CN212830952U - Deflection driving device, deflection type sorting device and logistics sorting system - Google Patents

Abstract

The utility model discloses a deflection drive arrangement, deflection formula sorting device and commodity circulation letter sorting system, wherein the drive arrangement that deflects includes two at least parallel driven racks, many driven rack connects as an organic whole and can whole sharp translation, every driven rack is parallel with a set of axis and rather than extending direction vertically driven gear engagement, the drive arrangement of its translation of integral connection drive that driven rack constitutes. The structure of the synchronous belt and the rotating belt wheel is replaced by a gear and rack transmission mode, a plurality of tensioning wheels are not needed, the structure is simpler, and the assembly is easier; meanwhile, the rack is more stably connected with a transmission structure of the gear, the slipping condition cannot occur, in addition, the service life of the rack is longer than that of a synchronous belt, the reliability is higher, and the deflection effectiveness is guaranteed.

Description

Deflection driving device, deflection type sorting device and logistics sorting system

Technical Field

The utility model belongs to the technical field of logistics equipment and specifically relates to drive arrangement, the formula sorting device that deflects and commodity circulation letter sorting system deflect.

Background

The goods reversing mode in the modern automatic intelligent sorting system mainly comprises a swing arm type, a turning plate type, a rotating disc type, a pushing head type, a sliding block type, a deflection type and the like.

Deflection belt type sorting, such as the belt type sorting disclosed in application No. 201910207235.0, in which two belt sorting units are disposed on one deflection seat, although this structure is advantageous for reducing the number of deflection seats, in this structure, a plurality of tension pulleys need to be disposed to ensure the tension of the belt by driving the rotation pulley on the rotation of each deflection seat through the synchronous belt, which increases the complexity of the structure, requires a plurality of processes for assembly, and increases the difficulty of the layout of the synchronous belt. In addition, the synchronous belt is adopted for driving, so that the belt has the problem of slipping, the belt is relatively easy to damage and break, the service life is long, and the stability is poor.

In addition, the size of the rotating pulleys on each deflector seat needs to be made larger, which is not beneficial to reducing the dead weight.

The drive of belt feeder is through the power shaft of circular area connection transmission shaft and belt feeder, but because the power shaft is fixed at the eccentric seat and along with the eccentric seat ground of rotating, consequently the circular area need twist reverse the deformation after the gyro wheel deflects, and the circular area twists reverse the back and can't continue to transmit the torsion, this just causes the gyro wheel and can't continue to be driven the rotation by circular area after the rotation along with the eccentric seat, just also can't realize the transport of article, and this kind of design is obviously unreasonable.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a deflection drive arrangement, formula sorting device and commodity circulation letter sorting system deflect in order to solve the above-mentioned problem that exists among the prior art.

The purpose of the utility model is realized through the following technical scheme:

the deflection driving device comprises at least two parallel driven racks, a plurality of driven racks are connected into a whole and can integrally linearly translate, each driven rack is meshed with a group of driven gears which are parallel to the axis and vertical to the extending direction of the driven rack, and the driven racks are integrally connected with a driving device for driving the driven racks to translate.

Preferably, in the yaw driving device, one of the driven racks is directly or indirectly connected to a gear for driving the driven rack to translate, and an axis of the gear is parallel to an axis of the driven gear and connected to a rotary power source for driving the driven gear to rotate around the axis.

Preferably, in the deflection driving device, the gear is engaged with a rack, and the rack is parallel to the driven rack and is integrally connected with all the driven racks through a connecting plate perpendicular to the rack.

Preferably, in the deflection driving device,

when the driven rack is odd, the rack corresponds to the driven rack in the middle position;

when the driven rack is an even number, the driven racks are symmetrically arranged on two sides of the rack.

The deflection type sorting device comprises a rack, a group of sorting units arranged on the rack in a rotatable mode, and any deflection driving device for driving all the sorting units to rotate.

Preferably, in the deflection type sorting device, each sorting unit comprises a deflection seat, at least one rotating roller is horizontally arranged on the deflection seat, the height of the working surface of the rotating roller is higher than that of the deflection seat,

when the number of the rotating rollers is 1, the rotating rollers are electric rollers;

when the number of the rotary rollers is more than or equal to 2 and the rotary rollers are parallel, one of the rotary rollers is an electric roller and can drive other rotary rollers; or each of the rotating rollers is a motorized roller; or all the rotating rollers are directly or indirectly driven by friction through a driving roller which is parallel to the axis of the rotating rollers, driven by a power source and positioned on the deflection seat; or the part of the rotary rollers is a motorized roller, and the other parts are directly or indirectly driven by friction through driving rollers which are parallel to the axes of the rollers and driven by a power source.

Preferably, in the deflection type sorting device, the deflection base at least comprises an automatic rotation shaft and a flat plate coaxially arranged thereon, and a routing channel coaxial with the automatic rotation shaft is formed on the flat plate and the automatic rotation shaft.

Preferably, in the deflecting sorting device, the deflecting base is fixed to an upper rotating body of a support bearing, and a rotation shaft of the deflecting base is inserted into a central hole of the support bearing.

Preferably, in the deflection type sorting device, when the rotating rollers are two and symmetrical, the rotating rollers are driven by the driving roller in friction connection with the rotating rollers;

when the roller is three or four, the driving roller drives the rollers through two driving rollers in friction connection with the driving roller.

Preferably, in the deflection type sorting device, the driving roller directly drives the rotating roller, and the driving roller is in friction connection with the rotating roller through a self-adjusting device;

or the driving roller drives the rotating roller through a driving roller, and the driving roller is in friction connection with the driving roller through a self-adjusting device and/or the driving roller is in friction connection with the rotating roller through a self-adjusting device.

Preferably, in the deflecting type sorting apparatus, a buffer roller driven by a driving source is provided on at least one side of the frame, which is to be deflected by the sorting unit.

The logistics sorting system comprises any one of the deflection sorting devices, and at least one side of each deflection sorting device is provided with a switching device.

The utility model discloses technical scheme's advantage mainly embodies:

the structure of the synchronous belt and the rotating belt wheel is replaced by a gear and rack transmission mode, a plurality of tensioning wheels are not needed, the structure is simpler, and the assembly is easier; meanwhile, the rack is more stably connected with a transmission structure of the gear, the slipping condition cannot occur, in addition, the service life of the rack is longer than that of a synchronous belt, the reliability is higher, and the deflection effectiveness is guaranteed.

The rotary power source of this scheme set up the position and can guarantee effectively that its power is even to be applied to each on the driven rack to guarantee the synchronism of each position removal, thereby avoid local atress inequality to cause local card to end and influence overall structure translation, improved deflection drive's smooth and easy nature.

This scheme is through the power integration with the rotation of drive change roller on the swivel seat that inclines, has avoided the rotation of swivel seat and the problem that conventional O takes the gyro wheel drive structure to interfere mutually effectively to, can change the quantity of roller according to the difference, nimble adjustment driven mode, its drive mode is simple, easily realizes, uses in a flexible way, and stability is good.

This scheme sets up a set of commentaries on classics roller through making on the transposition seat partially, can reduce transposition seat's quantity partially effectively, simplifies overall structure, reduces equipment dead weight, simultaneously, adopts friction driven mode to realize the drive of a plurality of commentaries on classics rollers, and its drive mode is simple, easily realizes, and does not have the interference with the deflection of changeing the roller, and stability is good.

The mode of arranging of a plurality of letter sorting units of this scheme can make the clearance between the transport face reduce as far as possible, fills the clearance region through universal ball or universal wheel simultaneously, can greatly reduce the probability of card material, guarantees the validity of letter sorting.

Every row of letter sorting unit of this scheme is located a support plate, can be effectively with whole letter sorting unit's gravity disperses, reduces the load to single support plate, avoids the risk that the support plate warp, improves the security.

The deflection seat of the scheme is provided with the wiring channel, so that favorable conditions are created for wiring of the electric roller, the assembly difficulty is reduced, the outward leakage of a circuit is avoided, the interference of deflection of the deflection seat on the circuit is reduced, and the circuit connection safety and the overall attractiveness are improved.

The rotating structure of the eccentric seat can effectively protect the bearing and reduce the risk of bearing damage.

The roller of this scheme can adopt different drive modes to drive according to different quantity needs, and the structure is nimble, and only needs a power supply can effectively realize the drive of whole roller.

The driving roller and the driving roller of the scheme adopt a self-adjusting structure to effectively ensure the contact stability between different rollers, thereby ensuring the transmission reliability between the rollers and improving the effective conveying.

Drawings

Fig. 1 is a front view of the sorting apparatus of the present invention (a part of the frame structure is hidden in the figure);

fig. 2 is a cross-sectional view of the sorting apparatus of the present invention;

fig. 3 is a top view of the sorting apparatus of the present invention;

fig. 4 is a bottom view of the sorting apparatus of the present invention;

fig. 5 is a schematic view of a sorting unit of the sorting apparatus of the present invention;

FIG. 6 is an enlarged view of area A of FIG. 2;

FIG. 7 is a cross-sectional view of only one rotating roller on the eccentric rotary table of the sorting device according to the present invention;

FIG. 8 is a top view of only one rotating roller on the eccentric rotary table of the sorting device according to the present invention;

fig. 9 is a top view of the sorting unit of the sorting apparatus of the present invention;

FIG. 10 is a schematic view of the drive wheel of the present invention disposed on the self-adjusting device;

FIG. 11 is a schematic view of the driving wheel and the driving wheel of the present invention disposed on the self-adjusting device;

fig. 12 is a plan view of the yaw drive apparatus of the present invention;

fig. 13 is a front view of the yaw drive of the present invention;

fig. 14 is a front view of a second embodiment of the yaw drive of the present invention;

fig. 15 is a plan view of a second embodiment of the yaw drive apparatus of the present invention.

Detailed Description

Objects, advantages and features of the present invention will be illustrated and explained by the following non-limiting description of preferred embodiments. These embodiments are merely exemplary embodiments for applying the technical solutions of the present invention, and all technical solutions formed by adopting equivalent substitutions or equivalent transformations fall within the scope of the present invention.

In the description of the embodiments, it should be noted that the terms "center", "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the embodiment, the operator is used as a reference, and the direction close to the operator is a proximal end, and the direction away from the operator is a distal end.

The deflecting sorting apparatus of the present invention is described with reference to the accompanying drawings, as shown in fig. 1 and fig. 2, which includes a frame 1000, wherein the frame 1000 includes a support leg 1100, a baffle 1200 and a top plate 1300. The supporting legs 1100 are four and distributed in a quadrilateral shape, and of course, the number of the supporting legs 1100 may be more.

As shown in fig. 1, each of the support legs 1100 may include a vertical column 1110 and a leg base 1120, the vertical column 1110 is disposed on the leg base 1120 in a height-adjustable manner, that is, waist-shaped holes 1121 are formed in the leg base 1120 and distributed along a longitudinal direction, a connection hole (not shown) corresponding to the waist-shaped hole 1121 is formed in the vertical column 1110, and the leg base 1120 and the vertical column 1110 may be connected to each other to fix the leg base 1120 and the vertical column 1110 by a bolt 1130 passing through the waist-shaped hole 1121 and the connection hole and then connecting a nut. The height of the pillar 1110 can be adjusted by adjusting the position of the connecting hole corresponding to the kidney-shaped hole. Of course, in other embodiments, the connection hole of the upright 1110 may also be a screw hole, and the bolt is screwed into the screw hole to connect the upright and the foot seat 1120.

As shown in fig. 1, the enclosure 1200 is integrally formed as a square sleeve body, which is erected on four of the supporting legs 1100, the top plate 1300 is square, which is fixed on the top of the enclosure 1200 and covers the upper opening of the enclosure 1200, as shown in fig. 3, a set of avoiding holes 1310 are formed on the top plate 1300 for installing the sorting units 2000, and the distribution of the avoiding holes 1310 is designed according to the distribution of the sorting units 2000.

As shown in fig. 1 and 2, each sorting unit 2000 has a structure capable of conveying articles thereon and is rotatable about a longitudinal axis X of its deflecting seat 100, and each sorting unit 2000 is connected to a deflecting drive device 3000 for driving the rotating about the longitudinal axis X. In operation, articles may be transported in a certain direction as they pass through the sorting unit 2000, and when the sorting unit 2000 is swung, the articles may continue to move in their initial direction of movement; when sorting unit 2000 deflects, the direction of movement of the articles as they pass through sorting unit 2000 is reversed to the direction to which sorting unit 2000 deflects.

In order to effectively achieve article diversion, as shown in fig. 3, the sorting units 2000 are arranged in a plurality of rows or columns, specifically, they are arranged in five rows, and each even-numbered row of sorting units 2200 is the same in number and one less than each odd-numbered row of sorting units 2100, i.e., each odd-numbered row has five sorting units 2100 and each even-numbered row has four sorting units 2200.

In addition, as shown in fig. 3, in order to reduce the gap between the sorting units 2000 as much as possible to ensure the sorting stability and avoid the jamming, each sorting unit 2100, 2200 of two adjacent rows is staggered and arranged closely, the sorting units 2100 of odd rows are in one-to-one correspondence, and the sorting units 2200 of even rows are in one-to-one correspondence. That is, each of the other sorting units is located between two sorting units of its adjacent row except for each odd-numbered row of sorting units 2100 located at both ends, and the rotation axes of the three sorting units are distributed in an equilateral triangle.

At this time, as shown in fig. 3, both ends of the even-numbered sorting units 2200 may be formed with a certain gap, which increases the risk of the jamming, and therefore, in a preferred embodiment, a set of supporting universal wheels or universal balls 4000, preferably a set of bull's eye universal balls, the tops of which are flush with the conveying surface of the sorting units 2200, are respectively provided at both ends of each even-numbered sorting unit 2200.

Generally, all the sorting units 2000 are rotatably disposed on a plate having an area close to the area enclosed by the enclosure 1200, but since the sorting units 2000 have a large weight, when an article passes through the sorting units 2000, the plate is subjected to an excessive load, and thus the plate is easily deformed, particularly, the plate is recessed toward the middle portion, after a long time use, which affects the position accuracy of the sorting units 2000. In a preferred embodiment, as shown in fig. 4, each row of sorting units 2000 is rotatably disposed on a carrier 1400 on the rack 1000, five rows of sorting units 200 are distributed on five carriers 1400, and two ends of each carrier 1400 are fixed on the opposite panels of the enclosure 1200.

As shown in fig. 5 and fig. 6, each sorting unit 2000 includes a biasing seat 100, the biasing seat 100 is rotatably disposed on the carrier 1400, and mainly used for providing a mounting space and a support for a structure thereon, and includes a rotation shaft 110, an axis of the rotation shaft 110 is a longitudinal axis X of the biasing seat 100, is perpendicular to the carrier 1400, and is fixed in an inner hole of a bearing 1500 on the carrier 1400, and an axis of the bearing 1500 is perpendicular to the carrier 1400, so that the biasing seat 100 can rotate relative to the carrier 1400.

In the above structure, since the eccentric base 100 and the structure thereon have a certain weight, and these weights are applied to the bearings (the bearings in which the inner and outer races rotate relative to each other) for rotating the eccentric base 100, the bearings are easily damaged. Then, as shown in fig. 6, the bearing 1500 is fixed in a sleeve 1610 of a bearing seat 1600, the sleeve 1610 vertically penetrates the carrier 1400 and is provided with a connecting plate 1620 at its outer periphery, the connecting plate 1620 is connected to the carrier 1400, a bearing 1700 is further provided at the top of the sleeve 1610, and the eccentric base 100 is provided on the upper rotating body 1710 of the bearing 1700. By adopting the structure, the gravity of the eccentric seat 100 and the structure thereon is mainly transmitted to the carrier plate 1400 by the bearing seat 1600, so that the bearing 1500 does not need to bear the gravity again or bear the gravity to be greatly reduced, thereby protecting the bearing 1500.

However, in another embodiment, the bearing 1500 is not necessary, as shown in fig. 7, that is, the eccentric base 100 may be directly coaxially fixed on the supporting bearing 1700, and the rotation shaft 110 thereof passes through the supporting bearing 1700, the supporting bearing 1700 is fixed on a bearing housing 1800 on the carrier plate, and a mounting groove for mounting the supporting bearing 1700 is formed on the bearing housing 1800 coaxially with the supporting bearing 1700.

As shown in fig. 5, a flat plate 120 is coaxially disposed on the rotation shaft 110, the flat plate 120 is circular or square, but may have other feasible shapes, preferably, a square is taken as an example, the four corners of the flat plate are provided with pillars 130, the pillars 130 are provided with mounting discs 140, the outer profile of the mounting discs 140 is approximately circular, a set of rotation rollers 200 with parallel axes and equal height is flatly disposed on the mounting discs 140, the height of a conveying surface 300 formed by the working surfaces of the set of rotation rollers 200 is slightly higher than the top surface of the eccentric seat 100 (i.e., the upper surface of the below-described cover disk 150) and the top plate 1300, the rotation rollers 200 may be integrally and rotatably disposed on the mounting discs 140, or shafts at two ends of the rotation rollers 200 are fixed on the mounting discs 140, and the rollers rotate relative to the shafts. Meanwhile, a cover circular plate 150 is disposed on the mounting plate 140, the height of the top surface of the cover circular plate 150 corresponds to the height of the top surface of the top plate 1300, and a rectangular hole 131 for each of the rollers 200 is formed in the cover circular plate 150.

Of course, in another embodiment, the plate 120 may not be provided with the mounting plate 140, the roller may not be provided on the mounting plate 140, the roller 200 is mounted on the channel on the plate 120, in this case, the roller body of the roller 200 may rotate relative to the shaft fixed to the channel 180, and the pillar 130 is directly provided with the covering circular plate 150.

When the conveying device works, articles on the rotating rollers 200 can be conveyed through the same-direction rotation of the rotating rollers 200, and when the rotating rollers 200 rotate horizontally, the articles passing through the rotating rollers can be turned, so that sorting is realized.

The number and size of the rollers 200 on each deflector base 100 can be designed according to different requirements, for example, when a plurality of rollers are disposed on one deflector base 100, the rollers 200 can be two relatively short and symmetrical rollers; or a long roller and two short rollers positioned in the middle of two sides of the long roller; or two symmetrical long rollers 210 and two short rollers 220 located at the middle positions of both sides thereof; of course, more short and long rolls are possible. Further alternatively, when two long rollers are mounted on the mounting plate 140, a certain space may exist in the area on both sides of the long rollers, and a universal ball may be provided in the space to fill the gap.

In other possible embodiments, as shown in fig. 8, only one roller 200 may be mounted on each of the deflector bases 100, in which case, the size of the whole deflector base 100 may be as small as possible, and the structure may be simplified, that is, the structure without the mounting plate 140 may be adopted, and the roller may be directly mounted by using a channel steel. In addition, when two short rollers 200 are mounted on each deflector base, the deflector base 100 having such a simplified structure can be used. However, as the structure of the deflector base 100 is simplified and the size is reduced, the number of the sorting units 2000 in the deflector sorting apparatus may be larger, for example, as shown in fig. 8, the sorting units 2000 are 7 rows and 7 columns, and in this case, two rows of the sorting units 2000 may be located on one carrier plate 1400.

In a preferred embodiment, as shown in fig. 9, two long rollers 210 with equal length and symmetry and two short rollers 220 with equal length and symmetry distributed on two sides of the long roller 210 are disposed on each of the mounting plates 140, the two short rollers 220 are located in a middle region of the long roller 210, and the four rotating rollers are disposed at equal intervals.

The roller 200 can be driven in various feasible manners, for example, when the number of the roller is 1, preferably, the roller is an electric roller, and at this time, the structure of the eccentric seat can be simplified, that is, only two channel steels for erecting the roller and covering circular plates fixed on the channel steels and the pillars need to be arranged on the flat plate.

When the number of the rotating rollers 200 is greater than or equal to 2, in an embodiment, one of the rotating rollers 200 is an electric roller, and the other rotating rollers 200 may be disposed on the mounting plate, and the electric roller is connected to and drives the other rotating rollers to rotate synchronously through a transmission mechanism, that is, the electric roller may realize the rotation of the other rollers through a transmission structure of an existing synchronous belt, a synchronous wheel or a chain wheel and a chain, and at this time, the plurality of rotating rollers 200 have the same length and have two parallel and level ends. Here, the specific structure of the motorized roller is a known technology, and is not a protection point of the present solution, and details are not described here.

In another embodiment, each of the rotating rollers 200 is a motorized roller.

In yet another embodiment, some of the rollers 200 are motorized rollers and others are driven directly or indirectly by drive rollers 400 parallel to their axes and driven by a power source. For example, when the number of the rotary rollers 200 is three, two rotary rollers 200 may be a set and rotatably mounted on the mounting plate, and they are directly or indirectly driven by one driving roller 400; another roller 200 may be a motorized roller 200.

In yet another possible embodiment, as shown in fig. 5, all the rollers 200 are arranged on the mounting plate and are driven directly or indirectly by a driving roller 400 parallel to its axis and driven by a power source. When the direct drive is performed, the roller surface of the driving roller 400 is in contact with the roller surface of the rotating roller 200, and when the driving roller 400 rotates, the rotating roller 200 rotates synchronously with the driving roller 400 under the action of friction force. When the indirect driving is adopted, the driving roller 400 drives the rotating roller 200 to rotate through the driving roller 500 which is in friction connection with the driving roller.

For example, when the number of the rollers 200 is 2, the driving roller 400 is located between the two rollers 200 and is in frictional contact with both of the rollers 200.

As shown in fig. 5, when the number of the rollers 200 is three or four, two adjacent rollers 200 may be in one set, and the remaining one or two rollers may be in one set, one set of the rollers 200 is in frictional contact with a driving roller 500, and both driving rollers 500 are in frictional contact with the driving roller 200. When the rotary rollers 200 are four, the rotary rollers 200, the driving rollers 500 and the driving rollers 400 are integrally distributed in an inverted triangle, so that the driving of the plurality of rotary rollers 200 can be realized by one power source.

As shown in fig. 5, the driving roller 400 and the driving roller 500 are mounted on the supporting seat 160 or the channel steel of the plate 120.

Since the continuous friction between the rotary roller 200 and the driving roller 500 and between the driving roller 500 and the driving roller 400 is required, the stability of the contact therebetween is relatively lowered due to the friction loss after a certain period of use, which affects the reliability of driving.

Therefore, in a preferred embodiment, it is desirable to form a stable frictional connection therebetween, and as shown in fig. 10, when the driving roller 400 directly drives the rotating roller 200, the driving roller 400 is self-adjusting frictionally connected to the rotating roller 200 by a self-adjusting device 600. Specifically, two ends of the driving roller 400 are respectively disposed on a lifting seat 610 on the flat plate 120, the lifting seat 610 is slidably disposed on two guide rails 620 which are disposed on two sides of the lifting seat and perpendicular to the flat plate, and a spring 630 which is in a compressed state in a normal state is further disposed at the bottom of the lifting seat 610, at this time, a reaction force of the spring 630 can provide a lifting force to the lifting seat 610, so that the driving roller 400 thereon can be continuously attached to the rotating roller 200.

When the driving roller 400 drives the rotating roller 200 through the driving roller 500, the driving roller 400 and the driving roller 500 are in self-adjusting friction connection and/or the driving roller 500 and the rotating roller are in self-adjusting friction connection. That is, as shown in fig. 11, the driving roller 400 can achieve its continuous effective engagement with the driving roller 500 by the adjustment means having the same structure as the above-described self-adjustment means 600. Meanwhile, the driving roller 500 also adopts an adjusting device with the same structure as the self-adjusting device 600 to realize the self-adjusting friction connection with the rotating roller 200.

Also, a power source for driving the driving roller 400 may be integrated in the driving roller 400 or provided outside thereof. For example, when the driving roller 400 may be a motorized roller, a power source is integrated into the driving roller 400. When the driving roller 400 is driven by an external power source, two ends of the driving roller are rotatably disposed on the supporting base, and one end of the driving roller is connected to a motor (not shown) disposed on the biasing base 100, wherein the motor may be a reduction motor with a reduction structure, and the motor may also be a common motor, and is connected to the driving roller 400 through a gear transmission or other known transmission structure.

Whether the rotating roller is an electric roller or the driving roller is an electric roller, the rotating roller 200 and the driving roller 400 need to be powered and communicated with an upper computer through a circuit 700, and the rotating roller 200 and the driving roller 400 need to rotate along with the deflection seat 100, so that the circuit 700 is inevitably interfered by deflection action, and in order to reduce interference, as shown in fig. 7, a routing channel 170 coaxial with the rotating shaft 110 and the flat plate 120 is formed on the rotating shaft 110 and the flat plate 120, and the circuit can penetrate into the routing channel 170 from the bottom of the rotating shaft and penetrate out of the flat plate 120 so as to be connected to the rotating roller 200 or the driving roller 400 on the deflection seat 100, so that the rotation of the deflection seat does not generate interference on the circuit 700 any more, and the stability of wiring is ensured.

Each of said sorting units 2000 may be driven by a separate yaw drive 3000, for example by connecting a motor to the rotation shaft 110 of the yaw deck 100 of each sorting unit 2000, but this is obviously disadvantageous for reducing the cost of components and energy consumption, and therefore, more preferably, a plurality of said sorting units are driven by one said yaw drive 3000. For example, the deflection structure disclosed in the applicant's filed application No. 201910265828.2.

More specifically, the five-row sorting unit 2000 is driven by two yaw drives 3000, one yaw drive 3000 driving two rows of sorting units, and the other yaw drive 3000 driving three rows of sorting units.

As shown in fig. 12 and 13, the deflection driving device 3000 for driving the two rows of sorting units includes a fixed motor 3100, a motor shaft of the motor 3100 is perpendicular to the conveying surface 300, the motor shaft of the motor 3100 is fixedly connected to one end of a driving arm 3200, the other end of the driving arm 3200 is pivotally connected to a middle portion of a driving plate 3300, two ends of the driving plate 3300 are respectively fixed with a slat 3400 perpendicular and parallel to the driving plate, two slats 3400 extend in a horizontal direction and are connected to each other by a connecting rod 3500 perpendicular to the slats, so that the driving plate 3300, the slats 3400 and the connecting rod 3500 form a fixed driving frame. Two of the slats 3400 are pivotally connected to the plate 120 of the deflector of the sorting unit 2000 in a row, and a shaft 3600 connecting the slats 3400 and the plate 120 is formed near one side edge of the plate 120, and a hole 3410 corresponding to each shaft 3600 is formed in the slat 3400. When the automatic sorting machine works, the motor drives the driving arm 320 to rotate around the motor shaft, so that the transmission frame formed by the transmission plate, the lath 3400 and the connecting rod 3500 is driven to integrally rotate without deformation, and the lath 3400 drives the sorting unit 2000 connected with the lath 3400 to rotate around the axis of the rotating shaft to realize deflection.

The overall structure and the operating principle of the deflection driving device 3000 driving the three-row sorting unit 2000 are similar to the overall structure of the deflection driving device 3000 driving the two-row sorting unit 200, and the principle is the same, and the difference is that: the number of the slats 3400 is three and parallel, two adjacent slats are connected into an integral frame through a connecting rod, and each slat 3400 is pivotally connected with one row of the sorting units 2000.

Or in another embodiment, as shown in fig. 14 and 15, the deflecting driving device 3000 may drive all the sorting devices 2000 to deflect by one power source.

Specifically, the yaw driving apparatus 3000 includes a stationary driving motor 3001, a motor shaft of the driving motor 3001 is perpendicular to the conveying surface 300, the motor shaft of the driving motor 3001 is coaxially connected with a gear 3002, the gear 3002 is engaged with a rack 3003, the rack 3003 is connected with at least one connecting plate 3004 perpendicular to the rack 3003, preferably two connecting plates 3004, two connecting plates 3004 are connected with a set of driven racks 3005 parallel to the rack 3003 and arranged at equal intervals, and, the driven racks 3005 have a height difference from the racks 3003, each of the driven racks 3005 is slidably disposed on a guide rail 3006 parallel to them by a set of sliders 3008, the guide rails 3006 are fixed on the bottom of the carrier plate 1400, each of the driven racks 3005 is engaged with a row of driven gears 3007, and each of the driven gears 3007 is coaxially fixed on the rotation shaft 110 of the eccentric base 100.

Of course, in other embodiments, the rack 3003 is not required, and the gear 3002 may directly engage one of the plurality of driven racks 3005.

Alternatively, in another embodiment, instead of driving the plurality of driven racks by the driving device constituted by the motor 3001, the gear 3003, and the rack 3003, the entire plurality of driven racks may be driven by one device capable of generating linear movement, for example, the driving device may be an air cylinder, an oil cylinder, a linear motor, or the like, and the moving direction of the movable portion thereof is parallel to the extending direction of the driven racks.

Further, when the driven rack 3005 is odd, the rack 3003 corresponds to a driven rack 3005 at an intermediate position; when the driven rack 3005 is an even number, the driven rack 3005 is symmetrically disposed on both sides of the rack 3003, that is, the rack 3003 is always located in the middle region of the plurality of driven racks. In addition, when the eccentric base 100 is in a state of being swung, the linear distances from the two ends of the rack 3003 to the two ends of the driven rack 3005 are equal, and the gear 3002 is located at the middle of the rack 3003.

In operation, the driving motor 3001 drives the gear 3002 to rotate, and the gear 3002 drives the rack 3003 and the driven rack 3005 to reciprocate along the extending direction thereof, so as to drive the driven gears 3006 engaged therewith to rotate, and further drive the deflector base 100 connected to each driven gear 3006 to rotate.

The scheme further discloses a logistics sorting system (not shown in the figure), which comprises the deflection sorting devices in the embodiment, wherein the deflection sorting devices are arranged in a plurality of gaps, the logistics sorting system further comprises conveying lines connected between the two deflection sorting devices, such as a belt conveyor and a roller conveyor, at least one side of each deflection sorting device is provided with a switching device, the switching devices can be sorting grids and other conveying lines, and the logistics sorting system is specifically designed according to the requirements of different application scenes.

Taking the switching device as an example of a sorting cell, the two sides of each deflecting device are provided with sorting cells, in order to reduce the impact force of the material entering the sorting cells during deflecting and sorting, the two sides of the rack 1000 are provided with buffer rollers (not shown in the figure) driven by a driving source, the buffer rollers are positioned on the side parts of the rack 1000, which are connected with the sorting cells, the top height of the buffer rollers is equal to the top height of the rotating rollers 200, the buffer rollers are preferably electric rollers, and the roller surfaces of the buffer rollers are provided with an encapsulating layer, and the rotating speed of the buffer rollers can be lower than the rotating speed of the rotating rollers 200 of the sorting unit during operation, so that the reduction of the article translation impact force can be effectively realized, and the safety of article sorting is improved.

The utility model has a plurality of implementation modes, and all technical schemes formed by adopting equivalent transformation or equivalent transformation all fall within the protection scope of the utility model.

Claims (12)

1. A yaw drive, characterized by: including two at least parallel driven racks, many but driven rack connects as an organic whole and whole straight line translation, every driven rack is parallel with a set of axis and rather than the driven gear meshing of extending direction vertically, the drive arrangement of its translation of integral connection drive that driven rack constitutes.

2. The yaw-drive apparatus of claim 1, wherein: and the driven rack is directly or indirectly connected with a gear for driving the driven rack to translate, and the axis of the gear is parallel to the axis of the driven gear and is connected with a rotary power source for driving the driven gear to rotate around the axis.

3. The yaw-drive apparatus of claim 2, wherein: the gear is meshed with a rack, and the rack is parallel to the driven rack and is connected with all the driven racks into a whole through a connecting plate vertical to the rack.

4. The yaw-drive apparatus of claim 3, wherein:

when the driven rack is odd, the rack corresponds to the driven rack in the middle position;

when the driven rack is an even number, the driven racks are symmetrically arranged on two sides of the rack.

5. The deflection type sorting device comprises a rack and a group of sorting units which can be arranged on the rack in a rotation manner, and is characterized in that: the swing driving apparatus as claimed in any one of claims 1 to 4 further comprising a driving unit for driving all the sorting units to rotate.

6. The deflection sorting apparatus of claim 5, wherein: each sorting unit comprises a deflection seat, at least one rotating roller is horizontally arranged on the deflection seat, the height of the working surface of the rotating roller is higher than that of the deflection seat,

when the number of the rotating rollers is 1, the rotating rollers are electric rollers;

when the number of the rotary rollers is more than or equal to 2 and the rotary rollers are parallel, one of the rotary rollers is an electric roller and can drive other rotary rollers; or each of the rotating rollers is a motorized roller; or all the rotating rollers are directly or indirectly driven by friction through a driving roller which is parallel to the axis of the rotating rollers, driven by a power source and positioned on the deflection seat; or the part of the rotary rollers is a motorized roller, and the other parts are directly or indirectly driven by friction through driving rollers which are parallel to the axes of the rollers and driven by a power source.

7. The deflection sorting apparatus of claim 6, wherein: the deflection seat at least comprises an automatic rotating shaft and a flat plate coaxially arranged on the automatic rotating shaft, and a wiring channel coaxial with the automatic rotating shaft is formed on the flat plate and the automatic rotating shaft.

8. The deflection sorting apparatus of claim 6, wherein: the eccentric seat is fixed on the upper rotating body of the supporting bearing, and the rotating shaft of the eccentric seat is inserted in the central hole of the supporting bearing.

9. The deflection sorting apparatus of claim 6, wherein:

when the two rotating rollers are symmetrical, the two rotating rollers are driven by the driving roller in friction connection with the two rotating rollers;

when the roller is three or four, the driving roller drives the rollers through two driving rollers (500) in friction connection with the driving roller.

10. The deflected sorting device of claim 9, wherein:

the driving roller directly drives the rotating roller and is in friction connection with the rotating roller through a self-adjusting device;

or the driving roller drives the rotating roller through a driving roller, and the driving roller is in friction connection with the driving roller through a self-adjusting device and/or the driving roller is in friction connection with the rotating roller through a self-adjusting device.

11. Deflecting sorting device according to any one of claims 5-10, characterised in that: and a buffer roller driven by a driving source is arranged on at least one side of the rack, which is to be deviated by the sorting unit.

12. Logistics sorting system, its characterized in that: comprising a deflector-type sorting device according to any one of claims 5-11, which is provided with switching means on at least one side.

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