CN112008556A

CN112008556A - Metal bar processing device

Info

Publication number: CN112008556A
Application number: CN202010884404.7A
Authority: CN
Inventors: 程军锋
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-28
Filing date: 2020-08-28
Publication date: 2020-12-01

Abstract

The invention relates to the field of metal bars, in particular to a metal bar processing device. The technical problems of the invention are as follows: provided is a metal bar processing device. The technical scheme is as follows: a metal bar processing device comprises a working frame plate, a supporting bottom plate, an operation control screen, a feeding control mechanism, a fixing mechanism, a storage cabin and the like; the feeding control mechanism is connected with the fixing mechanism. The six-edge-grinding-type quick turnover mechanism achieves the effects that the edges of the manufactured six-edge-grinding bar are ground in time to replace manual operation, the six-edge-grinding-type quick turnover mechanism can quickly turn over the six-edge-grinding bar, the six edges of the six-edge-grinding bar are completely ground in a short time, the six-edge-grinding-type quick turnover mechanism can quickly stack the six-edge-grinding bar after mass production, the space is saved, meanwhile, the six sides of the six-edge-grinding-type quick turnover mechanism are tightly attached, the overall stability after stacking is improved, and safety accidents are avoided.

Description

Metal bar processing device

Technical Field

The invention relates to the field of metal bars, in particular to a metal bar processing device.

Background

Bar stock is a material in the shape of a long rod of circular or polygonal shape having a certain length, for plates and other profiles. The existing hexagonal prism type bar is easy to form irregular redundant parts such as bulges and burrs at the edge positions after being manufactured and molded, six side faces of the hexagonal prism type bar are difficult to be tightly attached to each other during stacking, gaps are easy to form between the hexagonal prism type bars, the overall structure is unstable after stacking, the hexagonal prism type bar is easy to collapse and safety accidents are caused, the hexagonal prism type bar needs to be overturned for multiple times when the edge positions of the hexagonal prism type bar are polished manually, time and labor are wasted, the working efficiency is extremely low, the edges of the hexagonal prism type bar cannot be polished in time, the hexagonal prism type bar cannot be effectively stacked, a large amount of space is occupied, meanwhile, the redundant parts such as the bulges and the burrs are more tightly combined with the hexagonal prism type bar after being placed and cooled for a long time, the polishing difficulty is increased, and the production quality is greatly reduced.

In view of the above, there is a need for a metal bar processing apparatus to solve the above problems.

Disclosure of Invention

In order to overcome the defects that irregular redundant parts such as bulges and burrs and the like are easily formed at the edge positions of the conventional hexagonal prism-shaped bar after the conventional hexagonal prism-shaped bar is manufactured and molded, the six side surfaces of the hexagonal prism-shaped bar are difficult to be tightly attached to each other during stacking, gaps are easily formed among the hexagonal prism-shaped bars, the overall structure is unstable after stacking, the hexagonal prism-shaped bar is easy to collapse and safety accidents are caused, the hexagonal prism-shaped bar needs to be overturned for multiple times when the edge positions of the hexagonal prism-shaped bar are polished manually, time and labor are wasted, the working efficiency is extremely low, the edges of the hexagonal prism-shaped bar cannot be polished in time, the hexagonal prism-shaped bar cannot be effectively stacked, a large amount of space is occupied, and the redundant parts such as the bulges and the burrs are more tightly combined with the hexagonal prism-shaped bar after being cooled for a long time, the polishing, the technical problems of the invention are as follows: provided is a metal bar processing device.

The technical scheme is as follows: a metal bar processing device comprises a working frame plate, a supporting bottom plate, an operation control screen, a feeding control mechanism, a fixing mechanism, a polishing mechanism and a storage cabin; the working frame plate is welded with the supporting bottom plate; the working frame plate is connected with the operation control screen through the supporting seat; the working frame plate is connected with the feeding control mechanism; the working frame plate is connected with the fixing mechanism; the working frame plate is connected with the polishing mechanism; a feeding control mechanism, a fixing mechanism and a storage cabin are sequentially arranged above the supporting bottom plate; the feeding control mechanism is connected with the fixing mechanism.

Further, the feeding control mechanism comprises a stepping motor, a first driving wheel, a second driving wheel, a first electric push rod, a third driving wheel, a conveying belt, a fourth driving wheel, a first flat gear, a first connecting plate, a second electric push rod, a second flat gear, a fifth driving wheel, a third flat gear and a sixth driving wheel; the stepping motor is rotationally connected with the first driving wheel through a rotating shaft; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; the second driving wheel is connected with the first electric push rod through a supporting seat; the outer ring surface of the first driving wheel is in transmission connection with a third driving wheel through a belt; the outer ring surface of the second driving wheel is in transmission connection with a third driving wheel through a belt; the axle center of the third driving wheel is in transmission connection with the conveying belt through a transmission rod; the outer ring surface of the first driving wheel is in transmission connection with a fourth driving wheel through a belt; the axle center of the fourth driving wheel is rotationally connected with the first flat gear through a driving rod; the fourth transmission wheel and the first flat gear are both connected with the first connecting plate; the first connecting plate is inserted with the second electric push rod; a second flat gear is arranged on the side surface below the first flat gear; the second gear hub is rotationally connected with the fifth driving wheel through a driving rod; a third flat gear is arranged on the upper side surface of the first flat gear; the third gear hub is rotationally connected with the sixth driving wheel through a driving rod; the stepping motor is connected with the supporting bottom plate; the first electric push rod is connected with the working frame plate; the third driving wheel is connected with the working frame plate; the conveying belt is connected with the working frame plate; the first flat gear is connected with the working frame plate; the second electric push rod is connected with the supporting bottom plate; the second flat gear is connected with the working frame plate; the fifth driving wheel is connected with the fixing mechanism; the third horizontal gear is connected with the working frame plate; the sixth driving wheel is connected with the fixing mechanism.

Further, the fixing mechanism comprises a seventh driving wheel, a fourth flat gear, a first pinion rack, a first sliding base, a first sliding rod, a third electric push rod, a fixing frame, a fixing seat, a telescopic plate, a fourth electric push rod, a fifth electric push rod, a second sliding base, a second sliding rod, a second pinion rack, a fifth flat gear and an eighth driving wheel; the axle center of the seventh driving wheel is rotationally connected with the fourth flat gear through a driving rod; the lower part of the fourth flat gear is in transmission connection with the first gear tooth plate; the lower part of the first wheel toothed plate is welded with the first sliding base; the inner surface of the first sliding base is in sliding connection with the first sliding rod; a third electric push rod is arranged below the first sliding base; the third electric push rod is inserted into the fixed frame; a fixed seat is arranged below the fixed frame; a telescopic plate is arranged below the front side of the fixed seat; a fourth electric push rod and a fifth electric push rod are sequentially arranged below the telescopic plate; the lower parts of the fourth electric push rod and the fifth electric push rod are connected with a second sliding base; the inner surface of the second sliding base is in sliding connection with the second sliding rod; the lower part of the second sliding base is welded with a second gear tooth plate; the second toothed plate is in transmission connection with the fifth flat gear; the axis of the fifth flat gear is rotationally connected with the eighth transmission wheel through a transmission rod; the seventh driving wheel is connected with the sixth driving wheel; the fourth flat gear is connected with the working frame plate through a supporting seat; the first sliding rod is connected with the working frame plate through a supporting seat; the fixed seat is connected with the supporting bottom plate; the second sliding rod is connected with the supporting bottom plate through a supporting seat; the fifth flat gear is connected with the supporting bottom plate through a supporting seat; the eighth driving wheel is connected with the fifth driving wheel.

Further, the polishing mechanism comprises a bearing frame, a servo motor, a ninth transmission wheel, a tenth transmission wheel, a sixth flat gear, a third toothed plate, a third sliding base, a first sliding plate, a second sliding plate, a first sliding rail, a second sliding rail, an eleventh transmission wheel, a first bevel gear, a second bevel gear, a telescopic rod, a first column gear, a seventh flat gear, a second coupling plate, a sixth electric push rod, a second column gear, an inner gear ring sleeve, a switching frame, a micro motor, a first coupling rod, a second coupling rod, a third coupling rod, a fourth coupling rod, a fifth coupling rod, a fourth sliding base, a third sliding rail, a coupling block, a first polishing block and a second polishing block; a servo motor is arranged in the bearing frame; the outer ring surface of the ninth driving wheel is in transmission connection with the tenth driving wheel through a belt; the axle center of the tenth transmission wheel is rotationally connected with the sixth flat gear through a transmission rod; the sixth flat gear is in transmission connection with the third toothed plate; the upper part of the third pinion rack is welded with the third sliding base; a first sliding plate and a second sliding plate are sequentially arranged below the third sliding base; the first sliding plate is connected with the first sliding rail in a sliding manner; the second sliding plate is connected with the second sliding rail in a sliding manner; the outer ring surface of the ninth driving wheel is in transmission connection with the eleventh driving wheel through a belt; the shaft center of the eleventh transmission wheel is rotationally connected with the first bevel gear through a transmission rod; the first bevel gear is meshed with the second bevel gear; the second bevel gear hub is rotationally connected with the telescopic rod through a transmission rod; the telescopic rod is rotationally connected with the first column gear through the transmission rod; a seventh flat gear is arranged on the side surface above the first cylindrical gear; the seventh flat gear is connected with the second connecting plate; the second connection plate is inserted with a sixth electric push rod; the axis of the seventh flat gear is rotationally connected with the second column gear through a transmission rod; the outer surface of the second column gear is meshed with the inner gear sleeve; the third sliding base is connected with the inner gear ring sleeve through a supporting seat; the axis of the inner gear ring sleeve is rotationally connected with the switching frame through a transmission rod; a micro motor is arranged in the switching frame; the micro motor is rotationally connected with the first connecting rod through an output shaft; the first connecting rod is in transmission connection with the second connecting rod; one side of the outer surface of the third connecting rod is connected with the second connecting rod, and the other side of the outer surface of the third connecting rod is connected with the fourth connecting rod; the fourth connecting rod is in transmission connection with the fifth connecting rod; the fifth connecting rod is in transmission connection with the fourth sliding base; the fourth sliding base is in sliding connection with the third sliding rail; the side surface of the fourth sliding base is welded with the connecting block; one side of the connecting block is welded with the first polishing block, and the other side of the connecting block is welded with the second polishing block; the bearing frame is connected with the working frame plate.

Furthermore, a groove with a trapezoidal longitudinal section and a downward opening is arranged below the fixing frame.

Furthermore, a groove with a trapezoidal longitudinal section and an upward opening is arranged above the fixed seat.

Furthermore, the expansion plate is formed by mutually splicing a convex plate and a concave plate.

Furthermore, the longitudinal sections of the first sliding plate and the second sliding plate are both T-shaped.

Has the advantages that: 1. in order to solve the problem that irregular redundant parts such as bulges, burrs and the like are easily formed at the edge position after the existing hexagonal prism type bar is manufactured and molded, when stacking, the six side surfaces of the hexagonal prism-shaped bars are difficult to be tightly attached to each other, gaps are easy to form among the hexagonal prism-shaped bars, the overall structure is unstable after stacking, the hexagonal prism bar is easy to collapse, safety accidents are caused, the hexagonal prism bar needs to be overturned for multiple times when the edge position of the hexagonal prism bar is polished manually, time and labor are wasted, the working efficiency is extremely low, the edges of the hexagonal prism bar cannot be polished in time, therefore, the hexagonal prism-shaped bars cannot be effectively stacked, a large amount of space is occupied, and meanwhile, after the hexagonal prism-shaped bars are placed and cooled for a long time, the excessive parts such as bulges and burrs are combined with the hexagonal prism-shaped bars more tightly, the polishing difficulty is increased, and the production quality is greatly reduced;

2. the feeding control mechanism, the fixing mechanism and the polishing mechanism are designed, firstly, an operator places cut hexagonal prism-shaped bars on a conveyor belt, the feeding control mechanism moves the fed hexagonal prism-shaped bars into the fixing mechanism, then the fixing mechanism fixes the hexagonal prism-shaped bars at a specified position, then the polishing mechanism is started, edges of the manufactured hexagonal prism-shaped bars are polished by the polishing mechanism, and then the polished hexagonal prism-shaped bars are conveyed into a storage cabin through the fixing mechanism to be stacked;

3. the hexagonal prism type bar stock after having reached the preparation completion carries out timely edge polishing treatment, replace manual operation, can carry out quick upset to hexagonal prism type bar stock, the completion of polishing six edges of hexagonal prism type bar stock in the short time, and then make hexagonal prism type bar stock can put things in good order fast after mass production, save space, make six sides of hexagonal prism type bar stock closely laminate simultaneously, promote the overall stability after putting things in good order, avoid taking place the effect of incident.

Drawings

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

FIG. 2 is a schematic structural diagram of a feeding control mechanism according to the present invention;

FIG. 3 is a schematic structural view of a fixing mechanism of the present invention;

FIG. 4 is a left side view of the grinding mechanism of the present invention;

FIG. 5 is a schematic perspective view of a first sanding block of the present invention;

FIG. 6 is an enlarged view of area A of the present invention;

fig. 7 is an enlarged view of region B of the present invention.

In the figure: 1. working frame plate, 2, supporting base plate, 3, operation control screen, 4, feeding control mechanism, 5, fixing mechanism, 6, polishing mechanism, 7, storage cabin, 401, stepping motor, 402, first driving wheel, 403, second driving wheel, 404, first electric push rod, 405, third driving wheel, 406, conveyor belt, 407, fourth driving wheel, 408, first flat gear, 409, first connecting plate, 4010, second electric push rod, 4011, second flat gear, 4012, fifth driving wheel, 4013, third flat gear, 4014, sixth driving wheel, 501, seventh driving wheel, 502, fourth flat gear, 503, first toothed plate, 504, first sliding base, 505, first sliding rod, 506, third electric push rod, 507, fixing frame, 508, fixing seat, 509, telescopic plate, 5010, fourth electric push rod, 5011, fifth electric push rod, 5012, second sliding base, 5013, A second slide bar, 5014, a second toothed plate, 5015, a fifth flat gear, 5016, an eighth transmission wheel, 601, a receiving frame, 602, a servo motor, 603, a ninth transmission wheel, 604, a tenth transmission wheel, 605, a sixth flat gear, 606, a third toothed plate, 607, a third sliding base, 608, a first sliding plate, 609, a second sliding plate, 6010, a first sliding rail, 6011, a second sliding rail, 6012, an eleventh transmission wheel, 6013, a first bevel gear, 6014, a second bevel gear, 6015, a telescopic rod, 6016, a first column gear, 6017, a seventh flat gear, 6018, a second coupling plate, 6019, a sixth electric push rod, 6020, a second column gear, 6021, an internal tooth, a collar 6022, a switching frame, 6023, a micro motor, 6024, a first coupling rod, 6025, a second coupling rod, 6026, a third coupling rod, 6027, a fourth coupling rod, 6028, a fifth coupling rod, a third sliding base, 609, a fourth sliding rail, 6031. a coupling block 6032, a first sanding block 6033 and a second sanding block.

Detailed Description

The invention is described in further detail below with reference to the drawings and the detailed description, but the invention is not limited to the scope of protection and application.

Example 1

A metal bar processing device is shown in figures 1-7 and comprises a working frame plate 1, a supporting bottom plate 2, an operation control screen 3, a feeding control mechanism 4, a fixing mechanism 5, a grinding mechanism 6 and a storage cabin 7; the working frame plate 1 is welded with the supporting bottom plate 2; the working frame plate 1 is connected with the operation control screen 3 through a supporting seat; the working frame plate 1 is connected with a feeding control mechanism 4; the working frame plate 1 is connected with a fixing mechanism 5; the working frame plate 1 is connected with a polishing mechanism 6; a feeding control mechanism 4, a fixing mechanism 5 and a material storage cabin 7 are sequentially arranged above the supporting bottom plate 2; the feeding control mechanism 4 is connected with the fixing mechanism 5.

When the device is used, the device is horizontally fixed in a hexagonal prism bar manufacturing workshop through a working frame plate 1 and a supporting base plate 2 and is externally connected with a power supply, an operator allocates the device through an operation control screen 3, firstly, the operator places the cut hexagonal prism bar on a conveyor belt 406, moves the fed hexagonal prism bar into a fixing mechanism 5 through a feeding control mechanism 4, fixes the hexagonal prism bar at a specified position through the fixing mechanism 5, then, a polishing mechanism 6 is started, performs edge polishing on the manufactured hexagonal prism bar through the polishing mechanism 6, conveys the polished hexagonal prism bar into a storage cabin 7 through the fixing mechanism 5 to stack, the device achieves timely edge polishing treatment on the manufactured hexagonal prism bar, replaces manual operation, and can rapidly turn over the hexagonal prism bar, the six edges of the hexagonal prism type bar are completely polished in a short time, so that the hexagonal prism type bar can be quickly stacked after mass production, the space is saved, the six side faces of the hexagonal prism type bar are tightly attached, the overall stability after stacking is improved, and the safety accidents are avoided.

According to the invention, the feeding control mechanism 4 comprises a stepping motor 401, a first driving wheel 402, a second driving wheel 403, a first electric push rod 404, a third driving wheel 405, a conveyor belt 406, a fourth driving wheel 407, a first flat gear 408, a first connecting plate 409, a second electric push rod 4010, a second flat gear 4011, a fifth driving wheel 4012, a third flat gear 4013 and a sixth driving wheel 4014; the stepping motor 401 is rotatably connected with the first driving wheel 402 through a rotating shaft; the outer ring surface of the first driving wheel 402 is in driving connection with a second driving wheel 403 through a belt; the second driving wheel 403 is connected with the first electric push rod 404 through a support seat; the outer ring surface of the first driving wheel 402 is in driving connection with a third driving wheel 405 through a belt; the outer annular surface of the second driving wheel 403 is in transmission connection with a third driving wheel 405 through a belt; the axle center of the third driving wheel 405 is in driving connection with the conveyor belt 406 through a driving rod; the outer annular surface of the first driving wheel 402 is in transmission connection with a fourth driving wheel 407 through a belt; the axle center of the fourth driving wheel 407 is rotationally connected with the first flat gear 408 through a driving rod; the fourth transmission wheel 407 and the first flat gear 408 are both connected with a first connecting plate 409; the first connecting plate 409 is inserted into the second electric push rod 4010; a second flat gear 4011 is arranged on the side surface below the first flat gear 408; the axle center of the second flat gear 4011 is rotationally connected with a fifth driving wheel 4012 through a driving rod; a third flat gear 4013 is arranged on the upper side surface of the first flat gear 408; the axle center of the third flat gear 4013 is rotationally connected with a sixth driving wheel 4014 through a driving rod; the stepping motor 401 is connected with the support base plate 2; the first electric push rod 404 is connected with the working frame plate 1; the third driving wheel 405 is connected with the working frame plate 1; the conveyor belt 406 is connected with the working frame plate 1; the first spur gear 408 is connected with the working frame plate 1; the second electric push rod 4010 is connected with the support base plate 2; the second flat gear 4011 is connected with the working frame plate 1; the fifth driving wheel 4012 is connected with the fixing mechanism 5; the third horizontal gear 4013 is connected with the working frame plate 1; the sixth driving wheel 4014 is connected to the fixing mechanism 5.

When the manufactured hexagonal prism type bar stock is manually placed on the conveyor belt 406, an operator operates the control screen 3 to start the stepping motor 401, the stepping motor 401 drives the first driving wheel 402 to rotate, the third driving wheel 405 is further driven to rotate, the conveyor belt 406 is further driven, the hexagonal prism type bar stock is conveyed through the conveyor belt 406, when the stepping motor 401 needs to rotate reversely, the control screen 3 is operated to start the first electric push rod 404, the second driving wheel 403 is pushed to be pulled to one side close to the first electric push rod 404, a belt between the first driving wheel 402 and the third driving wheel 405 is loosened, the third driving wheel 405 stops rotating, the conveyor belt 406 is prevented from rotating reversely, when the fifth driving wheel 4012 needs to rotate to provide power for the fixing mechanism 5, the control screen 3 is operated to start the second electric push rod 4010, the first connecting plate 409 is pulled to move to one side close to the second electric push rod 4010, and then make first pinion 408 mesh with second pinion 4011 and first pinion 408 drive second pinion 4011 and rotate, and then drive fifth drive wheel 4012 and rotate, when needing sixth drive wheel 4014 to rotate and provide power for fixed establishment 5, then pull first link plate 409 to move to the side of keeping away from second electric push rod 4010 through second electric push rod 4010, and then make first pinion 408 mesh with third pinion 4013 and first pinion 408 drive third pinion 4013 and rotate, and then drive sixth drive wheel 4014 and rotate, this mechanism has realized the quick material loading to the hexagonal prism type bar stock and has carried out power control to fixed establishment 5.

According to the invention, the fixing mechanism 5 comprises a seventh transmission wheel 501, a fourth flat gear 502, a first toothed plate 503, a first sliding base 504, a first sliding rod 505, a third electric push rod 506, a fixed mount 507, a fixed seat 508, a telescopic plate 509, a fourth electric push rod 5010, a fifth electric push rod 5011, a second sliding base 5012, a second sliding rod 5013, a second toothed plate 5014, a fifth flat gear 5015 and an eighth transmission wheel 5016; the axle center of the seventh transmission wheel 501 is rotationally connected with the fourth flat gear 502 through a transmission rod; the lower part of the fourth flat gear 502 is in transmission connection with a first toothed plate 503; the lower part of the first toothed plate 503 is welded with the first sliding base 504; the inner surface of the first slide base 504 is in sliding connection with a first slide bar 505; a third electric push rod 506 is arranged below the first sliding base 504; the third electric push rod 506 is inserted into the fixing frame 507; a fixed seat 508 is arranged below the fixed frame 507; a telescopic plate 509 is arranged below the front side of the fixed seat 508; a fourth electric push rod 5010 and a fifth electric push rod 5011 are sequentially arranged below the telescopic plate 509; the lower parts of the fourth electric push rod 5010 and the fifth electric push rod 5011 are connected with a second sliding base 5012; the inner surface of the second slide base 5012 is slidably connected with a second slide bar 5013; the lower part of the second sliding base 5012 is welded with a second gear tooth plate 5014; the second gear tooth plate 5014 is in transmission connection with a fifth flat gear 5015; the axle center of the fifth flat gear 5015 is rotationally connected with the eighth transmission wheel 5016 through a transmission rod; the seventh driving wheel 501 is connected with a sixth driving wheel 4014; the fourth flat gear 502 is connected with the working frame plate 1 through a support seat; the first slide bar 505 is connected with the working frame plate 1 through a support seat; the fixed seat 508 is connected with the support base plate 2; the second slide bar 5013 is connected with the supporting base plate 2 through a supporting seat; the fifth flat gear 5015 is connected with the support base plate 2 through a support base; the eighth transmission wheel 5016 is connected to the fifth transmission wheel 4012.

When the hexagonal prism-shaped bar stock is conveyed to the fixed seat 508 through the conveyor belt 406, the conveyor belt 406 is stopped, at this time, the seventh drive wheel 501 is driven to rotate through the rotation of the sixth drive wheel 4014, the fourth flat gear 502 is driven to rotate, the first toothed plate 503 is driven through the fourth flat gear 502, the first toothed plate 503 drives the first sliding base 504 to slide on the surface of the first sliding rod 505, the third electric push rod 506 is driven to move transversely through the first sliding base 504, and the fixed seat 507 is driven to move transversely, at this time, according to the state of the hexagonal prism-shaped bar stock in the groove of the fixed seat 508, the third electric push rod 506 is started through the operation control screen 3, the fixed seat 507 is pushed downwards to a specified position, the fixed seat 507 is controlled to move transversely back and forth through the forward rotation and reverse rotation of the stepping motor 401, so that the hexagonal prism-shaped bar stock can be embedded with the groove of the fixed seat 508, then the fixed frame 507 is moved to the right above the hexagonal prism bar, the rotation of the seventh transmission wheel 501 is stopped, the fixed frame 507 is further stopped, the fixed frame 507 is pushed downwards by the third electric push rod 506, the groove below the fixed frame 507 is embedded with the hexagonal prism bar, the hexagonal prism bar is fixed, then the grinding mechanism 6 is used for grinding the hexagonal prism bar, after the grinding of the hexagonal prism bar is completed, the fourth electric push rod 5010 and the fifth electric push rod 5011 are started by operating the control screen 3, the expansion plate 509 is pushed upwards, the expansion plate 509 lifts the front part of the hexagonal prism bar, the expansion plate 509, the fourth electric push rod 5010, the fifth electric push rod 5011, the second sliding base 5012, the second slide rod 5013, the second gear tooth plate 5014, the fifth flat gear 5015 and the eighth transmission wheel 5016 are also arranged on the rear side of the fixed frame 508, the control panel 3 is operated to start the fourth electric push rod 5010 and the fifth electric push rod 5011, the telescopic plate 509 is pushed upwards, the telescopic plate 509 lifts the rear part of the hexagonal prism bar, the fixing frame 507 is synchronously pulled to move upwards through the third electric push rod 506, so that the fixing frame 507 is separated from the contact with the hexagonal prism bar, the hexagonal prism bar stays on the telescopic plate 509, the eighth driving wheel 5016 is driven to rotate through the rotation of the sixth driving wheel 4014, the fifth flat gear 5015 is driven to rotate, the second gear 5014 is driven to drive the second sliding base 5012 to slide on the surface of the second sliding rod 5013 through the second gear 5014, the telescopic plate 509 is driven to move towards the side close to the stock storage cabin 7 through the movement of the second sliding base 5012, and the eighth driving wheel 5016 is driven to rotate through the rotation of the sixth driving wheel 4014 synchronously at the rear side of the fixing base 508, further driving the fifth flat gear 5015 to rotate, further driving the second gear 5014, further driving the second sliding base 5012 to slide on the surface of the second sliding rod 5013 through the second gear 5014, further driving the telescopic plate 509 to move towards the side close to the storage compartment 7 through the movement of the second sliding base 5012, further controlling the fourth electric push rod 5010 to push the side of the telescopic plate 509 connected with the fourth electric push rod 5010 upwards to move upwards and the fifth electric push rod 5011 to not operate after the telescopic plate 509 drives the hexagonal rod to move to the designated position, simultaneously synchronously controlling the fourth electric push rod 5010 to push the side of the telescopic plate 509 connected with the fourth electric push rod 5010 upwards and the fifth electric push rod 5011 to not operate, so that the telescopic plate 509 tilts, because the telescopic plate 509 is formed by inserting a convex plate and a concave plate, when the telescopic plate 509 tilts, the convex plate and the concave plate are far away from each other to move, so that the hexagonal prism-shaped bars on the telescopic plate 509 slide down into the storage cabin 7, the mechanism realizes fixation of the hexagonal prism-shaped bars, and the polished hexagonal prism-shaped bars are rapidly transported.

The sanding mechanism 6 comprises a bearing frame 601, a servo motor 602, a ninth driving wheel 603, a tenth driving wheel 604, a sixth flat gear 605, a third toothed plate 606, a third sliding base 607, a first sliding plate 608, a second sliding plate 609, a first sliding rail 6010, a second sliding rail 6011, an eleventh driving wheel 6012, a first bevel gear 6013, a second bevel gear 6014, a telescopic rod 6015, a first column gear 6016, a seventh flat gear 6017, a second coupling plate 6018, a sixth electric push rod 6019, a second column gear 6020, internal teeth 6021, a changeover frame 6022, a micro motor 6023, a first coupling rod 6024, a second coupling rod 6025, a third coupling rod 6026, a fourth coupling rod 6027, a fifth coupling rod 6028, a fourth sliding base 6029, a third sliding rail 6030, a coupling block 6031, a first sanding block 6032 and a second sanding block 6033; a servo motor 602 is arranged in the bearing frame 601; the outer annular surface of the ninth driving wheel 603 is in transmission connection with a tenth driving wheel 604 through a belt; the axle center of the tenth transmission wheel 604 is rotationally connected with the sixth flat gear 605 through a transmission rod; the sixth flat gear 605 is in transmission connection with the third toothed plate 606; the upper part of the third pinion rack 606 is welded with the third sliding base 607; a first sliding plate 608 and a second sliding plate 609 are sequentially arranged below the third sliding base 607; the first slide 608 is slidably connected to the first slide rail 6010; the second sliding plate 609 is slidably connected with a second sliding rail 6011; the outer ring surface of the ninth driving wheel 603 is in transmission connection with an eleventh driving wheel 6012 through a belt; the shaft center of the eleventh driving wheel 6012 is rotatably connected with the first bevel gear 6013 through a driving rod; the first bevel gear 6013 meshes with the second bevel gear 6014; the axle center of the second bevel gear 6014 is rotationally connected with the telescopic rod 6015 through a transmission rod; the telescopic rod 6015 is rotationally connected with the first column gear 6016 through a transmission rod; a seventh spur gear 6017 is arranged on the side surface above the first spur gear 6016; the seventh flat gear 6017 is connected to the second coupling plate 6018; the second connecting plate 6018 is inserted into a sixth electric push rod 6019; the axis of the seventh flat gear 6017 is rotationally connected with the second column gear 6020 through a transmission rod; the outer surface of the second column gear 6020 is meshed with the inner gear sleeve 6021; the third sliding base 607 is connected with the inner gear ring 6021 through a supporting seat; the axle center of the inner gear ring sleeve 6021 is rotationally connected with the adapter 6022 through a transmission rod; the switching frame 6022 is internally provided with a micro motor 6023; the micro motor 6023 is rotationally connected with the first coupling rod 6024 through an output shaft; the first coupling rod 6024 is in transmission connection with the second coupling rod 6025; the third connecting rod 6026 is connected to the second connecting rod 6025 on one side of the outer surface thereof, and the third connecting rod 6026 is connected to the fourth connecting rod 6027 on the other side of the outer surface thereof; the fourth connecting rod 6027 is in transmission connection with the fifth connecting rod 6028; the fifth connecting rod 6028 is in transmission connection with the fourth sliding base 6029; the fourth sliding base 6029 is slidably connected to the third sliding rail 6030; the side surface of the fourth sliding base 6029 is welded with the coupling block 6031; one side of the coupling block 6031 is welded to the first sanding block 6032, and the other side of the coupling block 6031 is welded to the second sanding block 6033; the receiving frame 601 is connected to the work frame plate 1.

After the hexagonal prism-shaped bar stock is fixed on the fixing seat 508, the supporting frame 601 plays a supporting role, the servo motor 602 is started through controlling the operation control panel 3, the ninth driving wheel 603 is driven to rotate through the servo motor 602, the tenth driving wheel 604 is driven to rotate, the sixth flat gear 605 is driven to rotate, the third toothed plate 606 is driven to rotate, the third sliding base 607 is driven to move through the third toothed plate 606, the connecting block 6031 is driven through the movement of the third sliding base 607, the first polishing block 6032 and the second polishing block 6033 move to the position of being attached to the edge of the hexagonal prism-shaped bar stock, the first sliding plate 608 slides in the first sliding rail 6010, the second sliding plate 609 slides in the second sliding rail 6011 and is matched with the third sliding base 607 to move and play a supporting role on the third sliding base 607, then the motor 6023 is started through operating the control panel 3, the first connecting rod 6024 is driven to rotate through the micro motor 6023, further driving the second coupling rod 6025 to rotate, further driving the third coupling rod 6026 to make a circular track motion, further driving the fourth coupling rod 6027, further driving the fifth coupling rod 6028 to drive the fourth sliding base 6029 to slide in a reciprocating manner in the third sliding rail 6030, further driving the coupling block 6031 through the fourth sliding base 6029, integrally reciprocating the first polishing block 6032 and the second polishing block 6033, so that the first polishing block 6032 and the second polishing block 6033 polish two parallel edges of the hexagonal prism-shaped bar stock, further reversing the servo motor 602, so that the third sliding base 607 drives the coupling block 6031, the first polishing block 6032 and the second polishing block 6033 are far away from the edge position of the hexagonal prism-shaped bar stock, further driving the eleventh driving wheel 6012 to rotate through the rotation of the ninth driving wheel 603, further driving the first bevel gear 6013 to rotate and the first bevel gear 6014 to rotate in a meshing manner, further driving the telescopic rod 6015 to rotate, further driving the first column gear 6016 to rotate, starting the sixth electric push rod 6019 by operating the control panel 3, pushing the second coupling plate 6018 to move away from the sixth electric push rod 6019, synchronously driving the seventh flat gear 6017 and the second column gear 6020 to move synchronously, so that the first column gear 6016 is engaged with the seventh flat gear 6017, further the first column gear 6016 rotates to drive the seventh flat gear 6017 to rotate, further the second column gear 6020 rotates, further the inner gear collar 6021 rotates, further the adapter 6022 rotates, after the seventh flat gear 6017 rotates sixty degrees, the sixth electric push rod 6019 pushes the second coupling plate 6018 to move towards the side close to the sixth electric push rod 6019, further the first column gear 6016 is disengaged from the seventh flat gear 6017, so that the seventh flat gear 6017 stops rotating, and further the adapter 6022 stops rotating, then, the servo motor 602 is rotated forward again, the third sliding base 607 drives the connecting block 6031, the first polishing block 6032 and the second polishing block 6033 reach the position of the edge of the six-prism-shaped bar, the second group of parallel edges of the six-prism-shaped bar are polished by the first polishing block 6032 and the second polishing block 6033, after the second group of parallel edges of the six-prism-shaped bar are polished, the switching frame 6022 drives the connecting block 6031 again, the first polishing block 6032 and the second polishing block 6033 rotate sixty degrees to polish the third group of parallel edges of the six-prism-shaped bar, the polishing mechanism 6 is also arranged on the rear side of the fixed seat 508, the six edges on the rear side of the six-prism-shaped bar are polished in the same process by the polishing mechanism 6 on the rear side of the fixed seat 508, the mechanism achieves rapid polishing of the six edges of the six-prism-shaped bar, replaces manpower, and greatly improves the working efficiency.

In the present invention, a groove with a trapezoidal longitudinal section and a downward opening is provided below the fixing frame 507.

The upper side shape of the hexagonal prism-shaped bar stock is attached, and the hexagonal prism-shaped bar stock can be fixed by matching with the fixed seat 508.

In the present invention, a groove with a trapezoidal longitudinal section and an upward opening is formed above the fixing seat 508.

The hexagonal prism type bar can be fixed in the fixing seat 508, the lower side shape of the hexagonal prism type bar is attached, the fixing effect on the hexagonal prism type bar is strengthened, and the polishing quality is prevented from being influenced by displacement generated when the hexagonal prism type bar is polished.

In the present invention, the retractable plate 509 is formed by inserting a convex plate and a concave plate.

When the retractable plate 509 inclines, the convex plate and the concave plate move away from each other, so that the hexagonal prism-shaped bar material on the retractable plate 509 slides down into the storage bin 7.

According to the invention, the longitudinal sections of the first sliding plate 608 and the second sliding plate 609 are both T-shaped.

The first sliding plate 608 can slide in the first sliding rail 6010 and the second sliding plate 609 can slide in the second sliding rail 6011 to stably support the third sliding base 607.

It should be understood that the above description is for exemplary purposes only and is not meant to limit the present invention. Those skilled in the art will appreciate that variations of the present invention are intended to be included within the scope of the claims herein.

Claims

1. A metal bar processing device comprises a working frame plate (1), a supporting bottom plate (2) and an operation control screen (3); the method is characterized in that: the automatic grinding machine also comprises a feeding control mechanism (4), a fixing mechanism (5), a grinding mechanism (6) and a storage cabin (7); the working frame plate (1) is welded with the supporting bottom plate (2); the working frame plate (1) is connected with the operation control screen (3) through a supporting seat; the working frame plate (1) is connected with the feeding control mechanism (4); the working frame plate (1) is connected with the fixing mechanism (5); the working frame plate (1) is connected with the polishing mechanism (6); a feeding control mechanism (4), a fixing mechanism (5) and a storage cabin (7) are sequentially arranged above the supporting bottom plate (2); the feeding control mechanism (4) is connected with the fixing mechanism (5).

2. A metal bar stock processing apparatus as set forth in claim 1, wherein: the feeding control mechanism (4) comprises a stepping motor (401), a first driving wheel (402), a second driving wheel (403), a first electric push rod (404), a third driving wheel (405), a conveying belt (406), a fourth driving wheel (407), a first flat gear (408), a first connecting plate (409), a second electric push rod (4010), a second flat gear (4011), a fifth driving wheel (4012), a third flat gear (4013) and a sixth driving wheel (4014); the stepping motor (401) is rotationally connected with the first driving wheel (402) through a rotating shaft; the outer ring surface of the first driving wheel (402) is in transmission connection with a second driving wheel (403) through a belt; the second driving wheel (403) is connected with the first electric push rod (404) through a supporting seat; the outer ring surface of the first driving wheel (402) is in transmission connection with a third driving wheel (405) through a belt; the outer ring surface of the second driving wheel (403) is in transmission connection with a third driving wheel (405) through a belt; the axle center of the third driving wheel (405) is in transmission connection with the conveying belt (406) through a transmission rod; the outer ring surface of the first driving wheel (402) is in transmission connection with a fourth driving wheel (407) through a belt; the axle center of the fourth transmission wheel (407) is rotationally connected with the first flat gear (408) through a transmission rod; the fourth transmission wheel (407) and the first flat gear (408) are connected with a first connecting plate (409); the first connecting plate (409) is inserted into the second electric push rod (4010); a second flat gear (4011) is arranged on the side surface below the first flat gear (408); the axle center of the second flat gear (4011) is rotationally connected with a fifth driving wheel (4012) through a driving rod; a third flat gear (4013) is arranged on the upper side surface of the first flat gear (408); the axle center of the third horizontal gear (4013) is rotationally connected with a sixth driving wheel (4014) through a driving rod; the stepping motor (401) is connected with the supporting bottom plate (2); the first electric push rod (404) is connected with the working frame plate (1); the third driving wheel (405) is connected with the working frame plate (1); the conveyor belt (406) is connected with the working frame plate (1); the first flat gear (408) is connected with the working frame plate (1); the second electric push rod (4010) is connected with the supporting bottom plate (2); the second flat gear (4011) is connected with the working frame plate (1); the fifth driving wheel (4012) is connected with the fixing mechanism (5); the third horizontal gear (4013) is connected with the working frame plate (1); the sixth driving wheel (4014) is connected with the fixing mechanism (5).

3. A metal bar stock processing apparatus as set forth in claim 2, wherein: the fixing mechanism (5) comprises a seventh transmission wheel (501), a fourth flat gear (502), a first wheel toothed plate (503), a first sliding base (504), a first sliding rod (505), a third electric push rod (506), a fixing frame (507), a fixing seat (508), a telescopic plate (509), a fourth electric push rod (5010), a fifth electric push rod (5011), a second sliding base (5012), a second sliding rod (5013), a second wheel toothed plate (5014), a fifth flat gear (5015) and an eighth transmission wheel (5016); the axle center of the seventh transmission wheel (501) is rotationally connected with the fourth flat gear (502) through a transmission rod; the lower part of the fourth flat gear (502) is in transmission connection with a first toothed plate (503); the lower part of the first toothed plate (503) is welded with the first sliding base (504); the inner surface of the first sliding base (504) is in sliding connection with a first sliding bar (505); a third electric push rod (506) is arranged below the first sliding base (504); the third electric push rod (506) is inserted into the fixed frame (507); a fixed seat (508) is arranged below the fixed frame (507); a telescopic plate (509) is arranged below the front side of the fixed seat (508); a fourth electric push rod (5010) and a fifth electric push rod (5011) are sequentially arranged below the telescopic plate (509); the lower parts of the fourth electric push rod (5010) and the fifth electric push rod (5011) are connected with a second sliding base (5012); the inner surface of the second sliding base (5012) is in sliding connection with a second sliding rod (5013); the lower part of the second sliding base (5012) is welded with a second wheel toothed plate (5014); the second pinion plate (5014) is in transmission connection with the fifth flat gear (5015); the axle center of the fifth flat gear (5015) is rotationally connected with the eighth transmission wheel (5016) through a transmission rod; the seventh driving wheel (501) is connected with a sixth driving wheel (4014); the fourth flat gear (502) is connected with the working frame plate (1) through a supporting seat; the first sliding rod (505) is connected with the working frame plate (1) through a supporting seat; the fixed seat (508) is connected with the supporting bottom plate (2); the second sliding rod (5013) is connected with the supporting base plate (2) through a supporting seat; the fifth flat gear (5015) is connected with the supporting bottom plate (2) through a supporting seat; the eighth driving wheel (5016) is connected with the fifth driving wheel (4012).

4. A metal bar stock processing apparatus as set forth in claim 3, wherein: the polishing mechanism (6) comprises a bearing frame (601), a servo motor (602), a ninth transmission wheel (603), a tenth transmission wheel (604), a sixth flat gear (605), a third toothed plate (606), a third sliding base (607), a first sliding plate (608), a second sliding plate (609), a first sliding rail (6010), a second sliding rail (6011), an eleventh transmission wheel (6012), a first bevel gear (6013), a second bevel gear (6014), a telescopic rod (6015), a first column gear (6016), a seventh flat gear (6017), a second coupling plate (6018), a sixth electric push rod (6019), a second column gear (6020), an inner toothed ring sleeve (6021), a switching frame (6022), a micro motor (6023), a first coupling rod (6024), a second coupling rod (6025), a third coupling rod (6026), a fourth coupling rod (6027), a fifth coupling rod (6028), a fourth sliding base (6029), A third slide rail (6030), a connecting block (6031), a first polishing block (6032) and a second polishing block (6033); a servo motor (602) is arranged in the bearing frame (601); the outer ring surface of the ninth driving wheel (603) is in transmission connection with the tenth driving wheel (604) through a belt; the axle center of the tenth transmission wheel (604) is rotationally connected with the sixth flat gear (605) through a transmission rod; the sixth flat gear (605) is in transmission connection with the third toothed plate (606); the upper part of the third pinion rack (606) is welded with a third sliding base (607); a first sliding plate (608) and a second sliding plate (609) are sequentially arranged below the third sliding base (607); the first sliding plate (608) is in sliding connection with the first sliding rail (6010); the second sliding plate (609) is in sliding connection with a second sliding rail (6011); the outer ring surface of the ninth driving wheel (603) is in transmission connection with an eleventh driving wheel (6012) through a belt; the axis of an eleventh transmission wheel (6012) is rotatably connected with a first bevel gear (6013) through a transmission rod; the first bevel gear (6013) is meshed with the second bevel gear (6014); the axle center of the second bevel gear (6014) is rotationally connected with the telescopic rod (6015) through a transmission rod; the telescopic rod (6015) is rotationally connected with the first column gear (6016) through a transmission rod; a seventh flat gear (6017) is arranged on the side surface above the first column gear (6016); the seventh flat gear (6017) is connected with the second coupling plate (6018); the second connecting plate (6018) is spliced with a sixth electric push rod (6019); the axle center of the seventh flat gear (6017) is rotationally connected with the second column gear (6020) through a transmission rod; the outer surface of the second column gear (6020) is meshed with the inner gear sleeve (6021); the third sliding base (607) is connected with the inner gear ring sleeve (6021) through a supporting seat; the axle center of the inner gear ring sleeve (6021) is rotationally connected with the adapter rack (6022) through the transmission rod; a micro motor (6023) is arranged inside the switching frame (6022); the micro motor (6023) is rotationally connected with the first coupling rod (6024) through an output shaft; the first coupling rod (6024) is in transmission connection with the second coupling rod (6025); one side of the outer surface of the third connecting rod (6026) is connected with the second connecting rod (6025), and the other side of the outer surface of the third connecting rod (6026) is connected with the fourth connecting rod (6027); the fourth connecting rod (6027) is in transmission connection with the fifth connecting rod (6028); the fifth connecting rod (6028) is in transmission connection with the fourth sliding base (6029); the fourth sliding base (6029) is in sliding connection with the third sliding rail (6030); the side surface of the fourth sliding base (6029) is welded with the coupling block (6031); one side of the connecting block (6031) is welded with the first polishing block (6032), and the other side of the connecting block (6031) is welded with the second polishing block (6033); the bearing frame (601) is connected with the working frame plate (1).

5. A metal bar stock processing apparatus as set forth in claim 4, wherein: a groove with a trapezoidal longitudinal section and a downward opening is arranged below the fixing frame (507).

6. A metal bar stock machining apparatus as set forth in claim 5, wherein: a groove with a trapezoidal longitudinal section and an upward opening is arranged above the fixed seat (508).

7. A metal bar stock machining apparatus as set forth in claim 6, wherein: the expansion plate (509) is formed by mutually splicing a convex plate and a concave plate.

8. A metal bar stock processing apparatus as set forth in claim 7, wherein: the longitudinal sections of the first sliding plate (608) and the second sliding plate (609) are T-shaped.