CN214349651U

CN214349651U - Double-row tool rest table device of double-spindle numerical control core walking vehicle

Info

Publication number: CN214349651U
Application number: CN202023170019.0U
Authority: CN
Inventors: 吴石清; 陈建明
Original assignee: Shenzhen Sowin Precision Machine Tool Co ltd
Current assignee: Shenzhen Sowin Precision Machine Tool Co ltd
Priority date: 2020-12-24
Filing date: 2020-12-24
Publication date: 2021-10-08
Anticipated expiration: 2030-12-24

Abstract

The utility model relates to a double-row tool rest device of a double-spindle numerical control core walking vehicle, which comprises a rotary guide sleeve of the core walking vehicle for clamping a workpiece, a left side tool rest platform and a right side tool rest platform; a left cutter assembly and a first X shaft assembly are arranged on the left cutter support platform; the right side tool rest base is provided with a right side tool assembly and a second X shaft assembly; the left cutter assembly comprises a plurality of first cutter groups which are longitudinally distributed and have different cutter types and a first Y shaft assembly which drives the first cutter groups to lift; the right cutter assembly comprises a plurality of second cutter groups which are longitudinally distributed and have different cutter types and a second Y shaft assembly which drives the second cutter groups to lift; by applying the structural mode of the tool changer, the left tool rest table and the right tool rest table are mutually independently controlled, machining such as driving, milling, drilling and the like can be simultaneously performed on a workpiece at the main shaft end, so that the rigidity of the slender workpiece during machining is increased, the workpiece is prevented from generating a tool back-off phenomenon, and due to double-side machining, the machining beat is shortened, and the machining efficiency is improved.

Description

Double-row tool rest table device of double-spindle numerical control core walking vehicle

Technical Field

The utility model relates to a core lathe technical field is walked in the numerical control, more specifically says, relates to a double knife rest platform device of core car is walked in two main shaft numerical control.

Background

The numerical control core-moving lathe is a numerical control lathe with a workpiece (main shaft) capable of moving axially, belongs to precision machining equipment, can simultaneously complete combined machining such as turning, milling, drilling, boring, tapping and the like at one time, and is mainly used for batch machining of shaft special-shaped nonstandard parts;

the tool rest structure of the currently adopted core-moving lathe is complex, the assembly and control of the tools are inconvenient, the installation number of the tools is limited greatly, the rigidity is difficult to guarantee particularly when long and thin workpieces are machined, the tool back-off phenomenon is easy to occur, and the machining efficiency is low.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model lies in, to the above-mentioned defect of prior art, a double tool rest platform device of core car is walked in two main shaft numerical control is provided.

The utility model provides a technical scheme that its technical problem adopted is:

the double-row tool rest device of the double-spindle numerical control core walking vehicle is constructed, wherein the double-row tool rest device comprises a core walking vehicle rotating guide sleeve for clamping a workpiece, and a left tool rest platform and a right tool rest platform which are respectively positioned on the left side and the right side of the core walking vehicle rotating guide sleeve; a left cutter assembly for processing a workpiece and a first X-axis assembly for driving the left cutter assembly to move towards or away from the rotating guide sleeve of the core walking vehicle are arranged on the left cutter holder platform; the right side tool rest base is provided with a right side tool assembly for processing a workpiece and a second X-axis assembly for driving the right side tool assembly to move towards or away from the rotating guide sleeve of the core walking vehicle; the left cutter assembly comprises a plurality of first cutter groups which are longitudinally distributed and have different cutter types and a first Y shaft assembly which drives the first cutter groups to lift; the right side cutter assembly comprises a plurality of second cutter groups which are longitudinally distributed and have different cutter types and a second Y-axis assembly which drives the second cutter groups to lift.

Double tool post platform device of core car is walked in two main shaft numerical control, wherein, first cutter group includes one or more first side power tool, one or more first terminal surface stationary knife, one or more first turning cutter to and the first drive assembly who provides power to above-mentioned cutter.

Double tool rest platform device of core car is walked in numerical control of two main shafts, wherein, second cutter group includes one or more second side power tool, one or more end face cutter, one or more second end face stationary knife, one or more second turning cutter to and the second drive assembly who provides power to above-mentioned cutter.

Double-main-shaft numerical control walks double tool rest platform device of core car, wherein, first Y axle subassembly is including the left side cutter slide of installation first cutter group, drive its longitudinal movement's first Y axle lead screw, and drive the first Y axle servo motor of first Y axle lead screw.

The double-row tool rest device of the double-spindle numerical control core-moving vehicle of the utility model is characterized in that a left side sliding plate is arranged on the left side tool rest platform along the X axis in a sliding manner, and the left side tool sliding plate is longitudinally arranged on the left side sliding plate in a sliding manner; the first Y-axis screw rod and the first Y-axis servo motor are installed on the left sliding plate.

Double tool rest platform device of core car is walked in two main shaft numerical controls, wherein, first X axle subassembly is including driving first X axle lead screw and drive that the X axle removed are followed to the left side slide first X axle servo motor of first X axle lead screw.

Double-spindle numerical control walks double tool rest platform device of core car, wherein, second Y axle subassembly is including the right side cutter slide of installation second cutter group, drive its longitudinal movement's second Y axle lead screw, and drive the second Y axle servo motor of second Y axle lead screw.

The double-row tool rest device of the double-spindle numerical control core-moving vehicle of the utility model is characterized in that a right side sliding plate is arranged on the right side tool rest platform along the X axis in a sliding manner, and the right side tool sliding plate is longitudinally arranged on the right side sliding plate in a sliding manner; and the second Y-axis screw rod and the second Y-axis servo motor are arranged on the right sliding plate.

Double tool rest platform device of core car is walked in two main shaft numerical controls, wherein, second X axle subassembly is including driving second X axle lead screw and drive that the right side slide removed along the X axle the second X axle servo motor of second X axle lead screw.

Double tool rest platform device of core car is walked in two main shaft numerical controls, wherein, the device still includes the riser, walk the rotatory guide pin bushing of core car the left side tool rest platform with the right side tool rest platform all sets up on the riser.

The beneficial effects of the utility model reside in that: by applying the structural mode of the tool changer, the left tool rest table and the right tool rest table are mutually independently controlled, machining such as driving, milling, drilling and the like can be simultaneously performed on a workpiece at the main shaft end, so that the rigidity of the slender workpiece during machining is increased, the workpiece is prevented from generating a tool back-off phenomenon, and due to double-side machining, the machining beat is shortened, and the machining efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the present invention will be further described below with reference to the accompanying drawings and embodiments, wherein the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained without inventive work according to the drawings:

fig. 1 is a front view of a double-row tool rest device of a double-spindle numerical control core carriage according to a preferred embodiment of the present invention;

fig. 2 is a schematic structural view of a double-row tool rest device of a double-spindle numerical control core carriage according to a preferred embodiment of the present invention;

fig. 3 is another angle structure diagram of the double-row tool rest device of the double-spindle numerical control core carriage according to the preferred embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, a clear and complete description will be given below with reference to the technical solutions of the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

The double-row tool rest device of the double-spindle numerical control core-moving vehicle of the preferred embodiment of the utility model is shown in fig. 1, and simultaneously refers to fig. 2 and 3, and comprises a core-moving vehicle rotating guide sleeve 1 for clamping a workpiece, and a left tool rest 2 and a right tool rest 3 which are respectively positioned at the left side and the right side of the core-moving vehicle rotating guide sleeve; the left tool rest stand 2 is provided with a left tool assembly 20 for processing a workpiece and a first X-axis assembly 21 for driving the left tool assembly 20 to move towards or away from the rotary guide sleeve 1 of the core walking vehicle; the right tool rest stand 3 is provided with a right tool assembly 30 for processing a workpiece and a second X-axis assembly 31 for driving the right tool assembly 30 to move towards or away from the rotary guide sleeve 1 of the core walking vehicle; the left cutter assembly 20 comprises a plurality of first cutter groups 200 with different cutter types which are longitudinally distributed and a first Y shaft assembly 201 for driving the first cutter groups to ascend and descend; the right cutter assembly 30 comprises a plurality of second cutter groups 300 which are longitudinally distributed and have different cutter types and a second Y-axis assembly 301 which drives the plurality of second cutter groups to ascend and descend;

by applying the structural mode of the tool rest, the left tool rest table and the right tool rest table are controlled independently, and can simultaneously carry out machining such as driving, milling, drilling and the like on a workpiece at the main shaft end, so that the rigidity of the slender workpiece during machining can be increased, the workpiece is prevented from yielding, and due to double-sided machining, the machining beat is shortened, and the machining efficiency is improved;

specifically, during adjustment, the distance between the left tool assembly 20 and the right tool assembly 30 and a workpiece on the rotary guide sleeve 1 of the core carriage is respectively adjusted through the first X-axis assembly 21 and the second X-axis assembly 31, and the tools in the first tool set 200 and the second tool set 300 are respectively adjusted correspondingly through the first Y-axis assembly 201 and the second Y-axis assembly 301 to be over against the workpiece for machining.

Preferably, the first tool set 200 includes one or more first side power tools 2000, one or more first end stationary tools 2001, one or more first turning tools 2002, and a first drive assembly 2003 for powering the tools; one preferred number is: the first side power tool 4, the first end fixed tool 4 and the first turning tool 4, although it will be appreciated that other numbers may be provided as desired.

Preferably, the second tool set 300 includes one or more second side power tools 3000, one or more end face tools 3001, one or more second end face stationary tools 3002, one or more second turning tools 3003, and a second drive assembly 3004 for powering said tools; one preferred number is: the second side power tool 3, the end face tool 6, the second end face fixed tool 4 and the second turning tool 5, but it is understood that other numbers can be provided according to the needs.

Preferably, the first Y-axis assembly 201 includes a left tool slide 2010 for mounting the first tool set, a first Y-axis screw 2011 for driving the left tool slide to move longitudinally, and a first Y-axis servo motor 2012 for driving the first Y-axis screw; through a first Y axle servo motor 2012 drive first Y axle lead screw, and then drive left side cutter slide and move along the Y axle, and then adjust the cutter that switches and just right with the work piece.

Preferably, the left tool slide plate 22 is arranged on the left tool holder 2 in a sliding manner along the X axis, and the left tool slide plate 2010 is longitudinally arranged on the left slide plate 22 in a sliding manner; a first Y-axis lead 2011 and a first Y-axis servomotor 2012 are mounted on the left slide 22; reasonable and compact structure and good operation stability.

Preferably, the first X-axis assembly 21 includes a first X-axis lead screw 210 for driving the left slide plate 22 to move along the X-axis and a first X-axis servo motor 211 for driving the first X-axis lead screw; the first X-axis servo motor drives the first X-axis lead screw, and further drives the left slide plate 22 to move along the X-axis, so as to adjust the distance from the left tool to the workpiece.

Preferably, the second Y-axis assembly 301 includes a right-side tool slide 3010 on which the second tool set is mounted, a second Y-axis lead screw 3011 for driving the second Y-axis slide to move longitudinally, and a second Y-axis servo motor 3012 for driving the second Y-axis lead screw; and a second Y-axis screw rod is driven by a second Y-axis servo motor 3012 to drive the right cutter sliding plate to move along the Y axis, so that the cutter just opposite to the workpiece is adjusted and switched.

Preferably, a right slide plate 32 is arranged on the right tool rest 3 in a sliding manner along the X axis, and a right tool slide plate 3010 is longitudinally arranged on the right slide plate 32 in a sliding manner; a second Y-axis lead 3011 and a second Y-axis servo motor 3012 are mounted on the right slide 32; reasonable and compact structure and good operation stability.

Preferably, the second X-axis assembly 31 includes a second X-axis lead screw 310 driving the right slide plate 32 to move along the X-axis and a second X-axis servo motor 311 driving the second X-axis lead screw; the second X-axis servo motor drives the second X-axis lead screw, and further drives the right slide plate 22 to move along the X-axis, so as to adjust the distance from the right tool to the workpiece.

Preferably, the device also comprises a vertical plate 4, and the rotary guide sleeve 1 of the core walking vehicle, the left tool rest table 2 and the right tool rest table 3 are all arranged on the vertical plate 4; reasonable and compact structure and good operation stability.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are considered to be within the scope of the invention as defined by the following claims.

Claims

1. A double-row tool rest platform device of a double-spindle numerical control core walking vehicle is characterized by comprising a core walking vehicle rotating guide sleeve for clamping a workpiece, and a left tool rest platform and a right tool rest platform which are respectively positioned on the left side and the right side of the core walking vehicle rotating guide sleeve; a left cutter assembly for processing a workpiece and a first X-axis assembly for driving the left cutter assembly to move towards or away from the rotating guide sleeve of the core walking vehicle are arranged on the left cutter holder platform; the right side tool rest base is provided with a right side tool assembly for processing a workpiece and a second X-axis assembly for driving the right side tool assembly to move towards or away from the rotating guide sleeve of the core walking vehicle; the left cutter assembly comprises a plurality of first cutter groups which are longitudinally distributed and have different cutter types and a first Y shaft assembly which drives the first cutter groups to lift; the right side cutter assembly comprises a plurality of second cutter groups which are longitudinally distributed and have different cutter types and a second Y-axis assembly which drives the second cutter groups to lift.

2. The dual row tool post apparatus of a dual spindle cnc turning lathe of claim 1 wherein the first tool set includes one or more first side powered tools, one or more first end fixed tools, one or more first turning tools, and a first drive assembly that powers the tools.

3. The dual row tool post apparatus of a dual spindle cnc turning lathe of claim 1 wherein the second tool set comprises one or more second side powered tools, one or more face tools, one or more second face mounted tools, one or more second turning tools, and a second drive assembly for powering the tools.

4. The double-row tool post device of the double-spindle numerical control carriage of the carriage as claimed in any one of claims 1 to 3, wherein the first Y-axis assembly includes a left-side tool slide for mounting the first tool set, a first Y-axis screw for driving the first Y-axis screw to move longitudinally, and a first Y-axis servo motor for driving the first Y-axis screw.

5. The double-row tool rest device of the double-spindle numerical control core-moving vehicle as claimed in claim 4, wherein a left side slide plate is slidably arranged on the left side tool rest platform along an X axis, and the left side tool slide plate is longitudinally slidably arranged on the left side slide plate; the first Y-axis screw rod and the first Y-axis servo motor are installed on the left sliding plate.

6. The double row tool post device of the dual spindle numerical control carriage as recited in claim 5, wherein the first X-axis assembly comprises a first X-axis lead screw driving the left slide plate to move along the X-axis and a first X-axis servo motor driving the first X-axis lead screw.

7. The double-row tool post device of the double-spindle numerical control carriage of the carriage as claimed in any one of claims 1 to 3, wherein the second Y-axis assembly includes a right-side tool slide plate for mounting the second tool set, a second Y-axis screw for driving the second Y-axis screw to move longitudinally, and a second Y-axis servo motor for driving the second Y-axis screw.

8. The double-row tool rest device of the double-spindle numerical control core-moving vehicle as claimed in claim 7, wherein a right slide plate is slidably arranged on the right tool rest platform along an X-axis, and the right tool slide plate is longitudinally slidably arranged on the right slide plate; and the second Y-axis screw rod and the second Y-axis servo motor are arranged on the right sliding plate.

9. The double row tool post device of a dual spindle numerical control carriage as recited in claim 8, wherein the second X-axis assembly includes a second X-axis lead screw driving the right slide plate to move along the X-axis and a second X-axis servo motor driving the second X-axis lead screw.

10. The double-row tool rest device of the double-spindle numerical control core walking vehicle as claimed in any one of claims 1 to 3, further comprising a vertical plate, wherein the rotary guide sleeve of the core walking vehicle, the left side tool rest platform and the right side tool rest platform are all arranged on the vertical plate.