CN113910003A

CN113910003A - Double-spindle double-Y-axis composite numerical control machine tool

Info

Publication number: CN113910003A
Application number: CN202111240661.8A
Authority: CN
Inventors: 马升; 李元峰
Original assignee: Ningbo Jinhua Cnc Machine Tool Co ltd
Current assignee: Ningbo Jinhua Cnc Machine Tool Co ltd
Priority date: 2021-10-25
Filing date: 2021-10-25
Publication date: 2022-01-11
Anticipated expiration: 2041-10-25
Also published as: CN113910003B

Abstract

The invention discloses a double-spindle double-Y-axis composite numerical control machine tool, which comprises: the frame comprises a base frame, at least one vertical frame, a first main shaft device, a second main shaft device, a first longitudinal shaft device and a second longitudinal shaft device. The second longitudinal shaft device is arranged at a distance from the first longitudinal shaft device, and the first longitudinal shaft device and the second longitudinal shaft device are positioned in the area between the first spindle device and the second spindle device. The control module is respectively in communication connection with the first spindle device, the second spindle device, the first longitudinal axis device and the second longitudinal axis device; and the first longitudinal shaft device and/or the second longitudinal shaft device machine the workpiece clamped by one of the first main shaft device and the second main shaft device according to the instruction of the control module. One of the first longitudinal shaft device and the second longitudinal shaft device clamps the workpiece, and the other clamping device is replaced after the machining is finished, so that the automatic clamping and reversing of the workpiece are realized, the machining effect is good, and the efficiency is high.

Description

Double-spindle double-Y-axis composite numerical control machine tool

Technical Field

The invention relates to the technical field of numerical control machine tools, in particular to a double-spindle double-Y-axis composite numerical control machine tool.

Background

The existing numerical control machine tool adopts a single cutter shaft to process, the single cutter shaft can only process one part of a workpiece, and other parts of the workpiece can be processed only by changing the cutter, so that the processing efficiency is low. In addition, the workpiece can only be processed in a partial region by one-time clamping, and after the workpiece at the clamped part needs to be manually disassembled, the workpiece is subjected to secondary clamping, so that the processing standard changes, and the processing efficiency is low, so that improvement is needed.

Disclosure of Invention

The invention aims to provide a double-spindle double-Y-axis compound numerical control machine tool.

The technical scheme adopted by the invention is as follows: a double-spindle and double-Y-axis composite numerical control machine tool comprises:

the rack comprises an underframe and at least one vertical frame fixed on the underframe, wherein the length direction of the vertical frame is intersected with the plane where the underframe is located;

the first main shaft device and the second main shaft device are connected to the underframe in a sliding mode, and the second main shaft device is arranged opposite to the first main shaft device;

a first longitudinal axis means and a second longitudinal axis means slidably connected to said stand, said second longitudinal axis means being spaced from said first longitudinal axis means, said first longitudinal axis means and said second longitudinal axis means being located in a region between said first spindle means and said second spindle means;

the control module is respectively in communication connection with the first spindle device, the second spindle device, the first longitudinal axis device and the second longitudinal axis device; and the first longitudinal shaft device and/or the second longitudinal shaft device machine the workpiece clamped by one of the first main shaft device and the second main shaft device according to the instruction of the control module.

In one embodiment, the sliding directions of the first longitudinal shaft device and the second longitudinal shaft device are parallel, and the rotation axis of the first spindle device and the rotation axis of the second spindle device are parallel and perpendicular to the sliding direction of the first longitudinal shaft device.

In an embodiment, a projection of a rotation axis of the first spindle device and a projection of a rotation axis of the second spindle device on the stand coincide, and at least one of the first spindle device and the second spindle device can move towards the other direction along the rotation axis.

In an embodiment, the first spindle device includes a first sliding mechanism mounted on the chassis, a second sliding mechanism slidably connected to the first sliding mechanism, a driving assembly mounted on the second sliding mechanism, and a chuck assembly mounted on the driving assembly, the sliding direction of the first sliding mechanism driving the second sliding mechanism is perpendicular to the sliding direction of the second sliding mechanism driving the driving assembly, and the sliding direction of the first sliding mechanism is perpendicular to the rotation direction of the chuck assembly.

In one embodiment, the second sliding mechanism is provided with an orientation detection unit, which is in communication with the control module for detecting a centerline position of the chuck assembly.

In one embodiment, the first longitudinal axis device comprises a longitudinal moving assembly mounted on the stand, a power assembly slidably connected to the longitudinal moving assembly, and a tool rest assembly detachably mounted on the power assembly, wherein the power assembly drives the tool rest assembly to machine a workpiece.

In an embodiment, the folding device further comprises a first folding shielding component and a second folding shielding component which are slidably connected to the frame, at least a part of the first spindle device penetrates out of the first folding shielding component and is locked with the first folding shielding component, the first folding shielding component is folded or unfolded along with the first spindle device, at least a part of the second spindle device penetrates out of the second folding shielding component and is locked with the second folding shielding component, the second folding shielding component is folded or unfolded along with the second spindle device, a processing space is formed between the first folding shielding component and the second folding shielding component, and the first longitudinal axis device and the second longitudinal axis device are located in the processing space.

In one embodiment, the robot further comprises a mechanical arm device mounted on the frame, wherein the mechanical arm device is positioned above the first spindle device and the second spindle device and used for grabbing and replacing workpieces.

In one embodiment, the robot arm device comprises a head rail assembly, a lifting assembly connected to the head rail assembly in a sliding mode, and a manipulator assembly arranged on the lifting assembly, wherein the manipulator assembly comprises a first station and a second station for respectively grabbing workpieces.

In an embodiment, the mechanical arm device further comprises a feeding assembly arranged on the rack, the feeding assembly and the second spindle device are arranged at intervals, and the mechanical arm device moves between the feeding assembly and the first spindle device.

After adopting the structure, compared with the prior art, the invention has the advantages that: the control module controls at least one of the first spindle device and the second spindle device to process the workpiece, the processing mode is flexible, and the efficiency of the first spindle device and the second spindle device is highest when the workpieces are simultaneously processed. One of the first longitudinal shaft device and the second longitudinal shaft device clamps the workpiece, and the other clamping device is replaced after the machining is finished, so that the automatic clamping and reversing of the workpiece are realized, the machining effect is good, and the efficiency is high.

Drawings

The invention is further illustrated with reference to the following figures and examples:

fig. 1 is a schematic structural diagram of a double-spindle double-Y-axis compound numerical control machine tool of the invention.

Fig. 2 is a schematic cross-sectional structure view of the double-spindle double-Y-axis compound numerical control machine tool of the present invention.

Fig. 3 is a schematic structural diagram of the double-spindle double-Y-axis compound numerical control machine tool with the protective cover removed.

FIG. 4 is a schematic structural diagram of the double-spindle double-Y-axis composite NC machine tool with the protective cover removed, which has a machining space.

FIG. 5 is a schematic view of the first spindle assembly of the present invention mounted to the first foldable shield assembly.

Fig. 6 is a schematic view of the first and second longitudinal shaft assemblies of the present invention mounted to a stand.

Fig. 7 is a schematic structural view of the arm device of the present invention.

Figure 8 is a schematic diagram of the construction of the robot assembly of the present invention.

In the figure: a frame 10; a chassis 11; a stand 12; a first spindle device 20; a first slide mechanism 21; a lead screw nut assembly 211; a slide rail assembly 212; a second slide mechanism 22; a drive assembly 23; a chuck assembly 24; a second spindle device 30; a first longitudinal axis means 40; a longitudinal movement assembly 41; a power assembly 42; a blade carrier assembly 43; a second longitudinal axis means 50; a robot arm device 60; a head rail assembly 61; a lift assembly 62; a robot assembly 63; a mount 631; a turntable mechanism 632; a first station 633; a clamp motor 6331; a clamp chuck 6332; a grip claw 6333; a second station 634; a feeding assembly 70; a first folding shutter member 80; a mounting plate 81; a first folding frame 82; a second folding frame 83; a second folding shutter member 90; a workpiece 100.

Detailed Description

The following description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

As shown in fig. 1 to 3, the present invention discloses a dual spindle dual Y-axis composite numerical control machine, which includes: the device comprises a frame 10, a first spindle device 20, a second spindle device 30, a first vertical shaft device 40, a second vertical shaft device 50 and a control module. The frame 10 is a rigid structure for supporting the various components mounted thereon. The frame 10 includes a base frame 11 and at least one upright 12 fixed to the base frame 11, and a longitudinal direction of the upright 12 intersects a plane in which the base frame 11 is located. Optionally, the base frame 11 and the vertical frame 12 are arranged at a substantially vertical angle, and the vertical frame 12 is in a frame structure and partially protrudes from the upper surface of the base frame 11; alternatively, the stand 12 protrudes laterally from the base frame 11 to form an approximate "L" shaped structure. The vertical frame 12 partially protrudes from the bottom frame 11 to form a columnar structure, and the number of the vertical frame can be set to be one or two.

The first spindle device 20 and the second spindle device 30 are used for clamping the workpiece 100, and the first spindle device 20 and the second spindle device 30 are slidably connected to the base frame 11 to adjust a relative clamping position and a machining position of the workpiece 100. The second spindle device 30 is disposed opposite to the first spindle device 20, so that the workpiece 100 can be selectively clamped between the first spindle device 20 and the second spindle device 30. For example, the first spindle assembly 20 holds a first end of the workpiece 100, and the first and second longitudinal axis assemblies 40 and 50 machine the outer surface and a second end of the workpiece 100. After the second end is machined, the second spindle device 30 and the first spindle device 20 are close to each other, the second spindle device 30 clamps the second end of the workpiece 100, the first spindle device 20 releases the workpiece 100, so that the workpiece 100 is clamped and moved by the second spindle device 30, the first longitudinal axis device 40 and the second longitudinal axis device 50 can conveniently machine the outer surface and the first end of the workpiece 100, manual intervention for loading and unloading assistance of the workpiece 100 is not needed, and machining efficiency and machining precision are improved.

The first longitudinal axis device 40 and the second longitudinal axis device 50 are respectively used for machining the workpiece 100, and are arranged at intervals in the axial direction of the first longitudinal axis device 40. The first longitudinal shaft device 40 and the second longitudinal shaft device 50 are slidably connected to the vertical frame 12, and the first longitudinal shaft device 40 and the second longitudinal shaft device 50 move telescopically along the length direction of the vertical frame 12 so as to adjust different processing positions and achieve flexible processing modes. The second longitudinal axis means 50 is spaced from the first longitudinal axis means 40 in the axial direction of the first spindle means 20, and the first longitudinal axis means 40 and the second longitudinal axis means 50 are located in the region between the first spindle means 20 and the second spindle means 30. The second longitudinal axis device 50 and the first longitudinal axis device 40 can be used for processing independently or processing the workpiece 100 in a coordinated mode, and the use is more flexible. The row tool is mounted on the first longitudinal axis device 40 and the second longitudinal axis device 50 respectively to machine the corresponding machining area of the workpiece 100. For example, the gang tool tools mounted on the first longitudinal axis device 40 and the second longitudinal axis device 50 can be respectively used for drilling, turning, milling and other machining modes.

The control module is in communication connection with the first spindle device 20, the second spindle device 30, the first longitudinal axis device 40 and the second longitudinal axis device 50, respectively, wherein the first longitudinal axis device 40 and/or the second longitudinal axis device 50 machine the workpiece 100 clamped by one of the first spindle device 20 and the second spindle device 30 according to the instruction of the control module. The control module is a central control system of the double-spindle double-Y-axis composite numerical control machine tool and is used for controlling the overall operation of equipment. The control module comprises a keyboard, a touch screen, other output devices and a central control device, so that information interaction is facilitated.

As shown in fig. 1 to 3, the sliding directions of the first longitudinal shaft device 40 and the second longitudinal shaft device 50 are parallel, and the rotation axis of the first spindle device 20 and the rotation axis of the second spindle device 30 are parallel and perpendicular to the sliding direction of the first longitudinal shaft device 40. Alternatively, the sliding plane of the first longitudinal axis means 40 and the sliding plane of the second longitudinal axis means 50 are in the same plane to machine the workpiece 100 at different positions in the direction of the rotation axis of the first spindle means 20. Optionally, the sliding plane of the first longitudinal axis device 40 and the sliding plane of the second longitudinal axis device 50 are in different planes, and both have a height offset distribution, so as to machine the workpiece 100 at different positions and in different height directions in the direction of the rotation axis of the first spindle device 20, further expanding the flexibility of the machining mode.

The first spindle device 20 and the second spindle device 30 respectively clamp the workpiece 100, and the two devices can mutually cooperate to clamp the workpiece 100, so as to form the automatic reversing machining. The rotation axis of the first spindle device 20 and the projection of the rotation axis of the second spindle device 30 on the stand 12 are overlapped, the rotation axis of the first spindle device 20 and the rotation axis of the second spindle device 30 are at the same height, and when the axes of the first spindle device 20 and the second spindle device 30 move to the overlapped position. At least one of the first spindle device 20 and the second spindle device 30 can move close to each other along the rotation axis to form an exchange process of the clamped workpiece 100, and the adjustment is convenient.

The first spindle device 20 and the second spindle device 30 are disposed opposite to each other, and have the same function. The first spindle device 20 is taken as an example for illustration, and the second spindle device 30 can be understood by reference.

In an embodiment, the first spindle device 20 includes a first sliding mechanism 21 mounted on the chassis 11, a second sliding mechanism 22 slidably connected to the first sliding mechanism 21, a driving assembly 23 mounted on the second sliding mechanism 22, and a chuck assembly 24 mounted on the driving assembly 23, a sliding direction of the first sliding mechanism 21 driving the second sliding mechanism 22 is perpendicular to a sliding direction of the second sliding mechanism 22 driving the driving assembly 23, and the sliding direction of the first sliding mechanism 21 is perpendicular to a rotation direction of the chuck assembly 24. The chuck assembly 24 is connected to a driving device, and the driving device can drive the chuck assembly 24 to automatically grasp the workpiece 100 and drive the workpiece 100 to rotate. Wherein the drive device is electrically connected to the control module for controlling the movement of the chuck assembly 24 in response to commands output by the control module.

As shown in fig. 1 to 3, the first sliding mechanism 21 and the second sliding mechanism 22 are position adjusting structures for driving the driving assembly 23 to move, and the sliding directions of the first sliding mechanism 21 and the second sliding mechanism 22 are perpendicular to each other to form a movement approximate to an XY plane, so as to move the chuck assembly 24 to a corresponding processing position, so as to implement the processing of the workpiece 100. Further, the first slide mechanism 21 and the second slide mechanism 22 move to move the chuck assembly 24 to a position coaxial with the chuck mechanism of the second spindle device 30, so that the workpiece 100 held by the chuck assembly 24 is coaxially transferred to the second spindle device 30, and the machining orientation and the machining angle of the workpiece 100 are automatically changed. Alternatively, the second spindle device 30 can also realize XY plane movement to allow flexible adjustment of the machining position of the workpiece 100. Optionally, the first slide mechanism 21 and the second slide mechanism 22 are configured as a screw-nut pair structure to improve the accuracy of the position movement.

It should be noted that the first spindle device 20 and the second spindle device 30 may also have different configurations, such as different chuck configurations, different clamping manners, different driving manners, etc., and may be adjusted by referring to the existing spindle clamping configuration, which is not described herein again.

Optionally, the second slide mechanism 22 is provided with an orientation detection unit in communication with the control module for detecting the centerline position of the chuck assembly 24. The orientation detection unit is used to detect the centerline position of the chuck assembly 24 and, in turn, to precisely control the rotational angle and the moving orientation of the workpiece 100. Optionally, the orientation detection unit is an encoder mounted to the drive device for detecting the centerline position of the chuck assembly 24 for accurate docking. Further, the first slide mechanism 21 and the second slide mechanism 22 are each provided with an encoder for precisely positioning the moving positions of the driving means and the chuck assembly 24. Wherein, the encoders are all in communication connection with the control module. Optionally, both the first sliding mechanism 21 and the second sliding mechanism 22 are configured with a grating displacement sensor, and the grating displacement sensor is in communication connection with the control module and transmits and detects displacement positions in real time, so that the detection precision is high, and the real-time feedback effect is good.

The first slide mechanism 21 and the second slide mechanism 22 are similar in structure, and the first slide mechanism 21 is exemplified. The first sliding mechanism 21 includes a lead screw nut assembly 211 and sliding rail assemblies 212 distributed in parallel at two sides of the lead screw nut assembly 211, and the second sliding mechanism 22 is connected to the lead screw nut assembly 211 and is erected on the sliding rail assemblies 212. The screw nut assembly 211 drives the second sliding mechanism 22 to slide along the sliding rail assembly 212, and the screw nut assembly 211 only bears the driving force of the axis, does not bear the bending force and the torque force, so that the driving stability is good.

As shown in fig. 2 to 4 and 6, the first vertical shaft device 40 and the second vertical shaft device 50 are spaced apart and parallel to each other, and have the same function. The first longitudinal shaft device 40 is taken as an example for illustration, and the second longitudinal shaft device 50 can be understood by reference.

In one embodiment, the first longitudinal axis device 40 comprises a longitudinal moving assembly 41 mounted on the stand 12, a power assembly 42 slidably connected to the longitudinal moving assembly 41, and a carriage assembly 43 detachably mounted on the power assembly 42, wherein the power assembly 42 drives the carriage assembly 43 to process the workpiece 100. The power assembly 42 is coupled to the carriage assembly 43 to move the carriage assembly 43 in accordance with the built-in program to machine a designated area of the workpiece 100. The tool rest assembly 43 can mount a tool setting tool according to different machining requirements, wherein the tool setting tool includes a drill, a milling cutter, a turning tool and other tools for a numerical control machine.

The longitudinal moving assembly 41 drives the power assembly 42 and the tool rest assembly 43 to move telescopically along the stand 12 towards the base frame 11, so as to control the relative position between the tool rest assembly 43 and the workpiece 100. Meanwhile, the first sliding mechanism 21 and the second sliding mechanism 22 control the position of the chuck assembly 24 relative to the tool rest assembly 43, and cooperatively control the processing condition of the workpiece 100, so that the processing mode is flexible.

Optionally, the longitudinal moving assembly 41 includes a lead screw nut assembly 211 and slide rail assemblies 212 distributed in parallel on two sides of the lead screw nut assembly 211, and the power assembly 42 is provided with a base connected to the nut member of the lead screw nut assembly 211 and mounted on the slide rail assemblies 212. The screw nut assembly 211 drives the power assembly 42 to slide along the sliding rail assembly 212, and the screw nut assembly 211 only bears the driving force of an axis and does not bear bending force and torque force, so that the driving stability is good.

Optionally, a blocking wall frame is mounted on the base and covers the sliding rail assembly 212 to prevent foreign objects from falling into a movable gap between the sliding rail assembly 212 and the base, so that the protection effect is good.

As shown in fig. 2, fig. 4 and fig. 5, the dual-spindle dual-Y-axis composite numerical control machine further includes a first folding shielding component 80 and a second folding shielding component 90 slidably connected to the frame 10, the first folding shielding component 80 and the second folding shielding component 90 are foldable partition structures, the first folding shielding component 80 and the second folding shielding component 90 are oppositely disposed, a processing space is formed between the first folding shielding component 80 and the second folding shielding component 90, and the first longitudinal axis device 40 and the second longitudinal axis device 50 are located in the processing space. The first and second

folding shutter members

80 and 90 may be folded in an advancing direction of a sliding direction of the frame 10 and unfolded in the other direction.

At least a part of the first spindle device 20 penetrates through the first foldable shielding component 80 and is locked with the first foldable shielding component 80, and the first foldable shielding component 80 is folded or unfolded along with the first spindle device 20. The housing or the base of the driving assembly 23 of the first spindle device 20 is locked and connected to the first folding shielding assembly 80, so that the chuck assembly 24 passes through the first folding shielding assembly 80 and enters the processing space, and the other parts are located outside the processing space, thereby preventing the debris and impurities generated in the processing process from entering the moving areas of the first sliding mechanism 21 and the second sliding mechanism 22, stabilizing the operation environment, and further improving the moving precision and the processing precision of the first spindle device 20.

At least a part of the second spindle device 30 passes through the second folding screen assembly 90 and is locked with the second folding screen assembly 90, and the second folding screen assembly 90 is folded or unfolded along with the second spindle device 30. The connection structure and function of the second spindle device 30 and the second foldable shielding assembly 90 are substantially the same as the connection structure and function of the first spindle device 20 and the first foldable shielding assembly 80, and it can be understood by referring to the connection structure and function of the first spindle device 20 and the first foldable shielding assembly 80, and will not be described herein again.

The first folding shutter member 80 includes a mounting plate 81 sliding on the base frame 11, a first folding bracket 82 fixed to one side of the mounting plate 81, and a second folding bracket 83 fixed to the other side of the mounting plate 81, and the first spindle unit 20 is fixed to the mounting plate 81. The first folding frame 82 includes two or more first folding plates that slide on the base frame 11 and can be folded or unfolded with respect to each other. The second folding frame 83 includes two or more second folding plates that slide on the bottom frame 11 and can be folded or unfolded with respect to each other. The first folding frame 82 and the second folding frame 83 have opposite moving directions, so that the first folding shielding assembly 80 can always keep a shielding state in the sliding process of the first spindle device 20, and the isolation effect is good.

As shown in fig. 1 to 2, 7 and 8, the first spindle device 20 and the second spindle device 30 can clamp the workpiece 100, and the workpiece 100 may be manually or by a robot. In one embodiment, the dual spindle and dual Y-axis composite numerical control machine further includes a robot device 60 mounted on the frame 10, wherein the robot device 60 is located above the first spindle device 20 and the second spindle device 30 for grabbing and replacing the workpiece 100. The robot arm device 60 is used for automatically loading the workpiece 100 to be machined on the first spindle device 20 or the second spindle device 30; and/or, the robot arm device 60 is used to remove the workpiece 100 processed by the first spindle device 20 or the second spindle device 30 from the processing space, so as to facilitate the processing operation of the next workpiece 100 to be processed. It should be noted that the first spindle device 20 and the second spindle device 30 can alternately clamp the workpiece 100 to improve the processing efficiency.

In an alternative embodiment, the robot arm assembly 60 includes a head rail assembly 61, a lifting assembly 62 slidably coupled to the head rail assembly 61, and a robot assembly 63 mounted to the lifting assembly 62, wherein the robot assembly 63 includes a first station 633 and a second station 634 for respectively grasping the workpiece 100. The ceiling rail assembly 61 is positioned above the processing space, and the lifting assembly 62 moves along the ceiling rail assembly 61 and can move into or out of the processing space to adjust the robot assembly 63 to different working positions. Wherein the first station 633 and the second station 634 of the robot assembly 63 can respectively clamp or release the workpiece 100, so as to realize automatic clamping and positioning. Alternatively, the first station 633 and the second station 634 may be rotated relative to each other to adjust one of them to clamp the workpiece 100 to the first spindle device 20 or the second spindle device 30, and the other to remove the workpiece 100 that has been machined by the first spindle device 20 or the second spindle device 30.

In an alternative embodiment, the robot assembly 63 includes a mounting base 631, a turntable mechanism 632 mounted to the mounting base 631, and a first station 633 and a second station 634 mounted to the turntable mechanism 632 and rotationally switched by the turntable mechanism 632. Alternatively, the turntable mechanism 632 is configured as a pneumatic turntable or a hydraulic turntable. The first station 633 and the second station 634 are substantially identical in structure, and the first station 633 is taken as an example for illustration.

The first station 633 comprises a clamping motor 6331, a clamping chuck 6332 mounted on the clamping motor 6331, and two or more clamping jaws 6333 mounted on the clamping chuck 6332, wherein the clamping motor 6331 drives the clamping jaws 6333 to close up to clamp the workpiece 100; alternatively, the clamp motor 6331 drives the clamp jaws 6333 to spread apart to release the workpiece 100. Further, the grip motor 6331 is provided with a position sensor for determining the grip angle and the grip range of the grip claw 6333. Optionally, the clamping motor 6331 is provided with an encoder, which is in communication with the control module for determining the clamping angle and the clamping range of the clamping jaw 6333. Optionally, the clamp motor 6331 is provided with a camera assembly communicatively coupled to the control module for capturing the workpiece 100 and transmitting image information to the control module. The control module adjusts the clamping angle of the clamping jaw 6333 according to the image information of the workpiece 100, so that the workpiece 100 is accurately clamped, and the clamping device is suitable for clamping the special-shaped workpiece 100.

As shown in fig. 1 and 2, the dual spindle dual Y-axis composite numerical control machine further includes a feeding assembly 70 disposed on the machine frame 10, the feeding assembly 70 is spaced apart from the second spindle device 30, and the robot arm device 60 moves between the feeding assembly 70 and the first spindle device 20. The loading assembly 70 is located at one side of the frame 10 for carrying a workpiece 100 to be processed. The mechanical arm device 60 reciprocates between the feeding assembly 70 and the first spindle device 20 to grab or place the workpiece 100, and the automatic operation effect is good.

Optionally, the frame 10 is provided with a protective cover distributed around the base frame 11 to form a closed processing environment. The second spindle device 30 is located between the first spindle device 20 and the feeding assembly 70, and the feeding assembly 70 is located between the second folded shielding assembly 90 and the wall surface of the one-side shield. Optionally, the feeding assembly 70 includes a conveyor assembly to move the workpiece 100. Optionally, the feeding assembly 70 includes a moving assembly and a tray platform connected to the moving assembly, and the tray platform adjusts the placing position of the workpiece 100 along with the movement of the moving assembly. Optionally, the moving assembly is formed by combining a screw nut assembly, a hydraulic cylinder assembly, a cylinder assembly and other power assemblies with a guide rail.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention. Other structures and principles are the same as those of the prior art, and are not described in detail herein.

Claims

1. The utility model provides a compound digit control machine tool of two Y axles of two main shafts which characterized in that includes:

2. The compound numerical control machine tool of claim 1, characterized in that the sliding directions of said first longitudinal axis means and said second longitudinal axis means are parallel, and the rotation axis of said first spindle means and the rotation axis of said second spindle means are parallel and perpendicular to the sliding direction of said first longitudinal axis means.

3. The compound numerically-controlled machine tool with double spindles and double Y-axes as claimed in claim 1, wherein the projection of the rotation axis of the first spindle device and the projection of the rotation axis of the second spindle device on the stand coincide, and at least one of the first spindle device and the second spindle device can move close to each other along the rotation axis.

4. The dual-spindle dual-Y-axis compound numerical control machine tool according to claim 3, wherein the first spindle device comprises a first sliding mechanism mounted on the base frame, a second sliding mechanism slidably connected to the first sliding mechanism, a driving assembly mounted on the second sliding mechanism, and a chuck assembly mounted on the driving assembly, the sliding direction of the first sliding mechanism driving the second sliding mechanism is perpendicular to the sliding direction of the second sliding mechanism driving the driving assembly, and the sliding direction of the first sliding mechanism is perpendicular to the rotating direction of the chuck assembly.

5. The compound numerical control machine tool of claim 4, characterized in that the second sliding mechanism is provided with an orientation detection unit, which is in communication connection with the control module for detecting the centerline position of the chuck assembly.

6. The compound numerically-controlled machine tool with double spindles and double Y axes as claimed in claim 1, wherein the first longitudinal axis device comprises a longitudinal moving assembly mounted on the stand, a power assembly slidably connected to the longitudinal moving assembly, and a tool rest assembly detachably mounted on the power assembly, and the power assembly drives the tool rest assembly to machine a workpiece.

7. The compound digit control machine tool of two Y axle of two main shafts of claim 1, characterized in that still include sliding connection in the first of frame is folded and is sheltered from the subassembly and fold the subassembly with the second and shelter from the subassembly, at least part the first spindle unit wear out the first folding and shelter from the subassembly and lock with the first folding and shelter from the subassembly, the first folding is sheltered from the subassembly along with first spindle unit is folded or is expanded, at least part the second spindle unit wear out the second is folded and is sheltered from the subassembly and lock with the second is folded and shelter from the subassembly, the second is folded and is sheltered from the subassembly along with the second spindle unit is folded or is expanded, form processing space between first folding and sheltered from the subassembly, first axis of ordinates device and second axis of ordinates device are located in the processing space.

8. The compound numerical control machine tool of claim 1, further comprising a robot arm device mounted on the frame, the robot arm device being located above the first spindle device and the second spindle device for grasping and replacing a workpiece.

9. The compound numerical control machine tool with double spindles and double Y-axes of claim 8 is characterized in that the mechanical arm device comprises a sky rail assembly, a lifting assembly connected with the sky rail assembly in a sliding mode and a mechanical arm assembly arranged on the lifting assembly, and the mechanical arm assembly comprises a first station and a second station which respectively grab workpieces.

10. The compound digit control machine tool of claim 8, characterized in that, further includes a material loading assembly disposed on the frame, the material loading assembly and the second spindle device are disposed at an interval, the mechanical arm device moves between the material loading assembly and the first spindle device.