CN112222879A - Intelligent lathe equipment - Google Patents

Abstract

The invention relates to the field of intelligent manufacturing, in particular to an intelligent lathe device, which is an indispensable device in the modern manufacturing field, wherein a lathe cannot be synchronously processed by two workpieces in the traditional lathe, scrap iron cannot be pressed to save space.

Description

Intelligent lathe equipment

Technical Field

The invention relates to the field of intelligent manufacturing, in particular to intelligent lathe equipment.

Background

In the modern manufacturing field, the lathe is the indispensable equipment, and the processing of two work pieces can't be accomplished in step to traditional lathe, can't suppress iron fillings and save space, and above-mentioned problem has been solved to this equipment.

Disclosure of Invention

The invention aims to provide intelligent lathe equipment which can be used for independently turning or synchronously turning two identical workpieces and pressing scrap iron.

The purpose of the invention is realized by the following technical scheme:

the utility model provides an intelligent lathe equipment, includes that cutter presss from both sides tight assembly, work piece holder assembly and iron fillings and handles the assembly, and work piece holder assembly is connected with cutter clamp tight assembly, and cutter clamp tight assembly is handled the assembly with iron fillings and is connected.

As a further optimization of the technical scheme, the cutter clamping combination comprises a rack, a rack inner groove, a sliding rail, a rotary handle I, a threaded shaft I, a threaded support lug, a sliding frame, a positioning hole, a positioning column, a lifting handle, a tension spring I, a rotary support, a support column, a cutter clamping support, a knob, a threaded shaft II, a sliding column, a cutter clamping plate, a cutter, a rotary handle II, a camshaft I, a connecting disc I, a connecting rod, a connecting disc II, a camshaft II, a cam, a tension spring II, a clutch support, a sliding plate, a toggle ball column, a sliding sleeve, a threaded shaft III support, a threaded shaft IV, a spline, an inserting groove, a ball groove, a magnetic block I, a magnetic block II, a magnetic block III and a motor I, wherein the rack inner groove is positioned in the rack, the sliding rail is connected with the rack inner groove in a sliding manner, the rotary handle I is connected with the, the thread lug is connected with the sliding frame, the sliding frame is connected with the sliding rail in a sliding way, the positioning hole is positioned on the sliding frame, the rotating support is connected with the sliding frame in a rotating way, the handle is connected with the positioning column, the positioning column is connected with the rotating support in a sliding way, two ends of the tension spring I are respectively connected with the rotating support and the handle, the tension spring I is in a stretching state, the supporting column is connected with the rotating support, the supporting column is connected with the tool clamping support, the knob is connected with the threaded shaft II, the threaded shaft II is connected with the tool clamping support, the sliding column is connected with the tool clamping support, the tool clamping plate is connected with the threaded shaft II in a threaded way, the tool clamping plate is connected with the sliding column in a sliding way, the rotating handle II is connected with the camshaft I, the camshaft I is connected with the, II both ends of extension spring are connected with the separation and reunion support respectively, the sliding plate is connected, extension spring II is in tensile state, two sliding plates all are connected with stirring the ball post, stir ball post and ball groove sliding connection, the ball groove is located sliding sleeve, sliding sleeve and III sliding connection of screw thread axle, screw thread axle III is connected with III supports rotations of screw thread axle, III supports of screw thread axle are connected with the slide rail, III supports of screw thread axle and frame bottom spout sliding connection, screw thread axle IV and separation and reunion support sliding connection, screw thread axle IV is connected with the spline, the slot is located sliding sleeve, magnetic path I is connected with swing handle II, motor I is connected with screw thread axle IV, screw thread axle III, all be equipped with the screw thread on the screw thread axle IV and revolve to opposite directions, screw thread axle III, screw thread axle IV respectively with two screw thread journal eared.

As a further optimization of the technical scheme, the workpiece clamp assembly comprises a transmission case, a motor II shaft, a gear I, a gear II, a gear III, a gear IV shaft, a gear II shaft, a clamp connecting support, a clamp shell, a sliding clamping jaw, a clamping jaw limiting clamp, a clamping jaw, a helical rack, a helical tooth slider, a rack, a clamping gear, a worm wheel shaft, a worm, a grab handle, a sliding limiting frame, a limiting clamp I, a limiting clamp II, a gear support shaft, a gear V and a spring, wherein the transmission case is connected with a frame, the motor II is connected with the motor II shaft, the motor II shaft is rotatably connected with the transmission case, the motor II shaft is connected with the gear I and the gear III, the gear I is not meshed with the gear II, the gear II is connected with the gear II shaft, the gear II shaft is rotatably connected with, a gear III is meshed with a gear IV, the gear IV is connected with a gear IV shaft, the gear IV shaft is rotatably connected with a transmission case, a gear II shaft and the gear IV shaft are respectively connected with two clamp connecting brackets, the clamp connecting brackets are connected with a clamp shell, a sliding clamping jaw is slidably connected with the clamp shell, a clamping jaw limit clamp is connected with the clamp shell, the sliding clamping jaw is connected with a helical rack, the sliding clamping jaw is hinged with the clamping jaw, the helical rack is meshed with a helical tooth sliding block, the helical tooth sliding block is slidably connected with the clamp shell, the helical tooth sliding block is vertical to the position of the sliding clamping jaw, the helical tooth sliding block is connected with the rack, the rack is meshed with a clamping gear, the clamping gear is connected with a worm gear shaft, the worm gear shaft is rotatably connected with the clamp shell, the worm gear shaft is connected with a worm wheel, the worm wheel is meshed with a worm, grab handle and transmission case sliding connection, slip spacing and grab handle sliding connection, spacing checkpost I, spacing checkpost II all are connected with the spacing frame that slides, and the spring both ends are connected with spacing frame, the grab handle that slides respectively, and the spring is in compression state, and the grab handle is connected with gear bracket, and gear bracket rotates with gear bracket shaft to be connected, and gear bracket shaft is connected with gear V.

As a further optimization of the technical scheme, the scrap iron treatment assembly comprises a scrap collecting box, a motor T-shaped chute, a motor shaft chute, a chain wheel I, a chain wheel II, a chain wheel III, a chain wheel II shaft, a sliding support T-shaped chute, a tension spring III fixing plate, a cam shaft, a cam, a bottom plate limiting frame, a bottom plate and a compression roller, wherein the cam shaft I and the cam shaft II are both rotatably connected with the side wall of the scrap collecting box, a clutch support is connected with the inner wall of the scrap collecting box, a magnet block II and a magnet block III are both connected with the side wall of the scrap collecting box, a machine frame is connected with the scrap collecting box, the motor T-shaped chute and the motor shaft chute are both positioned on the side wall of the scrap collecting box, the motor I is slidably connected with the motor T-shaped chute, a threaded shaft IV is slidably connected with the motor shaft chute, the threaded shaft IV is, II axles of sprocket rotate with the sliding support to be connected, sliding support and sliding support T type spout sliding connection, sliding support T type spout are located collection bits case lateral wall, III both ends of extension spring respectively with the sliding support, III fixed plates of extension spring are connected, extension spring III is in tensile state, III fixed plates of extension spring are connected with collection bits case, sprocket III is connected with the camshaft, the camshaft rotates with collection bits case to be connected, the camshaft is connected with two cams, two cam installation opposite direction, two spacing framves of bottom plate are connected with collection bits incasement wall, the bottom plate is located two spacing framves of bottom plate, the compression roller is located the bottom plate, be equipped with the clear bits door on the collection bits case lateral wall.

The intelligent lathe equipment has the beneficial effects that: the cutter presss from both sides tight assembly and can press from both sides the cutter and switch a plurality of angles with the cutter, the turning of being convenient for or cut off the work piece operation, but through rotating two anchor clamps independent motions of swing handle switching or motion together, through the adjustable two work piece holder independent workings of pulling grab handle or simultaneous working, work piece holder is equipped with a plurality of clamping points, can play better clamping effect when pressing from both sides tight step shaft, the iron blood that cuts gets into collection bits case and is flattened the transportation of being convenient for by the compression roller is reciprocal.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

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

FIG. 2 is a first schematic view of the structure of the tool clamping assembly 1 of the present invention;

FIG. 3 is a schematic structural view II of the tool clamping assembly 1 of the present invention;

FIG. 4 is a partial cross-sectional view of the tool clamping assembly 1 of the present invention;

FIG. 5 is a schematic structural view III of the tool clamping assembly 1 of the present invention;

FIG. 6 is a fourth schematic structural view of the tool clamping assembly 1 of the present invention;

FIG. 7 is a schematic structural view of the tool clamping assembly 1 of the present invention;

FIG. 8 is a sixth schematic view of the tool clamping assembly 1 of the present invention;

fig. 9 is a seventh structural schematic view of the tool clamping assembly 1 of the present invention;

FIG. 10 is a partial sectional view of the tool clamping assembly 1 of the present invention;

FIG. 11 is a first schematic view of the present invention workpiece holder assembly 2;

FIG. 12 is a second schematic structural view of the work holder assembly 2 of the present invention;

FIG. 13 is a partial cross-sectional view of the work holder assembly 2 of the present invention;

FIG. 14 is a third schematic structural view of the work holder assembly 2 of the present invention;

FIG. 15 is a fourth schematic structural view of the present work holder assembly 2;

FIG. 16 is a fifth schematic structural view of the present work holder assembly 2;

FIG. 17 is a sixth schematic structural view of the present work holder assembly 2;

FIG. 18 is a seventh structural schematic view of the present work holder assembly 2;

FIG. 19 is a first schematic view of the iron-scrap-handling assembly 3 of the present invention;

FIG. 20 is a second schematic structural view of the iron scrap handling assembly 3 of the present invention;

FIG. 21 is a third schematic view of the iron-scrap handling assembly 3 of the present invention.

In the figure: a tool clamping assembly 1; a frame 1-1; an inner groove 1-2 of the frame; 1-3 of a slide rail; 1-4 of a rotating handle; 1-5 parts of a threaded shaft; 1-6 of a threaded support lug; a carriage 1-7; 1-8 of a positioning hole; positioning columns 1-9; 1-10 parts of a handle; 1-11 parts of a tension spring; 1-12 of a rotating bracket; 1-13 of a support column; a tool clamping holder 1-14; 1-15 of a knob; 1-16 parts of a threaded shaft; 1-17 of a sliding column; tool clamping plates 1-18; 1-19 parts of a cutter; 1-20 parts of a rotating handle II; 1-21 parts of a camshaft; 1-22 parts of a connecting disc; connecting rods 1-23; connecting discs II 1 to 24; 1-25 parts of a camshaft II; cams 1 to 26; a tension spring II 1-27; clutch supports 1-28; a slide plate 1-29; stirring the ball column by 1-30; sliding sleeves 1-31; 1-32 parts of a threaded shaft III; supports 1-33 of a threaded shaft III; 1-34 parts of a threaded shaft IV; splines 1-35; slots 1-36; 1-37 of ball grooves; 1-38 of magnetic blocks; magnetic blocks II 1 to 39; 1-40 of magnetic blocks III; 1-41 parts of a motor; a workpiece holder assembly 2; a transmission case 2-1; a motor II 2-2; 2-3 of a motor II shaft; 2-4 parts of a gear I; 2-5 of a gear II; 2-6 parts of a gear III; 2-7 of a gear IV; 2-8 parts of a gear IV shaft; 2-9 of a gear II shaft; the clamp is connected with the support 2-10; 2-11 parts of a clamp shell; 2-12 of a sliding clamping jaw; 2-13 parts of a clamping jaw limit clip; 2-14 parts of clamping jaws; 2-15 parts of a helical rack; 2-16 parts of helical tooth slide block; racks 2-17; 2-18 of a clamping gear; 2-19 of worm wheel shaft; 2-20 parts of worm wheel; 2-21 parts of worm; 2-22 of a grab handle; 2-23 of a sliding limiting frame; 2-24 parts of a limiting clamp; 2-25 of a limiting clip; gear supports 2-26; 2-27 parts of gear support shaft; gears V2-28; the iron scrap processing assembly 3; a scrap collecting box 3-1; a motor T-shaped chute 3-2; a motor shaft chute 3-3; 3-4 of a chain wheel; 3-5 parts of a chain; chain wheels II 3-6; 3-7 parts of a chain wheel III; 3-8 of a chain wheel II shaft; 3-9 of a sliding bracket; 3-10 parts of a T-shaped sliding chute of the sliding bracket; 3-11 parts of a tension spring III; fixing plates 3-12 by a tension spring III; 3-13 parts of a camshaft; 3-14 parts of a cam; 3-15 parts of a bottom plate limiting frame; a bottom plate 3-16; and (3) pressing rolls (3-17).

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 21, and an intelligent lathe apparatus includes a tool clamping assembly 1, a work holder assembly 2, and an iron scrap handling assembly 3, where the work holder assembly 2 is connected to the tool clamping assembly 1, and the tool clamping assembly 1 is connected to the iron scrap handling assembly 3.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1-21, and the present embodiment further describes the first embodiment, where the tool clamping assembly 1 includes a frame 1-1, a frame inner groove 1-2, a slide rail 1-3, a rotary handle i 1-4, a threaded shaft i 1-5, a threaded support lug 1-6, a carriage 1-7, a positioning hole 1-8, a positioning post 1-9, a handle 1-10, a tension spring i 1-11, a rotary support 1-12, a support post 1-13, a tool clamping support 1-14, a knob 1-15, a threaded shaft ii 1-16, a sliding post 1-17, a tool clamping plate 1-18, a tool 1-19, a rotary handle ii 1-20, a camshaft i 1-21, a connecting disk i 1-22, a connecting rod 1-23, a connecting rod i 1-23, Connecting disc II 1-24, camshaft II 1-25, cam 1-26, tension spring II 1-27, clutch support 1-28, sliding plate 1-29, toggle ball column 1-30, sliding sleeve 1-31, threaded shaft III 1-32, threaded shaft III support 1-33, threaded shaft IV 1-34, spline 1-35, slot 1-36, ball groove 1-37, magnet I1-38, magnet II 1-39, magnet III 1-40 and motor I1-41, frame inner groove 1-2 is located in frame 1-1, slide rail 1-3 is connected with frame inner groove 1-2 in a sliding manner, rotary handle I1-4 is connected with threaded shaft I1-5, threaded shaft I1-5 is connected with frame 1-1 in a rotating manner, threaded shaft I1-5 is connected with slide rail 1-3 in a threaded manner, the threaded support lugs 1-6 are connected with the sliding frames 1-7, the sliding frames 1-7 are connected with the sliding rails 1-3 in a sliding mode, the positioning holes 1-8 are located on the sliding frames 1-7, the rotating supports 1-12 are connected with the sliding frames 1-7 in a rotating mode, the handles 1-10 are connected with the positioning columns 1-9, the positioning columns 1-9 are connected with the rotating supports 1-12 in a sliding mode, two ends of a tension spring I1-11 are respectively connected with the rotating supports 1-12 and the handles 1-10, the tension spring I1-11 is in a stretching state, the support columns 1-13 are connected with the rotating supports 1-12, the support columns 1-13 are connected with the cutter clamping supports 1-14, the knobs 1-15 are connected with the threaded shafts II 1-16, and the threaded shafts II 1-16 are connected with, the sliding column 1-17 is connected with the tool clamping support 1-14, the tool clamping plate 1-18 is in threaded connection with the threaded shaft II 1-16, the tool clamping plate 1-18 is in sliding connection with the sliding column 1-17, the rotary handle II 1-20 is connected with the camshaft I1-21, the camshaft I1-21 is connected with the connecting disc I1-22, the connecting disc I1-22 is connected with the connecting rod 1-23, the connecting disc II 1-24 is connected with the camshaft II 1-25, the camshaft I1-21 and the camshaft II 1-25 are respectively connected with the two cams 1-26, the two ends of the tension spring II 1-27 are respectively connected with the clutch support 1-28 and the sliding plate 1-29, the tension spring II 1-27 is in a stretching state, and the two sliding plates 1-29 are respectively connected with the toggle ball column 1-30, a toggle ball column 1-30 is in sliding connection with a ball groove 1-37, the ball groove 1-37 is positioned on a sliding sleeve 1-31, the sliding sleeve 1-31 is in sliding connection with a threaded shaft III 1-32, the threaded shaft III 1-32 is in rotating connection with a threaded shaft III support 1-33, the threaded shaft III support 1-33 is connected with a sliding rail 1-3, the threaded shaft III support 1-33 is in sliding connection with a sliding groove at the bottom of a frame 1-1, a threaded shaft IV 1-34 is in sliding connection with a clutch support 1-28, the threaded shaft IV 1-34 is connected with a spline 1-35, a slot 1-36 is positioned on the sliding sleeve 1-31, a magnet I1-38 is connected with a rotating handle II 1-20, a motor I1-41 is connected with the threaded shaft IV 1-34, and the threaded shaft III 1-32 is connected with the spline 1-35, The threaded shafts IV 1-34 are provided with threads with opposite rotation directions, the threaded shafts III 1-32 and the threaded shafts IV 1-34 are respectively in threaded connection with the two threaded lugs 1-6, and two groups of cutters can be controlled to start working simultaneously or respectively.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1-21, and the present embodiment further describes the first embodiment, wherein the workpiece holder assembly 2 includes a transmission case 2-1, a motor ii 2-2, a motor ii shaft 2-3, a gear i 2-4, a gear ii 2-5, a gear iii 2-6, a gear iv 2-7, a gear iv shaft 2-8, a gear ii shaft 2-9, a holder connecting bracket 2-10, a holder housing 2-11, a sliding holder 2-12, a holder limiting clip 2-13, a holder 2-14, a helical rack 2-15, a helical slide 2-16, a rack 2-17, a clamping gear 2-18, a worm shaft 2-19, a worm wheel 2-20, a worm 2-21, a handle 2-22, and a sliding limiting frame 2-23, A limiting clamp I2-24, a limiting clamp II 2-25, a gear support 2-26, a gear support shaft 2-27, a gear V2-28 and a spring 2-29, wherein the transmission case 2-1 is connected with the frame 1-1, the motor II 2-2 is connected with the motor II shaft 2-3, the motor II shaft 2-3 is rotatably connected with the transmission case 2-1, the motor II shaft 2-3 is connected with the gear I2-4 and the gear III 2-6, the gear I2-4 is not meshed with the gear II 2-5, the gear II 2-5 is connected with the gear II shaft 2-9, the gear II shaft 2-9 is rotatably connected with the transmission case 2-1, and the gear III 2-6 is meshed with the gear IV 2-7, the gear IV 2-7 is connected with a gear IV shaft 2-8, the gear IV shaft 2-8 is rotationally connected with a transmission case 2-1, the gear II shaft 2-9 and the gear IV shaft 2-8 are respectively connected with two clamp connecting brackets 2-10, the clamp connecting brackets 2-10 are connected with a clamp shell 2-11, a sliding clamping jaw 2-12 is slidably connected with the clamp shell 2-11, a clamping jaw limit clamp 2-13 is connected with the clamp shell 2-11, the sliding clamping jaw 2-12 is connected with an oblique rack 2-15, the sliding clamping jaw 2-12 is hinged with a clamping jaw 2-14, the oblique rack 2-15 is meshed with an oblique tooth slider 2-16, the oblique tooth slider 2-16 is slidably connected with the clamp shell 2-11, the oblique tooth slider 2-16 is vertical to the sliding clamping jaw 2-12, the helical tooth slide block 2-16 is connected with a rack 2-17, the rack 2-17 is meshed with a clamping gear 2-18, the clamping gear 2-18 is connected with a worm wheel shaft 2-19, the worm wheel shaft 2-19 is rotatably connected with a clamp shell 2-11, the worm wheel shaft 2-19 is connected with a worm wheel 2-20, the worm wheel 2-20 is meshed with a worm 2-21, the worm 2-21 is rotatably connected with the clamp shell 2-11, one end of the worm 2-21 is provided with an inner hexagonal groove, a handle 2-22 is slidably connected with a transmission case 2-1, a sliding limiting frame 2-23 is slidably connected with the handle 2-22, a limiting clamp I2-24 and a limiting clamp II 2-25 are connected with the sliding limiting frame 2-23, two ends of a spring 2-29 are respectively connected with the sliding limiting frame 2-23, The grab handles 2-22 are connected, the springs 2-29 are in a compressed state, the grab handles 2-22 are connected with the gear supports 2-26, the gear supports 2-26 are rotatably connected with the gear support shafts 2-27, the gear support shafts 2-27 are connected with the gears V2-28, and two groups of workpiece clamps can be controlled to rotate simultaneously or respectively.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-21, and the embodiment further describes the first embodiment, the scrap iron handling assembly 3 includes a scrap collecting box 3-1, a motor T-shaped chute 3-2, a motor shaft chute 3-3, a chain wheel i 3-4, a chain 3-5, a chain wheel ii 3-6, a chain wheel iii 3-7, a chain wheel ii shaft 3-8, a sliding support 3-9, a sliding support T-shaped chute 3-10, a tension spring iii 3-11, a tension spring iii fixing plate 3-12, a cam shaft 3-13, a cam 3-14, a bottom plate limiting frame 3-15, a bottom plate 3-16 and a press roller 3-17, the cam shaft i 1-21 and the cam shaft ii 1-25 are rotatably connected with the side wall of the scrap collecting box 3-1, a clutch support 1-28 is connected with the inner wall of the scrap collecting box 3-1, the magnetic blocks II 1-39 and the magnetic blocks III 1-40 are connected with the side wall of the scrap collecting box 3-1, the frame 1-1 is connected with the scrap collecting box 3-1, the motor T-shaped chute 3-2 and the motor shaft chute 3-3 are positioned on the side wall of the scrap collecting box 3-1, the motor I1-41 is connected with the motor T-shaped chute 3-2 in a sliding way, the threaded shaft IV 1-34 is connected with the motor shaft chute 3-3 in a sliding way, the threaded shaft IV 1-34 is connected with the chain wheel I3-4, the chain wheel I3-4 is connected with the chain wheel II 3-6 and the chain wheel III 3-7 through the chain 3-5, the chain wheel II 3-6 is connected with the chain wheel II shaft 3-8, the chain wheel II shaft 3-8 is rotationally connected with the sliding bracket 3-9, the sliding bracket 3-9 is connected with the sliding bracket T-shaped, a sliding support T-shaped chute 3-10 is positioned on the side wall of a chip collecting box 3-1, two ends of a tension spring III 3-11 are respectively connected with a sliding support 3-9 and a tension spring III fixing plate 3-12, the tension spring III 3-11 is in a stretching state, the tension spring III fixing plate 3-12 is connected with the chip collecting box 3-1, a chain wheel III 3-7 is connected with a cam shaft 3-13, the cam shaft 3-13 is rotationally connected with the chip collecting box 3-1, the cam shaft 3-13 is connected with two cams 3-14, the installation directions of the two cams 3-14 are opposite, two bottom plate limiting frames 3-15 are connected with the inner wall of the chip collecting box 3-1, bottom plates 3-16 are positioned on two bottom plate limiting frames 3-15, a press roll 3-17 is positioned on the bottom plates 3-16, and a chip cleaning door is arranged on the side wall, the iron scraps can be flattened.

The invention relates to an intelligent lathe device, which has the working principle that: placing a cutter 1-19 between a cutter clamping support 1-14 and a cutter clamping plate 1-18, rotating a knob 1-15, wherein the knob 1-15 drives a threaded shaft II 1-16 to rotate, the threaded shaft II 1-16 is axially limited by the cutter clamping support 1-14, the threaded shaft II 1-16 drives the cutter clamping plate 1-18 to slide on a sliding column 1-17 through threads, under the action of the threads, the cutter clamping plate 1-18 clamps the cutter 1-19, a lifting handle 1-10 is pulled up, the lifting handle 1-10 drives a positioning column 1-9 to lift from a positioning hole 1-8, at the moment, the rotating support 1-12 can freely rotate, the angle is adjusted to loosen the lifting handle 1-10, the positioning column 1-9 is inserted into the positioning hole 1-8 again under the action of a tension spring I1-11, the rotary supports 1-12 are limited again, so that the angle of the cutter is adjusted, the motors I1-41 are started, the motors I1-41 drive the threaded shafts IV 1-34 to rotate, the threaded shafts IV 1-34 are limited axially by the motors I1-41, the threaded shafts IV 1-34 drive the threaded support lugs 1-6 to move through threads, the threaded support lugs 1-6 drive the sliding frames 1-7 to move along the sliding rails 1-3, the sliding rails 1-3 drive the rotary supports 1-12, the support columns 1-13 and the cutter clamping supports 1-14 to move, the cutter starts to move towards the moving workpiece clamp assembly 2 at a constant speed, when two cutters 1-19 need to work, the two threaded support lugs 1-6 are firstly adjusted to be completely positioned at two ends of the equipment, then the rotary handles II 1-20 are rotated, the rotary handles II 1-20 drive the magnetic blocks I1-38 to rotate, the angle of a rotary handle II 1-20 is adjusted by switching the adsorption of magnetic blocks I1-38, magnetic blocks II 1-39 and magnetic blocks III 1-40, the rotary handle II 1-20 drives a cam shaft I1-21 to rotate, the cam shaft I1-21 drives a connecting disc I1-22 to rotate, the connecting disc I1-22 drives a connecting rod 1-23 to rotate, the connecting rod 1-23 drives a connecting disc II 1-24 to rotate, the connecting disc II 1-24 drives a cam shaft II 1-25 to rotate, the cam shaft I1-21 and the cam shaft II 1-25 drive two cams 1-26 to be vertical and not in contact with a sliding plate 1-29, under the action of the tension of a tension spring II 1-27, the tension spring II 1-27 drives the sliding plate 1-29 to move, and the sliding plate 1-29 drives a toggle ball column 1, the ball column 1-30 is shifted to drive the sliding sleeve 1-31 to slide on the threaded shaft III 1-32, the spline 1-35 on the threaded shaft IV 1-34 is inserted into the slot 1-36 on the sliding sleeve 1-31, so that the threaded shaft III 1-32 is connected with the threaded shaft IV 1-34 through the sliding sleeve 1-31, when the disconnection is required, the rotating handle II 1-20 is rotated reversely to switch the magnetic block I1-38 to be contacted with the magnetic block II 1-39 and the magnetic block III 1-40, the motor I1-41 is started, the motor I1-41 drives the threaded shaft IV 1-34 to rotate, the threaded shaft IV 1-34 drives the threaded shaft III 1-32 to rotate through the spline 1-35, the slot 1-36 and the sliding sleeve 1-31, the threaded shaft III 1-32 and the threaded shaft IV 1-34 are both provided with threads with opposite rotating directions, 1-32 parts of a threaded shaft III and 1-34 parts of a threaded shaft IV rotate at the same speed to drive two cutters 1-19 to gradually approach, 1-41 parts of a motor are rotated reversely, 1-19 parts of the two cutters are gradually separated, an inner hexagonal wrench is inserted into an inner hexagonal groove of a worm 2-21 and rotates, the wrench drives the worm 2-21 to rotate, the worm 2-21 drives a worm wheel 2-20 to rotate, the worm wheel 2-20 drives a worm wheel shaft 2-19 to rotate, the worm wheel shaft 2-19 drives a clamping gear 2-18 to rotate, the clamping gear 2-18 drives three meshed racks 2-17 to move, the three racks 2-17 drive three helical tooth sliders 2-16 to slide in a clamp shell 2-11, the helical racks 2-15 are meshed with the helical tooth sliders 2-16, and the helical tooth sliders 2-16 are slidably connected with the clamp shell 2-11, the skewed tooth sliders 2-16 are perpendicular to the sliding clamping jaws 2-12, the three skewed tooth sliders 2-16 drive the three sliding clamping jaws 2-12 to simultaneously approach to each other or separate from each other through three skewed racks 2-15 to slide in the clamp shells 2-11, after gaps among the three sliding clamping jaws 2-12 are adjusted to enable a workpiece to be inserted, the three sliding clamping jaws 2-12 approach to each other by reversely rotating the wrench, the three sliding clamping jaws 2-12 drive the three clamping jaws 2-14 to approach to each other, the three clamping jaws 2-14 rotate around the hinge shaft when the workpiece is a stepped shaft, two ends of the clamping jaws 2-14 respectively clamp and automatically center different diameter shafts of the stepped shaft, the clamping is more difficult to loosen due to a plurality of clamping points, the motors II 2-2 are started, and the motors II 2-2 drive the motors II shaft 2-3 to rotate, a motor II shaft 2-3 drives a gear III 2-6 to rotate, the gear III 2-6 drives a gear IV 2-7 to rotate, the gear IV 2-7 drives a gear IV shaft 2-8 to rotate, the gear IV shaft 2-8 drives a clamp connecting support 2-10 to rotate, the clamp connecting support 2-10 drives a clamp shell 2-11 to rotate, the clamp shell 2-11 drives a sliding clamping jaw 2-12 and a clamping jaw 2-14 to rotate, the clamping jaw 2-14 drives a workpiece to rotate, the matched cutter can process by a cutter 1-19 at the moment, when two clamps need to work simultaneously, a holding handle 2-22 and a sliding limiting support 2-23 are held, the sliding limiting support 2-23 slides towards the holding handle 2-22, the sliding limiting support 2-23 drives a limiting clamp I2-24, The limiting clamps II 2-25 are completely slid into the grab handles 2-22, the grab handles 2-22 are not limited any more and can freely slide, the grab handles 2-22 are pushed, the grab handles 2-22 drive the gear supports 2-26 and the gear support shafts 2-27 to move, the gear support shafts 2-27 drive the gears V2-28 to be meshed with the gears I2-4 and II 2-5, the grab handles 2-22 are loosened, under the action of the elastic force of the springs 2-29, the sliding limiting frames 2-23, the limiting clamps I2-24 and the limiting clamps II 2-25 are popped out, the limiting clamps I2-24 are clamped into the transmission case 2-1, the gears V2-28 cannot be in motion stable transmission, the motor II shafts 2-3 drive the gears I2-4 to rotate, the gears I2-4 drive the gears V2-28 to rotate, the gear V2-28 drives the gear II 2-5 to rotate, the gear V2-28 drives the gear II shaft 2-9 to rotate, the gear II shaft 2-9 drives the other clamp connecting bracket 2-10 to rotate, the clamp connecting bracket 2-10 drives the other group of clamps to rotate, the cutters 1-19 on two sides simultaneously move at the moment, two workpieces rotate simultaneously and can start operation synchronously, when the cutting operation is needed, the cutters 1-19 are moved to a cutting position, the rotary handle I1-4 is rotated, the rotary handle I1-4 drives the threaded shaft I1-5 to rotate, the threaded shaft I1-5 is axially limited by the frame 1-1, the threaded shaft I1-5 drives the sliding rail 1-3 to slide in the inner groove 1-2 of the frame through threads, and the sliding rail 1-3 drives the two cutters 1-19 to simultaneously move to cut the workpieces rotating at high speed to finish the operation, scrap iron generated by turning and cutting falls onto a bottom plate 3-16 in a scrap collecting box 3-1, a threaded shaft IV 1-34 drives a chain wheel I3-4 to rotate, the chain wheel I3-4 drives a chain wheel II 3-6 and a chain wheel III 3-7 to rotate through a chain 3-5, when the threaded shaft IV 1-34 slides in a motor shaft chute 3-3, the chain wheel I3-4 moves, the chain wheel I3-4 drives the chain wheel II 3-6, a chain wheel II shaft 3-8 and a sliding support 3-9 to slide along a sliding support T-shaped chute 3-10 track, a tension spring III 3-11 generates tension on the sliding support 3-9, the sliding support 3-9 generates tension on the chain wheel II 3-6 and the chain wheel II shaft 3-8 to enable the chain 3-5 to keep in a tensioned state all the time, the transmission stability of the chain wheel I3-4, the chain 3-5, the chain wheel II 3-6 and the chain wheel III 3-7 is ensured, the chain wheel III 3-7 drives the cam shaft 3-13 to rotate, the cam shaft 3-13 drives the two cams 3-14 to rotate, the installation directions of the two cams 3-14 are opposite, the two cams 3-14 slowly and alternately stir the bottom plate 3-16 to enable the bottom plate 3-16 to alternately incline, the bottom plate 3-16 drives the compression rollers 3-17 to alternately roll at the two ends of the bottom plate 3-16 to flatten scrap iron, the transportation is convenient, and the scrap removing door on the side wall of the scrap collecting box 3-1 is opened to take out the scrap iron after a large amount of.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (4)

1. An intelligent lathe equipment which characterized in that: the intelligent lathe equipment comprises a cutter clamping assembly (1), a workpiece clamp assembly (2) and an iron scrap processing assembly (3), wherein the workpiece clamp assembly (2) is connected with the cutter clamping assembly (1), and the cutter clamping assembly (1) is connected with the iron scrap processing assembly (3).

2. The smart lathe apparatus according to claim 1, wherein: the cutter clamping assembly (1) comprises a rack (1-1), a rack inner groove (1-2), a sliding rail (1-3), a rotary handle I (1-4), a threaded shaft I (1-5), a threaded support lug (1-6), a sliding frame (1-7), a positioning hole (1-8), a positioning column (1-9), a lifting handle (1-10), a tension spring I (1-11), a rotary support (1-12), a support column (1-13), a cutter clamping support (1-14), a knob (1-15), a threaded shaft II (1-16), a sliding column (1-17), a cutter clamping plate (1-18), a cutter (1-19), a rotary handle II (1-20), a cam shaft I (1-21), a connecting disc I (1-22), Connecting rods (1-23), connecting discs II (1-24), camshafts II (1-25), cams (1-26), tension springs II (1-27), clutch supports (1-28), sliding plates (1-29), toggle ball columns (1-30), sliding sleeves (1-31), threaded shafts III (1-32), threaded shaft III supports (1-33), threaded shafts IV (1-34), splines (1-35), slots (1-36), ball grooves (1-37), magnetic blocks I (1-38), magnetic blocks II (1-39), magnetic blocks III (1-40) and motors I (1-41), wherein a rack inner groove (1-2) is located in a rack (1-1), and a sliding rail (1-3) is in sliding connection with the rack inner groove (1-2), the handle I (1-4) is connected with the threaded shaft I (1-5), the threaded shaft I (1-5) is rotatably connected with the rack (1-1), the threaded shaft I (1-5) is in threaded connection with the sliding rail (1-3), the threaded support lug (1-6) is connected with the sliding frame (1-7), the sliding frame (1-7) is in sliding connection with the sliding rail (1-3), the positioning hole (1-8) is positioned on the sliding frame (1-7), the rotating support (1-12) is rotatably connected with the sliding frame (1-7), the handle (1-10) is connected with the positioning column (1-9), the positioning column (1-9) is in sliding connection with the rotating support (1-12), two ends of the tension spring I (1-11) are respectively connected with the rotating support (1-12) and the handle (1-10), the tension spring I (1-11) is in a stretching state, the support column (1-13) is connected with the rotating support (1-12), the support column (1-13) is connected with the cutter clamping support (1-14), the knob (1-15) is connected with the threaded shaft II (1-16), the threaded shaft II (1-16) is rotatably connected with the cutter clamping support (1-14), the sliding column (1-17) is connected with the cutter clamping support (1-14), the cutter clamping plate (1-18) is in threaded connection with the threaded shaft II (1-16), the cutter clamping plate (1-18) is in sliding connection with the sliding column (1-17), the rotary handle II (1-20) is connected with the camshaft I (1-21), and the camshaft I (1-21) is connected with the connecting disc I (1-22), the connecting disc I (1-22) is connected with the connecting rod (1-23), the connecting disc II (1-24) is connected with the camshaft II (1-25), the camshaft I (1-21) and the camshaft II (1-25) are respectively connected with the two cams (1-26), two ends of the tension spring II (1-27) are respectively connected with the clutch support (1-28) and the sliding plate (1-29), the tension spring II (1-27) is in a stretching state, the two sliding plates (1-29) are both connected with the toggle ball column (1-30), the toggle ball column (1-30) is in sliding connection with the ball groove (1-37), the ball groove (1-37) is positioned on the sliding sleeve (1-31), the sliding sleeve (1-31) is in sliding connection with the threaded shaft III (1-32), the screw shaft III (1-32) is rotatably connected with a screw shaft III support (1-33), the screw shaft III support (1-33) is connected with a sliding rail (1-3), the screw shaft III support (1-33) is slidably connected with a sliding groove at the bottom of a rack (1-1), the screw shaft IV (1-34) is slidably connected with a clutch support (1-28), the screw shaft IV (1-34) is connected with a spline (1-35), a slot (1-36) is positioned on a sliding sleeve (1-31), a magnet I (1-38) is connected with a rotating handle II (1-20), a motor I (1-41) is connected with the screw shaft IV (1-34), threads are arranged on the screw shaft III (1-32) and the screw shaft IV (1-34) and have opposite rotating directions, and the screw shaft III (1-32) and the screw shaft IV (1-34) are connected, The threaded shaft IV (1-34) is respectively in threaded connection with the two threaded support lugs (1-6).

3. The smart lathe apparatus according to claim 1, wherein: the workpiece clamp assembly (2) comprises a transmission case (2-1), a motor II (2-2), a motor II shaft (2-3), a gear I (2-4), a gear II (2-5), a gear III (2-6), a gear IV (2-7), a gear IV shaft (2-8), a gear II shaft (2-9), a clamp connecting support (2-10), a clamp shell (2-11), a sliding clamping jaw (2-12), a clamping jaw limiting clamp (2-13), a clamping jaw (2-14), an inclined rack (2-15), an inclined tooth sliding block (2-16), a rack (2-17), a clamping gear (2-18), a worm wheel shaft (2-19), a worm wheel (2-20), a worm (2-21), a grab handle (2-22), A sliding limit frame (2-23), a limit clamp I (2-24), a limit clamp II (2-25), a gear support (2-26), a gear support shaft (2-27), a gear V (2-28) and a spring (2-29), a transmission case (2-1) is connected with a frame (1-1), a motor II (2-2) is connected with the frame (1-1), a motor II (2-2) is connected with a motor II shaft (2-3), the motor II shaft (2-3) is rotationally connected with the transmission case (2-1), the motor II shaft (2-3) is connected with a gear I (2-4) and a gear III (2-6), the gear I (2-4) is not meshed with the gear II (2-5), the gear II (2-5) is connected with a gear II shaft (2-9), a gear II shaft (2-9) is rotationally connected with a transmission case (2-1), a gear III (2-6) is meshed with a gear IV (2-7), the gear IV (2-7) is connected with a gear IV shaft (2-8), the gear IV shaft (2-8) is rotationally connected with the transmission case (2-1), the gear II shaft (2-9) and the gear IV shaft (2-8) are respectively connected with two clamp connecting brackets (2-10), the clamp connecting brackets (2-10) are connected with clamp shells (2-11), a sliding clamping jaw (2-12) is slidably connected with the clamp shells (2-11), a clamping jaw limiting clamp (2-13) is connected with the clamp shells (2-11), and the sliding clamping jaw (2-12) is connected with an oblique rack (2-15), the sliding clamping jaws (2-12) are hinged with the clamping jaws (2-14), the helical racks (2-15) are meshed with helical tooth sliders (2-16), the helical tooth sliders (2-16) are slidably connected with the clamp shell (2-11), the helical tooth sliders (2-16) are perpendicular to the sliding clamping jaws (2-12), the helical tooth sliders (2-16) are connected with the racks (2-17), the racks (2-17) are meshed with clamping gears (2-18), the clamping gears (2-18) are connected with worm gear shafts (2-19), the worm gear shafts (2-19) are rotatably connected with the clamp shell (2-11), the worm gear shafts (2-19) are connected with worm gears (2-20), and the worm gears (2-20) are meshed with worms (2-21), the worm (2-21) is rotationally connected with the clamp shell (2-11), one end of the worm (2-21) is provided with an inner hexagonal groove, the grab handle (2-22) is connected with the transmission case (2-1) in a sliding way, the sliding limiting frame (2-23) is connected with the grab handle (2-22) in a sliding way, the limiting clamp I (2-24) and the limiting clamp II (2-25) are both connected with the sliding limiting frame (2-23), two ends of the spring (2-29) are respectively connected with the sliding limiting frame (2-23), the grab handle (2-22) is connected, the spring (2-29) is in a compressed state, the grab handle (2-22) is connected with the gear support (2-26), the gear support (2-26) is rotationally connected with the gear support shaft (2-27), and the gear support shaft (2-27) is connected with the gear V (2-28).

4. The smart lathe apparatus according to claim 1, wherein: the scrap iron treatment assembly (3) comprises a scrap collecting box (3-1), a motor T-shaped chute (3-2), a motor shaft chute (3-3), a chain wheel I (3-4), a chain (3-5), a chain wheel II (3-6), a chain wheel III (3-7), a chain wheel II shaft (3-8), a sliding support (3-9), a sliding support T-shaped chute (3-10), a tension spring III (3-11), a tension spring III fixing plate (3-12), a cam shaft (3-13), a cam (3-14), a bottom plate limiting frame (3-15), a bottom plate (3-16) and a compression roller (3-17), wherein the cam shaft I (1-21) and the cam shaft II (1-25) are rotationally connected with the side wall of the scrap collecting box (3-1), and a clutch support (1-28) is connected with the inner wall of the scrap collecting box (3-1), the magnet II (1-39) and the magnet III (1-40) are connected with the side wall of the scrap collecting box (3-1), the rack (1-1) is connected with the scrap collecting box (3-1), the motor T-shaped chute (3-2) and the motor shaft chute (3-3) are positioned on the side wall of the scrap collecting box (3-1), the motor I (1-41) is connected with the motor T-shaped chute (3-2) in a sliding manner, the threaded shaft IV (1-34) is connected with the motor shaft chute (3-3) in a sliding manner, the threaded shaft IV (1-34) is connected with the chain wheel I (3-4), the chain wheel I (3-4) is connected with the chain wheel II (3-6) and the chain wheel III (3-7) through the chain (3-5), the chain wheel II (3-6) is connected with the chain wheel II (3-8), a chain wheel II shaft (3-8) is rotationally connected with a sliding support (3-9), the sliding support (3-9) is slidably connected with a sliding support T-shaped chute (3-10), the sliding support T-shaped chute (3-10) is positioned on the side wall of the chip collecting box (3-1), two ends of a tension spring III (3-11) are respectively connected with the sliding support (3-9) and a tension spring III fixing plate (3-12), the tension spring III (3-11) is in a stretching state, the tension spring III fixing plate (3-12) is connected with the chip collecting box (3-1), a chain wheel III (3-7) is connected with a cam shaft (3-13), the cam shaft (3-13) is rotationally connected with the chip collecting box (3-1), the cam shaft (3-13) is connected with two cams (3-14), the two cams (3-14) are installed in opposite directions, the two bottom plate limiting frames (3-15) are connected with the inner wall of the chip collecting box (3-1), the bottom plates (3-16) are positioned on the two bottom plate limiting frames (3-15), the press rollers (3-17) are positioned on the bottom plates (3-16), and chip cleaning doors are arranged on the side walls of the chip collecting box (3-1).

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