CN217617863U - CNC machine tool equipment for template processing - Google Patents

Abstract

The utility model discloses a CNC lathe equipment for template processing, a serial communication port, including falling L shape support, gross porosity processing mechanism, pore processing mechanism, transposition microscope carrier and processing base station, gross porosity processing mechanism includes the servo straight line module of first X axle, the servo straight line module of first Y axle, first lift drive subassembly, the first sliding seat that falls L shape, first lifter plate, gross porosity processing motor and gross porosity processing cutter, pore processing mechanism includes the servo straight line module of second X axle, the servo straight line module of second Y axle, second lift drive subassembly, the second sliding seat that falls L shape, second lifter plate, pore processing motor and pore processing cutter, the utility model discloses gross porosity processing mechanism, pore processing mechanism use with the cooperation of transposition microscope carrier, can carry out gross porosity and pore processing to it after the template transposition, in prior art, the utility model discloses can reduce operating personnel's intensity of labour, and can also improve work efficiency, have higher use value.

Description

CNC machine tool equipment for template processing

Technical Field

The utility model relates to a template processing technology field especially relates to a CNC lathe equipment for template processing.

Background

The template is an achievement for fixing and standardizing the structural rule of an object, and the template embodies the standardization of the structural form, so the template has higher requirement precision, most of the existing templates are processed by high-precision CNC (computer numerical control) during production, the CNC numerical control machine tool processing is controlled by a numerical control processing language, usually a G code, the numerical control processing G code language tells the processing tool of the numerical control machine tool which Cartesian position coordinate is adopted, the feeding speed and the spindle rotating speed of the tool are controlled, functions of a tool changer, a coolant and the like are controlled, and the numerical control processing has great advantages compared with manual processing.

But the template need carry out course of working and pore processing, just at this moment need shift the centre gripping to the template, and traditional template utilizes artifical manual transposition usually man-hour adding, and such work efficiency is lower relatively, and has improved operating personnel's intensity of labour, so in order to solve this problem the utility model discloses a CNC lathe equipment for template processing.

SUMMERY OF THE UTILITY MODEL

Utility model purpose: in order to solve the not enough of existence among the background art, so the utility model discloses a template is CNC lathe equipment for processing.

The technical scheme is as follows: the CNC machine tool equipment for processing the template comprises an inverted L-shaped support, a rough hole processing mechanism, a fine hole processing mechanism, a transposition carrying platform and a processing base platform, wherein the transposition carrying platform is arranged on the processing base platform, the inverted L-shaped support is arranged on the rear side of the processing base platform, the rough hole processing mechanism comprises a first X-axis servo linear module, a first Y-axis servo linear module, a first lifting driving assembly, a first inverted L-shaped sliding seat, a first lifting plate, a rough hole processing motor and a rough hole processing cutter, the first X-axis servo linear module is arranged on the left side below the top of the inverted L-shaped support, the first Y-axis servo linear module is connected and arranged on the first X-axis servo linear module, the first inverted L-shaped sliding seat is connected and arranged on the first Y-axis servo linear module, the first lifting driving assembly is arranged below the top of the first inverted L-shaped sliding seat, two first linear guide rails are arranged on the front side surface of the first inverted L-shaped sliding seat, the first lifting plate is connected and connected with the rough hole processing cutter output shaft of the first lifting driving assembly;

pore processing mechanism includes servo straight line module of second X axle, the servo straight line module of second Y axle, second lift drive assembly, the second shape of falling L sliding seat, second lifter plate, pore processing motor and pore processing cutter, the servo straight line module of second X axle sets up the top below right side at the shape of falling L support, the servo straight line module of second Y axle is connected and is set up on the servo straight line module of second X axle, the connection of the second shape of falling L sliding seat sets up on the servo straight line module of second Y axle, second lift drive assembly sets up the top below at the shape of falling L sliding seat of second, the front side surface of the slide seat of falling L shape of second is provided with two second linear guide, the second lifter plate sliding connection is on two second linear guide, pore processing motor sets up on the second lifter plate, just pore processing cutter is connected with pore processing motor's output shaft.

The utility model discloses realize following beneficial effect:

the utility model discloses coarse hole processing mechanism, pore processing mechanism use with the cooperation of transposition microscope carrier, can change the back at the template and carry out coarse hole and pore processing to it, compare in prior art, the utility model discloses can reduce operating personnel's intensity of labour, and can also improve work efficiency, have higher use value.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of a partial structure disclosed in the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Examples

Referring to fig. 1-2, a CNC machine tool device for processing a template comprises an inverted L-shaped support 70, a rough hole processing mechanism 80, a fine hole processing mechanism 80, a transposition carrying platform and a processing base 10, wherein the transposition carrying platform is arranged on the processing base, the inverted L-shaped support is arranged at the rear side of the processing base, the rough hole processing mechanism comprises a first X-axis servo linear module 81, a first Y-axis servo linear module 82, a first lifting drive component 84, a first inverted L-shaped sliding seat 83, a first lifting plate 85, a rough hole processing motor 87 and a rough hole processing cutter 88, the first X-axis servo linear module is arranged at the left side below the top of the inverted L-shaped support, the first Y-axis servo linear module is arranged on the first X-axis servo linear module, the first inverted L-shaped sliding seat is arranged on the first Y-axis servo linear module, the first lifting drive component is arranged below the top of the first inverted L-shaped sliding seat, two first linear guide rails 86 are arranged on the front side surface of the first inverted L-shaped sliding seat, the first lifting drive component is arranged on the first linear guide rails, and the first linear guide rails are connected with the rough hole processing motor, and the first lifting drive component is connected with the first linear guide rail;

the pore processing mechanism comprises a second X-axis servo linear module 91, a second Y-axis servo linear module 92, a second lifting driving assembly 94, a second inverted L-shaped sliding seat 93, a second lifting plate 95, a pore processing motor 97 and a pore processing tool 98, wherein the second X-axis servo linear module is arranged on the right side below the top of the inverted L-shaped support, the second Y-axis servo linear module is connected and arranged on the second X-axis servo linear module, the second inverted L-shaped sliding seat is connected and arranged on the second Y-axis servo linear module, the second lifting driving assembly is arranged below the top of the second inverted L-shaped sliding seat, the front side surface of the second inverted L-shaped sliding seat is provided with two second linear guide rails 98, the second lifting plate is connected onto the two second linear guide rails in a sliding manner, the pore processing motor is arranged on the second lifting plate, and the pore processing tool is connected with an output shaft of the pore processing motor.

In this embodiment, the transposition carrier comprises a rotary driving assembly 20, a clamping assembly, a connecting arm 40 and two carriers 30, the two carriers are movably arranged above the processing base and connected through the connecting arm, the rotary driving assembly is arranged at the bottom of the processing base and connected with the connecting arm, a straight chute 11 is formed on the surface of each of the left side and the right side of the processing base, the clamping assembly comprises two telescopic driving cylinders 60 and two clamping frames 50 with openings on one side, the two telescopic driving cylinders are respectively arranged on the two opposite sides of the processing base, the bottom of each clamping frame is connected with the straight chute through a sliding block 51, the driving shaft of each telescopic driving cylinder is correspondingly connected with one clamping frame, clamping driving cylinders are arranged on the inner walls of the front side and the rear side of each clamping frame, the driving shaft of each clamping driving cylinder is connected with a clamping column 53, a placing groove 31 is formed on the upper surface of each carrier, and a abdicating groove 32 communicated with the placing groove is formed on the surface of the front side and the rear side of each carrier so that the clamping column extends into the placing groove;

when selecting for use, first lift drive assembly and second lift drive assembly all preferably adopt servo hydraulic stem.

In the specific implementation process, an operator firstly places two templates to be processed on two carrying platforms, two telescopic driving cylinders respectively drive two clamping frames to move in opposite directions, after the templates are clamped in place, the clamping driving cylinders arranged on the front inner wall and the rear inner wall of each clamping frame drive the clamping columns to extend out, the clamping columns pass through the abdicating grooves to clamp the templates, after the templates are clamped, the rough hole processing mechanism and the fine hole processing mechanism respectively process the two templates, after the processing is finished, the clamping driving cylinders arranged on the front inner wall and the rear inner wall of the two clamping frames drive the clamping columns to retract, the two telescopic driving cylinders drive the two clamping frames to retract, after the step is finished, the servo motor drives the connecting arm to rotate 180 degrees so as to replace the two carrying platforms, after the replacement is finished, the two telescopic driving cylinders drive the two clamping frames to extend out again, the clamping cylinders on the front inner wall and the rear inner wall of the clamping frames drive the clamping columns to clamp the templates, and after the clamping is finished, the rough hole processing mechanism and the fine hole processing mechanism can process the templates again.

In this embodiment, the rotary driving mechanism includes servo motor 21, bearing seat 23 and pivot 24 that output shaft has reduction gear 22, and reduction gear and servo motor set up in the bottom of processing base station, and the bearing seat setting is inside the processing base station, and the pivot passes the bearing seat to be connected the reduction gear with the linking arm, and when servo motor drive pivot rotated, the linking arm alright drive two microscope carriers and rotate the transposition.

In this embodiment, the rotation driving mechanism drives the connecting arm at a single time to rotate by 180 °, so that the two stages can be replaced.

In this embodiment, the clamping column is a cylindrical structure, and the abdicating groove is a cylindrical groove matched with the clamping column.

The utility model discloses an operating principle does, when two templates of treating processing are placed on the transposition microscope carrier, at the servo straight line module of first X axle, under the drive of the servo straight line module of first Y axle and first lift drive assembly, the thick spot machining motor drive thick spot machining cutter moves and carries out the thick spot processing to a template, at the servo straight line module of second X axle, under the drive of the servo straight line module of second Y axle and second lift drive assembly, the action of pore machining motor drive pore machining cutter carries out the thick spot processing to another template, after processing, two template transpositions of transposition microscope carrier drive, thick spot machining mechanism carries out the thick spot processing to the template of having processed the pore, pore machining mechanism processes the template of having processed the thick spot, and processing step is the same with above-mentioned processing step, do not describe here repeatedly.

The above embodiments are only for illustrating the technical conception and characteristics of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered in the protection scope of the present invention.

Claims (6)

1. The CNC machine tool equipment for processing the template is characterized by comprising an inverted L-shaped support, a rough hole processing mechanism, a fine hole processing mechanism, a transposition carrying platform and a processing base platform, wherein the transposition carrying platform is arranged on the processing base platform, the inverted L-shaped support is arranged on the rear side of the processing base platform, the rough hole processing mechanism comprises a first X-axis servo linear module, a first Y-axis servo linear module, a first lifting driving component, a first inverted L-shaped sliding seat, a first lifting plate, a rough hole processing motor and a rough hole processing cutter, the first X-axis servo linear module is arranged on the left side below the top of the inverted L-shaped support, the first Y-axis servo linear module is connected and arranged on the first X-axis servo linear module, the first inverted L-shaped sliding seat is connected and arranged on the first Y-axis servo linear module, the first lifting driving component is arranged below the top of the first inverted L-shaped sliding seat, two first linear guide rails are arranged on the front side surface of the first inverted L-shaped sliding seat, the first lifting plate is connected and connected with the rough hole processing motor, and the first lifting driving component is connected with the rough hole processing motor;

pore processing mechanism includes servo straight line module of second X axle, the servo straight line module of second Y axle, second lift drive assembly, the second shape of falling L sliding seat, second lifter plate, pore processing motor and pore processing cutter, the servo straight line module of second X axle sets up the top below right side at the shape of falling L support, the servo straight line module of second Y axle is connected and is set up on the servo straight line module of second X axle, the connection of the second shape of falling L sliding seat sets up on the servo straight line module of second Y axle, second lift drive assembly sets up the top below at the shape of falling L sliding seat of second, the front side surface of the slide seat of falling L shape of second is provided with two second linear guide, the second lifter plate sliding connection is on two second linear guide, pore processing motor sets up on the second lifter plate, just pore processing cutter is connected with pore processing motor's output shaft.

2. The CNC machine tool equipment for processing the template as claimed in claim 1, wherein the transposition carrying platform comprises a rotary driving assembly, a clamping assembly, a connecting arm and two carrying platforms, the two carrying platforms are movably arranged above the processing base platform and are connected through the connecting arm, the rotary driving assembly is arranged at the bottom of the processing base platform and is connected with the connecting arm, a linear chute is formed in the surfaces of the left side and the right side of the processing base platform, the clamping assembly comprises two telescopic driving cylinders and two clamping frames, openings are formed in one side of each clamping frame, the two telescopic driving cylinders are respectively arranged on the two opposite sides of the processing base platform, the bottom of each clamping frame is connected with the linear chute through a sliding block, a driving shaft of each telescopic driving cylinder is correspondingly connected with one clamping frame, clamping driving cylinders are arranged on the inner walls of the front side and the rear side of each clamping frame, a clamping column is connected with the driving shaft of each clamping driving cylinder, a placing groove is formed in the upper surface of each carrying platform, and a abdicating groove communicated with the placing groove is formed in the surfaces of the front side and the rear side of each carrying platform so that the clamping column can extend into the placing groove.

3. The CNC machine tool equipment for processing the template as recited in claim 2, wherein the rotary driving mechanism comprises a servo motor with an output shaft connected with a reducer, a bearing seat and a rotating shaft, the reducer and the servo motor are arranged at the bottom of the processing base, the bearing seat is arranged inside the processing base, and the rotating shaft penetrates through the bearing seat to connect the reducer with the connecting arm.

4. The CNC machine apparatus for template processing according to claim 2, wherein the rotation angle of the connecting arm driven by the rotary driving mechanism at a time is 180 °.

5. The CNC machine tool equipment for template processing according to claim 2, wherein the clamping column is of a columnar structure, and the abdicating groove is a columnar groove matched with the clamping column.

6. The CNC machine equipment for template processing according to claim 1, wherein the first lifting driving component and the second lifting driving component are both servo hydraulic rods.

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