CN115122140B - Transition device and method for precisely machining hybrid mold of automobile part - Google Patents

Abstract

The application relates to a transition device of a precision machining mixing die for automobile parts, which comprises a floating material receiving unit, wherein the floating material receiving unit comprises a lifting frame, a material passing channel is formed on the lifting frame, a plurality of first conveyor belt components which are transversely arranged at intervals in parallel are arranged at the inner bottom of the material passing channel, a plurality of second conveyor belt components which are transversely arranged at intervals in parallel are arranged at the inner top of the material passing channel, and the first conveyor belt components and the second conveyor belt components are arranged in a one-to-one opposite way; the inner top of the material passing channel is provided with a first cutting tool and a first driving unit, and the inner bottom of the material passing channel is provided with a first female die; the lifting frame is provided with two parallel conveying frames and two transverse moving units; the lifting frame is provided with a second cutting tool, a second driving unit and a second female die; the conveying frame is provided with a third conveying belt assembly and a fourth conveying belt assembly; the butt joint operation between various continuous dies and various transfer dies is realized, so that the processing efficiency can be improved on the basis of ensuring the processing precision.

Description

Transition device and method for precisely machining hybrid mold of automobile part

Technical Field

The application relates to the technical field of precision machining of automobile parts, in particular to a transition device and a transition method for a precision machining mixing die of an automobile part.

Background

For some automobile parts, a situation is often encountered in the precision machining process: in the process flow of the part intersection, the processing precision of the latter part needs to be ensured, but the processing of the former part has no great precision requirement, and aiming at the processing situation with the precision requirement, a set of transmission dies is directly adopted to carry out fine processing at present, which results in the waste of resources and low efficiency when the processing of the former part is carried out, and how to combine a half set of continuous dies with a half set of transmission dies, the intermediate die transition is the core problem to be solved, so that the device and the method for precisely processing the automobile part for the transition of the hybrid die are needed.

Disclosure of Invention

The application aims to solve the technical problem of providing a transition device and a transition method for precisely machining a hybrid die of an automobile part aiming at the defects in the prior art.

The technical scheme adopted for solving the technical problems is as follows:

the transition device of the precise machining mixing die for the automobile parts comprises a floating receiving unit, wherein the floating receiving unit comprises a lifting frame which is synchronously lifted with a continuous die, a material passing channel is formed on the lifting frame, a plurality of first conveyor belt components which are transversely arranged at intervals in parallel are arranged at the inner bottom of the material passing channel, a plurality of second conveyor belt components which are transversely arranged at intervals in parallel are arranged at the inner top of the material passing channel, and the first conveyor belt components and the second conveyor belt components are arranged in a one-to-one opposite mode; the inner top of the material passing channel is provided with a first cutting tool and a first driving unit for driving the first cutting tool to lift, the first cutting tool is positioned between the two first conveyor belt components, and the inner bottom of the material passing channel is provided with a first female die matched with the first cutting tool; the lifting frame is positioned at the rear side of the material passing channel and is provided with two side-by-side conveying frames and two transverse moving units which are in one-to-one correspondence with the two conveying frames and drive the two conveying frames to transversely move; the lifting frame is provided with a second cutting tool positioned between the two conveying frames, a second driving unit for driving the second cutting tool to lift and a second female die matched with the second cutting tool; the conveying frame is provided with a third conveying belt assembly and a fourth conveying belt assembly which are used for clamping workpieces up and down.

The transition device for the precision machining mixing die of the automobile part, disclosed by the application, further comprises a lifting cylinder for driving the lifting frame to integrally lift, wherein the lifting cylinder and the ejection cylinder of the continuous die synchronously run.

The application discloses a transition device for an automobile part precision machining hybrid die, wherein the floating receiving unit further comprises a mounting seat for mounting a lifting cylinder, and a guide post for lifting and guiding a lifting frame is arranged on the mounting seat; and the lifting frame is provided with a linear bearing matched with the guide post.

The application relates to an automobile part precision machining mixing die transition device, wherein a lifting frame comprises a bottom plate, a top plate and a plurality of connecting columns for connecting the bottom plate and the top plate; the linear bearing is arranged on the bottom plate; the bottom plate is connected with the movable end of the lifting cylinder; the second conveyor belt assembly, the first driving unit, the traversing unit and the second driving unit are all arranged on the top plate; the first conveyor belt assembly, the first female die and the second female die are disposed on the base plate.

The application discloses a transition device for an automobile part precision machining hybrid die, wherein a visual recognition system for monitoring the position of a workpiece is further arranged on a top plate, and both a first driving unit and a second driving unit are controlled to operate by the visual recognition system.

The application relates to a transition device of a precision machining mixing die for an automobile part, wherein the front ends of the upper surfaces of a first female die and a second female die are respectively provided with a guide inclined plane.

The application method of the automobile part precision machining mixing die transition device is applied to the automobile part precision machining mixing die transition device, and the implementation method is as follows:

after the continuous die processes and forms the fitting of the semi-finished product on the hardware whole plate, the semi-finished product fitting enters a material passing channel along with the transmission of the continuous die;

under the clamping cooperation of a plurality of groups of first conveyor belt components and second conveyor belt components, the semi-finished product accessory stably advances to a first cutting tool;

the first driving unit drives the first cutting tool to move downwards, the first die is matched with the first driving unit to cut off a semi-finished product accessory from the hardware whole plate, and the first conveyor belt assembly and the second conveyor belt assembly operate to send the cut-off semi-finished product accessory out of the material passing channel and into the space between the third conveyor belt assembly and the fourth conveyor belt assembly of the two conveyor frames;

the second driving unit drives the second cutting tool to move downwards, and the second die is matched to cut the semi-finished product accessory from the middle to form two independent sub-workpieces;

the transverse moving unit drives the conveying frame to transversely move, and the independent sub-workpieces are conveyed to the feeding position of the manipulator of the subsequent conveying die.

The application has the beneficial effects that: after the continuous die processes and forms the fitting of the semi-finished product on the hardware whole plate, the semi-finished product fitting enters a material passing channel along with the transmission of the continuous die; under the clamping cooperation of a plurality of groups of first conveyor belt components and second conveyor belt components, the semi-finished product accessory stably advances to a first cutting tool; the first driving unit drives the first cutting tool to move downwards, the first die is matched with the first driving unit to cut off a semi-finished product accessory from the hardware whole plate, and the first conveyor belt assembly and the second conveyor belt assembly operate to send the cut-off semi-finished product accessory out of the material passing channel and into the space between the third conveyor belt assembly and the fourth conveyor belt assembly of the two conveyor frames; the second driving unit drives the second cutting tool to move downwards, and the second die is matched to cut the semi-finished product accessory from the middle to form two independent sub-workpieces; the transverse moving unit drives the conveying frame to transversely move, and the independent sub-workpieces are conveyed to the feeding position of the manipulator of the subsequent conveying die; the transition device for precisely machining the mixed die of the automobile part can realize the butt joint operation between various continuous dies and various transfer dies, thereby improving the machining efficiency on the basis of ensuring the machining precision of the automobile part.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the present application will be further described with reference to the accompanying drawings and embodiments, in which the drawings in the following description are only some embodiments of the present application, and other drawings may be obtained by those skilled in the art without inventive effort:

FIG. 1 is a schematic view of a transitional device for a precision machining hybrid mold for automotive parts according to a preferred embodiment of the application;

FIG. 2 is a side view of a transition device lift (second parting tool not shown) for a precision finishing hybrid mold for automotive parts in accordance with a preferred embodiment of the application;

FIG. 3 is a schematic view showing the structure of the bottom surface of the top plate of the transition device of the precision machining hybrid mold for automobile parts according to the preferred embodiment of the application;

FIG. 4 is a schematic view showing the upper surface structure of a transition device bottom plate of a precision finishing mixing die for automobile parts according to a preferred embodiment of the present application;

FIG. 5 is a flow chart of a method for applying a transition device for a precision finishing hybrid mold for an automotive part according to a preferred embodiment of the application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more apparent, the following description will be made in detail with reference to the technical solutions in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by a person skilled in the art without any inventive effort, are intended to be within the scope of the present application, based on the embodiments of the present application.

The transition device for the precise machining mixing die of the automobile part comprises a floating receiving unit, as shown in fig. 1, wherein the floating receiving unit comprises a lifting frame 1 which is lifted synchronously with a continuous die, a material passing channel 10 is formed on the lifting frame 1, a plurality of first conveyor belt components 11 which are arranged side by side at a transverse interval are arranged at the inner bottom of the material passing channel 10, a plurality of second conveyor belt components 12 which are arranged side by side at a transverse interval are arranged at the inner top of the material passing channel 10, and the first conveyor belt components 11 and the second conveyor belt components 12 are arranged opposite to each other; the inner top of the material passing channel 10 is provided with a first cutting tool 13 and a first driving unit 14 for driving the first cutting tool 13 to lift, the first cutting tool 13 is positioned between the two first conveyor belt assemblies 11, and the inner bottom of the material passing channel 10 is provided with a first female die 15 matched with the first cutting tool 13; the lifting frame 1 is positioned at the rear side of the material passing channel 10 and is provided with two side-by-side conveying frames 16 and two transverse moving units 17 which are in one-to-one correspondence with the two conveying frames 16 and drive the two conveying frames 16 to transversely move; the lifting frame 1 is provided with a second cutting tool 18 positioned between the two conveying frames 16, a second driving unit for driving the second cutting tool 18 to lift and a second female die 20 matched with the second cutting tool; the conveyor 16 is provided with a third conveyor assembly 21 and a fourth conveyor assembly 22 for gripping the workpiece up and down;

after the continuous die 2 processes the hardware whole plate 3 to form a semi-finished fitting, the semi-finished fitting 4 enters the material passing channel 10 along with the transmission of the continuous die; the semi-finished product accessory 4 stably advances to the first cutting tool 13 under the clamping cooperation of the plurality of groups of first conveyor belt assemblies 11 and second conveyor belt assemblies 12; the first driving unit 14 drives the first cutting tool 13 to descend, the first die 15 is matched to cut the semi-finished product accessories from the hardware whole plate 3, the first conveyor belt assembly 11 and the second conveyor belt assembly 12 operate to send the cut semi-finished product accessories 4 out of the material passing channel 10 and into the space between the third conveyor belt assembly 21 and the fourth conveyor belt assembly 22 of the two conveyor frames 16; the second driving unit drives the second cutting tool 18 to move downwards, and the semi-finished product accessory 4 is cut off from the middle by matching with the second female die 20 to form two independent sub-workpieces 40; the transverse moving unit 17 drives the conveying frame 16 to transversely move, and the independent sub-workpieces are conveyed to the feeding position of the manipulator 50 of the subsequent transfer die 5;

the first conveyor belt assembly, the second conveyor belt assembly, the third conveyor belt assembly and the fourth conveyor belt assembly of the application adopt the existing equipment; the transverse moving unit is a conventional XY axis moving mechanism;

the transition device for precisely machining the mixed die of the automobile part can realize the butt joint operation between various continuous dies and various transfer dies, thereby improving the machining efficiency on the basis of ensuring the machining precision of the automobile part.

Preferably, the floating receiving unit further comprises a lifting cylinder 23 for driving the lifting frame 1 to integrally lift, and the lifting cylinder 23 and the material ejection cylinder of the continuous die 2 synchronously operate; the floating receiving unit further comprises a mounting seat 24 for mounting the lifting cylinder 23, and a guide pillar 25 for lifting and guiding the lifting frame 1 is arranged on the mounting seat 24; the lifting frame 1 is provided with a linear bearing 26 matched with the guide post 25; the lifting frame 1 comprises a bottom plate 27, a top plate 28 and a plurality of connecting posts 29 connecting the bottom plate and the top plate; the linear bearing 26 is arranged on the bottom plate 27; the bottom plate 27 is connected with the movable end of the lifting cylinder 23; the second conveyor belt assembly, the first drive unit, the traversing unit, and the second drive unit are all disposed on the top plate 28; the first conveyor belt assembly, the first die and the second die are disposed on the base plate 27; the structure is reasonable and compact, the arrangement is convenient, the stability is good, and the external interference resistance is good; when the assembly device is used, the assembly can be completed by locking and connecting the progressive die, the mounting seat and the transfer die in sequence, and the flexibility is good.

Preferably, a visual recognition system for monitoring the position of the workpiece is further arranged on the top plate 28, and the first driving unit and the second driving unit are controlled to operate by the visual recognition system; as a preferred embodiment, a visual recognition system may be added to further ensure accuracy in severing.

Preferably, the front ends of the upper surfaces of the first female die 15 and the second female die 20 are provided with guide inclined surfaces 150; by the arrangement of the guiding inclined plane, the workpiece is beneficial to being guided when contacting the first female die.

The application method of the automobile part precision machining mixing die transition device is applied to the automobile part precision machining mixing die transition device, and the implementation method is as follows:

s01: after the continuous die processes and forms the fitting of the semi-finished product on the hardware whole plate, the semi-finished product fitting enters a material passing channel along with the transmission of the continuous die;

s02: under the clamping cooperation of a plurality of groups of first conveyor belt components and second conveyor belt components, the semi-finished product accessory stably advances to a first cutting tool;

s03: the first driving unit drives the first cutting tool to move downwards, the first die is matched with the first driving unit to cut off a semi-finished product accessory from the hardware whole plate, and the first conveyor belt assembly and the second conveyor belt assembly operate to send the cut-off semi-finished product accessory out of the material passing channel and into the space between the third conveyor belt assembly and the fourth conveyor belt assembly of the two conveyor frames;

s04: the second driving unit drives the second cutting tool to move downwards, and the second die is matched to cut the semi-finished product accessory from the middle to form two independent sub-workpieces;

s05: the transverse moving unit drives the conveying frame to transversely move, and the independent sub-workpieces are conveyed to the feeding position of the manipulator of the subsequent conveying die;

by applying the method provided by the application, the butt joint operation between various continuous dies and various transfer dies can be realized, so that the processing efficiency can be improved on the basis of ensuring the processing precision of automobile parts.

It will be understood that modifications and variations will be apparent to those skilled in the art from the foregoing description, and it is intended that all such modifications and variations be included within the scope of the following claims.

Claims (7)

1. The transition device for the precise machining mixing die of the automobile part is characterized by comprising a floating receiving unit, wherein the floating receiving unit comprises a lifting frame which is synchronously lifted with a continuous die, a material passing channel is formed on the lifting frame, a plurality of first conveyor belt components which are transversely arranged at intervals in parallel are arranged at the inner bottom of the material passing channel, a plurality of second conveyor belt components which are transversely arranged at intervals in parallel are arranged at the inner top of the material passing channel, and the first conveyor belt components and the second conveyor belt components are oppositely arranged one by one; the inner top of the material passing channel is provided with a first cutting tool and a first driving unit for driving the first cutting tool to lift, the first cutting tool is positioned between the two first conveyor belt components, and the inner bottom of the material passing channel is provided with a first female die matched with the first cutting tool; the lifting frame is positioned at the rear side of the material passing channel and is provided with two side-by-side conveying frames and two transverse moving units which are in one-to-one correspondence with the two conveying frames and drive the two conveying frames to transversely move; the lifting frame is provided with a second cutting tool positioned between the two conveying frames, a second driving unit for driving the second cutting tool to lift and a second female die matched with the second cutting tool; the conveying frame is provided with a third conveying belt assembly and a fourth conveying belt assembly which are used for clamping workpieces up and down.

2. The transition device for the precision machining mixing die for the automobile parts according to claim 1, wherein the floating receiving unit further comprises a lifting cylinder for driving the lifting frame to integrally lift, and the lifting cylinder and the ejection cylinder of the progressive die operate synchronously.

3. The transition device for the precision machining hybrid mold of the automobile part according to claim 2, wherein the floating receiving unit further comprises a mounting seat for mounting the lifting cylinder, and a guide post for lifting and guiding the lifting frame is arranged on the mounting seat; and the lifting frame is provided with a linear bearing matched with the guide post.

4. The automotive part precision finishing hybrid mold transition device of claim 3, wherein the crane comprises a bottom plate, a top plate, and a plurality of connecting posts connecting the bottom plate and the top plate; the linear bearing is arranged on the bottom plate; the bottom plate is connected with the movable end of the lifting cylinder; the second conveyor belt assembly, the first driving unit, the traversing unit and the second driving unit are all arranged on the top plate; the first conveyor belt assembly, the first female die and the second female die are disposed on the base plate.

5. The automotive part precision finishing hybrid mold transition device of claim 4, wherein a visual recognition system for monitoring the position of a workpiece is further provided on the top plate, and the first drive unit and the second drive unit are controlled to operate by the visual recognition system.

6. The transition device for precision finishing of automobile parts according to any one of claims 1 to 5, wherein the front ends of the upper surfaces of the first female die and the second female die are each provided with a guide slope.

7. An application method of a transition device of a precision machining hybrid die for an automobile part, which is applied to the transition device of the precision machining hybrid die for the automobile part, which is characterized by comprising the following steps:

after the continuous die processes and forms the fitting of the semi-finished product on the hardware whole plate, the semi-finished product fitting enters a material passing channel along with the transmission of the continuous die;

under the clamping cooperation of a plurality of groups of first conveyor belt components and second conveyor belt components, the semi-finished product accessory stably advances to a first cutting tool;

the first driving unit drives the first cutting tool to move downwards, the first die is matched with the first driving unit to cut off a semi-finished product accessory from the hardware whole plate, and the first conveyor belt assembly and the second conveyor belt assembly operate to send the cut-off semi-finished product accessory out of the material passing channel and into the space between the third conveyor belt assembly and the fourth conveyor belt assembly of the two conveyor frames;

the second driving unit drives the second cutting tool to move downwards, and the second die is matched to cut the semi-finished product accessory from the middle to form two independent sub-workpieces;

the transverse moving unit drives the conveying frame to transversely move, and the independent sub-workpieces are conveyed to the feeding position of the manipulator of the subsequent conveying die.