CN213893929U - Shuttle, goods shelves, goods letter sorting system and building - Google Patents

Abstract

The invention relates to a shuttle, a goods shelf, a goods sorting system and a building, wherein the shuttle comprises a frame, a traveling device and a switching device, the traveling device comprises a first traveling device capable of moving along a horizontal track and a second traveling device capable of moving along a vertical track, the traveling device is movably arranged on the frame so as to enable the shuttle to be in a first working state or a second working state through the switching device, in the first working state, the first traveling device moves to be capable of moving along the horizontal track, and the second traveling device moves to be capable of separating from the vertical track; in a second working state, the second walking device moves to move along the vertical track, and the first walking device moves to separate from the horizontal track. Therefore, the shuttle car provided by the disclosure can horizontally move and vertically move in the stereoscopic warehouse by depending on the self walking device under the control of the switching device, and the shuttle car can move on the shelf rails at different heights.

Description

Shuttle, goods shelves, goods letter sorting system and building

Technical Field

The disclosure relates to the technical field of logistics storage, in particular to a shuttle car, a goods shelf, a goods sorting system and a building.

Background

In recent years, with the rapid development of logistics storage, the shuttle car is widely applied as an intelligent robot device, can replace manpower to carry out a series of storage operations, efficiently sends goods to a designated goods shelf, greatly improves the operation efficiency and space utilization rate of a warehouse, and avoids the risk of manual high-altitude operation. A shuttle is usually provided with a running gear to be able to run along the rack rail.

In the related art, when the shuttle car needs to move on the rack rails (stereoscopic warehouse) at different heights, a lifting mechanism (e.g., a lifter) needs to be additionally added to lift the shuttle car onto the rack at the corresponding height, and then the shuttle car is controlled to travel along the rack rails. Alternatively, the rack rails can be designed to be deformable, so that the shuttle car can be turned from a horizontal movement to a vertical movement. However, in the scheme of adopting the elevator to cooperate with the shuttle car to move vertically, the space occupied by the elevator and the movement noise are large, and the height of the elevator of the stereoscopic warehouse is generally below 20m, so that the elevator cannot be suitable for high-rise residential quarters; in the scheme that the moving mechanism is arranged on the goods shelf rail to enable the goods shelf rail to be deformable, although the lifting machine is replaced, the reliability of the goods shelf is reduced due to too many moving mechanisms in the whole goods shelf, and meanwhile, the high-rise residential community cannot accept frequent maintenance work.

SUMMERY OF THE UTILITY MODEL

The purpose of the present disclosure is to provide a shuttle car, a goods shelf matched with the shuttle car, a goods sorting system configured with the shuttle car and the goods shelf, and a building configured with the goods sorting system, so as to improve the walking efficiency of the shuttle car on the track of the building such as a high-rise stereoscopic warehouse.

In order to achieve the above object, the present disclosure provides a shuttle vehicle including a vehicle frame, a traveling device movably mounted on the vehicle frame, and a switching device for controlling the traveling device, the traveling device including a first traveling device movable along a horizontal track and a second traveling device movable along a vertical track, so as to place the shuttle vehicle in a first operating state or a second operating state by the switching device,

in the first working state, the first walking device moves to be capable of moving along the horizontal track, and the second walking device moves to be capable of being separated from the vertical track;

in the second working state, the second walking device moves to be capable of moving along the vertical track, and the first walking device moves to be capable of being separated from the horizontal track.

Optionally, the first traveling devices are arranged on two opposite sides of the frame in the first direction, the switching device comprises a first switching device for controlling the first traveling device to move in a telescopic manner to approach or depart from the frame, the first switching device comprises a first driving piece and a telescopic mechanism connected between the first driving piece and the first traveling device, so that,

in the first working state, the first walking device extends to be in contact fit with the horizontal rail;

in the second operating state, the first running gear is retracted out of engagement with the horizontal rail.

Optionally, the first drive element has a first output shaft which is able to output a rotational movement, the telescopic mechanism is configured as a slider-crank mechanism comprising a crank structure connected to the first output shaft, a slider structure connected to the first running gear, and a connecting rod connected between the crank structure and the slider structure.

Optionally, the crank arrangement comprises a crank and a transmission assembly connected between the first drive member and the crank, the transmission assembly comprising:

the first belt wheel is sleeved on the first output shaft;

the crank is sleeved on a wheel shaft of the second belt wheel; and

and the first belt body is wound on the outer sides of the first belt wheel and the second belt wheel.

Optionally, the slider structure includes a linear bearing fixed on the frame and a shaft body matched with the linear bearing, one end of the shaft body is connected with the connecting rod, and the other end of the shaft body is connected with the first walking device.

Optionally, the crank structure includes a crank, a center of the crank in a length direction is in transmission connection with the first output shaft, and the first traveling devices on two sides of the frame are respectively connected to two ends of the crank through the respective slider structures and the connecting rod.

Optionally, first running gear is the walking wheel, the walking wheel includes the action wheel and sets up with dividing the action wheel both sides from the driving wheel, the action wheel with set up through first mounting panel scalable removal from the driving wheel on the frame, be fixed with on the first mounting panel and be used for the drive the first driving motor of action wheel.

Optionally, the second traveling devices are disposed on two opposite sides of the frame in the second direction, the switching device further includes a second switching device for controlling the second traveling device to move up and down, the second switching device includes a second driving element and a lifting mechanism connected between the second driving element and the second traveling device, so that,

in the first working state, the second walking device moves to be disengaged from the vertical track;

in the second working state, the second walking device moves to be in contact fit with the vertical rail.

Optionally, the second driving element has a second output shaft capable of outputting a rotational motion, the lifting mechanism includes a lead screw coaxially connected to the second output shaft and a nut sleeved on the lead screw, and the second traveling device is connected to the nut.

Optionally, the second switching device further comprises a transmission mechanism connected between the second driving member and the lifting mechanism, the transmission mechanism comprising:

the third belt wheel is sleeved on the second output shaft;

the wheel shaft of the fourth belt wheel is coaxially connected with the screw rod; and

and the second belt body is wound on the outer sides of the third belt wheel and the fourth belt wheel.

Optionally, the second belt body sequentially winds around the third belt wheel and the outer sides of the fourth belt wheels corresponding to the second running gear on the two sides of the frame.

Optionally, the transmission mechanism further includes a tension wheel disposed between the third pulley and the fourth pulley, and the tension wheel is movably disposed on the frame and is used for adjusting the tension of the second belt body.

Optionally, the second switching device further includes a guide mechanism for guiding the second traveling device in the up-and-down movement, the guide mechanism includes a linear rail fixed on the frame and a slider slidably connected to the linear rail, and the second traveling device is fixedly connected to the slider.

Optionally, the second traveling device includes a plurality of wheels arranged at intervals, the wheels are arranged on the frame through a second mounting plate in a manner of moving up and down, and a second driving motor for driving the wheels is fixed on the second mounting plate.

Optionally, the shuttle car further comprises a conveyor fixed above the frame, the conveyor being rotatable about a vertical axis.

Optionally, the conveying device is a belt conveying assembly, and the belt conveying assembly includes a conveying belt, conveying pulleys at two ends of the conveying belt, and a conveying driving motor for driving at least one of the conveying pulleys to rotate.

According to a second aspect of the present disclosure, there is provided a rack for cooperation with a shuttle according to the above, the rack comprising a horizontal rail for cooperation with the first running gear and a vertical rail for cooperation with the second running gear, the horizontal rail extending in a horizontal direction and the vertical rail extending in a vertical direction.

Optionally, the vertical rail includes a first rail and a second rail that are disposed opposite to each other, and the first rail and the second rail are respectively a rack extending in a vertical direction, and are configured to move in cooperation with a gear of the second traveling device.

Optionally, the rack further comprises an auxiliary rail extending in a vertical direction to be in contact engagement with the first running gear in the second operating state.

Optionally, a positioning device is disposed on the shelf, and is configured to perform positioning by triggering a position detection device mounted on the shuttle when the shuttle reaches a target position of the shelf.

According to a third aspect of the present disclosure, there is provided a cargo sorting system comprising a shuttle according to the above and a rack according to the above.

According to a fourth aspect of the present disclosure, there is provided a building comprising a building body and a cargo sorting system mounted on the building body, the cargo sorting system being according to the above.

Through the technical scheme, the shuttle car provided by the disclosure can utilize the horizontal motion of the first walking device or the vertical motion of the second walking device under the control of the switching device, so that the shuttle car can depend on the horizontal motion and the vertical motion of the self walking device in a stereoscopic warehouse, and the movement of the shuttle car on the shelf rails with different heights is realized.

Additional features and advantages of the disclosure will be set forth in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate embodiments of the disclosure and together with the description serve to explain the disclosure without limiting the disclosure. In the drawings:

FIG. 1 is a schematic structural view of an exemplary shuttle of the present disclosure;

FIG. 2 is a schematic diagram of an exemplary first conversion device of the present disclosure;

FIG. 3 is a schematic diagram of an exemplary second switching device according to the present disclosure;

FIG. 4 is a schematic illustration of an exemplary first road wheel of the present disclosure in an extended state;

FIG. 5 is a schematic illustration of an exemplary first road wheel of the present disclosure in a retracted state;

fig. 6 is a schematic structural view of an exemplary second road wheel of the present disclosure in an elevated state;

fig. 7 is a schematic structural view of an exemplary second road wheel of the present disclosure in a descending state;

FIG. 8 is a schematic illustration of an exemplary shuttle of the present disclosure in a first operating state;

FIG. 9 is a schematic illustration of an exemplary shuttle vehicle of the present disclosure during a transition from a first operating state to a second operating state;

FIG. 10 is a schematic illustration of an exemplary shuttle of the present disclosure in a second operating state;

FIG. 11 is a top plan view of an exemplary shuttle vehicle of the present disclosure in a second operating configuration;

FIG. 12 is a schematic view of an exemplary pallet according to the present disclosure;

fig. 13 is a schematic illustration of an exemplary shuttle car and rack mating configuration of the present disclosure.

Description of the reference numerals

100-vehicle frame, 110-first mounting plate, 111-first driving motor, 120-second mounting plate, 121-second driving motor, 200-walking device, 210-first walking device, 211-driving wheel, 212-driven wheel, 220-second walking device, 221-wheel body, 300-transmission device, 310-transmission belt, 400-first switching device, 410-first driving piece, 420-telescopic mechanism, 421-crank structure, 4211-crank, 4212-first belt wheel, 4213-second belt wheel, 4214-first belt body, 422-slide block structure, 4221-linear bearing, 4222-shaft body, 423-connecting rod, 500-second switching device, 510-second driving piece, 520-lifting mechanism, 521-screw rod, 522-nut, 530-transmission mechanism, 531-third belt wheel, 532-fourth belt wheel, 533-second belt body, 534-tensioning wheel, 540-guide mechanism, 541-linear rail, 542-sliding block, 10-shelf, 11-vertical rail, 101-first rail, 102-second rail and 20-shuttle car.

Detailed Description

The following detailed description of specific embodiments of the present disclosure is provided in connection with the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present disclosure, are given by way of illustration and explanation only, not limitation.

In the present disclosure, unless otherwise stated, the terms of orientation such as "upper", "lower", "top" and "bottom" are generally defined according to the normal use condition of the shuttle car, and refer to the direction of the drawing shown in fig. 1; "inner" and "outer" refer to the inner and outer contours of the respective components. Furthermore, the terms "first," "second," and the like, as used in this disclosure, are intended to distinguish one element from another, and not necessarily for order or importance. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated.

Referring to fig. 1, the disclosed embodiment provides a shuttle vehicle including a vehicle frame 100, a traveling device 200 movably installed on the vehicle frame 100, and a switching device for controlling the traveling device 200, and the traveling device 200 may include a first traveling device 210 movable along a horizontal rail and a second traveling device 220 movable along a vertical rail 11 to respectively implement horizontal movement and vertical movement of the shuttle vehicle on, for example, a shelf 10 by the first traveling device 210 and the second traveling device 220. The shuttle car can be in a first working state or a second working state through the switching device. In the first working state, the switching device moves the first walking device 210 to be capable of moving along the horizontal rail and moves the second walking device 220 to be capable of disengaging from the vertical rail 11; in the second operating state, the switching device moves the second traveling device 220 to be movable along the vertical rail 11 and moves the first traveling device 210 to be detachable from the horizontal rail. That is, the first operating state is a state in which the shuttle moves horizontally on the rack 10, and the second operating state is a state in which the shuttle moves vertically on the rack 10, and the corresponding horizontal rail may extend in the horizontal direction and the vertical rail 11 may extend in the vertical direction.

Through the technical scheme, the shuttle provided by the disclosure can horizontally move along the goods shelf 10 by using the first walking device 210 or vertically move along the goods shelf 10 by using the second walking device 220 under the control of the switching device, so that the shuttle can horizontally move and vertically move in a stereoscopic warehouse by using the self walking device 200, the walking efficiency of the shuttle on the track of buildings such as a high-rise stereoscopic warehouse is effectively improved, the shuttle can move on the goods shelf tracks at different heights, the goods shelf tracks can be deformed without additionally using a lifting mechanism or arranging a moving mechanism on the goods shelf, the shuttle can freely move and distribute goods in the stereoscopic goods shelf by using a simple fixed goods shelf, the space utilization rate of the goods shelf is greatly improved, the installation space is reduced, the reliability of the goods shelf is increased, the maintenance rate is reduced, and the shuttle can be suitable for logistics transportation of high-rise residential quarters, the problem of take-out, express delivery to home is solved.

According to some embodiments, referring to fig. 1, 2, 4, and 5, the vehicle frame 100 may be configured as a frame-type structure having two sides oppositely disposed in a first direction and two sides oppositely disposed in a second direction, which may be perpendicular to each other. The first traveling devices 210 may be disposed at opposite sides of the frame 100 in the first direction, and the second traveling devices 220 may be disposed at opposite sides of the frame 100 in the second direction, respectively, to increase stability when the shuttle travels. Wherein, the switching means may include a first switching means 400 for controlling the telescopic movement of the first running means 210 to achieve the contact or the disengagement thereof with the horizontal rail by the telescopic movement of the first running means 210. Specifically, as shown in fig. 2, the first switching device 400 may include a first driving member 410 and a telescoping mechanism 420 connected between a first output end of the first driving member 410 and the first traveling device 210, so that the telescoping mechanism 420 may be driven by the first driving member 410 and the first traveling device 210 is driven to move telescopically. Further, as shown in fig. 4 and 5, the first running gear 210 may be extended or retracted close to or away from the carriage 100, so that in the first working state, the first running gear 210 is extended to be engaged in contact with and movable along the horizontal rail; in the second operating condition, the first running gear 210 is retracted out of engagement with the horizontal rail to avoid interference with the vertical movement of the shuttle.

As an embodiment, referring to fig. 2, the first driving member 410 may have a first output shaft capable of outputting a rotational motion, i.e. the first output shaft is the above-mentioned first output end for outputting a torque, and the first driving member 410 may be a rotational driving device such as a motor. The telescopic mechanism 420 may be configured as a slider-crank mechanism, and the slider-crank mechanism may include a crank structure 421 connected to the first output shaft, a slider structure 422 connected to the first walking device 210, and a connecting rod 423 connected between the crank structure 421 and the slider structure 422, so that the crank structure 421 may be driven by the first output shaft to rotate, and then the connecting rod 423 and the slider structure 422 are driven to move, and finally, the first walking device 210 is telescopically moved. As another embodiment, the telescoping mechanism 420 may also be configured as a cam mechanism, which is not limited in this disclosure. Of course, the first driving member 410 may also have an output shaft capable of outputting linear motion, so that the first traveling device 210 may be driven to move telescopically by a linear mechanism such as a push rod or directly by the first driving member 410.

According to some embodiments, referring to fig. 2, the crank arrangement 421 described above may comprise a crank 4211 and a transmission assembly connected between the first driver 410 and the crank 4211 to make the required optimized change to the power of the first driver 410 by the transmission assembly. The transmission assembly may be a belt transmission assembly, and the belt transmission assembly may include a first belt pulley 4212, a second belt pulley 4213, and a first belt body 4214 wound around the first belt pulley 4212 and the second belt pulley 4213. The first belt pulley 4212 may be sleeved on the first output shaft or the wheel shaft of the first belt pulley 4212 may be coaxially connected with the first output shaft; the crank 4211 may be sleeved on the axle of the second pulley 4213. Thus, the first driving part 410 works to drive the first output shaft to rotate, the first output shaft drives the first pulley 4212 to rotate, the first pulley 4212 drives the second pulley 4213 to rotate through the first belt 4214, the second pulley 4213 drives the crank 4211 to rotate, and finally the first driving part 410 drives the crank 4211 to rotate synchronously. Here, it should be noted that the first pulley 4212 and its axle and the second pulley 4213 and its axle are all in fixed engagement, so that synchronous rotation can be realized. The belt transmission assembly has stable transmission and can eliminate vibration in the movement process, so that the stability of the telescopic movement of the first walking device 210 can be ensured. In other embodiments, the transmission assembly may also be, for example, a gear pair, and the disclosure is not limited thereto.

According to some embodiments, referring to fig. 2, the slider structure 422 may include a linear bearing 4221 fixed on the frame 100 and a shaft body 4222 engaged with the linear bearing 4221, i.e. the linear bearing 4221 is coaxially sleeved on the outer side of the shaft body 4222 and axially slidably engaged therewith. One end of the shaft 4222 may be connected to the connecting rod 423, and the other end of the shaft may be connected to the first walking device 210, so that the shaft 4222 may drive the first walking device 210 to move along the linear bearing 4221 in a telescopic manner under the driving of the connecting rod 423. The linear bearing 4221 and the shaft 4222 are matched to realize the telescopic movement of the first traveling device 210, and also can be used as a guide assembly to guide the telescopic movement of the first traveling device 210, so that accurate linear movement can be realized. In other embodiments, the sliding block structure 422 may also be a combination of a wire rail and a sliding block, the wire rail may be fixed on the frame 100, the sliding block may be slidably disposed on the wire rail, and the sliding block may be respectively connected to the connecting rod 423 and the first traveling device 210, so as to achieve the effects of extending and retracting movement and movement guiding of the first traveling device 210.

According to some embodiments, in order to ensure the motion synchronism of the first traveling devices 210 on both sides, the center of the crank 4211 in the length direction may be in transmission connection with the first output shaft, for example, the center of the crank 4211 in the length direction may be sleeved on the first output shaft, and the first traveling devices 210 on both sides of the frame 100 may be connected to both ends of the crank 4211 through the respective slider structures 422 and the connecting rod 423, so that a power device (the first driving member 410) can drive the first traveling devices 210 on both sides to synchronously extend and retract through two sets of slider-crank mechanisms. Further, in order to save space and facilitate assembly, referring to fig. 2, the center of the crank 4211 in the length direction may be sleeved on the axle of the second belt wheel 4213, so that the first traveling devices 210 on both sides may be driven to synchronously extend and retract by a set of transmission assembly.

Further, in embodiments provided by the present disclosure, referring to fig. 1 and 2, the first traveling device 210 may be a traveling wheel, i.e., a linear movement of the shuttle car along the horizontal track is achieved by rotation of the traveling wheel. The traveling wheels may include a driving wheel 211 and two driven wheels 212 respectively disposed at both sides of the driving wheel 211, the driving wheel 211 and the two driven wheels 212 may be telescopically and movably disposed on the frame 100 via the first mounting plate 110, for example, the shaft 4222 may be directly connected to the first mounting plate 110, so that the first traveling device 210 is telescopically moved by the telescopic movement of the first mounting plate 110. In this case, the shaft bodies 4222 and the linear bearings 4221 may also include a plurality of sets, a plurality of linear bearings 4221 may be disposed at intervals on the frame 100 and distributed at positions between the driving wheel 211 and the driven wheel 212, and a plurality of shaft bodies 4222 may also be connected to the connecting rod 423 through a connecting plate. Wherein, can be fixed with the first driving motor 111 that is used for driving the action wheel 211 on the first mounting panel 110 to make the work of first driving motor 111 drive action wheel 211 motion, action wheel 211 passes through first mounting panel 110 and drives two driven wheels 212 synchronous motion. This is disclosed does not limit to the quantity of walking wheel, through setting up a plurality of walking wheels to make every walking wheel correspond the different positions department that distributes at frame 100 uniformly, thereby can further guarantee the operating stability of shuttle during operation. In other embodiments, the first traveling device 210 may be configured as a moving device such as a crawler that is in contact with the horizontal rail, or may be configured as a moving device such as a magnetic levitation that is not in contact with the horizontal rail by an electromagnetic force.

According to some embodiments, referring to fig. 1, 3, 6 and 7, the switching means may further include a second switching means 500 for controlling the second traveling means 220 to move up and down to achieve contact or disengagement with the vertical rail 11 by the up and down movement of the second traveling means 220. Specifically, as shown in fig. 3, the second switching device 500 may include a second driving member 510 and a lifting mechanism 520 connected between a second output end of the second driving member 510 and the second traveling device 220, so that the lifting mechanism 520 may be driven by the second driving member 510 and the second traveling device 220 may be driven to move up and down. Further, as shown in fig. 6 and 7, the second traveling device 220 is provided on the carriage 100 movably up and down, so that in the first working state, the second traveling device 220 is raised out of engagement with the vertical rail 11 to avoid interference with the horizontal movement of the shuttle; in the second working state, the second traveling device 220 is lowered into contact engagement with the vertical rail 11 and can move along the vertical rail 11.

As an embodiment, referring to fig. 3, the second driver 510 may have a second output shaft capable of outputting a rotational motion, i.e. the second output shaft is the above-mentioned second output end for outputting a torque, and the second driver 510 may be a rotational driving device such as a motor. The lifting mechanism 520 may include a screw rod 521 coaxially connected to the second output shaft and a nut 522 sleeved on the screw rod 521, and the second traveling device 220 may be connected to the nut 522, so that the screw rod 521 may be driven to rotate by the second output shaft to drive the nut 522 to move, and finally, the second traveling device 220 may move up and down. Wherein the lead screw 521 may be disposed on the frame 100 in a vertical direction. As another embodiment, the lifting mechanism 520 may be configured in the form of a rack and pinion, etc., and the disclosure is not limited thereto. Of course, the second driving member 510 may also have an output shaft capable of outputting linear motion, so that the second traveling device 220 may be driven to move up and down by a linear mechanism such as a push rod or directly by the second driving member 510.

According to some embodiments, referring to fig. 3, the second switching device 500 may further include a transmission mechanism 530 connected between the second driving member 510 and the elevating mechanism 520 to make a desired optimal change in the power of the second driving member 510 through the transmission mechanism 530. The transmission mechanism 530 may also be a belt transmission assembly, and the transmission mechanism 530 may include a third pulley 531, a fourth pulley 532, and a second belt 533 wound around the third pulley 531 and the fourth pulley 532. The third belt wheel 531 may be sleeved on the second output shaft or the axle of the third belt wheel 531 may be coaxially connected with the second output shaft; the axle of the fourth pulley 532 may be coaxially connected to the screw 521. Therefore, the second driving member 510 drives the second output shaft to rotate, the second output shaft drives the third belt wheel 531 to rotate, the third belt wheel 531 drives the fourth belt wheel 532 to rotate through the second belt body 533, the fourth belt wheel 532 drives the screw rod 521 to rotate, and finally the second driving member 510 drives the screw rod 521 to rotate synchronously. It should be noted here that the third belt pulley 531 and the axle thereof and the fourth belt pulley 532 and the axle thereof are fixedly engaged, so that synchronous rotation can be realized. The belt transmission assembly has stable transmission and can eliminate vibration in the movement process, thereby ensuring the stability of the second walking device 220 moving up and down. In other embodiments, the transmission assembly may also be, for example, a gear pair, and the disclosure is not limited thereto.

Here, in order to ensure the movement synchronism of the second running gears 220 on both sides, referring to fig. 3, the second belt 533 may be sequentially wound around the third pulley 531 and the fourth pulley 532 corresponding to each of the second running gears 220 on both sides of the frame 100. That is, with the third pulley 531 as a starting point, the second belt 533 sequentially passes through the fourth pulley 532 corresponding to the second running gear 220 on the first side of the frame 100 and the fourth pulley 532 corresponding to the second running gear 220 on the second side of the frame 100, and then returns to the third pulley 531, so that the second running gears 220 on both sides can be driven by one power device (the second driving element 510) to move up and down synchronously.

According to some embodiments, referring to fig. 3, the transmission mechanism 530 may further include a tension pulley 534 disposed between the third pulley 531 and the fourth pulley 532, wherein the tension pulley 534 is movably disposed on the frame 100 for adjusting the tension of the second belt 533. Specifically, as shown in fig. 3, the second driving element 510 may be disposed at the position of the second running gear 220 near one side of the frame 100, where the third pulley 531 is closer to the fourth pulley 532 corresponding to the second running gear 220 at the one side, the length of the second belt 533 between the third pulley 531 and the fourth pulley 532 at the one side is shorter, the corresponding third pulley 531 is farther from the fourth pulley 532 corresponding to the second running gear 220 at the other side, the length of the second belt 533 between the third pulley 531 and the fourth pulley 532 at the other side is longer, and the tension pulley 534 may be disposed between the third pulley 531 and the fourth pulley 532 at the farther distance, so that the tension pulleys 534 may be avoided to be disposed between the third pulley 531 and the fourth pulleys 532 at both sides, and the occupied space may be reduced.

According to some embodiments, referring to fig. 3, the second switching device 500 may further include a guide mechanism 540 for guiding the up-and-down movement of the second traveling device 220, so that the second traveling device 220 can be precisely linearly moved. The guide mechanism 540 may include a wire rail 541 fixed to the carriage 100 and a slider 542 slidably coupled to the wire rail 541, the wire rail 541 may extend in a vertical direction, and the second traveling device 220 may be fixedly coupled to the slider 542, so that the linear movement of the slider 542 along the wire rail 541 drives the second traveling device 220 to move up and down along the wire rail 541. In other embodiments, the guiding mechanism 540 may also be a combination of a linear bearing and a shaft body, the linear bearing may be fixed on the frame 100, the shaft body may be connected to the second walking device 220, and the linear bearing is coaxially sleeved outside the shaft body and axially slidably engaged therewith, so that the shaft body can drive the second walking device 220 to move up and down along the linear bearing.

In addition, in the embodiments provided by the present disclosure, referring to fig. 1 and 3, the second walking device 220 may include a plurality of wheels 221 arranged at intervals, that is, the linear movement of the shuttle vehicle along the vertical track 11 is realized by the rotation of the wheels 221. The plurality of wheels 221 may be vertically movably disposed on the frame 100 through the second mounting plate 120, and for example, the nut 522 may be directly connected to the second mounting plate 120, so that the second traveling device 220 is driven to vertically move by the vertical movement of the second mounting plate 120. In this case, the guide mechanism 540 may include a plurality of sets, a plurality of the wire rails 541 may be spaced apart on the carriage 100, and a plurality of the sliders 542 may be each connected to the second mounting plate 120. The second mounting plate 120 may be fixed with a second driving motor 121 for driving the wheel 221, so that the second driving motor 121 operates to drive the wheel 221 to move. The number of the wheel bodies 221 is not limited in the present disclosure, and by providing a plurality of wheel bodies 221, each wheel body 221 can be uniformly and correspondingly distributed at different positions of the vehicle frame 100, so that the running stability of the shuttle vehicle during operation can be further ensured. In other embodiments, the second traveling device 220 may be configured as a moving device such as a crawler belt that is in contact with the vertical rail 11, or may be configured as a moving device such as a magnetic levitation that is not in contact with the vertical rail 11 by an electromagnetic force.

According to some embodiments, referring to fig. 1, the shuttle car may further include a transfer device 300 fixed above the frame 100 to transfer goods into the corresponding bin of the rack 10 through the transfer device 300. The conveying device 300 is rotatably disposed on the vehicle frame 100 about a vertical axis, for example, a rotating mechanism may be disposed at the bottom of the conveying device 300, so that four-way or multi-way distribution of the goods may be achieved, for example, the goods may be distributed to two sides corresponding to the first direction and the second direction, respectively. In other embodiments in which the transfer device 300 is not rotatable, directional adjustment of the shuttle car according to the cargo bay is also possible, so that distribution of the cargo in different directions is also possible. For example, according to the shuttle structure shown in fig. 1, both ends of the transfer device 300 for transferring the goods are oppositely arranged in the second direction, and after the first running device 210 is horizontally moved to the target position of the rack 10 in the second direction, the second running device 220 starts to move vertically, so that the goods can be distributed to both sides corresponding to the second direction. If the goods are required to be distributed to two sides corresponding to the first direction, the position of the shuttle car can be adjusted, so that two ends of the conveying device 300 for conveying the goods can be oppositely arranged along the first direction, at this time, the first walking device 210 can be controlled to horizontally move along the first direction, and after the target position of the shelf 10 is reached, the second walking device 220 starts to vertically move, so that the goods are distributed to two sides corresponding to the first direction. It should be noted that, the above description that the first running gear 210 and the second running gear 220 are respectively located on both sides of the frame 100 along the first direction and the second direction is made by taking the example that the shuttle car moves horizontally along the second direction as an example, when the shuttle car adjusts the orientation and moves horizontally along the first direction, the first running gear 210 is located on both sides of the frame 100 along the second direction, and the second running gear 220 is correspondingly located on both sides of the frame 100 along the first direction.

As an embodiment, referring to fig. 1, the transfer device 300 may be a belt transfer assembly, and the belt transfer assembly may include a transfer belt 310, transfer pulleys at both ends of the transfer belt 310, and a transfer driving motor for driving at least one of the transfer pulleys to rotate. The belt conveying assembly may be connected to the upper portion of the frame 100 through a bracket, and the wheel axle of the conveying belt wheel may be fixed to the bracket, and at this time, the conveying belt wheel and the wheel axle thereof may be in a rotation fit relationship, that is, the conveying belt wheel may rotate around the wheel axle thereof, so as to realize the conveying of the goods by the conveying belt 310.

Referring to fig. 12 and 13, the present disclosure also provides a rack 10 for cooperating with the above-described shuttle 20, the rack 10 may include a horizontal rail for cooperating with the first running gear 210 and a vertical rail 11 for cooperating with the second running gear 220, the horizontal rail may extend in a horizontal direction, and the vertical rail 11 may extend in a vertical direction, respectively. Wherein, the goods shelf 10 can comprise a plurality of layers arranged along the height direction, each layer of goods shelf is provided with a plurality of goods bins, at least one side of each goods bin can be provided with a vertical channel, and the vertical channel can be used as a channel for the vertical movement of the shuttle 20. Illustratively, the horizontal track may be disposed at the top of the shelf 10 and the vertical track 11 may be located within the vertical channel. Thus, referring to fig. 8 to 13, after receiving goods, the shuttle car 20 may first move along the horizontal rail at the top of the shelf 10, at this time, the first switching device 400 controls the first running device 210 to extend to be in contact with and engaged with the horizontal rail, the second switching device 500 controls the second running device 220 to ascend to be disengaged from and engaged with the vertical rail 11, the first driving motor 111 operates, and the shuttle car 20 is in the first operating state; when the shuttle car 20 moves horizontally to the vertical channel where the target warehouse is located, the first driving motor 111 stops working, the shuttle car 20 stops moving horizontally, at the moment, the second switching device 500 controls the second walking device 220 to descend to be in contact fit with the vertical track 11, the first switching device 400 controls the first walking device 210 to retract to be out of fit with the horizontal track, the second driving motor 121 works, and the shuttle car 20 moves along the vertical track 11 in the vertical channel and is in a second working state; when the shuttle car 20 vertically moves to the target warehouse with the corresponding height, the second driving motor 121 stops working, the shuttle car 20 stops vertically moving, and at the moment, the conveying device 300 starts working and conveys the goods on the shuttle car 20 to the corresponding warehouse; shuttle 20 may then return to the home position to await the next arrival. In the process, the horizontal rail and the vertical rail 11 can respectively have a guiding function, so that the shuttle car 20 can be ensured not to deviate from the moving direction in the moving process.

According to some embodiments, referring to fig. 8 to 11, the vertical track 11 may include a first rail 101 and a second rail 102 disposed oppositely, the first rail 101 and the second rail 102 may be respectively racks extending in a vertical direction, and accordingly, the second running gear 220 may include two gears cooperatively moving along the first rail 101 and the second rail 102 respectively, that is, the wheel body 221 may be a wheel body of the gear, so that the vertical movement of the shuttle 20 may be realized by the cooperative movement of the gear along the racks.

Here, as an embodiment, referring to fig. 8 to 11, the horizontal rail may include a third rail and a fourth rail that are oppositely disposed, and the first traveling devices 210 on both sides of the carriage 100 may be moved in cooperation with the third rail and the fourth rail, respectively. The third rail and the fourth rail may be correspondingly connected to the first rail 101 and the second rail 102, respectively. In this way, when the shuttle car 20 is in the first working state, the first traveling device 210 extends to be respectively in contact fit with the third rail and the fourth rail, the two gears of the second traveling device 220 ascend to move to be disengaged from the racks of the first rail 101 and the second rail 102, and the shuttle car 20 is switched from vertical motion to horizontal motion; when the shuttle 20 is in the second working state, the first traveling device 210 retracts to be disengaged from the third rail and the fourth rail, respectively, the two gears of the second traveling device 220 descend to be in contact fit with the racks of the first rail 101 and the second rail 102, and the shuttle 20 is switched from horizontal movement to vertical movement.

According to some embodiments, referring to fig. 11, the rack 10 may further include an auxiliary rail (not shown) extending in a vertical direction to be capable of being in contact engagement with the first running gear 210 in the second operating state. The auxiliary rail may also be provided in the vertical channel, i.e. it may be in contact engagement with the auxiliary rail in the vertical channel when the first running gear 210 is retracted out of engagement with the horizontal rail. Referring to fig. 8 to 11, taking an example that the first rail 101 of the vertical rail 11 is connected to the third rail of the horizontal rail, and the second rail 102 of the vertical rail 11 is connected to the fourth rail of the horizontal rail, the third rail and the fourth rail are oppositely disposed along the first direction, and the first rail 101 and the second rail 102 may be formed between the third rail and the fourth rail and respectively protrude from opposite inner side surfaces of the third rail and the fourth rail. The two first rails 101 respectively engaged with the second running gear 220 on both sides of the frame 100 may be disposed at intervals along the second direction, the two second rails 102 respectively engaged with the second running gear 220 on both sides of the frame 100 may also be disposed at intervals along the second direction, the first rail 101 and the second rail 102 may be configured as vertically extending bar-shaped block structures, for example, racks may be formed on the opposite sides of the first rail 101 and the second rail 102 in the first direction, and the auxiliary rails may be formed on the opposite sides of the two first rails 101 in the second direction and the opposite sides of the two second rails 102 in the second direction. In this way, since the first rail 101 and the second rail 102 protrude from the inner side surfaces of the third rail and the fourth rail, and the two first rails 101 and the two second rails 102 are respectively arranged at intervals along the second direction, in the second working state, the first running device 210 can be controlled to retract and move to a position between the inner side surface of the third rail and the side surface of the first rail 101 in the first direction and between the inner side surface of the fourth rail and the side surface of the second rail 102 in the first direction, that is, the first running device 210 is located between the two first rails 101 arranged at intervals along the second direction and the two second rails 102 arranged at intervals along the second direction, the first running device 210 is separated from the third rail and the fourth rail but does not exceed the side surfaces of the first rail 101 and the second rail 102 in the first direction, so that the first running device 210 can be in contact with the auxiliary rails on the opposite side surfaces of the two first rails 101 in the second direction and the auxiliary rails on the opposite sides of the two second rails 102 in the second direction, to guide the vertical movement of the shuttle car 20 when in the second operating state so that the shuttle car can walk stably. In the case that the first traveling device 210 includes a driving wheel 211 and driven wheels 212 respectively disposed at both sides of the driving wheel 211, the two driven wheels 212 may be respectively in contact with the auxiliary rails to guide the vertical movement of the shuttle car 20. As an embodiment, the auxiliary track may be designed to structurally match the driven wheel 212 such that the driven wheel 212 may simultaneously rotate on the auxiliary track and move downward during vertical movement of the shuttle 20. In other embodiments, the auxiliary track may be simply designed as a groove structure for accommodating the driven wheel 212, the driven wheel 212 may rotate when the groove bottom of the groove structure is in contact with the driven wheel 212, the driven wheel 212 may not rotate when the groove bottom of the groove structure is not in contact with the driven wheel 212 and may be restricted to move downwards between two side walls of the groove structure, so as to guide the shuttle 20 by restricting the movement of the shuttle 20 in the first direction and enable the shuttle 20 to stably walk.

In addition, in the embodiment provided by the present disclosure, a positioning device may be further disposed on the shelf 10, a position detection device capable of detecting the position of the shuttle 20 in real time may be mounted on the shuttle 20, and when the shuttle 20 reaches the target position of the shelf 10, the position detection device may trigger the positioning device through the controller, so as to limit the movement of the shuttle 20, position the shuttle 20, and further ensure the position accuracy of the shuttle 20. The positioning device and the position detection device can be respectively in signal connection with the controller, and the controller can also be in signal connection with the switching device of the shuttle car 20, so that the switching device can be remotely controlled to work through the controller, and the shuttle car 20 can be switched between the first working state and the second working state.

According to a third aspect of the present disclosure, a cargo sorting system is provided, wherein the cargo sorting system may comprise the shuttle 20 described above and the rack 10 described above. According to a fourth aspect of the present disclosure, there is provided a building including a building body and a goods sorting system installed on the building body, wherein the goods sorting system may be a goods sorting system configured with the shuttle car 20 and the shelf 10. The goods sortation system and building has all of the benefits of the shuttle 20 and the pallet 10 described above and will not be described in detail herein.

In addition, according to the embodiment that this disclosure provided, goods letter sorting system especially can be the commodity circulation letter sorting system of unmanned delivery, and the building especially can be high-rise building, and goods shelves 10 can be integrated with the building body to can utilize the motion of shuttle 20 on the goods shelves track to realize takeout, express delivery home, satisfy unmanned delivery demand, effectively improve logistics efficiency.

The preferred embodiments of the present disclosure are described in detail with reference to the accompanying drawings, however, the present disclosure is not limited to the specific details of the above embodiments, and various simple modifications may be made to the technical solution of the present disclosure within the technical idea of the present disclosure, and these simple modifications all belong to the protection scope of the present disclosure.

It should be noted that, in the foregoing embodiments, various features described in the above embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, various combinations that are possible in the present disclosure are not described again.

In addition, any combination of various embodiments of the present disclosure may be made, and the same should be considered as the disclosure of the present disclosure, as long as it does not depart from the spirit of the present disclosure.

Claims (22)

1. A shuttle car, comprising: the shuttle car comprises a car frame (100), a traveling device (200) movably mounted on the car frame (100), and a switching device for controlling the traveling device (200), wherein the traveling device (200) comprises a first traveling device (210) capable of moving along a horizontal track and a second traveling device (220) capable of moving along a vertical track, so that the shuttle car is in a first working state or a second working state through the switching device,

in the first working state, the first walking device (210) moves to be capable of moving along the horizontal track, and the second walking device (220) moves to be capable of disengaging from the vertical track;

in the second working state, the second walking device (220) moves to be capable of moving along the vertical track, and the first walking device (210) moves to be capable of disengaging from the horizontal track.

2. A shuttle as claimed in claim 1, characterized in that said first running means (210) are arranged on opposite sides of said first direction of the carriage (100), said switching means comprising first switching means (400) for controlling the telescopic movement of said first running means (210) towards and away from the carriage (100), said first switching means (400) comprising a first drive member (410) and a telescopic mechanism (420) connected between said first drive member (410) and said first running means (210) such that,

in the first working state, the first walking device (210) extends to be in contact fit with the horizontal rail;

in the second operating state, the first running gear (210) is retracted out of engagement with the horizontal rail.

3. A shuttle as claimed in claim 2, characterized in that said first drive member (410) has a first output shaft capable of outputting a rotary motion, said telescopic mechanism (420) being configured as a slider-crank mechanism comprising a crank structure (421) connected to said first output shaft, a slider structure (422) connected to said first running gear (210), and a connecting rod (423) connected between said crank structure (421) and said slider structure (422).

4. A shuttle as claimed in claim 3, characterized in that said crank structure (421) comprises a crank (4211) and a transmission assembly connected between said first driving member (410) and said crank (4211), said transmission assembly comprising:

a first belt wheel (4212) sleeved on the first output shaft;

the crank (4211) is sleeved on a wheel shaft of the second belt wheel (4213); and

and a first belt body (4214) wound around the first pulley (4212) and the second pulley (4213).

5. A shuttle as claimed in claim 3, characterized in that said slider structure (422) comprises a linear bearing (4221) fixed to said carriage (100) and a shaft body (4222) cooperating with said linear bearing (4221), said shaft body (4222) being connected at one end to said connecting rod (423) and at the other end to said first running gear (210).

6. A shuttle as claimed in claim 3, characterized in that said crank structure (421) comprises a crank (4211), the centre of said crank (4211) in the length direction is drivingly connected to said first output shaft, said first running gear (210) on both sides of said carriage (100) is connected to both ends of said crank (4211) through said slider structure (422) and said connecting rod (423), respectively.

7. The shuttle vehicle according to claim 2, wherein the first traveling device (210) is a traveling wheel, the traveling wheel comprises a driving wheel (211) and a driven wheel (212) respectively arranged at two sides of the driving wheel (211), the driving wheel (211) and the driven wheel (212) are telescopically and movably arranged on the vehicle frame (100) through a first mounting plate (110), and a first driving motor (111) for driving the driving wheel (211) is fixed on the first mounting plate (110).

8. A shuttle as claimed in claim 1, characterized in that said second running gear (220) is arranged on opposite sides of said carriage (100) in a second direction, said switching means further comprising a second switching means (500) for controlling said second running gear (220) to move up and down, said second switching means (500) comprising a second driving member (510) and a lifting mechanism (520) connected between said second driving member (510) and said second running gear (220) such that,

in the first working state, the second walking device (220) moves to be disengaged from the vertical track;

in the second working state, the second walking device (220) moves to be in contact fit with the vertical rail.

9. A shuttle as claimed in claim 8, characterized in that said second drive member (510) has a second output shaft capable of outputting a rotary motion, said lifting mechanism (520) comprises a screw (521) coaxially connected to said second output shaft and a nut (522) fitted over said screw (521), said second running gear (220) being connected to said nut (522).

10. A shuttle as claimed in claim 9, characterized in that said second switching means (500) further comprises a transmission mechanism (530) connected between said second drive member (510) and said lifting mechanism (520), said transmission mechanism (530) comprising:

a third belt wheel (531) sleeved on the second output shaft;

a fourth belt pulley (532), wherein the wheel shaft of the fourth belt pulley (532) is coaxially connected with the screw rod (521); and

and a second belt body (533) wound around the third pulley (531) and the fourth pulley (532).

11. A shuttle as claimed in claim 10, characterized in that said second belt (533) is wound in sequence around said third pulley (531) and outside of said fourth pulley (532) corresponding to each of said second running gear (220) on both sides of said carriage (100).

12. A shuttle as claimed in claim 10, characterized in that said transmission mechanism (530) further comprises a tension pulley (534) disposed between said third pulley (531) and said fourth pulley (532), said tension pulley (534) being movably disposed on said carriage (100) for adjusting the tension of said second belt (533).

13. The shuttle of claim 8, wherein the second switching device (500) further comprises a guide mechanism (540) for guiding the up and down movement of the second running gear (220), the guide mechanism (540) comprises a wire rail (541) fixed on the carriage (100) and a slider (542) slidably connected to the wire rail (541), and the second running gear (220) is fixedly connected to the slider (542).

14. The shuttle according to claim 8, wherein the second traveling device (220) comprises a plurality of wheels (221) arranged at intervals, the plurality of wheels (221) are arranged on the frame (100) in a manner of being movable up and down through a second mounting plate (120), and a second driving motor (121) for driving the wheels (221) is fixed on the second mounting plate (120).

15. A shuttle as claimed in claim 1, characterized in that it further comprises a conveyor (300) fixed above said carriage (100), said conveyor (300) being rotatable about a vertical axis.

16. A shuttle as claimed in claim 15, characterized in that said conveying means (300) is a belt conveying assembly comprising a conveyor belt (310), conveyor pulleys at both ends of said conveyor belt (310), and a conveyor drive motor for driving at least one of said conveyor pulleys in rotation.

17. A pallet, characterized in that for cooperation with a shuttle according to any one of claims 1-16, the pallet (10) comprises a horizontal rail for cooperation with the first running gear (210) and a vertical rail (11) for cooperation with the second running gear (220), the horizontal rail extending in a horizontal direction and the vertical rail (11) extending in a vertical direction.

18. The rack according to claim 17, characterized in that the vertical track (11) comprises a first rail (101) and a second rail (102) arranged opposite to each other, and the first rail (101) and the second rail (102) are respectively vertically extending racks for cooperating with the gears of the second running gear (220) for movement.

19. The pallet according to claim 17, characterized in that the pallet (10) further comprises an auxiliary rail extending in a vertical direction for contact engagement with the first running gear (210) in the second operating state.

20. The pallet according to claim 17, characterized in that positioning means are provided on the pallet (10) for positioning by triggering position detection means mounted on the shuttle (20) when the shuttle (20) reaches the target position of the pallet (10).

21. A cargo sorting system comprising a shuttle according to any of claims 1-16 and a rack according to any of claims 17-20.

22. A building comprising a building body and a cargo sortation system mounted thereon, wherein the cargo sortation system is the cargo sortation system of claim 21.

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