CN215279695U - Automatic forming device for bearing ring blank - Google Patents

Abstract

The utility model discloses a bearing ring embryo automatic molding device, including bearing steel bar material hot shearing mechanism with carry out the jumping-up, remove the core, the press of end of cutting, bearing steel bar material hot shearing machine is the hot shearing machine of adjustable length, and qualified rod is connected to the hot shearing machine and is carried positioner, and the press is automatic to carry out the jumping-up, remove the core, end of cutting with the qualified rod in location, and the hot shearing machine of adjustable length sets up the screw thread adjustment stopper in side of hot shearing machine cutter, holds the distance to the cutter through the adjustment stopper, realizes the shearing of the adjustable length of bearing steel bar material. This bearing ring embryo automatic molding device, the material core of getting rid of is by the translation upset material core manipulator centre gripping that sets up between press and the second press, removes the upset preparation station of upset to the second press, and the material core flies out because the bottom unevenness when preventing the second press upset, also avoids forging the in-process and need the operative employee to press from both sides to get, will the operative employee press from both sides when solving forging production and get the material core, can not the fashioned problem of automatic forging.

Description

Automatic forming device for bearing ring blank

Technical Field

The patent of the utility model relates to a bearing ring embryo automatic molding device belongs to the metal pressure processing field.

Background

The forging production of the bearing ring is generally mass production, the forging process directly influences the quality, the labor production efficiency and the production cost of products, the sleeve forging and rolling ring is the most common forging process of the bearing ring, a heated material section is upset, a material core is cut out by a sleeve, an outer ring blank of the material core is cut out by the sleeve and is rolled and formed to obtain a large-ring forge piece, the material core cut out by the sleeve is extruded and formed to be rolled and formed to be another small-ring forge piece, the forging method on a press is called as the sleeve forging and rolling process, the material core of the sleeve material is freely dropped below a working table of the press and then is lifted by a conveyer belt and then is conveyed to the next working procedure, and is clamped by an operator to be conveyed to a backward extrusion working station for forming, the defect is that the material core conveying time is too long, the material core temperature is reduced too much when the backward extrusion working station, the forging process is not beneficial to forging and forming, and the mould life-span reduces because of the temperature reduction of blank, and it is the big trend of current development to forge automation, and the conveyer belt can't realize the accurate positioning of automatic requirement the utility model discloses aim at developing an automatic upset and get the material core device and solve above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is that need the operative employee to press from both sides to get the material core in the forging production, can not the automatic forging shaping, for solving above-mentioned problem, the utility model provides a bearing ring embryo automatic molding device.

The purpose of the utility model is realized with the following mode:

the bearing ring billet automatic forming device comprises a bearing steel bar hot shearing mechanism and a press machine for upsetting, coring and bottoming, wherein the bearing steel bar hot shearing machine is a hot shearing machine with adjustable length, the hot shearing machine is connected with a qualified bar conveying and positioning device, and the press machine automatically performs upsetting, coring and bottoming on the qualified bar.

The hot shearing machine with the adjustable length is characterized in that a thread adjusting limiting block is arranged on the side of a cutter of the hot shearing machine, and the shearing of the bearing steel bar with the adjustable length is realized by adjusting the distance from the end of the limiting block to the cutter.

The qualified bar conveying and positioning device is characterized in that a movable material receiving groove is arranged below a cutter, the movable material receiving groove is connected with a tailing removing device, the tailing removing device is connected with a bar vertical device, the bar vertical device is connected with a vertical bar positioning device, and the stroke end of the vertical bar positioning device is a press upsetting preparation station.

The press machine automatically carries out upsetting, coring and bottom cutting on the well-positioned bar stock, and an upper upsetting die, an upper coring die, an upper bottom cutting die and a lower press machine die holder are sequentially arranged on an upper press machine die holder, an upsetting lower die, a coring lower die and a bottom cutting lower die are correspondingly arranged, four ternary walking beam manipulators are arranged on the corresponding sides of the upper die and the lower die, the device comprises a bar clamping manipulator, an upsetting manipulator, a coring manipulator and a bottom cutting manipulator which are correspondingly arranged in sequence, wherein the manipulators respectively correspondingly clamp a workpiece, and simultaneously moving the workpiece to the next station, moving the bar of the pre-upsetting station to the upsetting station by the bar manipulator, moving the upset material on the upsetting station to the coring station by the upsetting manipulator, moving the cored material on the coring station by the coring manipulator to the bottom cutting station, and moving the bottomed material on the bottom cutting station to the rolling station by the bottom cutting manipulator.

And a second press machine is arranged on the side of the press machine, a translation overturning material core manipulator is arranged between the press machine and the second press machine, and the translation overturning material core manipulator is used for carrying and clamping the material core removed by the press machine and moving and overturning to an upsetting preparation station of the second press machine.

The material core removed by the press machine is received and clamped, and the material core is moved and overturned to the upsetting preparation station of the second press machine, namely a channel for receiving the material core is arranged below the coring lower die of the press machine, and a translation overturning clamping manipulator is arranged between the channel and the upsetting preparation station of the second press machine.

The clamping manipulator capable of translating, overturning and overturning comprises a base, wherein a servo motor is fixed on the base, one end of a telescopic arm is fixed by an output shaft of the servo motor, and the other end of the telescopic arm is a clamping manipulator.

The telescopic arm is an electric telescopic rod or an air cylinder.

The translation, turnover and turnover clamping manipulator comprises a rack, wherein a sliding block is arranged on the rack, and a servo motor is fixed on the sliding block.

One end of the turnover arm is fixed by the output shaft of the servo motor, and the other end of the turnover arm is fixed with the clamping manipulator.

Compared with the prior art, the utility model discloses can be at bearing steel bar material hot shearing mechanism shearing bearing steel bar material, can realize bearing steel bar material adjustable length's shearing through the distance of adjusting thread stopper end to cutter, accomplish the shearing of the required bar of different bearings, adopt same press to carry out the upsetting, coring, the bottom cropping process, at the upsetting, coring, the side installation walking beam manipulator of bottom cropping's press, make the upsetting, the coring, the bottom cropping process is high-efficient to be gone on, material core transmission time is not long, when backward extrusion station, material core temperature reduces a little, be favorable to forging and forming, in addition, the material core that gets rid of is held by the translation upset material core manipulator that sets up between press and the second press, move the upset preparation station that overturns to the second press, the convex bottom of material core and the smooth top upset position that will get rid of so rapidly, the protruding bottom of the removed material core is contacted with the upsetting punch of the second press during downward upsetting, so that the material core is prevented from flying out due to uneven bottom during upsetting of the second press, and the situation that an operator needs to clamp the material core during the traditional forging process is avoided.

Drawings

FIG. 1 is a top perspective view of an automated bearing ring blank forming apparatus.

FIG. 2 is a front perspective view of an automatic molding apparatus for a bearing ring blank.

FIG. 3 is an enlarged view of the automatic forming apparatus for bearing ring blanks at A in FIG. 2.

FIG. 4 is a front view of an automatic molding apparatus for a bearing ring blank.

FIG. 5 is a perspective view of a shearing mechanism of the automatic forming device for bearing ring blanks.

FIG. 6 is a bottom view of the shearing mechanism of the automatic forming device for bearing ring blanks.

Wherein, the device comprises a support frame 1, a shearing press machine 2, a cutter 3, a lower cutting die 4, a thread adjusting limit block 5, a movable material receiving groove 6, a material receiving cylinder 7, a support seat 8, a feeder slide rail 9, a feeder slide block 10, a waste processing cylinder 11, a 12V-shaped groove, a 13 connecting rod, a 14 fixing block, a 15 rotating motor, a 16 discharging channel, a conveying belt 17, a material pushing cylinder 18, a material pushing manipulator 19, a material feeding limit pipe 20, a 21L-shaped baffle plate, a miniature servo motor 22, a press machine 23, a 24 conveying slide rail, a 25 ternary stepping beam manipulator, a 26 second press machine, a 27 servo motor, a 28 telescopic arm, a 29 slide block, a 30 rack, a 31 second ternary stepping beam manipulator, a 32 second conveying slide rail, a 33 second support frame, a 34 blanking support block, a 35 clamping manipulator, a 36 second blanking support block, a 37 bottom plate, a 38 second forging workbench, a 39 support frame, 40 motor support frames, 41 threaded rods, 42 conveying belt support frames, 43 forging workbenches, 44 material pushing servo motors, 45 signal transmitters, 46 arc-shaped material receiving grooves, 47 signal receivers and 48 sensors.

Detailed Description

As shown in fig. 1-5, the automatic forming device for bearing ring blanks comprises a hot shearing mechanism for bearing steel bars and a press 23 for upsetting, coring and bottoming, wherein the hot shearing mechanism for bearing steel bars is a hot shearing machine with adjustable length, the hot shearing machine is connected with a qualified bar conveying and positioning device, and the press 23 automatically performs upsetting, coring and bottoming on the qualified bars.

The hot shearing machine of adjustable length, including support frame 1, support frame 1 middle part lower fixed surface is connected with shearing press 2, and shearing press 2 output end fixedly connected with cutter 3, the connected mode between shearing press 2 and the cutter 3 is the same with the current connected mode in the forging process, and 3 below of cutter are provided with down cutting die 4, touch 4 through 3 downstream movements of cutter and lower cutter and constitute cutting die, set up screw thread adjustment stopper 5 in side of cutter 3, through the distance of adjustment stopper end to cutter 3, realize bearing steel bar adjustable length's shearing.

The qualified bar conveying and positioning device is characterized in that a movable material receiving groove 6 is arranged below a cutter 3, one side of the movable material receiving groove 6 is connected with a material receiving cylinder 7 through a connecting rod, the bottom of the material receiving cylinder 7 is fixedly connected to a supporting seat 8, one end, far away from the material receiving cylinder 7, of the supporting seat 8 is fixedly connected with a feeder slide rail 9, the feeder slide rail 9 is movably connected with a feeder slide block 10, the lower surface of one end, far away from the feeder slide rail 9, of the feeder slide block 10 is fixedly connected with a material pushing servo motor 44, the top of the supporting seat 8 is fixedly connected with a V-shaped groove 12, the V-shaped groove 12 and the material pushing servo motor 44 are coaxial, one end, far away from the material pushing servo motor 44, of the V-shaped groove 12 is provided with a tail material outlet, a waste material processing cylinder 11 is arranged opposite to the tail material outlet, one side, close to the waste material processing cylinder 11, of the V-shaped groove 12 is fixedly connected with a signal emitter 45, and the supporting seat 8 is connected with a fixing block 14 through a connecting rod 13, the connecting rod 13 is made of insulating rubber materials, a discharging channel 16 is arranged on the fixed block 14, an arc-shaped receiving groove 46 is fixedly connected to one side, close to the supporting seat 8, of the fixed block 14, a signal receiver 47 is fixedly connected to one end, close to the fixed block 14, of the outer surface of the bottom of the arc-shaped receiving groove 46, the height difference between the arc-shaped receiving groove 46 and the V-shaped groove 12 is smaller than the diameter of a processing bearing, a 1-2 mm gap is kept between the V-shaped groove 12 and the arc-shaped receiving groove 46, when no material exists on the V-shaped groove 12, the V-shaped groove 12 and the signal receiver are disconnected, if the material section sent to a testing position from a feeding area is a normal material section, the right end of the material section on the V-shaped groove 12 is in contact with the left end of the material section on the arc-shaped receiving groove 46, the signal receiver 47 receives a signal sent by the signal transmitter 45 and regards the signal as a qualified material section, and the slider 10 of the feeder returns to perform next round of circulation.

And on the contrary, if the feeding section cannot touch the previous section, the processing is carried out according to the material tail.

The scrap handling cylinder 11 opposite the tail outlet of the V-groove 12 is activated to push the length of bar out of the V-groove 12.

When the bottom of the fixed block 14 is fixedly connected with a rotating motor 15, the output end of the rotating motor 15 is connected with one end of a conveying belt 17, the other end of the conveying belt 17 is connected with a conveying belt supporting frame 42, the bottom of the conveying belt supporting frame 42 is connected with a forging workbench 43, one end of the forging workbench 43 is connected with a material pushing cylinder 18, the material pushing cylinder 18 is connected with a material pushing manipulator 19 through a piston rod, the top of the material pushing manipulator 19 is provided with a feeding limiting pipe 20, the bottom of the forging workbench 43 is fixedly connected with an inductor 48, the inductor 48 is positioned under the feeding limiting pipe 20, one side of the feeding limiting pipe 20, which is far away from the material pushing cylinder 18, is provided with an L-shaped baffle plate 21, the outer surface of the feeding limiting pipe 20 is fixedly connected with a motor supporting frame 40, the top of the motor supporting frame 40 is fixedly connected with a micro servo motor 22, the output end of the micro servo motor 22 is fixedly connected with a threaded rod 41, and the threaded rod 41 is in threaded connection with one end of the L-shaped baffle plate 21, the feeding limiting pipe 20 receives the workpiece output from the conveying belt 17, the feeding limiting pipe 20 is movably connected with the L-shaped baffle 21 through the sliding groove, when the workpiece falls onto the forging workbench 43 in the feeding limiting pipe 20, the falling workpiece is prevented from turning over laterally because the feeding limiting pipe 20 is matched with the L-shaped baffle 21, the sensor 48 can sense the workpiece, the micro servo motor 22 is triggered to start working, the micro servo motor 22 drives the threaded rod 41 to rotate, the L-shaped baffle 21 moves upwards to prevent the pushing manipulator 19 from moving, then the pushing manipulator 19 clamps the workpiece, and the workpiece is moved to the upsetting preparation station of the press 23 with the help of the pushing cylinder 18.

Forging workstation 43 top is provided with press 23, press 23 one side fixedly connected with support frame 39, forging workstation 43 keeps away from support frame 39 one side fixedly connected with and carries slide rail 24, carry slide rail 24 go up sliding connection have ternary walking beam manipulator 25, four ternary walking beam manipulators 25 are simultaneously equidistance removal on carrying slide rail 24, it connects the upright device of bar to go the tails device, the upright device of bar is connected upright bar positioner, upright bar positioner's stroke tip is press 23 upset preparation station.

The press 23 automatically carries out upsetting, coring and bottom cutting on the well-positioned bar stock, and an upper upsetting die, an upper coring die, an upper bottom cutting die and a lower press die holder are sequentially arranged on an upper press die holder, an upsetting lower die, a coring lower die and a bottom cutting lower die are correspondingly arranged, four ternary walking beam manipulators 25 are arranged on the corresponding sides of the upper die and the lower die, the device comprises a bar clamping manipulator, an upsetting manipulator, a coring manipulator and a bottom cutting manipulator which are correspondingly arranged in sequence, wherein the manipulators respectively correspondingly clamp a workpiece, and simultaneously moving the workpiece to the next station, moving the bar of the pre-upsetting station to the upsetting station by the bar manipulator, moving the upset material on the upsetting station to the coring station by the upsetting manipulator, moving the cored material on the coring station by the coring manipulator to the bottom cutting station, and moving the bottomed material on the bottom cutting station to the rolling station by the bottom cutting manipulator.

The second press machine 26 is arranged on the side of the press machine 23, a translation overturning material core manipulator is arranged between the press machine 23 and the second press machine 26, the translation overturning material core manipulator receives and clamps a material core removed by the press machine 23, and moves and overturns to an upsetting preparation station of the second press machine 26, one side of the second press machine 26 is connected with a bottom plate 37 through a second support frame 33, a second forging workbench 38 is fixedly connected above the bottom plate 37, a second blanking support block 36 is fixedly connected to the bottom of the second forging workbench 38, the second blanking support block 36 is concentric with a core removing process female die, one side of the second forging workbench 38, far away from the second support frame 33, is fixedly connected with a second conveying slide rail 32, and a second ternary stepping beam manipulator 31 is movably connected onto the second conveying slide rail 32.

The receiving and clamping of the material core removed by the press 23 and the moving and turning to the upsetting preparation station of the second press 26 mean that a channel for receiving the material core is arranged below the coring lower die of the press 23, a translational turning clamping manipulator is arranged between the channel and the upsetting preparation station of the second press 26, and the driving modes of the manipulator are generally four types: the clamping manipulator adopts hydraulic drive, and hydraulic transmission of the manipulator takes pressurized oil as a working medium for transmitting power.

The motor drives the oil pump to output pressure oil, and mechanical energy supplied by the motor is converted into pressure energy of the oil.

Pressure oil enters the oil cylinder through a pipeline and some control and regulation devices and the like, and the piston rod is pushed to move, so that the arm moves in a stretching mode, a lifting mode and the like, and the pressure energy of the oil is converted into mechanical energy.

The frictional resistance that the arm can overcome when moving to and the required holding power that keeps when the centre gripping formula hand presss from both sides tight work piece size are all relevant with the effective working area of fluid pressure and piston.

The speed of the arm in various movements is determined by the volume of oil flowing into the sealed oil cylinder.

The hydraulic transmission for transmitting power by means of the volume change of the moving pressure oil is called as a positive displacement hydraulic transmission, and the hydraulic transmission system of the manipulator belongs to the positive displacement hydraulic transmission.

Translation upset centre gripping manipulator, including the base, fixed servo motor 27 on the base, servo motor 27 output shaft fixes flexible arm 28 one end, and flexible arm 28 other end is centre gripping manipulator 35.

The telescopic arm 28 is an electric telescopic rod or an air cylinder.

The translation, turnover and clamping manipulator comprises a rack 30, wherein a sliding block 29 is arranged on the rack 30, a servo motor 27 is fixed on the sliding block 29, one end of a turnover arm is fixed on an output shaft of the servo motor 27, and a clamping manipulator 35 is fixed at the other end of the turnover arm.

The working process of the utility model is as follows: adjusting the distance between the thread adjusting limit block 5 and the cutter 3 to be the same as the length of a part to be processed, starting a shearing press to shear the bar, moving the sheared bar to the inlet of the V-shaped groove 12 by the material receiving cylinder 7, then pushing the bar to the V-shaped groove 12 by the material pushing servo motor 44, if the material section sent to the test position from the feeding area is a normal material section, contacting the right end of the material section on the V-shaped groove 12 with the left end of the material section on the arc-shaped receiving groove 46, receiving a signal transmitted by the signal transmitter 45 by the signal receiver 47, regarding the signal as a qualified material section, returning the feeder slide block 10, enabling the qualified bar to reach a preparation upsetting station of the press 23 through the conveyer belt 17 and the material pushing manipulator 19, clamping the qualified bar to a coring station by an upsetting manipulator in the ternary stepping beam manipulator 25 after upsetting of the press 23, clamping the cored bar to the next station of the forging workbench 43 by the coring manipulator, and finishing large-size bearing forging, overturning the removed core material to an upsetting preparation station of the second press 26 by the clamping manipulator 35, the servo motor 27 and the telescopic arm 28, and finishing small-size bearing forging under the cooperation of the second press 26 and the second three-way walking beam manipulator 31.

While the preferred embodiments of the present invention have been described, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the general inventive concept, and it is intended to cover all such changes and modifications as fall within the true spirit and scope of the invention.

Claims (9)

1. The automatic forming device for the bearing ring blank comprises a bearing material thermal shearing mechanism and a press machine for upsetting, coring and bottoming, and is characterized in that the bearing material thermal shearing mechanism is a thermal shearing machine with adjustable length, the thermal shearing machine is connected with a qualified bar conveying and positioning device, and the press machine automatically performs upsetting, coring and bottoming on the qualified bar.

2. The automatic forming device for the bearing ring blank according to claim 1, wherein a thread adjusting limiting block is arranged on the side of a cutter of the hot shearing machine, and the bearing steel bar is sheared in an adjustable length by adjusting the distance from the end of the limiting block to the cutter.

3. The automatic bearing ring billet forming device as claimed in claim 1, wherein the qualified bar material conveying and positioning device is provided with a movable receiving groove below the cutting knife, the movable receiving groove is connected with a tailing removing device, the tailing removing device is connected with a bar material standing device, the bar material standing device is connected with an upright bar material positioning device, and the stroke end of the upright bar material positioning device is a press upsetting preparation station.

4. The automatic forming device for the bearing ring blank as claimed in claim 1, wherein the press automatically performs upsetting, coring and bottom cutting on the well-positioned bar stock, an upper upsetting die, an upper coring die and a upper bottom cutting die are sequentially arranged on an upper die base of the press, a lower die base of the press is correspondingly provided with a lower upsetting die, a lower coring die and a lower bottom cutting die, four three-dimensional walking beam manipulators are correspondingly arranged on the corresponding sides of the upper die and the lower die, and the four-dimensional walking beam manipulators are correspondingly sequentially a bar stock clamping manipulator, an upsetting machine manipulator, a coring machine manipulator and a bottom cutting machine manipulator.

5. The automatic forming device for bearing ring blanks as claimed in claim 1, wherein a second press is arranged at the side of the press, a translation and overturning core manipulator is arranged between the presses and the second press, and the translation and overturning core manipulator receives and clamps the cores removed by the presses and moves to overturn to an upsetting preparation station of the second press.

6. The automatic forming device for bearing ring blanks as claimed in claim 5, wherein the step of receiving and clamping the removed core by the press and moving the turning-over to the upsetting preparation station of the second press is that a channel for receiving the core is arranged below the lower core removing die of the press, and a translation turning-over clamping manipulator is arranged between the channel and the upsetting preparation station of the second press.

7. The automatic molding device for bearing ring blanks as claimed in claim 6, wherein said translational overturning clamping robot comprises a base, a servo motor is fixed on the base, an output shaft of the servo motor is fixed on one end of a telescopic arm, and the other end of the telescopic arm is a clamping robot.

8. The automatic molding device for bearing ring blanks as claimed in claim 7, wherein said telescopic arm is an electric telescopic rod or a pneumatic cylinder.

9. The automatic molding device for bearing ring blanks as claimed in claim 6, wherein the translational overturning and clamping manipulator comprises a frame, a slide block is arranged on the frame, a servo motor is fixed on the slide block, a servo motor output shaft is fixed on the slide block, one end of an overturning arm is fixed, and the other end of the overturning arm is fixed on the clamping manipulator.

Images