CN202930500U - Winding mechanism of nickel-metal hydride cylindrical battery full-automatic winding all-in-one machine - Google Patents

Abstract

The utility model relates to automatic winding equipment and in particular relates to a winding mechanism of a nickel-metal hydride cylindrical battery full-automatic winding all-in-one machine in the automatic winding equipment. The winding mechanism comprises a first position winding driving part, a second position winding driving part, a first position winding needle and a second position winding needle, wherein the first position winding needle and the second position winding needle are interchangeable; the first position winding driving part is connected with the first position winding needle; the second position winding driving part is connected with the second position winding needle; and the first position winding needle and the second position winding needle are provided with U-shaped slots for upper cell diaphragm paper and lower cell diaphragm paper to insert. The winding mechanism has the beneficial effects of being beneficial to achieving full-automatic winding of the nickel-metal hydride cylindrical battery, improving the production efficiency and reducing the production cost.

Description

The winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one

Technical field

The utility model relates to auto reeling equipment, relates in particular to the winding mechanism of a kind of ni-mh cylindrical battery full automatic winding all-in-one in auto reeling equipment.

Background technology

Ni-MH battery is synthetic by hydrogen ion and metallic nickel, and the electric weight deposit Duos 30% than nickel-cadmium cell, and is lighter than nickel-cadmium cell, and useful life is also longer, and environmentally safe.

At present, the coiling automation of existing ni-mh cylindrical battery is lower, and production efficiency is lower.

Summary of the invention

In order to solve the problems of the prior art, the utility model provides a kind of winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one.

The utility model provides a kind of winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one, comprise the first station coiling drive division, the second station coiling drive division, interchangeable the first station volume pin and the second station volume pin, described the first station coiling drive division is connected with described the first station volume pin, described the second station coiling drive division is connected with described the second station volume pin, is equipped with the U-shaped slot that plugs for upper strata electric core membrane paper, lower floor's electric core membrane paper on described the first station volume pin and the second station volume pin.

As further improvement of the utility model, described the first station coiling drive division comprises the first station coiling motor, is connected and the first station coiling gear with described the first station coiling motor, and described the first station volume pin is connected by the first station coiling rotating shaft with described the first station coiling gear.

As further improvement of the utility model, described the second station coiling drive division comprises the second station coiling motor, is connected and the second station coiling gear with described the second station coiling motor, described the second station volume pin is connected by the second station coiling rotating shaft with described the second station coiling gear, described the first station volume pin is connected with the first station volume pin retraction cylinder, and described the second station volume pin is connected with the second station volume pin retraction cylinder and the second station volume pin stretches out cylinder.

As further improvement of the utility model, described winding mechanism also comprises coiling support column and station inversion mechanism, described coiling support column is connected with supporting bracket, rotating disk has been rotatably connected on described supporting bracket, described the first station volume pin and the second station volume pin all are arranged on described rotating disk, and described rotating disk is connected with described station inversion mechanism.

As further improvement of the utility model, described station inversion mechanism comprises station transposition motor, the first transposition gear that is connected with described station transposition motor and the second transposition gear that is meshed with described the first transposition gear, described the second transposition gear is connected with described rotating disk, described the second transposition gear is provided with the transposition location hole, described supporting bracket is provided with the transposition positioning cylinder, and described transposition positioning cylinder is connected with the transposition alignment pin that matches with described transposition location hole.

as further improvement of the utility model, described winding mechanism also comprises the post rod mechanism that matches with described the second station volume pin, described post rod mechanism comprises the push rod support, described push rod support is provided with push rod rotary cylinder and push rod telescopic cylinder, described push rod telescopic cylinder is connected with extension sleeve, be arranged with the push rod rotating shaft in described extension sleeve, described push rod rotating shaft is provided with sprocket wheel, be wound with chain on described sprocket wheel, one end of described chain is connected with described push rod rotary cylinder, the other end of described chain is connected with spring, described spring is connected with described push rod support, described push rod rotating shaft is connected with the push rod swing arm, described push rod swing arm is connected with push rod.

As further improvement of the utility model, the end of the U-shaped slot of described push rod and described the second station volume pin connects.

As further improvement of the utility model, the rotating shaft of described push rod rotating shaft and described rotating disk coincides, and the distance of the rotating shaft of described rotating disk and described the second station volume pin equals the distance of described push rod and described push rod rotating shaft.

The beneficial effects of the utility model are: by such scheme, be conducive to realize the full automatic winding of ni-mh cylindrical battery, improved production efficiency, reduced production cost.

Description of drawings

Fig. 1 is the perspective view of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Fig. 2 is the front view of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Fig. 3 is the part front view of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Fig. 4 is the partial enlarged drawing A of Fig. 3;

Fig. 5 is the structural representation of the upper strata tension adjustment mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Fig. 6 is the structural representation of the negative pole paillon foil material fetching mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Fig. 7 is the structural representation of the negative pole paillon foil material transferring mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Fig. 8 is the structural representation of the negative pole paillon foil feeding mechanical hand of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Fig. 9 is the perspective view of the winding mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 10 is the perspective view at another visual angle of the winding mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 11 is the part-structure schematic diagram of the winding mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 12 is the structural representation of post rod mechanism of the winding mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 13 is the perspective view of sending box hat mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 14 is the front view that send box hat mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 15 is the fractal structure schematic diagram that send box hat mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 16 is the perspective view at another visual angle of sending box hat mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 17 is the perspective view at another visual angle of sending box hat mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 18 is the sheath body of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one, the front view of shedding mechanism;

Figure 19 is the structural representation of machinery folder of sheath body, the shedding mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 20 is the sheath body of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one, the front view of shedding mechanism;

Figure 21 is the sheath body of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one, the structural representation that pushes away clamp mechanism of shedding mechanism;

Figure 22 is the sheath body of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one, the perspective view of shedding mechanism;

Figure 23 is the perspective view at another visual angle of sheath body, the shedding mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 24 is the perspective view at another visual angle of sheath body, the shedding mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 25 is the perspective view of the receiving mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 26 is the perspective view of the receiving mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Figure 27 is the perspective view at another visual angle of the receiving mechanism of a kind of ni-mh cylindrical battery of the utility model full automatic winding all-in-one;

Embodiment

Below in conjunction with description of drawings and embodiment, the utility model is further illustrated.

Drawing reference numeral in Fig. 1 to Figure 27 is: support 100; Control cabinet 101; Feed mechanism 1; Upper strata electric core membrane paper connecting gear 11; Paper disc 111 is put on the upper strata; Upper strata tension adjustment mechanism 112; Upper strata tension adjustment guide rail 1121; Upper strata tension adjustment slide block 1122; Upper strata tension adjustment balancing weight 1123; Upper strata guide rail 113; Upper break paper approach switch 114; Paper approach switch 115 is put on the upper strata; The upper strata stops putting paper and takes over switch 116; Paper approach switch 117 breaks on the upper strata; Lower floor's electric core membrane paper connecting gear 12; Paper disc 121 is put in lower floor; Lower floor's tension adjustment mechanism 122; Lower floor's guide rail 123; Negative pole paillon foil connecting gear 13; Negative pole paillon foil storage box 131; Negative pole paillon foil material fetching mechanism 132; Negative pole paillon foil feeding cylinder 1321; Negative pole paillon foil feeding sucker 1322; Negative pole paillon foil feeding bearing 1323; Negative pole paillon foil feeding guide rod 1324; Negative pole paillon foil feeding linear bearing 1325; Negative pole paillon foil material transferring mechanism 133; The negative pole paillon foil turns material motor 1331; The negative pole paillon foil turns material Timing Belt 1332; The negative pole paillon foil turns material slide block 1333; The negative pole paillon foil turns material guide rail 1334; The negative pole paillon foil turns material platform 1335; Negative pole paillon foil discharge mechanism 134; Negative pole paillon foil feeding mechanical hand 135; Negative pole paillon foil feeding motor 1351; Negative pole paillon foil feeding Timing Belt 1352; Negative pole paillon foil feeding slide block 1353; Negative pole paillon foil feeding guide 1354; Negative pole paillon foil feeding table 1355; Anodal paillon foil connecting gear 14; Anodal paillon foil storage box 141; Anodal paillon foil material fetching mechanism 142; Anodal paillon foil material transferring mechanism 143; Anodal paillon foil discharge mechanism 144; Anodal paillon foil feeding mechanical hand 145; Move back letterweight tight mechanism 15; Move back the tight cylinder 151 of letterweight; Move back the tight driven pulley 152 of letterweight; Move back paper motor 153; Move back the tight driving wheel 154 of letterweight; Shearing mechanism 16; Cut off cylinder 161; Upper scissors 162; Lower scissors 163; Winding mechanism 2; The first station volume pin 21; The first station coiling motor 211; The first station coiling gear 212; The first station volume pin retraction cylinder 213; The second station volume pin 22; The second station coiling motor 221; The second station coiling gear 222; The second station volume pin retraction cylinder 223; The second station volume pin stretches out cylinder 224; Coiling support column 231; Supporting bracket 232; Rotating disk 233; Station transposition motor 251; The first transposition gear 252; The second transposition gear 253; Transposition positioning cylinder 261; Transposition alignment pin 262; Push rod rotary cylinder 271; Chain 272; Sprocket wheel 273; Spring 274; Push rod rotating shaft 275; Push rod swing arm 276; Push rod telescopic cylinder 277; Extension sleeve 278; Push rod support 279; Push rod 2710; Send box hat mechanism 3; Box hat case 311; The box hat case is installed side plate 312; Advance steel shell hole 3121; Box hat reverse reflux hole 3122; Box hat support column 313; Box hat top board 314; Deep-slotted chip breaker 3141; Send box hat drive motors 321; Send box hat rotating band 322; Send box hat driving main shaft 323; Send box hat Timing Belt 331; Send box hat synchronizing wheel 332; Top box hat cam 333; Box hat conveyer belt 341; Box hat transmits guide rail 342; Oppositely box hat pushes away shell cylinder 343; Box hat set direction block 344; Set direction block shell cylinder 345; Box hat Position Control block 346; Box hat Position Control cylinder 347; The forward box hat pushes away shell cylinder 351; Push away box hat firing pin 352; Box hat guide holder 353; Box hat accumulator tank 36; Sheath body, shedding mechanism 4; Index dial 41; Index dial drive motors 411; Index dial location hole 412; Machinery folder 42; Gripper cylinder 421; Clamping swing arm 422; The first jig arm 423; Push away gas enclosure cylinder 424; Push away folder guide rail 425; Index dial positioning cylinder 431; Index dial alignment pin 432; The location cranks arm 44; The sub-cylinder 451 of gear bundle; Restraint sub-backgauge pin 452; Receiving mechanism 5; Rewinding bearing 51; Rewinding guide rail 52; Box hat blanking seat 531; X-axis pusher cylinder 532; Pendulum material mould 533; The first Y-axis pusher cylinder 534; Rewinding demixing plate 535; Blanking guide groove 5351; The first Y-axis guide rail 536; X-axis scraping wings 537; The second Y-axis drive division 541; The second Y-axis screw mandrel 542; The second Y-axis guide rail 543; Pendulum magazine 544; Rewinding demixing plate lift cylinder 55; Upper strata electric core membrane paper 201; Lower floor's electric core membrane paper 202; Negative pole paillon foil 203; Anodal paillon foil 204; Box hat 205; Power taking core bundle station 401; Cover box hat station 402; Quality Detection station 403; Unloading station 404.

As shown in Figure 1 to Figure 27, a kind of winding mechanism 2 of ni-mh cylindrical battery full automatic winding all-in-one, comprise the first station coiling drive division, the second station coiling drive division, interchangeable the first station volume pin 21 and the second station volume pin 22, described the first station coiling drive division is connected with described the first station volume pin 21, described the second station coiling drive division is connected with described the second station volume pin 22, is equipped with the U-shaped slot that plugs for upper strata electric core membrane paper 201, lower floor's electric core membrane paper 202 on described the first station volume pin 21 and the second station volume pin 22.

as shown in Figure 1 to Figure 27, for better, more fully describe, the utility model also provides a kind of ni-mh cylindrical battery full automatic winding all-in-one, comprises the support 100 that is provided with control cabinet 101, and described support 100 is provided with and transmits upper strata electric core membrane paper 201, lower floor's electric core membrane paper 202, negative pole paillon foil 203, the feed mechanism 1 of anodal paillon foil 204, upper strata electric core membrane paper 201 with described feed mechanism 1 transmission, lower floor's electric core membrane paper 202, negative pole paillon foil 203, the stacked winding mechanism 2 that is wound as battery core Shu Zi of anodal paillon foil 204, that transmits box hat 205 send box hat mechanism 3, the battery core Shu Zi that described winding mechanism 2 is reeled and the box hat 205 that send box hat mechanism 3 to transmit carry out sheath body and form finished product, and the sheath body that finished product is carried out discharging, shedding mechanism 4, with described sheath body, the finished product that shedding mechanism 4 unloads is arranged the receiving mechanism 5 of rewinding, and described feed mechanism 1 comprises the upper strata electric core membrane paper connecting gear 11 that upper strata electric core membrane paper 201 is sent to winding mechanism 2, lower floor's electric core membrane paper 202 is sent to lower floor's electric core membrane paper connecting gear 12 of winding mechanism 2, negative pole paillon foil 203 is sent to the negative pole paillon foil connecting gear 13 of winding mechanism 2, anodal paillon foil 204 is sent to the anodal paillon foil connecting gear 14 of winding mechanism 2, with upper strata electric core membrane paper 201, lower floor's electric core membrane paper 202, negative pole paillon foil 203, anodal paillon foil 204 compress and move back paper move back the tight mechanism 15 of letterweight and with upper strata electric core membrane paper 201, lower floor's electric core membrane paper 202, negative pole paillon foil 203, the shearing mechanism 16 that anodal paillon foil 204 is cut off, described winding mechanism 2 comprises the first station coiling drive division, the second station coiling drive division, interchangeable the first station volume pin 21 and the second station volume pin 22, described the first station coiling drive division is connected with described the first station volume pin 21, described the second station coiling drive division is connected with described the second station volume pin 22, is equipped with for upper strata electric core membrane paper 201 on described the first station volume pin 21 and the second station volume pin 22, the U-shaped slot that lower floor's electric core membrane paper 202 plugs, described sheath body, shedding mechanism 4 comprises power taking core bundle station 401, cover box hat station 402, Quality Detection station 403 and unloading station 404, wherein, described upper strata electric core membrane paper connecting gear 11 is identical with the structure of described lower floor electric core membrane paper connecting gear 12, and described negative pole paillon foil connecting gear 13 is identical with the structure of described anodal paillon foil connecting gear 14.

As shown in Figure 1 to Figure 27, described upper strata electric core membrane paper connecting gear 11 comprises that the upper strata of the upper strata electric core membrane paper 201 of placing web-like puts paper disc 111, adjusts the upper strata tension adjustment mechanism 112 of upper strata electric core membrane paper 201 tension force and upper strata electric core membrane paper 201 is directed to the upper strata guide rail 113 of winding mechanism 2.

As shown in Figure 1 to Figure 27, described lower floor electric core membrane paper connecting gear 12 comprises that the lower floor of lower floor's electric core membrane paper 202 of placing web-like puts paper disc 121, adjusts lower floor's tension adjustment mechanism 122 of lower floor's electric core membrane paper 202 tension force and lower floor's electric core membrane paper 202 is directed to lower floor's guide rail of winding mechanism 2.

as shown in Figure 1 to Figure 27, described negative pole paillon foil connecting gear 13 comprises the negative pole paillon foil storage box 131 by stacked on top of one another filling negative pole paillon foil 203, draw the negative pole paillon foil material fetching mechanism 132 of negative pole paillon foil 203 from negative pole paillon foil storage box 131, the negative pole paillon foil material transferring mechanism 133 that the negative pole paillon foil 203 that negative pole paillon foil material fetching mechanism 132 is drawn transmits, draw the negative pole paillon foil discharge mechanism 134 of negative pole paillon foil 203 and the negative pole paillon foil 203 that negative pole paillon foil discharge mechanism 134 is drawn is sent to the negative pole paillon foil feeding mechanical hand 135 of winding mechanism 2 from negative pole paillon foil material transferring mechanism 133.

as shown in Figure 1 to Figure 27, described anodal paillon foil connecting gear 14 comprises the anodal paillon foil storage box 141 by the anodal paillon foil 204 of stacked on top of one another filling, draw the anodal paillon foil material fetching mechanism 142 of anodal paillon foil 204 from anodal paillon foil storage box 141, the anodal paillon foil material transferring mechanism 143 that the anodal paillon foil 204 that anodal paillon foil material fetching mechanism 142 is drawn transmits, draw the anodal paillon foil discharge mechanism 144 of anodal paillon foil 204 and the anodal paillon foil 204 that anodal paillon foil discharge mechanism 144 is drawn is sent to the anodal paillon foil feeding mechanical hand 145 of winding mechanism 2 from anodal paillon foil material transferring mechanism 143.

As shown in Figure 1 to Figure 27, described upper strata tension adjustment mechanism 112 comprises the upper strata tension adjustment guide rail 1121 that is arranged on described support 100, be arranged on the upper strata tension adjustment slide block 1122 on described upper strata tension adjustment guide rail 1121 and be arranged on upper strata tension adjustment balancing weight 1123 on described upper strata tension adjustment slide block 1122, can adjust by the weight of adjusting upper strata tension adjustment balancing weight 1123 tensioning degree of upper strata electric core membrane paper 201.

as shown in Figure 1 to Figure 27, tension adjustment mechanism 112 sides, described upper strata are provided with the upper break paper approach switch 114 that matches with upper strata tension adjustment slide block 1122, paper approach switch 115 is put on the upper strata, the upper strata stops putting paper and takes over the disconnected paper approach switch 117 of switch 116 and upper strata, when upper break paper approach switch 114 is triggered, holding state appears stopping, when upper strata tension adjustment slide block 1122 rises to the upper strata and puts paper approach switch 115, the upper strata is put paper disc 111 and is put the paper Electric Machine Control and begin to put paper, upper strata tension adjustment slide block 1122 down slidings, when upper strata tension adjustment slide block 1122 down slidings, when touching the upper strata and stopping putting paper and take over switch 116, the upper strata is put the putting the paper Electric Machine Control of paper disc 111 and is shut down, if upper strata tension adjustment slide block 1122 glides when breaking paper approach switch 117 to the upper strata, equipment is judged as upper strata electric core membrane paper 201 and breaks away from the second station volume pin 22.

As shown in Figure 1 to Figure 27, described lower floor tension adjustment mechanism 122 comprises lower floor's tension adjustment guide rail of being arranged on described support 100, be arranged on the lower floor's tension adjustment slide block on described lower floor tension adjustment guide rail and be arranged on lower floor's tension adjustment balancing weight on described lower floor tension adjustment slide block.

As shown in Figure 1 to Figure 27, described lower floor tension adjustment mechanism 122 sides are provided with that the paper approach switch is put in the lower break paper approach switch, the lower floor that match with lower floor tension adjustment slide block, lower floor stops putting paper and takes over the disconnected paper approach switch of switch and lower floor.

As shown in Figure 1 to Figure 27, described negative pole paillon foil storage box 131 comprises negative pole paillon foil container cavity body, the bottom of described negative pole paillon foil container cavity body is provided with negative pole paillon foil jacking motor, described negative pole paillon foil jacking motor is connected with negative pole paillon foil lifting platform, be provided with negative pole paillon foil upper limit sense switch in described negative pole paillon foil container cavity body, be used for controlling negative pole paillon foil jacking motor with the height of negative pole paillon foil lifting platform jacking.

As shown in Figure 1 to Figure 27, described anodal paillon foil storage box 141 comprises anodal paillon foil container cavity body, the bottom of described anodal paillon foil container cavity body is provided with anodal paillon foil jacking motor, described anodal paillon foil jacking motor is connected with anodal paillon foil lifting platform, is provided with anodal paillon foil upper limit sense switch in described anodal paillon foil container cavity body.

As shown in Figure 1 to Figure 27, described negative pole paillon foil material fetching mechanism 132 comprises negative pole paillon foil feeding bearing 1323, is arranged on the negative pole paillon foil feeding cylinder 1321 on described negative pole paillon foil feeding bearing 1323, the negative pole paillon foil feeding sucker 1322 that is connected with described negative pole paillon foil feeding cylinder 1321, described negative pole paillon foil feeding bearing 1323 is provided with negative pole paillon foil feeding linear bearing 1325, described negative pole paillon foil feeding bearing 1325 is provided with negative pole paillon foil feeding guide rod 13241, and described negative pole paillon foil feeding guide rod 1324 is connected with described negative pole paillon foil feeding sucker 1322.

As shown in Figure 1 to Figure 27, described anodal paillon foil material fetching mechanism 142 comprises anodal paillon foil feeding bearing, is arranged on the anodal paillon foil feeding cylinder on described anodal paillon foil feeding bearing, the anodal paillon foil feeding sucker that is connected with described anodal paillon foil feeding cylinder, described anodal paillon foil feeding bearing is provided with anodal paillon foil feeding linear bearing, described anodal paillon foil feeding bearing is provided with anodal paillon foil feeding guide rod, and described anodal paillon foil feeding guide rod is connected with described anodal paillon foil feeding sucker.

As shown in Figure 1 to Figure 27, described negative pole paillon foil material transferring mechanism 133 comprises that the negative pole paillon foil turns material motor 1331, negative pole paillon foil and turns material guide rail 1334, turns with described negative pole paillon foil negative pole paillon foil that material motor 1331 is connected and turn material Timing Belt 1332, turn with described negative pole paillon foil negative pole paillon foil that material Timing Belt 1332 is connected and turn material slide block 1333 and expect that negative pole paillon foil that slide block 1333 is connected turns and expect that platform 1335, described negative pole paillon foil turn and expect that slide block 1333 is arranged on described negative pole paillon foil and turns and expect on guide rail 1334 with turning with described negative pole paillon foil.

As shown in Figure 1 to Figure 27, described anodal paillon foil material transferring mechanism 143 comprises that anodal paillon foil turns material motor, anodal paillon foil and turns the material guide rail, turns with described anodal paillon foil anodal paillon foil that the material motor is connected and turn the material Timing Belt, turn with described anodal paillon foil anodal paillon foil that the material Timing Belt is connected and turn and expect that slide block expects that with turning with described anodal paillon foil the anodal paillon foil that slide block is connected turns the material platform, and described anodal paillon foil turns expects that slide block is arranged on described anodal paillon foil and turns and expect on guide rail.

As shown in Figure 1 to Figure 27, described negative pole paillon foil feeding mechanical hand 135 comprises negative pole paillon foil feeding motor 1351, negative pole paillon foil feeding guide 1354, the negative pole paillon foil feeding Timing Belt 1352 that is connected with described negative pole paillon foil feeding motor 1351, the negative pole paillon foil feeding slide block 1353 that is connected with described negative pole paillon foil feeding Timing Belt 1352 and the negative pole paillon foil feeding table 1355 that is connected with described negative pole paillon foil feeding slide block 1353, and described negative pole paillon foil feeding slide block 1353 is arranged on described negative pole paillon foil feeding guide 1354.

As shown in Figure 1 to Figure 27, described anodal paillon foil feeding mechanical hand 145 comprises anodal paillon foil feeding motor, anodal paillon foil feeding guide, the anodal paillon foil feeding Timing Belt that is connected with described anodal paillon foil feeding motor, the anodal paillon foil feeding slide block that is connected with described anodal paillon foil feeding Timing Belt and the anodal paillon foil feeding table that is connected with described anodal paillon foil feeding slide block, and described anodal paillon foil feeding slide block is arranged on described anodal paillon foil feeding guide.

As shown in Figure 1 to Figure 27, described negative pole paillon foil discharge mechanism 134 comprises negative pole paillon foil blowing bearing, is arranged on the negative pole paillon foil blowing cylinder on described negative pole paillon foil blowing bearing, the negative pole paillon foil blowing sucker that is connected with described negative pole paillon foil blowing cylinder, described negative pole paillon foil blowing bearing is provided with negative pole paillon foil blowing linear bearing, described negative pole paillon foil dispensing shaft holds and is provided with negative pole paillon foil blowing guide rod, and described negative pole paillon foil blowing guide rod is connected with described negative pole paillon foil blowing sucker.

As shown in Figure 1 to Figure 27, described anodal paillon foil discharge mechanism 144 comprises anodal paillon foil blowing bearing, is arranged on the anodal paillon foil blowing cylinder on described anodal paillon foil blowing bearing, the anodal paillon foil blowing sucker that is connected with described anodal paillon foil blowing cylinder, described anodal paillon foil blowing bearing is provided with anodal paillon foil blowing linear bearing, described anodal paillon foil dispensing shaft holds and is provided with anodal paillon foil blowing guide rod, and described anodal paillon foil blowing guide rod is connected with described anodal paillon foil blowing sucker.

As shown in Figure 1 to Figure 27, described move back letterweight tight mechanism 15 comprise move back the tight cylinder 151 of letterweight, with described move back that the tight cylinder 151 of letterweight is connected move back the tight driven pulley 152 of letterweight, move back paper motor 153 with described move back that paper motor 153 is connected move back the tight driving wheel 154 of letterweight.

As shown in Figure 1 to Figure 27, described shearing mechanism 16 comprises to be cut off cylinder 161, cuts off the upper scissors 162 that cylinder 161 is connected and be arranged on lower scissors 163 on described winding mechanism 2 with described.

as shown in Figure 1 to Figure 27, described the first station coiling drive division comprises the first station coiling motor 211, be connected with described the first station coiling motor 211 and the first station coiling gear 212, described the first station volume pin 21 is connected by the first station coiling rotating shaft with described the first station coiling gear 212, described the second station coiling drive division comprises the second station coiling motor 221, be connected with described the second station coiling motor 221 and the second station coiling gear 222, described the second station volume pin 22 is connected by the second station coiling rotating shaft with described the second station coiling gear 222, described the first station volume pin 21 is connected with the first station volume pin retraction cylinder 213, described the second station volume pin 22 is connected with the second station volume pin retraction cylinder 223 and the second station volume pin stretches out cylinder 224.

as shown in Figure 1 to Figure 27, described winding mechanism 2 also comprises coiling support column 231 and station inversion mechanism, described coiling support column 231 is connected with supporting bracket 232, rotating disk 233 has been rotatably connected on described supporting bracket 232, described the first station volume pin 21 and the second station volume pin 22 all are arranged on described rotating disk 233, described rotating disk 233 is connected with described station inversion mechanism, described station inversion mechanism comprises station transposition motor 251, the the first transposition gear 252 that is connected with described station transposition motor 251 and the second transposition gear 253 that is meshed with described the first transposition gear 252, described the second transposition gear 253 is connected with described rotating disk 233, described the second transposition gear 253 is provided with the transposition location hole, described supporting bracket 232 is provided with transposition positioning cylinder 261, described transposition positioning cylinder 261 is connected with the transposition alignment pin 262 that matches with described transposition location hole.

as shown in Figure 1 to Figure 27, described winding mechanism 2 also comprises the post rod mechanism that matches with described the second station volume pin 22, described post rod mechanism comprises push rod support 279, described push rod support 279 is provided with push rod rotary cylinder 271 and push rod telescopic cylinder 277, described push rod telescopic cylinder 277 is connected with extension sleeve 278, be arranged with push rod rotating shaft 275 in described extension sleeve 278, described push rod rotating shaft 275 is provided with sprocket wheel 273, be wound with chain 272 on described sprocket wheel 273, one end of described chain 272 is connected with described push rod rotary cylinder 271, the other end of described chain 272 is connected with spring 274, described spring 274 is connected with described push rod support 279, described push rod rotating shaft 275 is connected with push rod swing arm 276, described push rod swing arm 276 is connected with push rod 2710, described push rod 2710 connects with the end of the U-shaped slot of described the second station volume pin 22.

To Figure 27, described push rod rotating shaft 275 coincides with the rotating shaft of described rotating disk 233 as shown in Figure 1, and the distance of the rotating shaft of described rotating disk 233 and described the second station volume pin 22 equals the distance of described push rod 2710 and described push rod rotating shaft 275.

As shown in Figure 1 to Figure 27, describedly send box hat mechanism 3 to comprise be used to the box hat case 311 that holds box hat, the box hat case that is connected with described box hat case 311 side plate 312 is installed, described box hat case is installed side plate 312 and is provided with and send the box hat drive division, send with described the box hat drive division is connected send the box hat tape handler and be connected with top box hat mechanism with the described box hat drive division that send, and described top box hat mechanism comprises pushes up box hat 205 to the box hat top board 314 that send on the box hat tape handler from box hat case 311.

To Figure 27, described box hat case is installed side plate 312 and is provided with into steel shell hole 3121 as shown in Figure 1, and described box hat top board 314 is provided with the deep-slotted chip breaker 3141 that matches with box hat 205.

As shown in Figure 1 to Figure 27, described send the box hat drive division to comprise to send box hat drive motors 321, with described send that box hat drive motors 321 is connected send box hat rotating band 322 with described send that box hat rotating band 322 is connected send box hat driving main shaft 323, the described box hat driving main shaft 323 of sending is connected with described box hat tape handler, the top box hat mechanism of sending respectively.

As shown in Figure 1 to Figure 27, the described box hat tape handler that send comprises and the described box hat conveyer belt 341 that send box hat driving main shaft 323 to be connected, described box hat case is installed side plate 312 and is provided with box hat transmission guide rail 342, and described box hat conveyer belt 341 is tangent with described box hat transmission guide rail 342.

as shown in Figure 1 to Figure 27, described box hat case is installed side plate 312 and is provided with box hat Position Control cylinder 347, set direction block shell cylinder 345 and reverse box hat push away shell cylinder 343, described box hat Position Control cylinder 347 is connected with box hat Position Control block 346, described set direction block shell cylinder 345 is connected with box hat set direction block 344, described box hat set direction block 344 is provided with the box hat direction detection switch, described reverse box hat pushes away shell cylinder 343 and is connected with reverse box hat push rod, described box hat case is installed side plate 312 and is provided with box hat reverse reflux hole 3122, wherein, the box hat direction detection switch is used for the both forward and reverse directions of identification box hat 205, if in the other direction, push away shell cylinder 343 by reverse box hat reverse box hat 205 3122 is pushed back box hat case 311 through box hat reverse reflux hole.

To Figure 27, described box hat case is installed side plate 312 and is provided with box hat accumulator tank 36 as shown in Figure 1, and described box hat accumulator tank 36 transmits guide rail 342 with described box hat and is connected.

As shown in Figure 1 to Figure 27, described box hat case installation side plate 312 is provided with the forward box hat and pushes away shell cylinder 351 and box hat guide holder 353, described forward box hat pushes away shell cylinder 351 and is connected with and pushes away box hat firing pin 352, described box hat guide holder 353 is provided with the box hat pilot hole, described box hat guide holder 353, pushes away the both sides that box hat firing pin 352 lays respectively at described box hat accumulator tank 36.

To Figure 27, described box hat accumulator tank 36 is formed by box hat storage right baffle-plate and the right baffle plate of box hat storage of phase obvolvent as shown in Figure 1.

As shown in Figure 1 to Figure 27, described top box hat mechanism is cam mechanism, described cam mechanism comprise with described send that box hat driving main shaft 323 is connected send box hat Timing Belt 331, with described send that box hat Timing Belt 331 is connected send box hat synchronizing wheel 332 with the described top box hat cam 333 that send box hat synchronizing wheel 332 to be connected, described top box hat cam 333 is connected with described box hat top board 314.

To Figure 27, described box hat case is installed side plate 312 and is connected by box hat support column 313 with described box hat accumulator tank 36 as shown in Figure 1.

To Figure 27, described sheath body, shedding mechanism 4 comprise index dial drive motors 411 and the index dial 41 that is connected with described index dial drive motors 411 as shown in Figure 1, and described index dial 41 is connected with machinery folder 42.

To Figure 27, described machinery folder 42 comprises fixture and promotes the clamp mechanism that pushes away of described fixture as shown in Figure 1.

To Figure 27, the described clamp mechanism that pushes away comprises that pushing away gas enclosure cylinder 424 presss from both sides guide rail 425 with pushing away as shown in Figure 1, and the described gas enclosure cylinder 424 that pushes away is connected with described fixture, and described fixture is arranged on described pushing away on folder guide rail 425.

To Figure 27, described fixture comprises clamping drive division and the clip that is connected with described clamping drive division as shown in Figure 1.

As shown in Figure 1 to Figure 27, described fixture comprise gripper cylinder 421, with the hinged clamping swing arm 422 of described gripper cylinder 421, described clamping swing arm 422 is connected with the clamping driving gear, described clamping driving gear is connected with the first jig arm 423, described clamping driving gear is engaged with the clamping driven gear, described clamping driven gear is connected with the second jig arm that matches with described the first jig arm 423, wherein, describedly states under the first jig arm 423 and the second jig arm clamping and forms clip.

To Figure 27, described machinery folder 42 has four and corresponding one by one with described power taking core bundle station 401, cover box hat station 402, Quality Detection station 403 and unloading station 404 at least as shown in Figure 1.

To Figure 27, described machinery folder 42 distributes around the circumferential interval of described index dial 41 90 degree as shown in Figure 1.

To Figure 27, described cover box hat station 402 is provided with the location and cranks arm 44 as shown in Figure 1.

To Figure 27, described cover box hat station 402 is provided with the sub-cylinder 451 of gear bundle as shown in Figure 1, and described gear bundle cylinder 451 is connected with the sub-backgauge pin 452 of bundle.

To Figure 27, described Quality Detection station 403 is provided with short-circuit detecting device as shown in Figure 1.

As shown in Figure 1 to Figure 27, described sheath body, shedding mechanism 4 comprise index dial positioning cylinder 431 and be connected the index dial alignment pin 432 that index dial positioning cylinder 431 connects, and described index dial 41 is provided with the index dial location hole 412 that matches with described index dial alignment pin 432.

To Figure 27, described receiving mechanism 5 comprises rewinding bearing 51 as shown in Figure 1, and described rewinding bearing 15 is provided with rewinding guide rail 52, and described rewinding bearing 51 is provided with box hat blanking seat 531, and described box hat blanking seat 531 is connected with described rewinding guide rail 52.

To Figure 27, described rewinding bearing 51 is provided with X-axis pusher cylinder 532 as shown in Figure 1, and described X-axis pusher cylinder 532 is connected with X-axis and falls scraping wings 537, and described X-axis scraping wings 537 is arranged in described box hat blanking seat 531.

To Figure 27, described box hat blanking seat 531 is communicated with the pendulum material mould 533 that box hat 205 is arranged in a row as shown in Figure 1.

As shown in Figure 1 to Figure 27, described rewinding bearing 51 is provided with rewinding demixing plate 535, described X-axis pusher cylinder 532, box hat blanking seat 531, pendulum material mould 533 are arranged on described rewinding demixing plate 535, described pendulum material mould 533 is connected with the first Y-axis feed mechanism, and described the first Y-axis feed mechanism is arranged on described rewinding demixing plate 535.

As shown in Figure 1 to Figure 27, described the first Y-axis feed mechanism comprises the first Y-axis pusher cylinder 534 and the first Y-axis guide rail 536, described pendulum material mould 533 is arranged on described the first Y-axis guide rail 536, and described the first Y-axis pusher cylinder 534 is connected with described pendulum material mould 533.

as shown in Figure 1 to Figure 27, described rewinding bearing 51 is provided with the second Y-axis feed mechanism, described the second Y-axis feed mechanism is connected with pendulum magazine 544, described rewinding demixing plate 535 is provided with blanking guide groove 5351, described pendulum magazine 544 is arranged under described rewinding demixing plate 535, after being booked box hat 205 in pendulum material mould 533, can promote pendulum material mould 533 by the first Y-axis pusher cylinder 534, just the box hat 205 that is arranged in a row is in blanking guide groove 5351 falls into pendulum magazine 544, control pendulum magazine 544 slow asterns units by the second Y-axis drive division 541, so circulation, occupy box hat 205 will put magazine 544.

As shown in Figure 1 to Figure 27, described the second Y-axis feed mechanism comprises the second Y-axis drive division 541, the second Y-axis screw mandrel 542 and the second Y-axis guide rail 543 that are connected with described the second Y-axis drive division 541, described pendulum magazine 544 is connected with described the second Y-axis screw mandrel 542 by the second Y-axis feed screw nut, and described pendulum magazine 544 is arranged on described the second Y-axis guide rail 543.

To Figure 27, described the second Y-axis drive division 541 comprises the second Y-axis drive motors and the second Y-axis tape handler that is connected with described the second Y-axis drive motors as shown in Figure 1.

To Figure 27, described rewinding bearing 51 is provided with rewinding demixing plate lifting drive division as shown in Figure 1, and described rewinding demixing plate lifting drive division is connected with described rewinding demixing plate 535.

To Figure 27, rewinding demixing plate lifting drive division is rewinding demixing plate lift cylinder 55 as shown in Figure 1.

A kind of ni-mh cylindrical battery full automatic winding all-in-one that the utility model provides, be used for professional production ni-mh cylindrical battery, integrated coiling, enter shell, pendulum and expect high efficiency, the low energy consumption in one, the production equipment of environmental protection, equipment operating is easy, stable performance, the plurality of advantages such as easy to maintenance.

Above content is in conjunction with concrete preferred implementation further detailed description of the utility model, can not assert that concrete enforcement of the present utility model is confined to these explanations.For the utility model person of an ordinary skill in the technical field, without departing from the concept of the premise utility, can also make some simple deduction or replace, all should be considered as belonging to protection range of the present utility model.

Claims (10)

1. the winding mechanism of a ni-mh cylindrical battery full automatic winding all-in-one, it is characterized in that: comprise the first station coiling drive division, the second station coiling drive division, interchangeable the first station volume pin and the second station volume pin, described the first station coiling drive division is connected with described the first station volume pin, described the second station coiling drive division is connected with described the second station volume pin, is equipped with the U-shaped slot that plugs for upper strata electric core membrane paper, lower floor's electric core membrane paper on described the first station volume pin and the second station volume pin.

2. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 1, it is characterized in that: described the first station coiling drive division comprises the first station coiling motor, is connected and the first station coiling gear with described the first station coiling motor, and described the first station volume pin is connected by the first station coiling rotating shaft with described the first station coiling gear.

3. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 2 is characterized in that: described the first station volume pin is connected with the first station volume pin retraction cylinder.

4. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 1, it is characterized in that: described the second station coiling drive division comprises the second station coiling motor, is connected and the second station coiling gear with described the second station coiling motor, and described the second station volume pin is connected by the second station coiling rotating shaft with described the second station coiling gear.

5. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 4 is characterized in that: described the second station volume pin is connected with the second station volume pin retraction cylinder and the second station volume pin stretches out cylinder.

6. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 1, it is characterized in that: described winding mechanism also comprises coiling support column and station inversion mechanism, described coiling support column is connected with supporting bracket, rotating disk has been rotatably connected on described supporting bracket, described the first station volume pin and the second station volume pin all are arranged on described rotating disk, and described rotating disk is connected with described station inversion mechanism.

7. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 6, it is characterized in that: described station inversion mechanism comprises station transposition motor, the first transposition gear that is connected with described station transposition motor and the second transposition gear that is meshed with described the first transposition gear, described the second transposition gear is connected with described rotating disk, described the second transposition gear is provided with the transposition location hole, described supporting bracket is provided with the transposition positioning cylinder, and described transposition positioning cylinder is connected with the transposition alignment pin that matches with described transposition location hole.

8. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 1, it is characterized in that: described winding mechanism also comprises the post rod mechanism that matches with described the second station volume pin, described post rod mechanism comprises the push rod support, described push rod support is provided with push rod rotary cylinder and push rod telescopic cylinder, described push rod telescopic cylinder is connected with extension sleeve, be arranged with the push rod rotating shaft in described extension sleeve, described push rod rotating shaft is provided with sprocket wheel, be wound with chain on described sprocket wheel, one end of described chain is connected with described push rod rotary cylinder, the other end of described chain is connected with spring, described spring is connected with described push rod support, described push rod rotating shaft is connected with the push rod swing arm, described push rod swing arm is connected with push rod.

9. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 8 is characterized in that: the end of the U-shaped slot of described push rod and described the second station volume pin connects.

10. the winding mechanism of ni-mh cylindrical battery full automatic winding all-in-one according to claim 8, it is characterized in that: the rotating shaft of described push rod rotating shaft and described rotating disk coincides, and the distance of the rotating shaft of described rotating disk and described the second station volume pin equals the distance of described push rod and described push rod rotating shaft.

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