blocks which are connected in a matched manner are arranged on the connecting plate corresponding to one horizontal guide rail and the vertical guide rail, two side wall surfaces of the sliding block, which are contacted with the horizontal guide rail or the vertical guide rail, are curved surfaces which are outwards protruded, the cutting knife group is arranged on the knife rack plate, the knife rack plate is arranged on the connecting plate through the vertical guide rails and the sliding blocks, and the connecting plate is arranged on the frame through the sliding blocks and the horizontal guide rails. The transmission device of the cutter is further optimized, so that the movement of the cutter is stable and controllable, and the machining precision of the cutter on products is further improved.

Description

Multi-axis linkage numerical control machine tool suitable for multi-product processing

Technical Field

The utility model relates to the field of processing machine tools, in particular to a multi-axis linkage numerical control machine tool suitable for multi-product processing.

Background

With the development of the modern machining industry, the requirements on the quality and precision of product machining are continuously improved, and the requirements on the production efficiency improvement, the production cost reduction and the high-intelligent automatic machining function are also improved. The numerical control processing machine is a common processing device which meets the development requirements of the modern mechanical processing industry. The numerical control processing machine drives the machine tool to move by using a numerical program, and the randomly worn processing tool processes the object along with the movement of the machine tool. Such an electromechanical machine is called a numerically controlled machine tool.

Related prior art such as chinese patent application "a dish washing basket accessory is with multi-angle cutting mechanism", application number: CN202221882613.9; the device comprises a supporting mechanism, wherein a clamping mechanism is arranged below the inner side of the supporting mechanism, and a processing mechanism is arranged above the supporting mechanism. According to the utility model, the threaded rod is driven to rotate by the first motor, the movable blocks can be mutually closed, the clamping blocks are driven by the movable blocks to clamp the workpiece, the workpiece is clamped by the convex blocks, the power machine and the connecting block at the communicating pipe are used for supplying energy, the workpiece is cut by the laser cutting head, the second motor can be used for driving the laser cutting head to rotate, and the laser cutting head is obliquely arranged, so that the laser cutting head can be mutually matched with the components to realize multi-angle adjustment of the laser cutting head, and the workpiece is conveniently processed.

I need to machine a workpiece similar to a half bowl shape as shown in fig. 1. After the workpiece is processed and formed, more injection molding waste materials, burrs and the like exist at the edge of the section of the workpiece, and the workpiece needs to be further processed by cutting equipment to form a flat and smooth section. The cutting mechanism disclosed in the above patent application can meet the cutting requirement of the product, but the workpiece structure to be processed by the utility model is smaller and more complex, and the processing precision requirement is higher, so that the movement precision of the workpiece and the cutter is required to be high, and the utility model further improves the movement precision.

Disclosure of Invention

The technical problem to be solved by the utility model is to provide a multi-axis linkage numerical control machine tool suitable for multi-product processing, which further optimizes a transmission device of a cutter, ensures that the movement of the cutter is stable and controllable, and further improves the processing precision of the cutter on products.

The utility model adopts the technical scheme that: the utility model provides a multiaxis linkage digit control machine tool suitable for processing of many products, includes frame and cutting knife group, the cutting knife group install in the frame through plane track group, plane track group include tool rest board and connecting plate, the frame on install two horizontal guide rails that the level set up, the tool rest board on install two vertical guide rails of vertical setting, the connecting plate on correspond a horizontal guide rail, vertical guide rail and all be provided with the slider that two at least cooperations are connected, slider and horizontal guide rail or two lateral wall faces of vertical guide rail contact be outside convex curved surface, the cutting knife group install on the tool rest board, the tool rest board passes through vertical guide rail, the slider is installed in the connecting plate, the connecting plate passes through slider, horizontal guide rail and installs in the frame.

Compared with the prior art, the utility model has the advantages that at least two sliding blocks are arranged corresponding to one longitudinal guide rail, and two points determine a straight line, so that the movement of the cutter frame plate can be ensured to be along the preset longitudinal guide rail under the action of the at least two sliding blocks. Secondly, the knife rest plate is installed by two vertical guide rails which are vertically arranged, namely, the two vertical guide rails which are arranged in parallel limit the moving track of the knife rest plate, and compared with a common single guide rail, the knife rest plate has better stability. By matching with the arrangement of the sliding blocks, the utility model can ensure the stability of the cutting knife group moving in the vertical direction and improve the processing precision. The same principle can be achieved, at least two sliding blocks are arranged corresponding to one transverse guide rail, and the stability of the cutting knife set in the horizontal transverse direction is ensured by matching with the arrangement of the two transverse guide rails, so that the machining precision is improved. In addition, the two side wall surfaces of the sliding block, which are in contact with the transverse guide rail or the longitudinal guide rail, are outwards convex curved surfaces, so that the friction resistance of the sliding block moving on the transverse guide rail and the longitudinal guide rail is effectively reduced, the sliding block moves smoothly relative to the transverse guide rail or the longitudinal guide rail, and unnecessary shaking is avoided. The utility model further optimizes the transmission device of the cutter, so that the movement of the cutter is stable and controllable, and the machining precision of the cutter on products is further improved.

In some embodiments of the present utility model, the sliding block is provided with a notch connected with the transverse guide rail or the longitudinal guide rail, and the bottom surface of the notch is a plane and is adapted to the top surfaces of the transverse guide rail and the longitudinal guide rail. Namely, the top surfaces of the transverse guide rail and the longitudinal guide rail in the utility model are plane surfaces.

The side wall surface of the notch comprises a flat contact surface and an outwards protruding curved contact surface, the curved contact surface is arranged close to the opening end of the notch, and the flat contact surface is arranged close to the bottom surface of the notch. In the utility model, the curved contact surface forms the main contact surface of the notch and the transverse guide rail or the longitudinal guide rail, and plays roles of reducing friction resistance and avoiding shaking. The flat contact surface plays a limiting role, and the connection deviation of the sliding block and the transverse guide rail or the longitudinal guide rail is avoided.

In some embodiments of the present utility model, a chamfer is disposed between the flat contact surface and the bottom surface of the notch, and the chamfer is a curved surface. The chamfer surface is additionally arranged, so that a stiff folding angle is avoided between the bottom surface of the notch and the flat contact surface of the notch, and the stiff folding angle can easily cause sliding and clamping. The utility model adopts the chamfer surface to connect and transition the flat contact surface with the bottom surface of the notch, thereby increasing the smoothness of the movement of the slide block.

In some embodiments of the present utility model, the planar track group includes a horizontal ball screw and a vertical ball screw, the ball screw is located between two transverse rails and installed on the frame, the ball screw and the two transverse rails are parallel, the ball screw is located between two vertical rails and installed on the connecting plate, and the ball screw and the two vertical rails are parallel.

In some embodiments of the utility model, the back of the connecting plate is provided with at least two cross-slides corresponding to one cross-rail, and the front of the connecting plate is provided with at least two longitudinal slides corresponding to one longitudinal rail.

Preferably, the back of the connecting plate is provided with two transverse sliding blocks arranged at intervals corresponding to one transverse guide rail, and the front of the connecting plate is provided with two longitudinal sliding blocks arranged at intervals corresponding to one longitudinal guide rail.

The transverse nut support on the transverse ball screw is connected with the connecting plate, the transverse ball screw works to drive the connecting plate to horizontally and transversely move, and the transverse nut support is positioned in the middle of the four transverse sliding blocks. Preferably, the four sliders form a rectangle.

According to the utility model, the frame and the connecting plate are connected through the five connecting points which are regularly arranged, so that the movement of the connecting plate is completely in a preset movement track, the shaking and the shaking of the connecting plate are avoided, the movement precision of the connecting plate is improved, and the processing precision of the cutting knife group is further improved.

Similarly, the longitudinal nut support on the longitudinal ball screw is connected with the tool rest plate. Because the longitudinal nut support is limited by the volume of the whole structure, the height of the whole machine tool can be greatly increased when the longitudinal nut support is arranged at the middle of the four longitudinal sliding blocks, and therefore, the longitudinal nut support is arranged on the central axis of the longitudinal guide rail.

In some embodiments of the utility model, four cross slides are provided on the lower portion of the connecting plate, and four longitudinal slides fixed to the connecting plate are provided near the cross rails. The gravity center of the connecting plate is moved downwards, so that the heavy head and the light foot of the connecting plate structure are avoided.

In some embodiments of the present utility model, the frame is further provided with a horizontal straight track, the horizontal straight track is perpendicular to the longitudinal guide rail, the horizontal straight track is perpendicular to the transverse guide rail, and the mounting seat for mounting the workpiece to be processed is mounted on the horizontal straight guide rail.

In the utility model, the workpiece comprises a curved top surface, a semicircular ring surface and an annular bottom surface from top to bottom,

in some embodiments of the present utility model, the mounting seat is a groove penetrating through the upper top surface, the lower top surface and one side surface of the mounting plate, the wall surface of the groove is a semicircular structure adapted to the structure of the workpiece, and the bottom of the groove is provided with a rest plate with a semicircular structure. The workpiece is placed on the placing plate, and the circumferential surface of the workpiece is attached to the wall surface of the groove. The mounting seat with the structure is arranged, so that one side surface of the workpiece to be cut into a plane is completely exposed outside the mounting seat, and a cutter can conveniently process the workpiece.

Further, the outer peripheral surface of the placing plate is connected with the wall surface of the groove, and the diameter of the inner peripheral surface of the placing plate is larger than the inner diameter of the annular bottom surface of the workpiece and smaller than the outer diameter of the annular bottom surface of the workpiece. The shelving plate with the structure can support the workpiece and is convenient for the cutter to cut the inner peripheral surface of the annular bottom surface of the workpiece. The semi-annular bottom surface of the workpiece is exposed outside the mounting seat, so that the cutter can conveniently process the inner ring of the semi-annular bottom surface.

The workpiece is placed on the placing plate, and the curved top surface of the workpiece extends out of the mounting seat; the press-fit assembly acts on the curved top surface. The press-fitting assembly is convenient to act on the workpiece, and the workpiece is pressed and fixed on the mounting seat. The tool may also machine the curved top surface.

Specifically, the press-fit assembly is a quick clamp, and a press-fit head of the quick clamp is made of elastic materials. The damage to the workpiece caused by the press-fitting assembly can be avoided. The quick clamp is a common press-fitting tool in the field and can be obtained by direct purchase. The quick clamp acts on the curved top surface of the workpiece.

The above embodiments may be arbitrarily combined on the basis of common knowledge in the art.

Drawings

The utility model will be described in further detail below in connection with the drawings and the preferred embodiments, but it will be appreciated by those skilled in the art that these drawings are drawn for the purpose of illustrating the preferred embodiments only and thus should not be taken as limiting the scope of the utility model. Moreover, unless specifically indicated otherwise, the drawings are merely schematic representations, not necessarily to scale, of the compositions or constructions of the described objects and may include exaggerated representations.

FIG. 1 is a schematic diagram of the structure of a processed product;

FIG. 2 is a schematic diagram of the structure of the present utility model;

FIG. 3 is a schematic view of a structure of a connecting plate according to the present utility model;

FIG. 4 is a schematic diagram of a second embodiment of the present utility model;

FIG. 5 is a side view of a slider of the present utility model;

fig. 6 is a schematic view of a structure of a mounting seat according to the present utility model.

Wherein, the reference numerals specifically explain as follows: 10. a workpiece; 101. a curved top surface; 102. a semicircular ring surface; 103. an annular bottom surface;

11. a frame; 13. a mounting plate; 14. a mounting base; 141. a rest plate; 142. groove wall surfaces; 15. press-fitting the assembly; 18. a cutting knife group;

21. a knife rest plate; 22. a connecting plate; 23. a transverse guide rail; 24. a longitudinal guide rail; 25. a slide block; 26. a notch; 261. the bottom surface of the notch; 262. a flat contact surface; 263. a curved contact surface; 264. chamfering the surface; 27. rolling the ball screw rod; 271. a transverse nut support; 28. a longitudinal ball screw; 281. a longitudinal nut support; 29. a horizontal straight track.

Detailed Description

The present utility model will be described in detail with reference to the accompanying drawings.

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Multi-axis linkage numerical control machine tool suitable for multi-product processing, an embodiment is shown in fig. 1 to 2: including frame 11 and cutting knife group 18, cutting knife group 18 install on frame 11 through plane track group, plane track group include frame plate 21 and connecting plate 22, frame 11 on install two horizontal guide rails 23 that the level set up, frame plate 21 on install two vertical guide rails 24 that set up, connecting plate 22 on correspond a horizontal guide rail 23, vertical guide rail 24 and all be provided with the slider 25 that two at least cooperations are connected, cutting knife group 18 install on frame plate 21, frame plate 21 passes through vertical guide rail 24, slider 25 installs in connecting plate 22, connecting plate 22 passes through slider 25, horizontal guide rail 23 installs in frame 11. The two points define a straight line, so that under the action of the at least two slides 25 it is ensured that the movement of the carriage plate 21 is along the predetermined longitudinal rail 24. Secondly, the tool rest plate 21 is provided with two vertical guide rails 24 which are vertically arranged, namely, the two parallel vertical guide rails 24 limit the moving track of the tool rest plate 21, and compared with a common single guide rail, the tool rest plate has better stability. By matching with the arrangement of the sliding blocks 25, the utility model can ensure the stability of the movement of the cutting knife group 18 in the vertical direction and improve the processing precision. Similarly, at least two sliding blocks 25 are arranged corresponding to one transverse guide rail 23, and the stability of the cutting knife group 18 moving horizontally and transversely is ensured by matching with the arrangement of the two transverse guide rails 23, so that the machining precision is improved.

The two side wall surfaces of the sliding block 25, which are in contact with the transverse guide rail 23 or the longitudinal guide rail 24, are curved surfaces protruding outwards, so that the friction resistance of the sliding block 25 moving on the transverse guide rail 23 and the longitudinal guide rail 24 is effectively reduced, the sliding block 25 moves smoothly relative to the transverse guide rail 23 or the longitudinal guide rail 24, and unnecessary shaking is avoided. The utility model further optimizes the transmission device of the cutter, so that the movement of the cutter is stable and controllable, and the machining precision of the cutter on products is further improved.

Embodiment two: as shown in fig. 2 to 5, the slide block 25 is provided with a notch 26 connected with the transverse guide rail 23 or the longitudinal guide rail 24, and the bottom surface 261 of the notch 26 is a plane and is matched with the top surfaces of the transverse guide rail 23 and the longitudinal guide rail 24. Namely, the top surfaces of the transverse rail 23 and the longitudinal rail 24 in the present utility model are flat surfaces.

The sidewall surface of the notch 26 includes a flat contact surface 262 and an outwardly convex curved contact surface 263, the curved contact surface 263 being disposed adjacent to the open end of the notch 26, the flat contact surface 262 being disposed adjacent to the bottom surface 261 of the notch 26. In the present utility model, the curved contact surface 263 forms the main contact surface where the notch 26 contacts the cross rail 23 or the vertical rail 24, and plays a role of reducing friction resistance and avoiding shake. The flat contact surface 262 plays a limiting role, and the connection deviation of the sliding block 25 and the transverse guide rail 23 or the longitudinal guide rail 24 is avoided.

A chamfer surface 264 is arranged between the flat contact surface 262 and the bottom surface 261 of the notch 26, and the chamfer surface 264 is a curved surface. The addition of the chamfer 264 can avoid a stiff fold between the bottom 261 of the notch 26 and the flat contact 262 of the notch 26, which can easily cause sliding jamming. The utility model adopts the chamfer surface 264 to connect and transition the flat contact surface 262 and the bottom surface 261 of the notch 26, thereby increasing the smoothness of the movement of the slide block 25.

The plane track group comprises a horizontal rolling ball screw 27 and a vertical longitudinal ball screw 28, wherein the horizontal rolling ball screw 27 is arranged in the middle of the two transverse guide rails 23 and is arranged on the frame 11, the horizontal rolling ball screw 27 and the two transverse guide rails 23 are arranged in parallel, the longitudinal ball screw 28 is arranged in the middle of the two longitudinal guide rails 24 and is arranged on the connecting plate 22, and the longitudinal ball screw 28 and the two longitudinal guide rails 24 are arranged in parallel.

At least two transverse sliding blocks 25 are arranged on the back surface of the connecting plate 22 corresponding to one transverse guide rail 23, and at least two longitudinal sliding blocks 25 are arranged on the front surface of the connecting plate 22 corresponding to one longitudinal guide rail 24. Preferably, two transverse sliding blocks 25 are arranged at intervals corresponding to one transverse guide rail 23 on the back surface of the connecting plate 22, and two longitudinal sliding blocks 25 are arranged at intervals corresponding to one longitudinal guide rail 24 on the front surface of the connecting plate 22.

The transverse nut support 271 on the transverse ball screw 27 is connected with the connecting plate 22, the transverse ball screw 27 works to drive the connecting plate 22 to horizontally and transversely move, and the transverse nut support 271 is positioned at the middle of the four transverse sliding blocks 25. Preferably, four cross slides 25 form a rectangle.

According to the utility model, the frame 11 and the connecting plate 22 are connected through the five connecting points which are regularly arranged, so that the movement of the connecting plate 22 is completely in a preset movement track, the shaking and the shaking of the connecting plate 22 are avoided, the movement precision of the connecting plate 22 is improved, and the processing precision of the cutting knife group 18 is further improved.

Likewise, the longitudinal nut support 281 on the longitudinal ball screw 28 is connected to the tool carrier plate 21. Because of the limitation of the overall structure volume, the vertical nut support 281 is arranged at the middle of the four vertical sliding blocks 25 to greatly heighten the height of the whole machine tool, and therefore, the vertical nut support 281 is arranged on the central axis of the vertical guide rail 24.

Four lateral sliding blocks 25 are arranged at the lower part of the connecting plate 22, and four longitudinal sliding blocks 25 fixed on the connecting plate 22 are arranged close to the lateral guide rail 23. The gravity center at the connecting plate 22 is moved downwards, so that the structure of the connecting plate 22 is prevented from being heavy and light.

The machine frame 11 is also provided with a horizontal straight track 29, the horizontal straight track 29 is perpendicular to the longitudinal guide rail 24, the horizontal straight track 29 is perpendicular to the transverse guide rail 23, and the mounting seat 14 for mounting the workpiece 10 to be processed is mounted on the horizontal straight guide rail.

The other contents of the second embodiment are the same as those of the first embodiment.

Embodiment III: as shown in fig. 1, in the present utility model, the workpiece 10 includes, from top to bottom, a curved top surface 101, a semicircular annular surface 102, and an annular bottom surface 103.

As shown in fig. 2 and 6: the mounting seat 14 is a groove penetrating through the upper top surface, the lower top surface and one side surface of the mounting plate 13, the wall surface 142 of the groove is of a semicircular structure which is matched with the structure of the workpiece 10, and the bottom of the groove is provided with a rest plate 141 of a semicircular structure. The work 10 is placed on the rest plate 141, and the circumferential surface of the work 10 is fitted with the groove wall surface 142. The utility model is provided with the mounting seat 14 with the structure, so that one side surface of the workpiece 10 which needs to be cut into a plane is completely exposed outside the mounting seat 14, and a cutter is convenient to process the workpiece.

Further, the outer peripheral surface of the rest plate 141 is connected with the groove wall surface 142, and the diameter of the inner peripheral surface of the rest plate 141 is larger than the inner diameter of the annular bottom surface 103 of the workpiece 10 and smaller than the outer diameter of the annular bottom surface 103 of the workpiece 10. The rest plate 141 with the structure can support the workpiece 10 and is convenient for the cutter to cut the inner peripheral surface of the annular bottom surface 103 of the workpiece 10. The semi-annular bottom surface 103 of the workpiece 10 is exposed outside the mounting seat 14, so that the inner ring of the semi-annular bottom surface 103 is conveniently machined by a cutter.

The workpiece 10 is placed on the placing plate 141, and then the curved top surface 101 of the workpiece 10 protrudes out of the mounting seat 14; the press-fit assembly 15 acts on the curved top surface 101. The press-fit assembly 15 is conveniently applied to the workpiece 10 to press-fix the workpiece 10 to the mounting block 14. The tool may also machine the curved top surface 101.

Specifically, the press-fitting assembly 15 is a quick clamp, and a press-fitting head of the quick clamp is made of an elastic material. Damage to the work 10 by the press-fit assembly 15 can be avoided. The quick clamp is a common press-fitting tool in the field and can be obtained by direct purchase. The quick clamp acts on the curved top surface 101 of the workpiece 10.

The other contents of the third embodiment are the same as those of the first or second embodiments.

The foregoing has outlined rather broadly the more detailed description of the utility model in order that the detailed description of the utility model that follows may be better understood, and in order that the present utility model may be better understood. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the utility model can be made without departing from the principles of the utility model and these modifications and adaptations are intended to be within the scope of the utility model as defined in the following claims.

Claims (10)

1. The multi-axis linkage numerical control machine tool is suitable for processing multiple products and is characterized by comprising a frame and a cutting knife group, wherein the cutting knife group is arranged on the frame through a plane track group, the plane track group comprises a knife rack plate and a connecting plate, two horizontal guide rails which are horizontally arranged are arranged on the frame, two vertical guide rails which are vertically arranged are arranged on the knife rack plate, at least two sliding blocks which are matched and connected are arranged on the connecting plate corresponding to one horizontal guide rail and the corresponding vertical guide rail, the two side wall surfaces of the sliding blocks, which are contacted with the horizontal guide rail or the corresponding vertical guide rail, are curved surfaces which are outwards convex, the cutting knife group is arranged on the knife rack plate, the knife rack plate is arranged on the connecting plate through the vertical guide rails and the sliding blocks, and the connecting plate is arranged on the frame through the sliding blocks and the horizontal guide rails.

2. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 1, wherein the sliding block is provided with a notch connected with the transverse guide rail or the longitudinal guide rail, and the bottom surface of the notch is a plane and is matched with the top surfaces of the transverse guide rail and the longitudinal guide rail.

3. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 2, wherein the side wall surface of the notch comprises a flat contact surface and an outwards protruding curved contact surface, the curved contact surface is arranged near the opening end of the notch, and the flat contact surface is arranged near the bottom surface of the notch.

4. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 3, wherein a chamfer surface is arranged between the flat contact surface and the bottom surface of the notch, and the chamfer surface is a curved surface.

5. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 1, wherein the planar track group comprises a horizontal rolling ball screw and a vertical rolling ball screw, the rolling ball screw is arranged on the frame between two transverse guide rails, the rolling ball screw and the two transverse guide rails are arranged in parallel, the rolling ball screw is arranged on the connecting plate between the two longitudinal guide rails, and the rolling ball screw and the two longitudinal guide rails are arranged in parallel.

6. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 5, wherein two transverse sliding blocks are arranged at intervals corresponding to one transverse guide rail on the back surface of the connecting plate, and two longitudinal sliding blocks are arranged at intervals corresponding to one longitudinal guide rail on the front surface of the connecting plate.

7. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 6, wherein a transverse nut support on the transverse ball screw is connected with the connecting plate, the transverse ball screw works to drive the connecting plate to horizontally and transversely move, and the transverse nut support is positioned in the middle of the four transverse sliding blocks; the four cross slides form a rectangle.

8. The multi-axis linkage numerical control machine tool applicable to multi-product processing according to claim 6, wherein a longitudinal nut support on the longitudinal ball screw is connected with a tool rest plate; the four horizontal sliding blocks are arranged at the lower part of the connecting plate, and the four vertical sliding blocks fixed on the connecting plate are arranged close to the horizontal guide rail.

9. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 1, wherein the machine frame is further provided with a horizontal straight track, the horizontal straight track is perpendicular to the longitudinal guide rail, the horizontal straight track is perpendicular to the transverse guide rail, and a mounting seat for mounting a workpiece to be processed is mounted on the horizontal straight guide rail.

10. The multi-axis linkage numerical control machine tool suitable for multi-product processing according to claim 9, wherein the mounting seat is a groove penetrating through the upper top surface, the lower top surface and one side surface of the mounting plate, the wall surface of the groove is of a semicircular structure which is matched with the structure of a workpiece, and a rest plate of a semicircular annular structure is arranged at the bottom of the groove.