CN203305751U - Numerical-control five-axis linkage ceramic carving machine - Google Patents

Abstract

The utility model discloses a numerical-control five-axis linkage ceramic carving machine. A numerical-control box is connected to and controls motors connected with axis lead screws; the Z-axis transmission block of a horizontal Z-axis lead screw is fixedly provided with an X-axis bracket; the X-axis bracket is provided with an X-axis lead screw vertical to the Z axis; the X-axis transmission block of the X-axis lead screw is fixedly connected with a Y-axis bracket; a Y-axis lead screw installed on the Y-axis bracket is vertical to the X axis and the Z axis; the Y-axis lead screw is provided with three or five identical Y-axis transmission blocks; each Y-axis transmission block is fixedly provided with a spindle motor; each spindle motor is connected with a cutter holder; the B-axis transmission block of a B-axis lead screw parallel to the Z axis is fixedly provided with a tray mounting plate; the top ends of three or five vertical A axes on the tray mounting plate are respectively provided with a tray; three or five A-axis motors fixedly arranged on the tray mounting plate are respectively used for driving the A axes; each tray is provided with a chuck jaw to position a workpiece on the tray. According to the numerical-control five-axis linkage ceramic carving machine, three or five workpieces can be simultaneously processed, and the production efficiency is improved.

Description

Numerical control five-shaft linkage pottery engraving machine

Technical field

The utility model relates to the ceramic-processing mechanical technical field, is specially a kind of numerical control five-shaft linkage pottery engraving machine.

Background technology

There is embossment on many ceramics surface as decoration.The emerging pottery of the mud of Guangxi Qinzhou for example, maximum characteristics are not glazings and adopt the various patterns of engraving to decorate.The embossing pattern on pottery surface is carved after the greenwave moulding, then fire typing.

Obviously, hand engraving efficiency is extremely low, and quality also seldom arrives assurance.

In order to improve carving efficiency, existing existing various multi-shaft interlocked digital controlled ceramic processing machines are 200620069271 utility model patent " novel Five-axis linkage carving machine " etc. as: application number be 200710152319.6 utility model patent " digital controlled ceramic constructing forming machine ", application number be 200620140404.1 utility model patent " Ceramic numerical control cutting machine ", application number.

Although these engraving machines have improved the efficiency of ceramic engraving greatly, once can only process a workpiece, utilization rate of equipment and installations and production efficiency are difficult to improve.

The utility model content

The purpose of this utility model is a kind of numerical control five-shaft linkage pottery of design engraving machine, the tray for work pieces part that comprises numerical control part, XYZ tri-axle tool feeding parts and A, the interlock of B axle, its Y-axis has 3 or 5 secondary cutters, the tray for work pieces that the 3 or 5 cover A axles that match with cutter are arranged on the B axle, simultaneously can process three or five workpiece, raise the efficiency.

Numerical control five-shaft linkage pottery engraving machine of the present utility model, the tray for work pieces part that comprises numerical control box, XYZ tri-axle tool feeding parts and A, the interlock of B axle, numerical control box connects controls each spindle motor, X, Y, Z tri-axle tool feeding partly comprise orthogonal X, Y, Z screw mandrel, are installed on the motor that the drive block of each screw mandrel is connected with each screw mandrel.Z axis screw mandrel level rotationally is installed on frame, one end is connected with the Z axis motor, the Z-axis transmission piece has screw to be enclosed within on the Z axis screw mandrel, fixing X-axis support on the Z-axis transmission piece, and the X-axis screw mandrel is rotatably installed on the X-axis support, the X-axis screw mandrel is perpendicular to the Z axis screw mandrel, one end is connected with the X-axis motor that is installed on the X-axis support, and the X-axis drive block has screw, is enclosed within on the X-axis screw mandrel, on the X-axis drive block, is fixedly connected with the Y-axis support, the Y-axis screw mandrel is rotatably installed on the Y-axis support, and the Y-axis screw mandrel is perpendicular to X-axis and Z axis screw mandrel.Y-axis screw mandrel one end is connected with the y-axis motor that is installed on the Y-axis support.

3 or 5 identical Y-axis drive blocks are installed on the Y-axis screw mandrel of the utility model engraving machine, each Y-axis drive block has screw to be enclosed within on the Y-axis screw mandrel, on each Y-axis drive block, be fixed with a spindle motor, the output shaft of each spindle motor is parallel with the Z axis screw mandrel, each spindle motor output shaft connects cutting tool gripper, and the engraving cutter is installed on cutting tool gripper.

On frame, also be rotatably mounted the B axial filament bar parallel with the Z axis screw mandrel, an end of B axial filament bar is equipped with handle.B through-drive piece has screw, is enclosed within B axial filament bar.Fixed installation pallet installing plate on B through-drive piece, on the pallet installing plate, be rotatably mounted 3 or 5 identical vertical A axles, the A axle is parallel with the X-axis screw mandrel, 3 or 5 identical pallets are individually fixed in 3 or 5 A axle tops, corresponding with 3 or 5 Y-axis drive blocks on the Y-axis screw mandrel, on the pallet installing plate, also have 3 or 5 identical A spindle motors to connect respectively and drive 3 or 5 A axles.

On frame, fix 2 of vertical front and back Z axis support installing plate, Z axis screw mandrel two ends are rotatably installed on Z axis support installing plate, and respectively there is a Z axis optical axis in parallel Z axis screw mandrel both sides, and Z axis support installing plate is fixed at the two ends of Z axis optical axis.On the Z axis slide block, have and Z axis optical axis unthreaded hole movingly, every Z axis optical axis cover has a Z axis slide block, and two Z axis slide blocks all are fixedly connected with the X-axis support.When the rotation of Z axis screw mandrel, Z-axis transmission piece moved along the Z axis screw mandrel, the Z axis slide block slided on the Z axis optical axis, make the X-axis support-moving steady.

The X-axis support that is fixed in Z axis comprises X-axis support installing plate and X-axis optical axis, X-axis support installing plate is upper and lower 2 blocks of level boards, the upper and lower side of X-axis screw mandrel is rotatably installed on upper and lower X-axis support installing plate, 1 X-axis optical axis that is parallel to the X-axis screw mandrel is respectively arranged in the both sides of X-axis screw mandrel, the upper and lower end of X-axis optical axis is fixedly connected with respectively upper and lower X-axis support installing plate, forms the rectangular frame of X-axis support.On the X-axis slide block, have and X-axis optical axis unthreaded hole movingly, every X-axis optical axis cover has an X-axis slide block, and two X-axis slide blocks all are fixedly connected with the Y-axis support.

When the X-axis screw mandrel rotated, the X-axis drive block moved up and down along the X-axis screw mandrel, and the X-axis slide block slides and play the guiding role on the X-axis optical axis.Thereby guarantee that the Y-axis support and the Y-axis screw mandrel that are fixedly mounted on X-axis slide block and X-axis drive block move up and down steadily.

Respectively there is an X-axis holder stay vertical with the Y-axis screw mandrel in 2 X-axis optical axis outsides, and the upper and lower end of X-axis holder stay is fixedly connected with upper and lower X-axis support installing plate respectively.Make the framework of X-axis support more firm.

The Y-axis support comprises Y-axis support installing plate, Y-axis support end plate and Y-axis optical axis, and Y-axis support installing plate is perpendicular to the Z axis screw mandrel, and 2 Y-axis support end plates vertically are fixedly connected on two ends, Y-axis support installing plate left and right, forms Jiong shape.The Y-axis screw mandrel is rotatably installed on Y-axis support end plate, the Y-axis screw mandrel 1 Y-axis optical axis that is parallel to the Y-axis screw mandrel respectively arranged up and down, the left and right end of Y-axis optical axis is fixedly connected with respectively left and right Y-axis support end plate, forms the rectangular frame of Y-axis support.On the Y-axis slide block, having with the Y-axis optical axis is unthreaded hole movingly, and each Y-axis drive block is furnished with 2 Y-axis slide blocks, is enclosed within respectively on upper and lower Y-axis optical axis.The upper and lower Y-axis slide block coordinated with certain Y-axis drive block is fixedly connected with the spindle motor that this Y-axis drive block is connected.When the Y-axis screw mandrel rotated, 3 or 5 Y-axis drive blocks synchronously moved forward and backward along the Y-axis screw mandrel, and the Y-axis slide block is synchronizeed along the slip of Y-axis optical axis, play the guiding role with drive block, guaranteed that the spindle motor be fixed on Y-axis slide block and Y-axis drive block moves forward and backward steadily.

The B bracing strut comprises B bracing strut installing plate and B axle optical axis, B bracing strut installing plate is the flat boards of two of front and back perpendicular to the Z axis screw mandrel, be fixed in frame, B axial filament bar front and back ends is rotatably installed on forward and backward B bracing strut installing plate, 1 B axle optical axis that is parallel to B axial filament bar is respectively arranged in the left and right of B axial filament bar, B axle optical axis front and back ends is fixedly connected with respectively forward and backward B bracing strut installing plate, forms the rectangular frame of B bracing strut.On B axle slide block, having with B axle optical axis is unthreaded hole movingly, and on every B axle optical axis, cover has a B through-drive piece.When B axial filament bar rotated, B through-drive piece moved forward and backward, B axle slide block on B axle optical axis synchronizing moving, play the guiding role.Thereby guarantee that the pallet installing plate be arranged on B axle slide block and B through-drive piece moves forward and backward steadily.

Chuck jaw is arranged on pallet, and workpiece is positioned on pallet, and chuck jaw is fixed the location of workpiece on pallet.

On A spindle motor output shaft, be fixed with driven wheel, be fixedly mounted with travelling gear on the A axle, gear band connects driven wheel and travelling gear, and the A spindle motor drives the rotation of A axle.

X-axis motor, y-axis motor and Z axis motor are connected with X-axis screw mandrel, Y-axis screw mandrel and Z axis screw mandrel through shaft coupling respectively.

During the work of this engraving machine, on each pallet, place identical workpiece, manual adjustments B axial filament bar, be in the tool sharpening scope of Y-axis drive block the workpiece on pallet.When the surface of the work of three pallets is not quite identical, in the engraving process, there will be the engraving lines deep mixed, the front and back position by B axle fine setting workpiece, make to carve the carving depth of cutter on each surface of the work basic identical.Start this engraving machine, the A spindle motor drives pallet and the rotation of the workpiece on it, and under the control of numerical control box, cutter moves at XYZ tri-axles, to the surface of the work Carving Machining.

Compared with prior art, the advantage of the utility model numerical control five-shaft linkage pottery engraving machine is: the machine can be processed nearly three or five workpiece simultaneously, production efficiency can be three or five times of existing equipment, the ceramic form quality that cause is not fired is crisp, be easy to processing, can realize processing request without the power that strengthens each motor.

The accompanying drawing explanation

Fig. 1 is this numerical control five-axle linkage pottery engraving machine example structure schematic diagram; For the A-A of Fig. 2 to view;

Fig. 2 is this numerical control five-axle linkage pottery engraving machine embodiment front view;

Fig. 3 is this numerical control five-axle linkage pottery engraving machine embodiment top view.

Number in the figure:

1, the X-axis drive block, 11, the X-axis motor, 12, X-axis support installing plate, 13, the X-axis screw mandrel, 14, the X-axis holder stay, 15, the X-axis optical axis, 16, the X-axis slide block, 2, the Y-axis drive block, 21, Y-axis support installing plate, 22, the Y-axis slide block, 23, the Y-axis optical axis, 24, Y-axis support end plate, 25, y-axis motor, 26, the Y-axis screw mandrel, 3, the Z-axis transmission piece, 31, the Z axis motor, 32, the Z axis screw mandrel, 33, Z axis support installing plate, 34, the Z axis optical axis, 4, frame, 5, numerical control box, 6, B through-drive piece, 61, B axial filament bar, 62, B bracing strut installing plate, 63, B axle optical axis, 7, pallet, 71, the A axle, 72, the pallet installing plate, 73, the A spindle motor, 8, cutting tool gripper, 81, spindle motor, 82, the spindle motor installing plate.

The specific embodiment

Below in conjunction with embodiment and accompanying drawing, the utility model is further illustrated.

This numerical control five-axle linkage pottery engraving machine embodiment as shown in Figures 1 to 3, the tray for work pieces part that comprises numerical control box, XYZ tri-axle tool feeding parts and A, the interlock of B axle, numerical control box connects controls each axis drive motor, X, Y, Z tri-axle tool feeding parts, comprise orthogonal X, Y, Z screw mandrel, be installed on drive block and the slide block of each screw mandrel, drive the motor of each screw mandrel.

The table-surface level of frame 4, its lower fixedly numerical control box 5, on the table top of frame 4, be fixed with 2 of vertical front and back Z axis support installing plate 33, Z axis screw mandrel 32 two ends through bearing rotationally level be installed on before and after Z axis support installing plate 33, the rear end of this routine Z axis screw mandrel 32 is connected with Z axis motor 31 through shaft coupling, and Z axis motor 31 is fixedly installed in the Z axis support installing plate 33 of rear end.Z-axis transmission piece 3 has screw to be enclosed within on Z axis screw mandrel 32.Respectively there is a Z axis optical axis 34 in parallel Z axis screw mandrel 32 both sides, and Z axis support installing plate 33 is fixed at the two ends of Z axis optical axis 34.On the Z axis slide block, have and Z axis optical axis 34 unthreaded hole movingly, every Z axis optical axis 34 covers have a Z axis slide block, and two Z axis slide blocks all are fixedly connected with X-axis support installing plate.

Fixing X-axis support on Z-axis transmission piece 3 and Z axis slide block, the X-axis support comprises X-axis support installing plate 12, X-axis holder stay 14 and X-axis optical axis 15, X-axis support installing plate 12 is upper and lower 2 blocks of level boards, X-axis screw mandrel 13 upper and lower ends are rotatably installed on upper and lower X-axis support installing plate 12 through bearing, X-axis screw mandrel 13 is perpendicular to Z axis screw mandrel 32, fixed installation X-axis motor 11 on the X-axis support installing plate 12 of top, X-axis motor 11 is connected with X-axis screw mandrel 13 through shaft coupling.The X-axis optical axis 15 that is parallel to X-axis screw mandrel 13 that 1 symmetry is respectively arranged in the both sides of X-axis screw mandrel 13, the upper and lower end of X-axis optical axis 15 are fixedly connected with respectively upper and lower X-axis support installing plate 12.The center of X-axis drive block 1 is screw, is enclosed within on X-axis screw mandrel 13.On X-axis slide block 16, have and X-axis optical axis 15 unthreaded hole movingly, every X-axis optical axis 15 covers have an X-axis slide block 16, and X-axis drive block 1 all is fixedly connected with Y-axis support installing plate 21 with two X-axis slide blocks 16.Respectively there is an X-axis holder stay 14 in 2 X-axis optical axis 15 outsides, and the upper and lower end of X-axis holder stay 14 is fixedly connected with upper and lower X-axis support installing plate 12 respectively.X-axis holder stay 14 is vertical with Y-axis screw mandrel 26, X-axis support installing plate 12, X-axis holder stay 14 and the common rectangular frame that forms the X-axis support of X-axis optical axis 15.

On X-axis drive block 1 and X-axis slide block 16, be fixedly connected with the Y-axis support, the Y-axis support comprises Y-axis support installing plate 21, Y-axis support end plate 24 and Y-axis optical axis 23, Y-axis support installing plate 21 is perpendicular to Z axis screw mandrel 32,2 Y-axis support end plates 24 vertically are fixedly connected on Y-axis support installing plate 21 two ends, left and right, form Jiong shape.Y-axis screw mandrel 26 two ends are rotatably installed on left and right Y-axis support end plate 24 through bearing, and Y-axis screw mandrel 26 is perpendicular to X-axis screw mandrel 13 and Z axis screw mandrel 32.The Y-axis support end plate 24 fixed installation y-axis motors 25 of this routine left end, y-axis motor 25 is connected with Y-axis screw mandrel 26 through shaft coupling.Y-axis screw mandrel 26 1 symmetrical parallel is respectively arranged up and down in the Y-axis optical axis 23 of Y-axis screw mandrel 26, the left and right end of Y-axis optical axis 23 is fixedly connected with respectively left and right Y-axis support end plate 24.All there is screw at the center of 3 identical Y-axis drive blocks 2, is enclosed within on Y-axis screw mandrel 26.

Each Y-axis drive block 2 respectively has 1 Y-axis slide block 22 up and down, on Y-axis slide block 22, have and Y-axis optical axis 23 phases unthreaded hole movingly, upper and lower Y-axis optical axis 23 passes respectively the unthreaded hole that is in the upper and lower Y-axis slide block 22 of Y-axis drive block 2, and on every Y-axis optical axis 23, cover has 3 Y-axis slide blocks 22.

On 3 Y-axis drive blocks 2, respectively be fixed with spindle motor installing plate 82, the upper and lower Y-axis slide block 22 coordinated with certain Y-axis drive block 2 is fixedly connected with the spindle motor installing plate 82 that this Y-axis drive block 2 is connected.Spindle motor 81 is fixedly installed in spindle motor installing plate 82.

The output shaft of spindle motor 81 is parallel with Z axis screw mandrel 32, and spindle motor 81 output shafts connect cutting tool gripper 8.The engraving cutter is installed on cutting tool gripper 8.

On the table top of frame 5, also be installed with the B bracing strut installing plate 62 of B bracing strut, B bracing strut installing plate 62 is perpendicular to Z axis screw mandrel 32,33 whiles of Z axis support installing plate of this routine front end are as the B bracing strut installing plate 62 of rear end, B axial filament bar 61 front and back ends are rotatably installed on forward and backward B bracing strut installing plate 62 through bearing, B axial filament bar 61 is parallel with Z axis screw mandrel 32, the front end of this routine B axial filament bar 61, be equipped with handle in B bracing strut installing plate 62 outsides, and turning handle is rotatable B axial filament bar 61.1 B axle optical axis 63 that is parallel to B axial filament bar 61 is respectively arranged in the left and right of B axial filament bar 61, and B axle optical axis 63 front and back ends are fixedly connected with respectively forward and backward B bracing strut installing plate 62.The center of B through-drive piece 6 is screw, is enclosed within on B axial filament bar 62, and the unthreaded hole matched with B axle optical axis 63 is arranged on B axle slide block, and every B axle optical axis 63 covers have a B axle slide block, and the two is for movingly.

Fixed installation pallet installing plate 72 on B through-drive piece 6 and B axle slide block, on the pallet installing plate, bearing is installed, be rotatably mounted 3 identical vertical A axles 71, A axle 71 is parallel with X-axis screw mandrel 13, 3 identical pallets 7 are individually fixed in 3 A axle 71 tops, corresponding with 3 Y-axis drive blocks 2 on Y- axis screw mandrel 26, 3 identical A spindle motors 73 of fixed installation on pallet installing plate 72, on these routine A spindle motor 73 output shafts, be fixed with driven wheel, on A axle 71, be fixedly mounted with travelling gear, gear band connects driven wheel and travelling gear, A spindle motor 73 drives A axle 71 and 7 rotations of the pallet on it.On pallet 7, chuck jaw is arranged.

Above-described embodiment, be only the specific case that the purpose of this utility model, technical scheme and beneficial effect are further described, and the utility model not is defined in this.All any modifications of making, be equal to replacement, improvement etc., within all being included in protection domain of the present utility model within scope of disclosure of the present utility model.

Claims (9)

1. numerical control five-shaft linkage pottery engraving machine, the tray for work pieces part that comprises numerical control box, XYZ tri-axle tool feeding parts and A, the interlock of B axle, numerical control box connects controls each spindle motor, X, Y, Z tri-axle tool feeding parts, comprise orthogonal X, Y, Z screw mandrel, be installed on the motor that the drive block of each screw mandrel is connected with each screw mandrel;

Z axis screw mandrel (32) level rotationally is installed on frame (4), and an end is connected with Z axis motor (31), and Z-axis transmission piece (3) has screw to be enclosed within on Z axis screw mandrel (32); The upper fixedly X-axis support of Z-axis transmission piece (3), X-axis screw mandrel (13) is rotatably installed on the X-axis support, X-axis screw mandrel (13) is connected perpendicular to Z axis screw mandrel (32), an end and the X-axis motor (11) that is installed on the X-axis support, and X-axis drive block (1) has screw, is enclosed within on X-axis screw mandrel (13); The X-axis drive block is fixedly connected with the Y-axis support on (1), Y-axis screw mandrel (26) is rotatably installed on the Y-axis support, Y-axis screw mandrel (26) is perpendicular to X-axis screw mandrel (13) and Z axis screw mandrel (32), and Y-axis screw mandrel (26) one ends are connected with the y-axis motor that is installed on the Y-axis support (25); It is characterized in that:

3 or 5 identical Y-axis drive blocks (2) are installed on described Y-axis screw mandrel (26), each Y-axis drive block (2) has screw to be enclosed within on Y-axis screw mandrel (26), on each Y-axis drive block (2), be fixed with a spindle motor (81), the output shaft of each spindle motor (81) is parallel with Z axis screw mandrel (32), each spindle motor (81) output shaft connects cutting tool gripper (8), the upper engraving cutter of installing of cutting tool gripper (8);

On frame (4), also be rotatably mounted the B axial filament bar (61) parallel with Z axis screw mandrel (32), an end of B axial filament bar (61) is equipped with handle; B through-drive piece (6) has screw, is enclosed within B axial filament bar (61), the upper fixed installation of B through-drive piece (6) pallet installing plate (72), on pallet installing plate (72), be fixed with rotationally 3 or 5 identical vertical A axles (71), A axle (71) is parallel with X-axis screw mandrel (13), 3 or 5 identical pallets (7) are individually fixed in 3 or 5 A axles (71) top, corresponding with 3 or 5 the Y-axis drive blocks (2) on Y-axis screw mandrel (26), pallet installing plate (72) is upper also has 3 or 5 identical A spindle motors (73) to connect respectively driving 3 or 5 A axles (71).

2. numerical control five-shaft linkage according to claim 1 pottery engraving machine is characterized in that:

The upper fixing vertical 2 Z axis support installing plates in front and back (33) of described frame (4), Z axis screw mandrel (32) two ends are rotatably installed on Z axis support installing plate (33), respectively there is a Z axis optical axis (34) in parallel Z axis screw mandrel (32) both sides, and Z axis support installing plate (33) is fixed at the two ends of Z axis optical axis (34); On the Z axis slide block, have and Z axis optical axis (34) unthreaded hole movingly, every Z axis optical axis (34) cover has a Z axis slide block, and two Z axis slide blocks all are fixedly connected with the X-axis support.

3. numerical control five-shaft linkage according to claim 1 pottery engraving machine is characterized in that:

Described X-axis support comprises X-axis support installing plate (12) and X-axis optical axis (15), X-axis support installing plate (12) is upper and lower 2 blocks of level boards, X-axis screw mandrel (13) upper and lower end is rotatably installed on upper and lower X-axis support installing plate (12), the upper fixed installation of the X-axis support installing plate (12) of top X-axis motor (11), 1 X-axis optical axis (15) that is parallel to X-axis screw mandrel (13) is respectively arranged in the both sides of X-axis screw mandrel (13), and the upper and lower end of X-axis optical axis (15) is fixedly connected with respectively upper and lower X-axis support installing plate (12); It is unthreaded hole movingly that X-axis slide block (16) has with X-axis optical axis (15), and the upper cover of every X-axis optical axis (15) has an X-axis slide block (16), and two X-axis slide blocks (16) all are fixedly connected with the Y-axis support.

4. numerical control five-shaft linkage according to claim 3 pottery engraving machine is characterized in that:

Respectively there is an X-axis holder stay (14) vertical with Y-axis screw mandrel (26) in described 2 X-axis optical axises (15) outside, and the upper and lower end of X-axis holder stay (14) is fixedly connected with upper and lower X-axis support installing plate (12) respectively.

5. numerical control five-shaft linkage according to claim 1 pottery engraving machine is characterized in that:

Described Y-axis support comprises Y-axis support installing plate (21), Y-axis support end plate (24) and Y-axis optical axis (23), Y-axis support installing plate (21) is perpendicular to Z axis screw mandrel (32), 2 Y-axis support end plates (24) vertically are fixedly connected on Y-axis support installing plate (21) two ends, left and right, form Jiong shape; Y-axis screw mandrel (26) two ends are rotatably installed on left and right Y-axis support end plate (24), Y-axis support end plate (24) the fixed installation y-axis motor (25) of one end, Y-axis screw mandrel (26) 1 Y-axis optical axis (23) that is parallel to Y-axis screw mandrel (26) respectively arranged up and down, the left and right end of Y-axis optical axis (23) is fixedly connected with respectively left and right Y-axis support end plate (24); On Y-axis slide block (22), having with Y-axis optical axis (23) is unthreaded hole movingly, and each Y-axis drive block (2) is furnished with 2 Y-axis slide blocks (22), is enclosed within respectively on upper and lower Y-axis optical axis (23);

On each Y-axis drive block (2), be fixed with spindle motor installing plate (82), the upper and lower Y-axis slide block (22) coordinated with certain Y-axis drive block (2) is fixedly connected with the spindle motor installing plate (82) that this Y-axis drive block (2) is connected; Spindle motor (81) is fixedly installed in spindle motor installing plate (82).

6. numerical control five-shaft linkage according to claim 1 pottery engraving machine is characterized in that:

Described B bracing strut comprises B bracing strut installing plate (62) and B axle optical axis (63), front and back B bracing strut installing plates (62) vertically are fixed in frame (4), B bracing strut installing plate (62) before and after B axial filament bar (61) front and back end is rotatably installed on, 1 B axle optical axis (63) that is parallel to B axial filament bar (61) is respectively arranged in the left and right of B axial filament bar (61), and B axle optical axis (63) front and back ends is fixedly connected on respectively forward and backward B bracing strut installing plate (62); (6 center is screw to B through-drive piece, is enclosed within B axial filament bar (62) upper, and on B axle slide block, having with B axle optical axis (63) is unthreaded hole movingly mutually, and the upper cover of every B axle optical axis (63) has a B axle slide block.

7. according to the described numerical control five-shaft linkage pottery of any one in claim 1 to 6 engraving machine, it is characterized in that:

On described A spindle motor (73) output shaft, be fixed with driven wheel, the A axle is fixedly mounted with travelling gear on (71), and gear band connects driven wheel and travelling gear.

8. according to the described numerical control five-shaft linkage pottery of any one in claim 1 to 6 engraving machine, it is characterized in that:

Described X-axis motor (11), y-axis motor (25) and Z axis motor (31) are connected with X-axis screw mandrel (13), Y-axis screw mandrel (26) and Z axis screw mandrel (32) through shaft coupling respectively.

9. according to the described numerical control five-shaft linkage pottery of any one in claim 1 to 6 engraving machine, it is characterized in that:

Described pallet has chuck jaw on (7).

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