CN117748851B - Stator core assembly quality is used in brushless motor production - Google Patents

Abstract

The invention relates to the technical field of brushless motor production, in particular to a stator core assembly device for brushless motor production, which comprises a workbench, a shell, a sliding rail, a placing table, an elastic piece and the like, wherein the top of the workbench is connected with the shell and the sliding rail, the sliding rail is positioned in the shell, the placing table for placing a shell is connected onto the sliding rail in a sliding manner, and the elastic piece I is connected between the placing table and the sliding rail. According to the invention, the triangular frame can be driven to move leftwards through the screw rod motor, the triangular frame on the left side pushes the heating plate to move forwards, the heating plate moves into the machine shell to heat the interior of the machine shell, then the triangular frame on the left side is gradually separated from the roller, the heating plate moves out of the stator iron core, then the triangular frame on the right side pushes the heating plate to move forwards, the stator iron core on the stock frame is pushed into the machine shell on the placing table, the assembly of the stator iron core and the machine shell is completed, and the machine shell is assembled immediately after being heated, so that the stator iron core can smoothly enter the machine shell, and the sleeving qualification rate is higher.

Description

Stator core assembly quality is used in brushless motor production

Technical Field

The invention relates to the technical field of brushless motor production, in particular to a stator core assembly device for brushless motor production.

Background

Stator cores are important components in brushless motors for enhancing electromagnetic induction and concentrating electromagnetic fields, reducing magnetic leakage, and in the production of brushless motors, it is generally necessary to assemble the stator cores into a casing, and protect the stator cores through the casing.

When assembling, generally heat the casing inside through the heating furnace, the manipulator snatchs the pressure equipment bench with the casing after heating, then unclamps the casing after heating, later the manipulator snatchs stator core again, and pack into the casing after heating with stator core, accomplish stator core's assembly, the manipulator snatchs casing and stator core and needs certain time, during this period, the temperature of casing can drop, the inside shrinkage of casing, leads to the unable casing of packing into of stator core, thereby lead to the suit disqualification, influence the qualification rate of suit.

Disclosure of Invention

In order to overcome the defect that a manipulator needs a certain time for grabbing a shell and a stator core, the temperature of the shell is reduced, the interior of the shell is contracted with cold, so that the stator core cannot be installed in the shell, and the assembly is unqualified, and the qualification rate of the assembly is affected.

The technical scheme of the invention is as follows: the utility model provides a brushless motor production is with stator core assembly quality, including the workstation, a housing, the slide rail, the platform of placing, first elastic component, the slide bar, elastic component second, the guide arm, the slider, the connecting rod, the hot plate, electric putter, the lead screw motor, the carriage, the tripod, stock subassembly and fender material subassembly, the workstation top is connected with shell and slide rail, the slide rail is located the shell, sliding connection has the platform of placing that is used for placing the casing on the slide rail, be connected with elastic component first between platform and the slide rail, sliding connection has the slide bar in the shell, be connected with elastic component second between shell and the slide bar, the slide bar resets through elastic component second, be connected with the guide arm on the slide bar, sliding connection has the slider on the guide arm, all rotate on guide arm and the slider and be connected with the hot plate on the relative two connecting rods, be connected with a plurality of electric putter on the guide arm, electric putter's telescopic link and slider are connected with the lead screw motor, the lead screw motor is located the shell, sliding connection is used for sliding frame bottom and sliding rail top contact, be connected with two tripods between placing the platform and the slide rail, sliding frame sliding connection has two, sliding connection has the slide bar, the carriage bottom and the iron core to push away from the inside the stator, the stator can be moved into the frame and the corresponding iron core to the stator, and the stator can be moved to the inside the stator, and be moved to the frame, and the stator is moved to the stator to the inside, and the stator is moved to the frame.

In one embodiment, the stock assembly comprises a stock box, a stock guide and a stock frame, the casing is connected with the stock box for storing the stator core, the top of the workbench is connected with the stock guide, the stock guide is connected with the stock frame, and the stator core in the stock box can roll onto the stock frame along the stock guide, so that the stator core corresponds to the heating plate.

In one embodiment, the material blocking assembly comprises a wedge-shaped stop block and an elastic piece III, wherein the wedge-shaped stop block is slidably connected to the two sides of the front of the placement table and used for blocking a shell on the placement table, the shell cannot move when the stator core is pushed into the shell, the elastic piece III is connected between the placement table and the wedge-shaped stop block, and the wedge-shaped stop block is reset through the elastic piece III.

In one embodiment, the guide plate is inclined upwards towards one side of the magazine.

In one embodiment, the stator iron core guide device further comprises a material blocking mechanism, wherein the material blocking mechanism comprises a guide rod, a baffle plate and a connecting plate, the guide rod is connected in the shell, the baffle plate is connected to the guide rod in a sliding mode, the baffle plate is connected with a sliding rod through the connecting plate, the sliding rod drives the baffle plate to move forwards through the connecting plate, and when the heating plate enters the stator iron core, the baffle plate blocks the stator iron core on the material guide plate.

In one embodiment, the air cooling device further comprises an air cooling mechanism, the air cooling mechanism comprises a material storage plate and fans, the top of the shell is connected with the material storage plate, the top of the workbench is connected with a plurality of fans, the stator core assembled on the placing bench can be moved to the material storage plate, and the fans blow air to the assembled stator core on the material storage plate.

In one embodiment, the automatic discharging device further comprises a discharging mechanism, the discharging mechanism comprises a sliding plate, a discharging frame and an elastic piece IV, the sliding plate is connected to the shell in a sliding mode, the discharging frame used for pushing the stator iron core assembled on the placing table to the material storage plate is connected to the sliding plate in a sliding mode, the elastic piece IV is connected between the sliding plate and the discharging frame, and the discharging frame is reset through the elastic piece IV.

In one embodiment, the machine further comprises a discharging plate, the top of the shell is connected with the discharging plate for storing the machine shell, and the machine shell on the discharging plate can be moved to the placing table.

In one embodiment, the device further comprises a guide rail, the top of the workbench is connected with the guide rail, the guide rail is positioned in the shell, and the guide rail is in sliding connection with the tripod.

In one embodiment, the device further comprises a roller, the lower end of the sliding rod is rotatably connected with the roller, and the roller is used for reducing friction force generated when the tripod pushes the sliding rod.

The beneficial effects are that: 1. according to the invention, the triangular frame can be driven to move leftwards through the screw rod motor, the triangular frame on the left side pushes the heating plate to move forwards, the heating plate moves into the machine shell to heat the interior of the machine shell, then the triangular frame on the left side is gradually separated from the roller, the heating plate moves out of the stator iron core, then the triangular frame on the right side pushes the heating plate to move forwards, the stator iron core on the stock frame is pushed into the machine shell on the placing table, the assembly of the stator iron core and the machine shell is completed, and the machine shell is assembled immediately after being heated, so that the stator iron core can smoothly enter the machine shell, and the sleeving qualification rate is higher.

2. When the heating plate moves forwards, the baffle plate can block the stator core on the material guide plate, so that friction between the heating plate and the stator core on the material guide plate is avoided, and abrasion of the stator core on the material guide plate can be avoided.

3. Can remove the stator core that assembles to the flitch through removing the frame of unloading, do not need the manual contact stator core that assembles, avoid staff's hand to be scalded, the fan can be to the stator core that assembles bloies for the cooling rate of the stator core that assembles.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a cross-sectional view of the housing of the present invention.

Fig. 3 is a schematic perspective view of the elastic member II, the guide rod, the sliding block and the heating plate according to the present invention.

Fig. 4 is a schematic perspective view of the connecting rod, the heating plate and the electric push rod.

Fig. 5 is a schematic view of a first perspective structure of the stock assembly of the present invention.

Fig. 6 is a schematic diagram of a second perspective structure of the stock assembly of the present invention.

Fig. 7 is a schematic perspective view of a material blocking assembly according to the present invention.

Fig. 8 is an enlarged view of portion a of fig. 7 in accordance with the present invention.

Fig. 9 is a schematic view of a first perspective structure of the dam mechanism of the present invention.

Fig. 10 is a schematic view of a second perspective structure of the dam mechanism of the present invention.

Fig. 11 is a schematic perspective view of an air cooling mechanism and a discharging mechanism of the present invention.

Fig. 12 is a schematic perspective view of the discharging mechanism of the present invention.

In the reference numerals: the device comprises a 1-workbench, a 2-shell, a 3-sliding rail, a 4-placing table, a 5-elastic piece I, a 6-sliding bar, a 7-elastic piece II, an 8-guide bar, a 9-sliding block, a 10-connecting bar, a 11-heating plate, a 12-electric push bar, a 13-screw motor, a 14-sliding frame, a 15-tripod, a 161-storage box, a 162-guide plate, a 163-storage frame, a 171-wedge-shaped stop block, a 172-elastic piece III, a 181-guide bar, a 182-baffle, a 183-connecting plate, a 19-air cooling mechanism, a 191-storage plate, a 192-fan, a 201-sliding plate, a 202-discharge frame, a 203-elastic piece IV, a 21-discharge plate, a 22-guide rail and a 23-roller.

Detailed Description

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

Example 1: 1-8, including workstation 1, shell 2, slide rail 3, place the platform 4, elastic component one 5, slide bar 6, elastic component two 7, guide arm 8, slider 9, connecting rod 10, hot plate 11, electric putter 12, lead screw motor 13, carriage 14, tripod 15, stock subassembly and fender material subassembly, there is shell 2 at workstation 1 top through bolted connection, there is slide rail 3 in the middle of the workstation 1 top through bolted connection, slide rail 3 is located shell 2, sliding connection has place platform 4 on the slide rail 3, place platform 4 can slide about slide rail 3, be connected with two elastic components one 5 between place platform 4 right side and the slide rail 3 right side, elastic component one 5 is the spring, sliding connection has slide bar 6 in the middle of the top in the shell 2, slide bar 6 can slide about shell 2, the slide bar 6 is sleeved with an elastic piece II 7, two ends of the elastic piece II 7 are respectively connected with the shell 2 and the slide bar 6, the elastic piece II 7 is a spring, the front end of the slide bar 6 is connected with a guide bar 8, the guide bar 8 is connected with a slide block 9 in a sliding way, the slide block 9 can slide back and forth relative to the guide bar 8, the guide bar 8 and the slide block 9 are respectively connected with three connecting rods 10 in a rotating way at equal intervals along the circumferential direction, the two connecting rods 10 which are opposite in front and back are jointly connected with a heating plate 11 in a rotating way, the rear part of the guide bar 8 is connected with three electric push rods 12 at equal intervals along the circumferential direction, the front ends of telescopic rods of the electric push rods 12 are connected with the rear side of the slide block 9, the middle of the top of the workbench 1 is connected with a screw motor 13 through a bolt, the screw motor 13 is positioned in the shell 2, the screw motor 13 is connected with the slide rail 3 in a rotating way, the screw motor 13 is connected with a slide frame 14 through a thread way, the bottom of the slide frame 14 is contacted with the top of the slide rail 3, the right side of the sliding frame 14 contacts with the left side of the placing table 4, the left side and the right side of the front side of the sliding frame 14 are both connected with a tripod 15, a stock component is used for storing stator iron cores, and a material blocking component is used for blocking a shell on the placing table 4.

As shown in fig. 5 and 6, the stock assembly includes a stock box 161, a stock guide 162 and a stock frame 163, the left side of the housing 2 is connected with the stock box 161 by bolts, the left side of the top of the table 1 is connected with the stock guide 162 by bolts, the stock guide 162 is inclined upward toward one side of the stock box 161, and the right side of the stock guide 162 is connected with the stock frame 163.

As shown in fig. 7 and 8, the material blocking assembly comprises a wedge-shaped stop block 171 and an elastic piece III 172, wherein the wedge-shaped stop block 171 is slidably connected to the left and right sides of the front portion of the placement table 4, the wedge-shaped stop block 171 can slide left and right relative to the placement table 4, the elastic piece III 172 is sleeved on the wedge-shaped stop block 171, two ends of the elastic piece III 172 are respectively connected with the placement table 4 and the wedge-shaped stop block 171, and the elastic piece III 172 is a spring.

As shown in fig. 1, the device further comprises a discharging plate 21, the discharging plate 21 is connected to the right front side of the top of the shell 2 through bolts, and the discharging plate 21 is located right in front of the placing table 4.

As shown in fig. 1 and 2, the front side of the top of the workbench 1 is connected with a guide rail 22 through bolts, the guide rail 22 is positioned in the shell 2, and the guide rail 22 is in sliding connection with the tripod 15.

As shown in fig. 3, the sliding rod further comprises a roller 23, and the lower end of the sliding rod 6 is rotatably connected with the roller 23.

Initially, the first elastic member 5 is in a compressed state, the worker places a plurality of shells on the discharging plate 21, then pushes the shells, pushes the shell at the rearmost side on the discharging plate 21 to the placing table 4, under the action of the third elastic member 172, the shell can cross the wedge-shaped stop block 171, then places a plurality of stator cores into the storage box 161, the stator cores roll rightwards onto the storage box 163 along the guide plate 162, the guide plate 162 inclines upwards towards one side of the storage box 161, so that the stator cores can roll rightwards better, the worker controls the lead screw motor 13 to drive the sliding frame 14 to move leftwards, the sliding frame 14 does not block the placing table 4 any more, the placing table 4 moves leftwards under the action of the first elastic member 5, the shell on the placing table 4 moves leftwards along with the shell on the placing table 4, the shell on the placing table 4 corresponds to the stator cores on the storage box 163, the carriage 14 can also drive the tripod 15 to move leftwards, the guide rail 22 guides the tripod 15, the stability of the tripod 15 is improved, the tripod 15 on the left side can be contacted with the roller 23, the roller 23 is pushed to move forwards, the roller 23 drives the slide bar 6 to move forwards, the elastic member II 7 is compressed, the slide bar 6 drives the heating plate 11 to move forwards, meanwhile, the heating plate 11 is started by a worker to heat the inside of the casing by penetrating through the stator iron core on the stock rest 163 to move into the casing on the placing table 4, then the tripod 15 on the left side is gradually separated from the roller 23, the slide bar 6 moves backwards under the action of the elastic member II, the heating plate 11 moves backwards along with the movement of the slide bar 6 from the stator iron core, then the telescopic rod of the electric push rod 12 is controlled to stretch, the sliding block 9 is driven to move forwards, three heating plates 11 are driven to move towards the direction away from each other through a connecting rod 10, then a tripod 15 on the right side is contacted with a roller 23, the roller 23 is pushed to move forwards, the heating plate 11 moves forwards along with the tripod, a stator iron core on a stock rack 163 is pushed into a shell on a placing table 4, the assembly of the stator iron core and the shell is completed, the shell is heated and assembled immediately, the stator iron core can smoothly enter the shell, the sleeving qualification rate is higher, a wedge-shaped stop 171 can stop the shell on the placing table 4, the shell on the placing table 4 is prevented from moving backwards, after the assembly is completed, a telescopic rod of an electric push rod 12 is controlled to be shortened, a sliding block 9 is driven to move backwards, three heating plates 11 are driven to move towards the direction close to each other through the connecting rod 10, then a lead screw motor 13 is controlled to drive a sliding frame 14 to move rightwards, the sliding frame 14 pushes the placing table 4 to move rightwards to reset, an elastic piece I5 is compressed, the tripod 15 is separated from the roller 23, and the heating plate 11 moves backwards under the action of an elastic piece II 7.

Example 2: on the basis of embodiment 1, as shown in fig. 9 and 10, the device further comprises a material blocking mechanism, wherein the material blocking mechanism comprises a guide rod 181, a baffle 182 and a connecting plate 183, the guide rod 181 is connected in the middle of the inner top of the shell 2, the guide rod 181 is positioned on the left side of the slide rod 6, the baffle 182 is connected on the guide rod 181 in a sliding manner, the baffle 182 can slide back and forth relative to the guide rod 181, the right side of the baffle 182 is connected with the connecting plate 183, and the right side of the connecting plate 183 is connected with the slide rod 6.

When the slide bar 6 moves forwards, the baffle 182 is driven to move forwards through the connecting plate 183, the stator iron cores on the material guide plate 162 are blocked by the baffle 182, so that the stator iron cores on the material guide plate 162 cannot roll on the material storage frame 163, friction between the heating plate 11 and the stator iron cores on the material guide plate 162 is avoided, abrasion of the stator iron cores on the material guide plate 162 can be avoided, and when the slide bar 6 moves backwards, the baffle 182 is driven to move backwards through the connecting plate 183, and the stator iron cores on the material guide plate 162 are not blocked by the baffle 182.

As shown in fig. 11, the air cooling device 19 is further included, the air cooling device 19 includes a material storage plate 191 and a fan 192, the material storage plate 191 is connected to the right rear side of the top of the housing 2 through bolts, the material storage plate 191 is located right behind the placement table 4, two fans 192 are connected to the right rear side of the top of the workbench 1, and the two fans 192 are arranged in a front-back opposite mode.

As shown in fig. 11 and 12, the device further comprises a discharging mechanism, the discharging mechanism comprises a sliding plate 201, a discharging frame 202 and an elastic member IV 203, the sliding plate 201 is slidably connected to the upper right side of the housing 2, the sliding plate 201 can slide back and forth relative to the housing 2, the discharging frame 202 is slidably connected to the right side of the sliding plate 201, the discharging frame 202 can slide up and down relative to the sliding plate 201, the elastic member IV 203 is sleeved on the upper portion of the discharging frame 202, two ends of the elastic member IV 203 are respectively connected with the sliding plate 201 and the discharging frame 202, and the elastic member IV 203 is a spring.

After the stator core is assembled, the worker presses the discharging frame 202 downwards, the elastic piece IV 203 compresses, the discharging frame 202 is sleeved on the assembled stator core, then the discharging frame 202 is moved backwards, the assembled stator core is moved to the stock plate 191, the assembled stator core does not need to be contacted manually, hands of the worker are prevented from being scalded, the fan 192 is started, the fan 192 blows air to the assembled stator core, and the cooling speed of the assembled stator core is accelerated.

It should be understood that this example is only illustrative of the application and is not intended to limit the scope of the application. Furthermore, it should be understood that various changes and modifications can be made by one skilled in the art after reading the teachings of the present application, and such equivalents are intended to fall within the scope of the application as defined in the appended claims.

Claims (7)

1. The stator core assembly device for brushless motor production comprises a workbench (1), a housing (2), a sliding rail (3) and a placing table (4), wherein the top of the workbench (1) is connected with the housing (2) and the sliding rail (3), the sliding rail (3) is positioned in the housing (2), the placing table (4) for placing a shell is connected to the sliding rail (3) in a sliding way, the stator core assembly device is characterized by further comprising a first elastic piece (5), a sliding rod (6), a second elastic piece (7), a guide rod (8), a sliding block (9), a connecting rod (10), a heating plate (11), an electric push rod (12), a screw motor (13), a sliding frame (14), a tripod (15), a stock component and a material blocking component, the first elastic piece (5) is connected between the placing table (4) and the sliding rail (3), the sliding bar (6) is connected to the housing (2) in a sliding way, the second elastic piece (7) is connected between the housing (2) and the sliding bar (6), the sliding bar (6) is reset through the second elastic piece (7), the guide rod (8) is connected to the guide rod (8) in a sliding way, the sliding connection with the sliding block (9) on the guide rod (8) is connected to the sliding block (9) and the third connecting rod (10), the two opposite connecting rods (10) are connected with a heating plate (11) in a rotating mode together, a plurality of electric push rods (12) are connected to the guide rods (8), telescopic rods of the electric push rods (12) are connected with the sliding blocks (9), the tops of the working tables (1) are connected with screw rod motors (13), the screw rod motors (13) are located in the outer shell (2), the screw rod motors (13) are rotationally connected with the sliding rails (3), the screw rod motors (13) are connected with sliding frames (14) through threads, the bottoms of the sliding frames (14) are in contact with the tops of the sliding rails (3), two triangular frames (15) are connected to the sliding frames (14), a stock component is used for storing stator iron cores, a stock blocking component is used for blocking a shell on the placing table (4), the screw rod motors (13) drive the sliding frames (14) and the triangular frames (15) to move leftwards, the elastic pieces (5) push the placing table (4) to move leftwards to enable the shell and the stator iron cores to correspond, the triangular frames (6) to move forwards, the sliding rods (11) to enter the shell on the placing table (4), the inner part of the shell on the placing table (4) is contacted with the top of the sliding rails, the stator iron cores (3) are heated, and the stator iron cores can be pushed into the shell (4) to be assembled, and the stator iron cores can be assembled into the shell, and the shell (4) is heated;

The material storage assembly comprises a material storage box (161), a material guide plate (162) and a material storage frame (163), wherein the material storage box (161) for storing stator iron cores is connected to the shell (2), the material guide plate (162) is connected to the top of the workbench (1), the material storage frame (163) is connected to the material guide plate (162), and the stator iron cores in the material storage box (161) can roll onto the material storage frame (163) along the material guide plate (162) to enable the stator iron cores to correspond to the heating plates (11);

the material guide plate (162) is inclined upwards towards one side of the material storage box (161);

The automatic lifting device is characterized by further comprising a guide rail (22), wherein the guide rail (22) is connected to the top of the workbench (1), the guide rail (22) is positioned in the shell (2), and the guide rail (22) is in sliding connection with the tripod (15).

2. The stator core assembly device for brushless motor production as claimed in claim 1, wherein the material blocking component comprises a wedge-shaped stop block (171) and an elastic piece III (172), the wedge-shaped stop block (171) is slidably connected to both sides in front of the placement table (4), the wedge-shaped stop block (171) is used for blocking a casing on the placement table (4), when the stator core is pushed into the casing, the casing cannot move, the elastic piece III (172) is connected between the placement table (4) and the wedge-shaped stop block (171), and the wedge-shaped stop block (171) is reset through the elastic piece III (172).

3. The stator core assembly device for brushless motor production as claimed in claim 2, further comprising a material blocking mechanism, wherein the material blocking mechanism comprises a guide rod (181), a baffle plate (182) and a connecting plate (183), the guide rod (181) is connected in the shell (2), the baffle plate (182) is connected to the guide rod (181) in a sliding manner, the baffle plate (182) and the sliding rod (6) are connected through the connecting plate (183), the sliding rod (6) drives the baffle plate (182) to move forwards through the connecting plate (183), and the baffle plate (182) blocks the stator core on the material guide plate (162) when the heating plate (11) enters the stator core.

4. The stator core assembling device for brushless motor production according to claim 1, further comprising an air cooling mechanism (19), wherein the air cooling mechanism (19) comprises a material storage plate (191) and fans (192), the material storage plate (191) is connected to the top of the housing (2), a plurality of fans (192) are connected to the top of the workbench (1), the assembled stator core on the placement table (4) can be moved to the material storage plate (191), and the fans (192) blow air to the assembled stator core on the material storage plate (191).

5. The stator core assembling device for brushless motor production as claimed in claim 4, further comprising a discharging mechanism, wherein the discharging mechanism comprises a sliding plate (201), a discharging frame (202) and a fourth elastic member (203), the sliding plate (201) is slidably connected to the housing (2), the discharging frame (202) for pushing the assembled stator core on the placement table (4) onto the stock plate (191) is slidably connected to the sliding plate (201), the fourth elastic member (203) is connected between the sliding plate (201) and the discharging frame (202), and the discharging frame (202) is reset through the fourth elastic member (203).

6. A stator core assembly device for brushless motor production as claimed in claim 1, further comprising a blanking plate (21), wherein the top of the housing (2) is connected with the blanking plate (21) for storing the casing, and the casing on the blanking plate (21) is movable to the placement table (4).

7. The stator core assembly device for brushless motor production as claimed in claim 1, further comprising a roller (23), wherein the roller (23) is rotatably connected to the lower end of the slide bar (6), and the roller (23) is used for reducing friction force generated when the tripod (15) pushes the slide bar (6).