CN211351987U - Material circulation type flexible stator assembling machine - Google Patents
Material circulation type flexible stator assembling machine Download PDFInfo
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- CN211351987U CN211351987U CN202020246147.XU CN202020246147U CN211351987U CN 211351987 U CN211351987 U CN 211351987U CN 202020246147 U CN202020246147 U CN 202020246147U CN 211351987 U CN211351987 U CN 211351987U
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- 238000010438 heat treatment Methods 0.000 claims description 12
- 238000006073 displacement reaction Methods 0.000 claims description 4
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- 230000001681 protective effect Effects 0.000 claims description 2
- 238000004519 manufacturing process Methods 0.000 abstract description 10
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 abstract description 2
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- XAGFODPZIPBFFR-UHFFFAOYSA-N aluminium Chemical compound [Al] XAGFODPZIPBFFR-UHFFFAOYSA-N 0.000 description 1
- 229910052782 aluminium Inorganic materials 0.000 description 1
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Abstract
The utility model discloses a material circulation type flexible stator assembling machine, which comprises a frame; the assembling machine is characterized by further comprising a shell feeding mechanism, a rotary lifting mechanism, a traveling fixture, a blanking mechanism, a synchronous belt conveying mechanism, a stator carrying mechanism, a fixing mechanism and a shell carrying and press-fitting mechanism; the machine shell feeding mechanism, the rotary lifting mechanism, the discharging mechanism, the synchronous belt conveying mechanism, the stator carrying mechanism, the fixing mechanism and the machine shell carrying press-fitting mechanism are all arranged on the machine frame. The assembling machine is compact in overall structure, reasonable in internal structure design and arrangement, capable of achieving material circulation, capable of achieving minimization of the overall structure and wide in market prospect. Two upper and lower stations are connected respectively at the both ends of the defeated material mechanism of hold-in range, adapt to the linear type overall arrangement, are convenient for incorporate this kludge directly into the production water line. The rotary lifting mechanism realizes the linkage effect through the innovative structural design, and horizontal rotation can be realized while vertical lifting is realized through the action of one power source.
Description
Technical Field
The utility model relates to an automatic equipment of motor housing specifically is a material circulation formula flexible stator kludge.
Background
The motor is a very important industrial product, and is the heart of various production equipment. In the production process of the motor, the assembly of the stator and the shell is a very important link, and the use performance of the motor is directly influenced by the quality of the assembly quality. The stator and the shell are assembled in an interference fit mode, and in order to achieve smooth assembly of the stator and the shell, the shell needs to be heated first, so that enough assembly gaps are generated in the shell to complete press mounting.
Currently, the assembly of the stator and the housing is mainly assembled by manual assembly or rigid automated equipment. The manual assembly needs a large amount of assembly personnel, so that the labor intensity is high, the production efficiency is low, the assembly timeliness is poor, and the work under the high-temperature condition has certain dangerousness. The casing self dispels the heat fast, if the casing leaves the stove because the assembly timeliness is poor, can not in time carry out the pressure equipment and cause and can not satisfy assembly temperature, just need to return the casing to the stove and heat again, production efficiency greatly reduced. The document of application No. 201721228819.9 discloses an automatic assembling machine for motor stator shells, which solves the problems of automatic feeding and blanking, greatly improves the assembling efficiency, and reduces the labor intensity of operators, but the equipment belongs to rigid automatic assembling equipment, and software and hardware such as control programs, clamps and manipulators can not be easily changed, and the automatic assembling machine is only suitable for a large amount of assembling work of motors with fixed models, and can not be qualified for automatic production work of multiple varieties and small-batch production, and simultaneously, because of the machining error of a shell and the positioning error accumulated during assembling, the rigid automatic assembling equipment can not be timely adjusted to cause a large amount of assembling faults.
SUMMERY OF THE UTILITY MODEL
Not enough to prior art, the utility model discloses the technical problem who plans to solve provides a material circulation formula flexible stator kludge.
The technical scheme of the utility model for solving the technical problems is to provide a material circulation type flexible stator assembling machine, which comprises a frame; the assembling machine is characterized by further comprising a shell feeding mechanism, a rotary lifting mechanism, a traveling fixture, a blanking mechanism, a synchronous belt conveying mechanism, a stator carrying mechanism, a fixing mechanism and a shell carrying and press-fitting mechanism; the shell feeding mechanism, the rotary lifting mechanism, the blanking mechanism, the synchronous belt conveying mechanism, the stator carrying mechanism, the fixing mechanism and the shell carrying and press-fitting mechanism are all arranged on the rack;
the following fixture is used for clamping and positioning the stator;
the synchronous belt conveying mechanism is used for feeding the clamped stator, conveying the clamped stator to a grabbing position of the stator carrying mechanism and conveying a finished product formed by assembling the clamped stator and the machine shell to the next station;
the stator conveying mechanism is used for conveying the clamped stator on the synchronous belt conveying mechanism to the fixing mechanism;
the fixing mechanism is positioned at the moving intersection of the stator conveying mechanism and the shell conveying press-fitting mechanism and is used for fixing the clamped stator conveyed by the stator conveying mechanism;
the shell feeding mechanism is used for conveying the shell to a grabbing position of the shell carrying and press-fitting mechanism;
the shell carrying and press-mounting mechanism is used for grabbing a shell on the shell feeding mechanism, carrying the shell to a fixing mechanism where a clamped stator is fixed, flexibly press-mounting the shell on the outer side of the clamped stator to obtain a finished product and carrying the finished product to a discharging mechanism;
the blanking mechanism is used for conveying the finished product to a grabbing position of the rotary lifting mechanism;
the rotary lifting mechanism is positioned above the blanking mechanism before being rotated and lifted and is used for grabbing finished products; and the rotary lifting mechanism is positioned above the synchronous belt conveying mechanism and used for placing the grabbed finished product on the synchronous belt conveying mechanism.
The rotary lifting mechanism comprises a second linear cylinder, a pneumatic claw, an L-shaped support, a rear rotating shaft, a rocker, a swing rod, a first bevel gear, a connecting rod connecting plate, a first synchronous belt, a synchronous rotating shaft, a rotating plate rotating shaft, an upper support plate, a second bevel gear, a bottom support and a first motor;
the bottom bracket is fixed on the frame; the rocker, the connecting rod connecting plate, the oscillating bar and the bottom bracket are sequentially connected through a shaft to form a parallel four-bar linkage, wherein the rear rotating shaft is in interference fit with the rocker; the output end of the first motor is fixedly connected with the rocker; the synchronous rotating shaft is rotatably arranged in a hole of the connecting rod connecting plate and is in interference fit with a first bevel gear; two ends of the first synchronous belt are respectively arranged on the rear rotating shaft and the synchronous rotating shaft; the upper support plate is fixed at the upper part of the connecting rod connecting plate; the rotating plate rotating shaft is rotatably arranged in the hole of the upper support plate; a second bevel gear is arranged at the tail end of the rotating shaft of the rotating plate in an interference fit mode and is in meshed connection with the first bevel gear; the rotating plate is in interference fit with the rotating shaft of the rotating plate; the L-shaped bracket is fixed on the rotating plate, and the tail end of the L-shaped bracket is fixedly connected with the cylinder body of the second linear cylinder; the pneumatic claw is arranged on a cylinder shaft of the second linear cylinder, and the up-and-down movement of the pneumatic claw is controlled through the extension and retraction of the second linear cylinder.
The stator carrying mechanism comprises a first pneumatic claw, a side mounting plate, a third linear guide rail, a fourth linear moving module and a first connecting bracket; the side mounting plate is fixed on the rack through the supporting legs; the third linear guide rail is fixed on the side mounting plate; the first connecting bracket is slidably mounted on the side mounting plate through a fourth linear moving module, is also slidably mounted on the third linear guide rail and is matched with the third linear guide rail to realize sliding along the third linear guide rail; the first pneumatic claw is slidably mounted on the first connecting support through a third linear moving module or a linear cylinder, and the movement in the Z direction is realized.
The machine shell carrying and press-fitting mechanism comprises a passive compliant device, a rotary encoder, a second pneumatic paw, a grating ruler connecting plate, a grating ruler, a side connecting plate, a sixth linear moving module, a fourth linear guide rail and a second connecting bracket; the side connecting plate is fixed on the rack through the supporting legs; the fourth linear guide rail is fixed on the side connecting plate; the second connecting bracket is slidably mounted on the side connecting plate through a sixth linear moving module, is also slidably mounted on the fourth linear guide rail and is matched with the fourth linear guide rail to realize sliding along the fourth linear guide rail; the main scale part of the grating scale is fixed on the supporting leg through the grating scale connecting plate, and the reading head part is fixed on the second connecting bracket, so that the linear displacement detection of the shell is realized; the passive compliance device is slidably mounted on the second connecting bracket through a fifth linear moving module or a linear cylinder to realize the movement in the Z direction; the tail end of the passive compliance device is provided with a second pneumatic paw; the rotary encoder is arranged on a rotating shaft of the passive compliant device, and the position offset condition of the machine shell during assembly is monitored in real time.
Compared with the prior art, the utility model discloses beneficial effect lies in:
(1) the assembling machine is compact in overall structure, reasonable in internal structure design and arrangement, capable of achieving material circulation, capable of achieving minimization of the overall structure and wide in market prospect.
(2) Two upper and lower stations are connected respectively at the both ends of the defeated material mechanism of hold-in range, adapt to the linear type overall arrangement, are convenient for incorporate this kludge directly into the production water line.
(3) The assembling machine has high flexibility, is suitable for assembling motor stators of various models such as 60, 70, 80 and 90 full series, and is convenient for production of various types and small batches; in addition, a passive compliance device with better compliance and a larger compliance range is configured, so that better flexibility adjustment is realized, the assembly failure rate is reduced, meanwhile, the wrist mechanism can be prevented from being replaced to generate positioning errors, the motor stator and the shell can be continuously flexibly assembled, and the assembly quality is improved.
(4) When the assembly work of one motor shell is not completely finished, the assembly machine can start the assembly of the next motor shell, thereby realizing continuous generation and improving the production efficiency.
(5) The assembling machine can parameterize and design the whole assembling process, has better human-computer interaction, realizes high-precision full-automatic production, solves the problem of low assembling precision existing in stator assembling for a long time, improves the assembling quality and the assembling efficiency, and reduces the labor intensity of operators.
(6) The synchronous belt conveying mechanism is designed by taking the characteristics of a double-speed chain conveying belt as a reference, and the conveying plate is tangent to the side support plate without deflection. The conveying mechanism of the synchronous belt can stop the conveying plate on the conveying mechanism at a required position, the positioning is accurate, the positioning accuracy of material feeding and discharging is convenient to improve, and the conveying mechanism continues to move forwards to be conveyed to the next station after assembly operation is completed.
(7) The rotary lifting mechanism realizes the linkage effect through the innovative structural design, and horizontal rotation can be realized while vertical lifting is realized through the action of one power source.
Drawings
Fig. 1 is an axial view of the overall structure of the present invention;
fig. 2 is a schematic front view of the overall structure of the present invention;
fig. 3 is a schematic axial view of the feeding mechanism of the casing of the present invention;
fig. 4 is a schematic front view of the rotary lifting mechanism of the present invention;
fig. 5 is a left side view schematically illustrating the rotary lifting mechanism of the present invention;
fig. 6 is a schematic front view of the pallet of the present invention;
fig. 7 is a schematic bottom view of the pallet of the present invention;
fig. 8 is a left side view schematically illustrating the blanking mechanism of the present invention;
fig. 9 is a schematic top view of the blanking mechanism of the present invention;
fig. 10 is a schematic axial view of the conveying mechanism of the synchronous belt of the present invention;
FIG. 11 is a schematic top view of a delivery board according to the present invention;
fig. 12 is an axial view of the stator handling mechanism of the present invention;
fig. 13 is a schematic axial view of the case carrying press-fitting mechanism of the present invention;
fig. 14 is a schematic front view of the case carrying press-fitting mechanism of the present invention;
fig. 15 is a three-view diagram of the passive compliance device of the present invention (the upper left is a front view, the upper right is a left view, and the lower left is a top view).
In the figure, 1, a frame; 2. a shell feeding mechanism; 3. a rotary lifting mechanism; 4. a pallet; 5. a blanking mechanism; 6. a synchronous belt material conveying mechanism; 7. a stator handling mechanism; 8. a fixing mechanism; 9. a machine shell carrying and press-mounting mechanism; 10. an electric cabinet;
201. a first linear moving module; 202. a first support plate; 203. a first linear slider; 204. a first linear guide rail; 205. A first fixing plate; 206. side supporting plates; 207. heating a tube; 208. a first linear cylinder;
301. a second linear cylinder; 302. a pneumatic claw; 303. an L-shaped bracket; 304. a rear rotating shaft; 305. a rocker; 306. a swing rod; 307. a first bevel gear; 308. a connecting rod connecting plate; 309. a first synchronization belt; 310. a synchronous rotating shaft; 311. a rotating plate; 312. A rotating plate rotating shaft; 313. an upper bracket plate; 314. a second bevel gear; 315. a protection plate; 316. a bottom bracket; 317. a first motor;
401. a threaded shaft; 402. rotating the nut; 403. a fastening sheet; 404. a connecting bolt; 405. a base; 406. a first outwardly extending rod; 407. a second outer extension bar; 408. a moving block; 409. a positioning notch;
501. a second fixing plate; 502. a second linear guide; 503. a second linear moving module; 504. a second linear slider; 505. Connecting blocks; 506. a second support plate;
601. a photosensor; 602. a material conveying plate; 603. a material conveying plate side wheel; 604. a side bracket plate; 605. a drive shaft; 606. a bearing plate; 607. a synchronous pulley; 608. a second synchronous belt; 609. a second motor; 610. a reduction gear; 611. a third linear cylinder; 612. a third linear cylinder support; 613. a stopper;
701. a third linear movement module; 702. a first pneumatic gripper; 703. a side mounting plate; 704. a third linear guide rail; 705. a first tow chain; 706. a fourth linear moving module; 707. a first connecting bracket;
801. a turntable; 802. a pressure sensor; 803. positioning blocks; 804. a rotating cylinder;
901. a fifth linear moving module; 902. a passive compliance device; 903. a rotary encoder; 904. a second pneumatic gripper; 905. A grating scale connecting plate; 906. a grating scale; 907. a side connection plate; 908. a sixth linear moving module; 909. a second tow chain; 910. a fourth linear guide; 911. a second connecting bracket.
Detailed Description
The present invention will be further explained with reference to the following embodiments and accompanying drawings. The specific embodiments are only used for further elaboration of the invention, and do not limit the scope of protection of the claims of the present application.
The utility model provides a material circulation type flexible stator assembling machine (an assembling machine for short, see figures 1-15), which comprises a frame 1; the assembling machine is characterized by further comprising a shell feeding mechanism 2, a rotary lifting mechanism 3, a traveling fixture 4, a blanking mechanism 5, a synchronous belt conveying mechanism 6, a stator carrying mechanism 7, a fixing mechanism 8 and a shell carrying and press-fitting mechanism 9; the shell feeding mechanism 2, the rotary lifting mechanism 3, the blanking mechanism 5, the synchronous belt conveying mechanism 6, the stator carrying mechanism 7, the fixing mechanism 8 and the shell carrying press-fitting mechanism 9 are all arranged on the rack 1;
the follower fixture 4 is positioned in the stator, realizes the clamping and positioning of the stator in an internal tensioning mode, and can be adapted to the same series of stators with different models;
the synchronous belt conveying mechanism 6 is used for feeding the clamped stator, conveying the clamped stator to a grabbing position of the stator carrying mechanism 7, and conveying a finished product (called finished product for short) formed by assembling the clamped stator and the machine shell to the next station;
the stator conveying mechanism 7 can realize movement in the XZ direction and is used for conveying the clamped stator on the synchronous belt conveying mechanism 6 to the fixing mechanism 8;
the fixing mechanism 8 is positioned at the moving intersection of the stator conveying mechanism 7 and the machine shell conveying press-fitting mechanism 9 and is used for fixing the clamped stator conveyed by the stator conveying mechanism 7;
the shell feeding mechanism 2 is used for accurately conveying the shell to a grabbing position of the shell conveying press-fitting mechanism 9;
the machine shell conveying and press-mounting mechanism 9 can realize movement in YZ direction and is used for grabbing a machine shell on the machine shell feeding mechanism 2, conveying the machine shell to the fixing mechanism 8 where the clamped stator is fixed, flexibly press-mounting the machine shell on the outer side of the clamped stator (assembly of the clamped stator and the machine shell is realized) to obtain a finished product and conveying the finished product to the blanking mechanism 5;
the blanking mechanism 5 is used for conveying the finished product to the grabbing position of the rotary lifting mechanism 3;
the rotary lifting mechanism 3 is positioned above the blanking mechanism 5 before being rotated and lifted and is used for grabbing finished products; and the rotary lifting mechanism is positioned above the synchronous belt conveying mechanism 6 and used for placing the grabbed finished product on the synchronous belt conveying mechanism 6.
The case feeding mechanism 2 comprises a first linear moving module 201, a first supporting plate 202, a first linear sliding block 203, a first linear guide rail 204 and a first fixing plate 205; the first fixing plate 205 is fixed on the frame 1; the first linear guide 204 is fixed on the first fixing plate 205; a first linear sliding block 203 is fixed at the bottom of the first bearing plate 202; one end of the first supporting plate 202 is slidably mounted on the side supporting plate 206 of the first fixing plate 205 through the first linear moving module 201 (in this embodiment, the housing of the first linear moving module 201 is fixed on the side supporting plate 206 of the first fixing plate 205; one end of the first supporting plate 202 is fixed on the sliding part of the first linear moving module 201), the first linear slider 203 arranged at the bottom is matched with the first linear guide 204 for supporting the housing, and the first supporting plate 202 can slide on the first linear guide 204 under the action of the first linear moving module 201;
preferably, the housing feeding mechanism 2 further comprises a heating pipe 207 and a first linear cylinder 208; through holes are formed in the middle parts of the first fixing plate 205 and the first bearing plate 202; the cylinder body of the first linear cylinder 208 is fixed on the frame 1, the cylinder shaft of the first linear cylinder is provided with a heating pipe 207, and the heating pipe 207 is opposite to the through hole of the first fixing plate 205; when the first linear moving module 201 drives the first supporting plate 202 to move so that the through hole of the first supporting plate 202 coincides with the through hole of the first fixing plate 205, the up-and-down movement of the heating pipe 207 is controlled by the extension and contraction of the first linear cylinder 208, so that the heating pipe 207 sequentially passes through the through hole of the first fixing plate 205 and the through hole of the first supporting plate 202 to heat the housing to obtain the interference fit with the stator. The first linear cylinder 208 may employ a single rod linear cylinder.
The rotary lifting mechanism 3 comprises a second linear cylinder 301, an air claw 302, an L-shaped bracket 303, a rear rotating shaft 304, a rocker 305, a swing rod 306, a first bevel gear 307, a connecting rod connecting plate 308, a first synchronous belt 309, a synchronous rotating shaft 310, a rotating plate 311, a rotating plate rotating shaft 312, an upper bracket plate 313, a second bevel gear 314, a protective plate 315, a bottom bracket 316 and a first motor 317;
the bottom bracket 316 is fixed on the frame 1; the rocker 305, the connecting rod connecting plate 308, the oscillating bar 306 and the bottom bracket 316 are sequentially connected through a shaft to form a parallel four-bar linkage, wherein the rear rotating shaft 304 is in interference fit with the rocker 305; the output end of the first motor 317 is fixedly connected with the rocker 305 through a coupler; the synchronous rotating shaft 310 is rotatably arranged in a round hole of the connecting rod connecting plate 308 through a 61804 bearing, and a first bevel gear 307 is in interference fit on the synchronous rotating shaft 310; two ends of the first synchronous belt 309 are respectively installed on the rear rotating shaft 304 and the synchronous rotating shaft 310; the upper bracket plate 313 is fixed on the upper part of the connecting rod connecting plate 308; the rotating plate rotating shaft 312 is rotatably mounted in the circular hole of the upper bracket plate 313 through a thrust bearing, and the thrust bearing is used for bearing a larger axial force of the rotating plate rotating shaft 312; a second bevel gear 314 is in interference fit at the tail end of the rotating plate rotating shaft 312, and the second bevel gear 314 is in meshed connection with the first bevel gear 307; the rotating plate 311 is in interference fit with the rotating plate rotating shaft 312; the L-shaped bracket 303 is fixed on the rotating plate 311, and the tail end of the L-shaped bracket is fixedly connected with the cylinder body of the second linear cylinder 301; the air claw 302 is arranged on the cylinder shaft of the second linear cylinder 301, and the up-and-down movement of the air claw 302 is controlled by the extension and contraction of the second linear cylinder 301; the first motor 317 drives the rocker 305 to rotate, so that the parts above the connecting rod connecting plate 308 are lifted or lowered in the vertical direction (in this embodiment, the parts are lifted or lowered by 150mm), the rear rotating shaft 304 rotates 90 degrees along with the rocker 305, meanwhile, the synchronous rotating shaft 310 rotates 90 degrees through the transmission of the first synchronous belt 309, and the rotating plate rotating shaft 312 rotates 90 degrees through the engagement of the second bevel gear 314 and the first bevel gear 307, so that the gas claw 302 rotates 90 degrees while being lifted vertically. The second linear cylinder 301 may employ a three-rod linear cylinder. The gas claw 302 may be a wide type gas claw. The first motor 317 may employ a stepping motor.
Preferably, the rotary lifting mechanism 3 further includes a protection plate 315; the protection plate 315 is fixed to a lower portion of the link coupling plate 308, and a space formed by the link coupling plate 308, the upper support plate 313, and the protection plate 315 protects internal components such as the first bevel gear 307, the second bevel gear 314, and the first timing belt 309.
The pallet 4 comprises a threaded shaft 401, a rotating nut 402, a tightening piece 403, a connecting bolt 404, a base 405, a first external extension rod 406, a second external extension rod 407 and a moving block 408; the threaded shaft 401 is fixed on the upper surface of the base 405; the lower surface of the base 405 is provided with a positioning notch 409; a swivel nut 402 is threadedly engaged with the threaded shaft 401; the moving block 408 is nested on the outer side of the threaded shaft 401 and is in contact with the rotating nut 402; the middle parts of the first external extension bar 406 and the second external extension bar 407 are hinged; one end of the first outward extending rod 406 is hinged to the moving block 408, and the other end is hinged to the fastening piece 403; one end of the second outward extending rod 407 is hinged to the threaded shaft 401, and the other end is slidably mounted in the through groove of the fastening piece 403 through a connecting bolt 404; the rotating nut 402 is rotated to slide on the threaded shaft 401, and is matched with the moving block 408 to realize the extension and retraction of the first external extension rod 406 and the second external extension rod 407, so that the fixing of the fastening piece 403 to the stator is realized.
The blanking mechanism 5 comprises a second fixing plate 501, a second linear guide rail 502, a second linear moving module 503, a second linear sliding block 504, a connecting block 505 and a second supporting plate 506; one end of the connecting block 505 is slidably mounted on the frame 1 through the second linear moving module 503 (in this embodiment, the housing of the second linear moving module 503 is fixed on the frame 1, and the sliding portion of the second linear moving module is fixedly connected with the connecting block 505); a second fixing plate 501 is fixed on the frame 1, and a second linear guide rail 502 is fixed on the second fixing plate 501; the other end of the connecting block 505 passes through the second fixing plate 501 and is fixedly connected with the second linear sliding block 504; the second linear sliding block 504 is slidably mounted on the second linear guide rail 502, and is matched with the second linear guide rail 502 to realize sliding along the second linear guide rail 502; a second support plate 506 is mounted on the second linear slide 504.
The synchronous belt material conveying mechanism 6 comprises a photoelectric sensor 601, a material conveying plate 602, a side bracket plate 604, a transmission shaft 605, a synchronous belt wheel 607, a second synchronous belt 608, a second motor 609, a reduction gear 610, a first blocking mechanism and a second blocking mechanism; the side support plate 604 is fixed on the frame 1, two ends of the side support plate 604 are respectively rotatably provided with a transmission shaft 605 through 61806 bearings (in this embodiment, the side support plate 604 is uniformly provided with a plurality of rotatable transmission shafts 605, the transmission shafts 605 at the two ends are in interference fit with two synchronous pulleys 607, the other transmission shafts 605 are in interference fit with four synchronous pulleys 607, two adjacent transmission shafts 605 are in transmission connection through the synchronous pulleys 607 and a second synchronous belt 608, and a bearing plate 606 is arranged below each group of the second synchronous belts 608); a synchronous pulley 607 is arranged on the transmission shaft 605 in an interference fit manner, and the synchronous pulleys 607 are connected through a second synchronous belt 608; the output end of the second motor 609 is connected with the transmission shaft 605 through a coupling via a reduction gear 610, and transmits power to the transmission shaft 605; the material conveying plate 602 is placed on the second synchronous belt 608 and can move along the second synchronous belt 608; the photoelectric sensor 601 is arranged on the frame 1, is positioned beside the side support plate 604 and is used for sensing the feeding condition of the clamped stator; the first blocking mechanism is arranged on the rack 1, is positioned beside the side support plate 604 and is matched with the material conveying plate 602 to block the conveying of the material conveying plate 602 along the second synchronous belt 608, so that the clamped stator is parked to the grabbing position of the stator carrying mechanism 7 in advance, and the grabbing of the stator carrying mechanism 7 is facilitated; the second blocking mechanism is disposed on the rack 1, is located beside the side supporting plate 604, and is matched with the feeding plate 602 to block the feeding of the feeding plate 602 along the second synchronous belt 608, so as to park the feeding plate 602 in advance to a position where the feeding plate is conveyed to a position where a finished product is received, and facilitate the rotary lifting mechanism 3 to pick the finished product and then place the finished product thereon. The second motor 609 may employ a three-phase motor.
The synchronous belt conveying mechanism 6 further comprises a bearing plate 606; the bearing plate 606 is fixed on the side bracket plate 604 and positioned below the second synchronous belt 608, and is used for bearing the weight of the conveyed materials; the bearing plate 606 is made of aluminum.
The synchronous belt material conveying mechanism 6 further comprises a material conveying plate side wheel 603; the material conveying plate side wheels 603 are rotatably arranged at four corners of the material conveying plate 602, and the material conveying plate side wheels 603 are tangent to the side support plates 604; the material conveying plate side wheel 603 may adopt a bearing or a pulley, etc.
The first blocking mechanism and the second blocking mechanism have the same structure and respectively comprise a third linear cylinder 611, a third linear cylinder bracket 612 and a stop block 613; the third linear cylinder bracket 612 is fixed on the frame 1, the cylinder body of the third cylinder 611 is fixed on the third linear cylinder bracket 612, the stop 613 is fixed on the cylinder shaft of the third cylinder 611, and the extension and retraction of the stop 613 are realized by controlling the extension and retraction of the third cylinder 611, so that the contact or non-contact with the material conveying plate 602 is realized; the third linear cylinder 611 employs a dual-rod linear cylinder.
The stator conveying mechanism 7 includes a third linear moving module 701, a first pneumatic gripper 702, a side mounting plate 703, a third linear guide 704, a fourth linear moving module 706, and a first connecting bracket 707; the side mounting plate 703 is fixed on the frame 1 through a support leg; the third linear guide 704 is fixed to the side mounting plate 703; the first connecting bracket 707 is slidably mounted on the side mounting plate 703 through the fourth linear moving module 706 (in this embodiment, the housing of the fourth linear moving module 706 is fixed on the side mounting plate 703, and the first connecting bracket 707 is fixedly connected to the sliding portion of the fourth linear moving module 706), and is also slidably mounted on the third linear guide 704 to cooperate with the third linear guide 704 to slide along the third linear guide 704, that is, to move in the X direction; the first pneumatic gripper 702 is slidably mounted on the first connecting bracket 707 through the third linear moving module 701 (in this embodiment, the housing of the third linear moving module 701 is fixed on the first connecting bracket 707; the first pneumatic gripper 702 is fixed on the sliding part of the third linear moving module 701 through the connecting plate), so as to realize the movement in the Z direction;
the stator handling mechanism 7 further comprises a first drag chain 705; a first tow chain 705 is mounted on the side mounting plate 703 for converging the line and preventing wear of the line.
The third linear moving module 701 may be replaced with a linear cylinder; the cylinder body of the linear cylinder is fixed on a first connecting bracket 707, and a first pneumatic gripper 702 is mounted on the cylinder shaft.
The fixing mechanism 8 comprises a turntable 801, a pressure sensor 802, a positioning block 803 and a rotary cylinder 804; the cylinder body of the rotary cylinder 804 is fixed on the frame 1; the turntable 801 is fixed on the cylinder shaft of the rotary cylinder 804 through a key; the upper surface of the turntable 801 is provided with a bulge which is matched with a positioning notch 409 of the pallet 4 to fix the pallet 4 on the fixing mechanism 8, namely, the fixed stator after clamping is realized; the pressure sensor 802 is arranged on the upper surface of the turntable 801, contacts with the base 405 of the pallet 4, and measures pressure data; the positioning block 803 is fixed on the frame 1 and is matched with the base 405 of the pallet 4; the positioning notch 409 of the pallet 4 is matched with the protrusion on the turntable 801, the rotary cylinder 804 drives the turntable 801 to rotate, the base 405 of the pallet 4 is clamped in the positioning block 803, and the positioning of the clamped stator is realized.
The chassis carrying and press-fitting mechanism 9 comprises a fifth linear moving module 901, a passive compliance device 902, a rotary encoder 903, a second pneumatic gripper 904, a grating ruler connecting plate 905, a grating ruler 906, a side connecting plate 907, a sixth linear moving module 908, a fourth linear guide rail 910 and a second connecting support 911; the side connecting plate 907 is fixed on the frame 1 through a support leg; the fourth linear guide 910 is fixed to the side connection plate 907; the second connecting bracket 911 is slidably mounted on the side connecting plate 907 through the sixth linear moving module 908 (in this embodiment, the housing of the sixth linear moving module 908 is fixed on the side connecting plate 907, and the second connecting bracket 911 is fixedly connected to the sliding portion of the sixth linear moving module 908), and is also slidably mounted on the fourth linear guide 910, and cooperates with the fourth linear guide 910 to slide along the fourth linear guide 910, that is, to move in the Y direction; the main scale part of the grating scale 906 is fixed on the supporting leg through a grating scale connecting plate 905, and the reading head part is fixed on the second connecting bracket 911, so that the linear displacement detection of the shell is realized; the passive compliant device 902 is slidably mounted on the second connecting bracket 911 through the fifth linear moving module 901 (in this embodiment, the sliding part of the fifth linear moving module 901 is fixedly connected with the second connecting bracket 911, and the housing of the fifth linear moving module 901 is connected with one end of the passive compliant device 902), so as to realize the movement in the Z direction; a second pneumatic gripper 904 is arranged at the tail end of the passive compliance device 902; the rotary encoder 903 is arranged on a rotating shaft of the passive compliant device 902, and the position offset condition of the machine shell during assembly is monitored in real time;
the case carrying press-fitting mechanism 9 further includes a second drag chain 909; a second drag chain 909 is mounted on the side connection plate 907 to converge the line, preventing wear of the line.
The fifth linear moving module 901 can be replaced by a linear cylinder; the cylinder body of the linear cylinder is fixed on a second connecting bracket 911, and a passive compliance device 902 is installed on the cylinder shaft.
The model number of the photoelectric sensor 601 is E3Z-LS 66; the pressure sensor 802 is of the type OMRON E8F 2-A01C; the rotary encoder 903 is E6A2-CS3C 500P/R0.5M, and two rotary encoders are adopted in the embodiment and are respectively connected with two crossed rotary shafts in the upper section or the lower section of the compression spring unit of the passive compliance device 902; the type of the grating scale 906 is LS323 of Heidenhain;
the passive compliance device 902 may be the passive compliance device disclosed in the patent application No. 201720253028.5.
The stator clamped by the following clamp 4 is called the clamped stator for short; and a finished product obtained after the clamped stator and the shell are assembled is called a finished product for short.
The assembling machine further comprises an electric cabinet, wherein the electric cabinet is used for adjusting various actions of various mechanisms of the assembling machine, mainly comprises a PLC (model number NJ501) and a touch panel (man-machine interaction interface, model number NB7W-TW11B), and belongs to the prior art. When the electric cabinet is not provided, the movement of each mechanism can be manually controlled.
The utility model discloses a theory of operation and work flow are:
(1) the wound stator is placed on the outer side of the following clamp 4, the rotating nut 402 is rotated to slide on the threaded shaft 401 and is matched with the moving block 408 to realize the extending and retracting of the first outer stretching rod 406 and the second outer stretching rod 407, and when the first outer stretching rod 406 and the second outer stretching rod 407 extend outwards, the fastening piece 403 contacts the inner wall of the stator to clamp the stator, so that the clamping and the positioning of the stator are realized;
(2) the clamped stator is placed on the material conveying plate 602 and moves along with the second synchronous belt 608 to finish feeding; the photoelectric sensor 601 recognizes the stator feeding after winding, the third linear cylinder 611 of the first blocking mechanism extends out, and the material conveying plate 602 is stopped, so that the material conveying plate is stopped at the first blocking mechanism, namely the grabbing position of the first pneumatic gripper 702;
meanwhile, the first supporting plate 202 conveys the casing to the position where the through hole of the first supporting plate 202 is overlapped with the through hole of the first fixing plate 205, the first linear cylinder 208 extends outwards, and the heating pipe 207 sequentially passes through the through hole of the first fixing plate 205 and the through hole of the first supporting plate 202 and then extends into the casing to heat the casing to a proper temperature (120 ℃ in the embodiment) so that the casing obtains interference fit with the stator; then the first supporting plate 202 conveys the heated enclosure to the grabbing position of the enclosure conveying press-fitting mechanism 9;
(3) the first pneumatic claw 702 grabs the clamped stator and carries the stator to the fixing mechanism 8; after the positioning notch 409 is matched with the protrusion on the turntable 801, the rotary cylinder 804 rotates to drive the turntable 801 to rotate, so that the base 405 is clamped in the positioning block 803, the clamped stator is positioned, and the stator is ready to be assembled; the first pneumatic gripper 702 is reset; meanwhile, the third linear cylinder 611 of the first blocking mechanism retracts, releasing the delivery plate 602; a third linear cylinder 611 of the second blocking mechanism extends out, and the material conveying plate 602 is stopped, so that the material conveying plate is stopped in advance at the second blocking mechanism, namely, a finished product (called a finished product for short) after the stator and the machine shell are assembled after clamping is waited to be placed;
the second pneumatic gripper 904 grabs the heated enclosure and carries it to the fixing mechanism 8; the fifth linear moving module 901 acts to continuously perform flexible press-fitting of the housing and the clamped stator under the action of the passive compliant device 902; the grating scale 906 and the pressure sensor 802 monitor position change and assembly pressure change in the assembly process in real time, and the assembly quality is ensured by combining the passive compliance adjustment capability of the passive compliance device 902 (specifically, by combining the linear relationship between the displacement of the lower connecting plate of the passive compliance device 902 and the rotation angle of the compression spring unit of the passive compliance device 902, which is connected with the rotary encoder 903, the position offset condition during assembly is monitored in real time by the rotary encoder 903, so that the assembly positioning and the real-time adjustment in the assembly process are realized, and the assembly quality is ensured);
(4) after press fitting (assembling) is completed, a finished product is obtained, the rotary cylinder 804 rotates, and the base 405 is released to be matched with the positioning block 803; the second pneumatic gripper 904 picks the finished product to the second support plate 506; meanwhile, the next clamped stator is placed on the material conveying plate 602 and moves along with the second synchronous belt 608, and the next round of assembly is started;
(5) the second linear moving module 503 acts to drive the second supporting plate 506 to convey the finished product to the grabbing position of the rotary lifting mechanism 3; the air claw 302 grabs a finished product, the first motor 307 is started to drive the rocker 305 to rotate upwards along a vertical surface to realize vertical lifting, the rocker 305 drives the rear rotating shaft 304 in interference fit with the rocker 305 to rotate, and the rotation of the synchronous rotating shaft 310 is realized through the first synchronous belt 309; due to the meshing action of the bevel gears, the rotating plate rotating shaft 312 rotates, and then the rotating plate 311 fixedly connected with the rotating plate rotating shaft 312 is driven to rotate, so that the gas claw 302 on the rotating plate 311 is driven to rotate to the position above the material conveying plate 602 (in the embodiment, the finished product is lifted vertically by 150mm to the stroke end and horizontally rotated by 90 degrees); then the pneumatic claw 302 releases the finished product onto the feeding plate 602; then the third linear cylinder 611 of the second blocking mechanism retracts, releasing the material conveying plate 602; the second timing belt 608 advances the finished product to the next station.
The utility model discloses the nothing is mentioned the part and is applicable to prior art.
Claims (10)
1. A material circulation type flexible stator assembling machine comprises a frame; the assembling machine is characterized by further comprising a shell feeding mechanism, a rotary lifting mechanism, a traveling fixture, a blanking mechanism, a synchronous belt conveying mechanism, a stator carrying mechanism, a fixing mechanism and a shell carrying and press-fitting mechanism; the shell feeding mechanism, the rotary lifting mechanism, the blanking mechanism, the synchronous belt conveying mechanism, the stator carrying mechanism, the fixing mechanism and the shell carrying and press-fitting mechanism are all arranged on the rack;
the following fixture is used for clamping and positioning the stator;
the synchronous belt conveying mechanism is used for feeding the clamped stator, conveying the clamped stator to a grabbing position of the stator carrying mechanism and conveying a finished product formed by assembling the clamped stator and the machine shell to the next station;
the stator conveying mechanism is used for conveying the clamped stator on the synchronous belt conveying mechanism to the fixing mechanism;
the fixing mechanism is positioned at the moving intersection of the stator conveying mechanism and the shell conveying press-fitting mechanism and is used for fixing the clamped stator conveyed by the stator conveying mechanism;
the shell feeding mechanism is used for conveying the shell to a grabbing position of the shell carrying and press-fitting mechanism;
the shell carrying and press-mounting mechanism is used for grabbing a shell on the shell feeding mechanism, carrying the shell to a fixing mechanism where a clamped stator is fixed, flexibly press-mounting the shell on the outer side of the clamped stator to obtain a finished product and carrying the finished product to a discharging mechanism;
the blanking mechanism is used for conveying the finished product to a grabbing position of the rotary lifting mechanism;
the rotary lifting mechanism is positioned above the blanking mechanism before being rotated and lifted and is used for grabbing finished products; and the rotary lifting mechanism is positioned above the synchronous belt conveying mechanism and used for placing the grabbed finished product on the synchronous belt conveying mechanism.
2. The material circulation type flexible stator assembling machine according to claim 1, wherein the machine shell feeding mechanism comprises a first linear moving module, a first bearing plate, a first linear sliding block, a first linear guide rail and a first fixing plate; the first fixing plate is fixed on the frame; the first linear guide rail is fixed on the first fixing plate; but the one end of first bearing board passes through first linear movement module slidable mounting on first fixed plate, and the cooperation of first linear slider and first linear guide rail that the bottom set up, under the effect of first linear movement module, first bearing board can slide on first linear guide rail.
3. The material circulation type flexible stator assembling machine according to claim 2, wherein the casing feeding mechanism further comprises a heating pipe and a first linear cylinder; through holes are formed in the middle parts of the first fixing plate and the first bearing plate; the cylinder body of the first linear cylinder is fixed on the frame, a heating pipe is arranged on a cylinder shaft of the first linear cylinder, and the heating pipe is opposite to the through hole of the first fixing plate; when the first linear moving module drives the first bearing plate to move so that the through hole of the first bearing plate is overlapped with the through hole of the first fixing plate, the up-and-down movement of the heating pipe is controlled through the extension and retraction of the first linear cylinder, so that the heating pipe sequentially penetrates through the through hole of the first fixing plate and the through hole of the first bearing plate to further heat the shell to obtain the interference magnitude matched with the stator.
4. The material circulation type flexible stator assembling machine according to claim 1, wherein the rotary lifting mechanism comprises a second linear cylinder, a pneumatic claw, an L-shaped bracket, a rear rotating shaft, a rocker, a swing rod, a first bevel gear, a connecting rod connecting plate, a first synchronous belt, a synchronous rotating shaft, a rotating plate rotating shaft, an upper bracket plate, a second bevel gear, a bottom bracket and a first motor;
the bottom bracket is fixed on the frame; the rocker, the connecting rod connecting plate, the oscillating bar and the bottom bracket are sequentially connected through a shaft to form a parallel four-bar linkage, wherein the rear rotating shaft is in interference fit with the rocker; the output end of the first motor is fixedly connected with the rocker; the synchronous rotating shaft is rotatably arranged in a hole of the connecting rod connecting plate and is in interference fit with a first bevel gear; two ends of the first synchronous belt are respectively arranged on the rear rotating shaft and the synchronous rotating shaft; the upper support plate is fixed at the upper part of the connecting rod connecting plate; the rotating plate rotating shaft is rotatably arranged in the hole of the upper support plate; a second bevel gear is arranged at the tail end of the rotating shaft of the rotating plate in an interference fit mode and is in meshed connection with the first bevel gear; the rotating plate is in interference fit with the rotating shaft of the rotating plate; the L-shaped bracket is fixed on the rotating plate, and the tail end of the L-shaped bracket is fixedly connected with the cylinder body of the second linear cylinder; the pneumatic claw is arranged on a cylinder shaft of the second linear cylinder and controls the pneumatic claw to move up and down through the extension and retraction of the second linear cylinder;
the rotary lifting mechanism also comprises a protection plate; the protective plate is fixed at the lower part of the connecting rod connecting plate; the space formed by the connecting rod connecting plate, the upper support plate and the protection plate is used for protecting the internal components.
5. The material circulation type flexible stator assembling machine according to claim 1, wherein the follower fixture comprises a threaded shaft, a rotating nut, a tightening piece, a connecting bolt, a base, a first outer extension rod, a second outer extension rod and a moving block; the threaded shaft is fixed on the upper surface of the base; the lower surface of the base is provided with a positioning notch; the rotating nut is in threaded fit with the threaded shaft; the moving block is nested on the outer side of the threaded shaft and is in contact with the rotating nut; the middle parts of the first externally extending rod and the second externally extending rod are hinged; one end of the first outward extending rod is hinged to the moving block, and the other end of the first outward extending rod is hinged to the fastening piece; one end of the second external extension rod is hinged to the threaded shaft, and the other end of the second external extension rod is slidably mounted in the through groove of the fastening piece through a connecting bolt.
6. The material circulation type flexible stator assembling machine according to claim 1 or 5, wherein the fixing mechanism comprises a turntable, a pressure sensor, a positioning block and a rotary cylinder; the cylinder body of the rotary cylinder is fixed on the frame; the rotary table is fixed on a cylinder shaft of the rotary cylinder; the upper surface of the turntable is provided with a bulge which is matched with a positioning notch of the pallet to fix the pallet on the fixing mechanism; the pressure sensor is arranged on the upper surface of the turntable, is in contact with the base of the pallet and measures pressure data; the positioning block is fixed on the frame and matched with the base of the following fixture.
7. The material circulation type flexible stator assembling machine according to claim 1, wherein the blanking mechanism comprises a second fixing plate, a second linear guide rail, a second linear moving module, a second linear sliding block, a connecting block and a second supporting plate; one end of the connecting block is slidably arranged on the rack through a second linear moving module; the second fixing plate is fixed on the rack, and the second linear guide rail is fixed on the second fixing plate; the other end of the connecting block passes through a second fixing plate and is fixedly connected with a second linear sliding block; the second linear sliding block is slidably arranged on the second linear guide rail and is matched with the second linear guide rail to realize sliding along the second linear guide rail; the second bearing plate is arranged on the second linear sliding block.
8. The material circulation type flexible stator assembling machine according to claim 1, wherein the synchronous belt conveying mechanism comprises a photoelectric sensor, a conveying plate, a side bracket plate, a transmission shaft, a synchronous pulley, a second synchronous belt, a second motor, a first blocking mechanism and a second blocking mechanism; the side bracket plate is fixed on the rack, and transmission shafts are respectively and rotatably arranged at two ends of the side bracket plate; synchronous belt wheels are arranged on the transmission shaft in an interference fit mode and connected through a second synchronous belt; the output end of the second motor is connected with the transmission shaft and transmits power to the transmission shaft; the material conveying plate is placed on the second synchronous belt and can move along the second synchronous belt; the photoelectric sensor is used for sensing the feeding condition of the clamped stator; the first blocking mechanism is used for blocking the conveying of the conveying plate along the second synchronous belt and parking the clamped stator to the grabbing position of the stator conveying mechanism; the second blocking mechanism is used for blocking the conveying of the conveying plate along the second synchronous belt and is used for parking the conveying plate to a position where the conveying plate is conveyed to a finished product receiving position;
the synchronous belt material conveying mechanism also comprises a bearing plate; the bearing plate is fixed on the side bracket plate and positioned below the second synchronous belt and used for bearing the weight of conveyed materials;
the synchronous belt material conveying mechanism also comprises a material conveying plate side wheel; the side wheels of the material conveying plate are rotatably arranged at four corners of the material conveying plate and are tangent to the side bracket plates;
the first blocking mechanism and the second blocking mechanism have the same structure and respectively comprise a third linear cylinder, a third linear cylinder bracket and a stop block; the third linear cylinder support is fixed on the rack, the cylinder body of the third cylinder is fixed on the third linear cylinder support, and the stop block is fixed on the cylinder shaft of the third cylinder.
9. The material circulation type flexible stator assembling machine according to claim 1, wherein the stator handling mechanism comprises a first pneumatic claw, a side mounting plate, a third linear guide rail, a fourth linear moving module and a first connecting bracket; the side mounting plate is fixed on the rack through the supporting legs; the third linear guide rail is fixed on the side mounting plate; the first connecting bracket is slidably mounted on the side mounting plate through a fourth linear moving module, is also slidably mounted on the third linear guide rail and is matched with the third linear guide rail to realize sliding along the third linear guide rail; the first pneumatic claw is slidably mounted on the first connecting bracket through a third linear moving module or a linear cylinder to realize the movement in the Z direction;
the stator carrying mechanism further comprises a first drag chain; the first drag chain is arranged on the side mounting plate and used for converging the line and preventing the line from being worn.
10. The material circulation type flexible stator assembling machine according to claim 1, wherein the machine shell carrying and press-fitting mechanism comprises a passive compliant device, a rotary encoder, a second pneumatic gripper, a grating ruler connecting plate, a grating ruler, a side connecting plate, a sixth linear moving module, a fourth linear guide rail and a second connecting bracket; the side connecting plate is fixed on the rack through the supporting legs; the fourth linear guide rail is fixed on the side connecting plate; the second connecting bracket is slidably mounted on the side connecting plate through a sixth linear moving module, is also slidably mounted on the fourth linear guide rail and is matched with the fourth linear guide rail to realize sliding along the fourth linear guide rail; the main scale part of the grating scale is fixed on the supporting leg through the grating scale connecting plate, and the reading head part is fixed on the second connecting bracket, so that the linear displacement detection of the shell is realized; the passive compliance device is slidably mounted on the second connecting bracket through a fifth linear moving module or a linear cylinder to realize the movement in the Z direction; the tail end of the passive compliance device is provided with a second pneumatic paw; the rotary encoder is arranged on a rotating shaft of the passive compliant device, and the position offset condition of the machine shell during assembly is monitored in real time;
the machine shell carrying and press-mounting mechanism further comprises a second drag chain; the second drag chain is installed on the side connecting plate for converging the circuit, prevent the circuit wearing and tearing.
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CN202020246147.XU CN211351987U (en) | 2020-03-03 | 2020-03-03 | Material circulation type flexible stator assembling machine |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111193362A (en) * | 2020-03-03 | 2020-05-22 | 天津工业大学 | Material circulation type flexible stator assembling machine |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111193362A (en) * | 2020-03-03 | 2020-05-22 | 天津工业大学 | Material circulation type flexible stator assembling machine |
CN111193362B (en) * | 2020-03-03 | 2024-04-26 | 天津工业大学 | Flexible stator kludge of material circulation formula |
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