CN217832728U - Processing device - Google Patents

Abstract

The utility model provides a processing device, include: a processing platform; a carrier assembly, comprising: the rotating piece is arranged on the processing platform and connected to the processing platform; the first bearing piece is rotationally connected with the rotating piece, bears the workpiece and is driven by the rotating piece to rotate; the positioning piece is arranged on the first bearing piece to position the workpiece; the pressing assembly comprises a pressing driving piece and a pressing piece, the pressing driving piece is arranged on the processing platform and is positioned on one side of the first bearing piece, the pressing piece is arranged above the first bearing piece, and the pressing driving piece drives the pressing piece to move towards the bearing assembly so as to clamp a workpiece; and the processing assembly is arranged above the pressing piece. First carrier bears work piece and setting element location work piece to compress tightly the work piece in first carrier through compressing tightly, realize fixed to the stability of work piece, improved processingequipment's machining precision, drive first carrier through rotating the piece and rotate, with the adjustment work piece treat the machining position, improved processingequipment's machining efficiency.

Description

Processing device

Technical Field

The utility model relates to an automatic processing equipment technical field especially relates to a processingequipment.

Background

At present, people have higher and higher requirements on the precision of workpieces, so when a CNC machining machine platform machines the workpieces, the CNC machining machine platform needs to stably bear the workpieces through a machining device, and the CNC machining machine platform can accurately machine the workpieces.

The existing machining device bears a workpiece through a bearing platform and penetrates through a connecting hole of the workpiece through a positioning column to perform rough positioning on the workpiece borne by the bearing platform, so that a CNC machining machine platform can accurately machine the workpiece. However, since the size and weight of different workpieces are different greatly, the position of the workpiece is often difficult to be stably positioned, and when the different positions of the workpiece need to be machined, the position of the workpiece needs to be adjusted and corrected by an operator, and then the workpiece is machined, which reduces the machining efficiency of the workpiece.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide a processing apparatus to solve the technical problem of low processing efficiency of the processing apparatus.

The utility model provides a processing device, include: a processing platform; a carrier assembly, comprising: the rotating part is arranged on the processing platform, and one end of the rotating part is connected to the processing platform; the first bearing piece is rotationally connected to the other end of the rotating piece and is used for bearing a workpiece and driven by the rotating piece to rotate; the positioning piece is arranged on the first bearing piece and matched with the first bearing piece to position the workpiece; the pressing component comprises a pressing driving part and a pressing part, the pressing driving part is arranged on the processing platform and is positioned on one side of the first bearing part, the pressing part is arranged above the first bearing part, and the pressing driving part is connected with the pressing part and is used for driving the pressing part to move towards the bearing component so as to be matched with the bearing component to clamp and fix the workpiece on the first bearing part; and the processing assembly is arranged above the pressing piece and used for processing the workpiece on the first bearing piece.

In some embodiments, the pressing member is provided with a first processing hole and a second processing hole, and the processing assembly processes the workpiece on the first bearing member through the first processing hole and the second processing hole.

In some embodiments, the compression assembly further comprises: the supporting piece is arranged on the processing platform and located on one side of the rotating piece, the pressing driving piece is connected to the supporting piece, and the pressing piece is arranged above the supporting piece.

In some embodiments, the support comprises: the lower supporting piece is arranged on the processing platform and positioned on one side of the rotating piece, and the lower supporting piece is connected to the processing platform; the connecting piece is arranged on the lower supporting piece and connected to the lower supporting piece; the upper supporting piece is arranged between the connecting piece and the pressing piece and connected to the connecting piece, the pressing driving piece is arranged between the upper supporting piece and the lower supporting piece, and the output end of the pressing driving piece penetrates through the upper supporting piece and is connected with the pressing piece.

In some embodiments, the processing platform comprises: the rotating piece and the supporting piece are arranged on the second bearing piece; the first shifting assembly is arranged below the second bearing piece and is connected with the second bearing piece in a sliding mode along a first direction; the second moves and carries the assembly, locate the said first moves and carries the assembly below, and move and carry the assembly with the said first one and carry the assembly along the second direction sliding connection perpendicular to the said first direction.

In some embodiments, the first transfer assembly comprises: the second bearing piece is arranged on the first bearing piece; the first sliding rail is arranged above the first carrying piece and is connected with the second carrying piece in a sliding manner; and the first shifting driving part is arranged below the second bearing part and connected with the second bearing part so as to drive the second bearing part to reciprocate along the first direction.

In some embodiments, the second transfer assembly comprises: the first transfer part is arranged on the second transfer part; the second sliding rail is arranged above the second transferring piece and is connected with the first transferring piece in a sliding manner; and the second transfer driving part is arranged below the first transfer part and connected with the first transfer part so as to drive the first transfer part to reciprocate along the second direction.

In some embodiments, the processing device further comprises: the guide piece is arranged between the support piece and the pressing piece, one end of the guide piece is connected with the support piece in a sliding mode, the other end of the guide piece is connected with the pressing piece, and the guide piece is used for guiding the movement of the pressing piece.

In some embodiments, the processing assembly comprises: the third transfer piece is arranged above the bearing assembly; and the machining tool is connected below the third transfer part and is driven by the third transfer part to move to a machining position to machine the workpiece on the bearing assembly.

In some embodiments, the processing device further comprises: and the cooling liquid pipeline is arranged above the pressing piece and connected to the third transfer piece, and the cooling liquid pipeline is used for transmitting cooling liquid to the pressing piece so as to cool the machining cutter.

Among the above-mentioned processingequipment, first carrier bears the work piece and the work piece that first carrier born is fixed a position to the setting element compresses tightly the work piece in first carrier through compressing tightly, realizes fixed to the work piece, so that processing subassembly processing work piece, drive first carrier through rotating the piece and rotate, treat the processing position with the automatic adjustment work piece. Therefore, the pressing piece is matched with the rotating piece to realize the fixation of the workpiece and the automatic adjustment of the machining position, and the machining efficiency of the machining device is improved.

Drawings

Fig. 1 is a schematic perspective view of a processing apparatus provided by an embodiment of the present invention.

Fig. 2 is a schematic perspective view of the processing platform, the pressing assembly and the guiding member shown in fig. 1.

Fig. 3 is an exploded view of the processing platform, hold down assembly and guide shown in fig. 2.

Fig. 4 is a schematic perspective view of the processing platform shown in fig. 1.

Fig. 5 is a partially enlarged view of the processing apparatus shown in fig. 1.

Description of the main elements

Machining apparatus 100

Machining platform 10

Second bearing part 11

First transfer assembly 12

The first transfer member 121

First slide rail 122

First transfer driving member 123

Second transfer unit 13

Second transfer member 131

Second slide rail 132

Second transfer drive unit 133

Load bearing assembly 20

Rotor 21

First carrier 22

Positioning piece 23

Compression assembly 30

Compression drive 31

Pressing member 32

First machining hole 321

Second machining hole 322

Pressing part 323

Abutting portion 324

Processing tank 325

Support 33

Lower support 331

Connecting piece 332

Upper support 333

Tooling assembly 40

Third transfer member 41

Machining tool 42

Guide 50

Coolant line 60

Workpiece 200

Emptying hole 201

Cooling hole 202

Positioning hole 203

Detailed Description

The present application, however, should not be limited to the details given herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict. In the following description, numerous specific details are set forth to provide a thorough understanding of the present application, and the described embodiments are merely a subset of the embodiments of the present application and are not intended to be a complete embodiment.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

It will be evident to those skilled in the art that the application is not limited to the details of the foregoing illustrative embodiments, and that the present application may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

When the CNC machine station is used for machining workpieces, due to the fact that the sizes and weight differences of different workpieces are large, the positions of the workpieces are usually difficult to stably position, and when different positions of the workpieces need to be machined, operators are required to adjust and correct the positions of the workpieces, then the workpieces are machined, and machining efficiency of the workpieces is reduced.

An embodiment of the utility model provides a processingequipment is applied to CNC processing board, and processingequipment includes: a processing platform; a carrier assembly, comprising: the rotating part is arranged on the processing platform, and one end of the rotating part is connected to the processing platform; the first bearing piece is rotationally connected to the other end of the rotating piece and is used for bearing a workpiece and driven by the rotating piece to rotate; the positioning piece is arranged on the first bearing piece and matched with the first bearing piece to position the workpiece; the pressing assembly comprises a pressing driving piece and a pressing piece, the pressing driving piece is arranged on the processing platform and is positioned on one side of the first bearing piece, the pressing piece is arranged above the first bearing piece, and the pressing driving piece is connected with the pressing piece and is used for driving the pressing piece to move towards the bearing assembly so as to be matched with the bearing assembly to clamp and fix the workpiece on the first bearing piece; and the processing assembly is arranged above the pressing piece and used for processing the workpiece on the first bearing piece.

Among the above-mentioned processingequipment, first carrier bears the work piece and the first work piece that bears carrier of setting element location to compress tightly the work piece in first carrier through compressing tightly, realize fixing the work piece, so that processing subassembly processing work piece, drive first carrier through rotating the piece and rotate, treat the processing position with the automatic adjustment work piece. Therefore, the pressing piece is matched with the rotating piece to realize the fixation of the workpiece and the automatic adjustment of the machining position, and the machining efficiency of the machining device is improved.

The embodiments of the present invention will be further explained with reference to the drawings.

Referring to fig. 1, in some embodiments, a processing apparatus 100 includes a processing platform 10, a carrier assembly 20, a pressing assembly 30, and a processing assembly 40.

In the present embodiment, the bearing assembly 20 includes a rotating member 21, a first bearing member 22 and a positioning member 23. The rotating member 21 is disposed on the processing platform 10, one end of the rotating member 21 is connected to the processing platform 10, the first bearing member 22 is rotatably connected to the other end of the rotating member 21, and the first bearing member 22 can be configured to be matched with the size of the workpiece 200, so that the first bearing member 22 can bear the workpiece 200 more stably. The positioning element 23 is disposed on the first supporting element 22, and is matched with the first supporting element 22 to position the workpiece 200, and the rotating element 21 drives the first supporting element 22 to rotate, so as to adjust the position of the workpiece 200 carried by the first supporting element 22, in an embodiment, the workpiece 200 is provided with a connecting hole (not shown), the positioning element 23 is disposed in the connecting hole in a penetrating manner, and is then matched with the first supporting element 22 to position the workpiece 200, so that when the workpiece 200 is placed on the first supporting element 22, the positioning element 23 is disposed in the connecting hole in a penetrating manner and is matched with the first supporting element 22 to position the workpiece 200, so that the first supporting element 22 stably supports the workpiece 200.

Further, the compression assembly 30 includes a compression drive 31 and a compression member 32. The pressing driving member 31 is disposed on the processing platform 10 and located at one side of the first carrying member 22, and the pressing member 32 is disposed above the first carrying member 22 and connected to the pressing driving member 31. In this way, the pressing driving member 31 drives the pressing member 32 to move toward the first bearing member 22, and the pressing member 32 presses the upper surface of the workpiece 200 and cooperates with the first bearing member 22 to clamp and fix the workpiece 200 on the first bearing member 22, so as to achieve stable fixation of the workpiece 200.

The processing assembly 40 is movably disposed above the pressing member 32, and after the pressing member 32 and the first bearing member 22 clamp and fix the workpiece 200, the processing assembly 40 moves above the workpiece 200 and processes the workpiece 200.

In some embodiments, the compression drive 31 may be a pneumatic cylinder.

In the processing apparatus 100, the workpiece 200 to be processed is placed on the first carrier 22, and the positioning element 23 and the first carrier 22 cooperate with each other to stably carry the workpiece 200; meanwhile, the pressing driving element 31 can drive the pressing element 32 to move towards the first bearing element 22, and the pressing element 32 and the first bearing element 22 cooperate with each other to clamp and fix the workpiece 200, so that the workpiece 200 is stably fixed on the first bearing element 22; then the processing assembly 40 moves to the upper part of the workpiece 200, processes the clamped and fixed workpiece 200, then the pressing driving member 31 drives the pressing member 32 to move away from the first bearing member 22 to release the workpiece 200, the rotating member 21 drives the first bearing member 22 to rotate, and the position to be processed of the workpiece 200 carried by the first bearing member 22 is adjusted, so as to achieve automatic adjustment of the position to be processed of the workpiece 200; finally, the machining assembly 40 moves to the position above the workpiece 200, and the adjusted workpiece 200 is machined, so that the machining assembly 40 can completely machine the workpiece 200, and the machining efficiency is improved.

Referring to fig. 2 and 3, in some embodiments, the pressing member 32 further includes a first processing hole 321 and a second processing hole 322, and the first processing hole 321 and the second processing hole 322 are disposed at intervals along a direction from the pressing member 32 to the positioning member 23 and respectively correspond to the discharge hole 201 and the cooling hole 202 of the workpiece 200.

In this way, after the pressing member 32 and the first carrier 22 cooperate with each other to clamp and fix the workpiece 200, the machining assembly 40 machines the workpiece 200 through the first machining hole 321 and the second machining hole 322, so that the workpiece 200 forms the discharge hole 201 and the cooling hole 202, wherein the size of the cooling hole 202 is the same as that of the first machining hole 321, the size of the discharge hole 201 is the same as that of the second machining hole 322, and the first machining hole 321 and the second machining hole 322 define a machining area of the machining assembly 40, thereby improving the machining precision. In some implementations, the shape and size of the first and second machining holes 321 and 322 are not limited thereto, and may be adjusted depending on the type of the workpiece 200.

In some embodiments, the pressing member 32 includes a pressing portion 323 and an abutting portion 324. The pressing portion 323 is disposed above the first supporting member 22 and connected to the pressing driving member 31, so that the pressing driving member 31 drives the pressing portion 323 to move toward the first supporting member 22, the pressing portion 323 presses the upper surface of the workpiece 200, and the two abutting portions 324 move and abut against the periphery of the positioning member 23 under the driving of the pressing portion 323, so that the pressing portion 323 and the first supporting member 22 cooperate with each other to stably clamp the workpiece 200, thereby avoiding the workpiece 200 from shaking, enabling the processing assembly 40 to stably process the workpiece 200, and improving the processing precision.

In some embodiments, two abutting portions 324 are provided, two abutting portions 324 are spaced apart from each other in a direction perpendicular to the direction from the pressing member 32 to the positioning member 23, and the two abutting portions 324 are connected to an end of the pressing portion 323 away from the pressing driving member 31.

In some embodiments, the pressing portion 323 and the two abutting portions 324 form a processing groove 325, and the processing groove 325 corresponds to the positioning hole 203 of the workpiece 200.

In this way, when the pressing member 32 presses the workpiece 200 on the first carrier 22, the processing assembly 40 processes the workpiece 200 through the processing groove 325, so that the positioning hole 203 is formed on the surface of the workpiece 200, wherein the size of the processing groove 325 is the same as that of the positioning hole 203, and the processing groove 325 defines a processing area of the processing assembly 40, thereby improving the processing precision. In some embodiments, the shape and size of the machining tank 325 is not limited thereto, and may be adjusted depending on the type of the workpiece 200.

In some embodiments, the pressing assembly 30 further includes a supporting member 33, the supporting member 33 is disposed on the processing platform 10 and located at one side of the rotating member 21, the pressing driving member 31 is connected to the supporting member 33, and the pressing member 32 is disposed above the supporting member 33, the supporting member 33 is used for supporting the pressing driving member 31, so that the pressing driving member 31 stably drives the pressing member 32 to move.

In the present embodiment, the supporting member 33 includes a lower supporting member 331, two connecting members 332 and an upper supporting member 333. The lower supporting member 331 is disposed on the processing platform 10, the lower supporting member 331 is located at one side of the rotating member 21 and connected to the processing platform 10, the two connecting members 332 are disposed on the lower supporting member 331 at intervals and connected to the lower supporting member 331, and the upper supporting member 333 is disposed between the connecting member 332 and the pressing member 32 and respectively connected to the two connecting members 332.

Thus, the pressing driving member 31 is disposed between the upper supporting member 333 and the lower supporting member 331, and the output end of the pressing driving member 31 passes through the upper supporting member 333 and is connected to the pressing member 32, so that the supporting member 33 stably supports the pressing driving member 31, the pressing driving member 31 stably drives the pressing member 32 to move, the pressing member 32 is prevented from shifting, and the pressing member 32 stably presses the workpiece 200 on the first supporting member 22.

In some embodiments, the processing device 100 further includes a guiding element 50, the guiding element 50 is disposed between the supporting element 33 and the pressing element 32, one end of the guiding element 50 is slidably connected to the supporting element 33, and the other end of the guiding element 50 is connected to the pressing element 32.

In this way, when the pressing member 32 is driven by the pressing driving member 31 to move toward the first bearing member 22, the guiding member 50 is used for guiding the movement of the pressing member 32, so that the pressing member 32 can stably press the workpiece 200 carried by the first bearing member 22, thereby improving the clamping stability.

Referring to fig. 4, in some embodiments, the processing platform 10 includes a second carrier 11, a first transfer assembly 12 and a second transfer assembly 13. The rotating member 21 and the supporting member 33 are disposed on the second carrying member 11, the first transferring assembly 12 is disposed below the second carrying member 11, the first transferring assembly 12 and the second carrying member 11 are slidably connected along a first direction, the second transferring assembly 13 is disposed below the first transferring assembly 12, and the second transferring assembly 13 and the first transferring assembly 12 are slidably connected along a second direction perpendicular to the first direction.

In the present embodiment, the first direction is a moving direction of the second carrier 11, i.e. a direction of an X axis in fig. 4, and the second direction is a moving direction of the first transfer unit 12, i.e. a direction of a Y axis in fig. 4.

Thus, the second bearing component 11 drives the rotating component 21 to move along the first direction to adjust the position of the workpiece 200 in the first direction, the first transferring component 12 drives the second bearing component 11 to move along the second direction to adjust the position of the workpiece 200 in the second direction, and the second bearing component 11, the first transferring component 12 and the second transferring component 13 cooperate with each other to adjust the position of the workpiece 200, so that the processing component 40 accurately processes the workpiece 200, and the processing precision of the processing device 100 is improved.

In the present embodiment, the first transferring assembly 12 includes a first transferring member 121, a first slide rail 122 and a first transferring driving member 123. The second carrying component 11 is disposed on the first transferring component 121, the first slide rail 122 is disposed above the first transferring component 121 and extends along the first direction, the first slide rail 122 is slidably connected to the second carrying component 11, the first transferring driving component 123 is disposed below the second carrying component 11 and connected to the second carrying component 11, and the first transferring driving component 123 is configured to drive the second carrying component 11 to reciprocate along the first direction.

In this way, the first transfer driving element 123 drives the second carrier 11 to move on the first slide rail 122 along the first direction, so as to adjust the position of the workpiece 200 in the first direction, so that the processing assembly 40 accurately processes the workpiece 200. In some embodiments, the first transfer drive 123 may be a pneumatic cylinder.

In the present embodiment, the second transferring assembly 13 includes a second transferring member 131, a second slide rail 132 and a second transferring driving member 133. The first transfer member 121 is disposed on the second transfer member 131, the second slide rail 132 is disposed above the second transfer member 131 and extends along the second direction, the second slide rail 132 is slidably connected to the first transfer member 121, and the second transfer driving member 133 is disposed below the first transfer member 121 and connected to the first transfer member 121 to drive the first transfer member 121 to reciprocate along the second direction.

In this way, the second transfer driving member 133 drives the first transfer member 121 to move in the second direction on the second slide rail 132 to adjust the position of the workpiece 200 in the second direction, so that the processing assembly 40 accurately processes the workpiece 200.

In some embodiments, the second transfer drive 133 may be a pneumatic cylinder.

Referring to fig. 5, in some embodiments, the processing assembly 40 includes a third transfer member 41 and a processing tool 42. The third transfer member 41 is disposed above the first carrier 22, and the machining tool 42 is disposed between the third transfer member 41 and the first carrier 22 and connected below the third transfer member 41.

In this way, the machining tool 42 is driven by the third transfer member 41 to move to the machining position, which is located in the first machining hole 321 and the second machining hole 322 of the pressing member 32 in some embodiments, and machines the workpiece 200 carried on the first carrier 22, so that the workpiece 200 forms the discharge hole 201 and the cooling hole 202 through the first machining hole 321 and the second machining hole 322 by the machining tool 42.

In some embodiments, the processing apparatus 100 further includes a cooling fluid conduit 60, and the cooling fluid conduit 60 is disposed above the pressing member 32 and connected to the third transfer member 41. Since the machining tool 42 generates a large amount of cutting heat during the machining process of the workpiece 200, in order to prevent the cutting heat from damaging the machining tool 42 and prevent the position of the workpiece 200 to be machined from being deformed due to the cutting heat, the coolant pipe 60 transmits coolant to the pressing member 32 to cool the machining tool 42, thereby preventing the machining tool 42 from being damaged.

The working process of the processing apparatus 100 described above is: the pressing member 32 is driven by the pressing driving member 31 to move away from the first carrier 22, the workpiece 200 to be machined is placed on the first carrier 22, the positioning member 23 is arranged in the connecting hole of the workpiece 200 in a penetrating manner to position the workpiece 200 carried by the first carrier 22, then the pressing driving member 31 drives the pressing portion 323 to move towards the first carrier 22, the pressing portion 323 presses the upper surface of the workpiece 200, the abutting portion 324 abuts against the periphery of the positioning member 23, so that the pressing member 32 and the first carrier 22 are matched with each other to stably clamp and fix the workpiece 200, then the third carrier 41 drives the machining tool 42 to move above the workpiece 200 to machine the clamped and fixed workpiece 200, then the pressing driving member 31 drives the pressing member 32 to move away from the first carrier 22 to release the workpiece 200, the rotating member 21 drives the first carrier 22 to rotate to adjust the position of the workpiece 200 carried by the first carrier 22, the pressing member 32 presses the workpiece 200 tightly, and finally the machining assembly 40 moves above the workpiece 200 to machine the adjusted workpiece 200. In some embodiments, the machining tool 42 may machine the workpiece 200 through the first machining hole 321 and the second machining hole 322.

In the processing device 100, the first bearing part 22 bears the workpiece 200, the positioning part 23 positions the workpiece 200 borne by the first bearing part 22, and the workpiece 200 is pressed on the first bearing part 22 through the pressing part 32, so that the workpiece 200 is stably fixed, the processing assembly 40 accurately processes the workpiece 200, the processing precision of the processing device 100 is improved, the first bearing part 22 is driven to rotate through the rotating part 21, the position to be processed of the workpiece 200 is adjusted, the position to be processed of the workpiece 200 is prevented from being manually adjusted, and the processing efficiency of the processing device 100 is improved.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present application and not for limiting, and although the present application is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present application without departing from the spirit and scope of the technical solutions of the present application.

Claims (10)

1. A processing apparatus, comprising:

a processing platform;

a carrier assembly, comprising:

the rotating part is arranged on the processing platform, and one end of the rotating part is connected to the processing platform;

the first bearing piece is rotationally connected to the other end of the rotating piece and is used for bearing a workpiece and driven by the rotating piece to rotate;

the positioning piece is arranged on the first bearing piece and matched with the first bearing piece to position the workpiece;

the pressing component comprises a pressing driving part and a pressing part, the pressing driving part is arranged on the processing platform and is positioned on one side of the first bearing part, the pressing part is arranged above the first bearing part, and the pressing driving part is connected with the pressing part and is used for driving the pressing part to move towards the bearing component so as to be matched with the bearing component to clamp and fix the workpiece on the first bearing part; and

and the processing assembly is arranged above the pressing piece and used for processing the workpiece on the first bearing piece.

2. The processing apparatus as claimed in claim 1,

the pressing piece is provided with a first processing hole and a second processing hole, and the processing assembly penetrates through the first processing hole and the second processing hole to process a workpiece positioned on the first bearing piece.

3. The tooling apparatus of claim 1 wherein the hold-down assembly further comprises:

the supporting piece is arranged on the processing platform and located on one side of the rotating piece, the pressing driving piece is connected to the supporting piece, and the pressing piece is arranged above the supporting piece.

4. The processing apparatus as set forth in claim 3, wherein the support member comprises:

the lower supporting piece is arranged on the processing platform and positioned on one side of the rotating piece, and the lower supporting piece is connected to the processing platform;

the connecting piece is arranged on the lower supporting piece and connected to the lower supporting piece;

the upper supporting piece is arranged between the connecting piece and the pressing piece and connected to the connecting piece, the pressing driving piece is arranged between the upper supporting piece and the lower supporting piece, and the output end of the pressing driving piece penetrates through the upper supporting piece and is connected with the pressing piece.

5. The processing apparatus as set forth in claim 3, wherein the processing platform comprises:

the rotating piece and the supporting piece are arranged on the second bearing piece;

the first shifting assembly is arranged below the second bearing piece and is connected with the second bearing piece in a sliding mode along a first direction;

the second moves and carries the assembly, locate the said first moves and carries the assembly below, and move and carry the assembly with the said first one and carry the assembly along the second direction sliding connection perpendicular to the said first direction.

6. The processing apparatus as claimed in claim 5, wherein the first transfer unit comprises:

the second bearing piece is arranged on the first bearing piece;

the first sliding rail is arranged above the first load-moving piece and is connected with the second load-bearing piece in a sliding manner; and

and the first transfer driving part is arranged below the second bearing part and connected to the second bearing part so as to drive the second bearing part to reciprocate along the first direction.

7. The processing apparatus as claimed in claim 6, wherein the second transfer unit comprises:

the first transfer piece is arranged on the second transfer piece;

the second sliding rail is arranged above the second transferring piece and is connected with the first transferring piece in a sliding manner; and

and the second transfer driving part is arranged below the first transfer part and connected with the first transfer part so as to drive the first transfer part to reciprocate along the second direction.

8. The processing apparatus as set forth in claim 5, wherein the processing apparatus further comprises:

the guide piece is arranged between the support piece and the pressing piece, one end of the guide piece is connected with the support piece in a sliding mode, the other end of the guide piece is connected with the pressing piece, and the guide piece is used for guiding the movement of the pressing piece.

9. The processing device of claim 1, wherein the processing assembly comprises:

the third transfer piece is arranged above the bearing assembly;

and the machining tool is connected below the third transfer part and is driven by the third transfer part to move to a machining position to machine the workpiece on the bearing assembly.

10. The processing apparatus as set forth in claim 9, wherein the processing apparatus further comprises:

and the cooling liquid pipeline is arranged above the pressing piece and connected to the third transfer piece, and the cooling liquid pipeline is used for transmitting cooling liquid to the pressing piece so as to cool the machining cutter.

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