CN217205661U - Automatic guided vehicle and parking system - Google Patents

Abstract

The utility model provides an automatic guided vehicle and parking system. The automated guided vehicle includes: a vehicle body; the traveling device is arranged on the vehicle body to drive the vehicle body to travel; the lifting device comprises a lifting mechanism in a scissor fork structure, a connecting arm hinged with the lifting mechanism and a driving structure connected with and driving the connecting arm to rotate; one end of the lifting mechanism is connected with the vehicle body; the driving structure can drive the connecting arm to rotate under the lifting stroke to drive the lifting mechanism to lift; and the upper bracket is connected to the other end of the lifting mechanism, lifted by the lifting mechanism and capable of being lifted relative to the vehicle body, and is used for supporting a vehicle carrying plate. The utility model discloses an automatic guided vehicle utilizes same drive structure can control the height of lifting of upper portion bracket reliably to on will carrying sweep and vehicle to transport the parking stall of co-altitude. The automatic guided vehicle has simple integral structure and convenient operation.

Description

Automatic guided vehicle and parking system

Technical Field

The utility model relates to a stereo garage technical field, in particular to automatic guided vehicle and parking system.

Background

The stereo garage allows a plurality of vehicles to be parked at intervals in the height direction, thereby improving the space utilization rate. In some prior art schemes, an automated guided vehicle is used to transport a vehicle to a stereo parking garage, and two lifting mechanisms are arranged on the automated guided vehicle, so that a vehicle carrying plate and a trolley are respectively lifted to parking spaces of a specified layer by using different lifting mechanisms. In this solution, two lifting mechanisms need to be installed on the chassis, and the parking operation needs to control the two lifting mechanisms separately, so that the structure and operation of the automated guided vehicle are complex, and further improvement is needed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a simple structure just conveniently transports the automated guided vehicle of vehicle.

Another object of the present invention is to provide a parking system with the above automatic guided vehicle.

In order to solve the technical problem, the utility model adopts the following technical scheme:

according to an aspect of the utility model, the utility model provides an automatic guided vehicle, include: a vehicle body; the traveling device is arranged on the vehicle body to drive the vehicle body to travel; the lifting device comprises a lifting mechanism in a scissor fork structure, a connecting arm hinged with the lifting mechanism and a driving structure connected with and driving the connecting arm to rotate; one end of the lifting mechanism is connected with the vehicle body; the driving structure can drive the connecting arm to rotate under the lifting stroke to drive the lifting mechanism to lift; and the upper bracket is connected to the other end of the lifting mechanism, lifted by the lifting mechanism and capable of being lifted relative to the vehicle body, and is used for supporting a vehicle carrying plate.

In some embodiments, the connecting arm is provided with a lifting part at one end close to the connection of the driving structure; when the driving structure drives the connecting arm to rotate to the first position under the lifting stroke, the upper supporting part is abutted to the upper bracket.

In some embodiments, the upper bracket includes a main frame and an abutment plate fixed to the main frame; when the upper support part is located at the first position, the upper support part is abutted to the abutting plate.

In some embodiments, the connecting arm comprises two connecting plates arranged in parallel at intervals, a connecting shaft connected with one ends of the two connecting plates, and a sleeve detachably sleeved on the connecting shaft, and the upper supporting part is arranged on the periphery of the sleeve; the driving structure is hinged with the connecting shaft.

In some embodiments, the lifting mechanism includes a first lifting unit, a second lifting unit, a hinge shaft, and a limiting member; the middle parts of the two lifting units are hinged through the hinge shaft; the limiting piece is arranged on the second lifting unit; the connecting arm is hinged to the hinged shaft, and when the driving structure drives the connecting arm to rotate from the first position to the second position under the lifting stroke, the connecting arm is abutted to the limiting part to drive the second lifting unit to rotate.

In some embodiments, the two sides of the vehicle body are respectively provided with a lower rail, and the two sides of the upper bracket are provided with an upper rail; the lower end of the first lifting unit is hinged with the vehicle body, and the upper end of the first lifting unit is in sliding fit with the upper rail; the lower end of the second lifting unit is in sliding fit with the lower rail, and the upper end of the second lifting unit is hinged to the upper bracket.

In some embodiments, the driving structure comprises a hydraulic cylinder, a lower end of the hydraulic cylinder is hinged with a lower end of the first lifting unit, and an upper end of the hydraulic cylinder is connected with the connecting arm.

In some embodiments, the first lifting unit comprises two first support legs arranged at intervals, the second lifting unit comprises two second support legs arranged at intervals, and the two second support legs are positioned between the two first support legs; the limiting piece is connected with the two second supporting legs; the connecting arm is located between the two second support legs.

In some embodiments, the upper bracket includes a support beam and a plurality of limit blocks protruding upward from the support beam, the limit blocks are used for limiting the vehicle carrying board, and the limit blocks are detachably connected to the support beam.

According to another aspect of the present invention, the utility model provides a parking system, include: the parking garage comprises a plurality of stand columns which are arranged in an array manner, and two layers of parking spaces which are spaced along the height direction are arranged between two columns of stand columns; the vehicle carrying plate is used for carrying vehicles and can be detachably connected with the upright post to be fixed on any layer of parking space; according to the automatic guided vehicle, the upper bracket of the automatic guided vehicle supports the vehicle carrying plate, and the automatic guided vehicle can enter the parking garage through the traveling device of the automatic guided vehicle.

According to the above technical scheme, the utility model discloses following advantage and positive effect have at least: the utility model discloses an among the automated guided vehicle, utilize upper portion bracket bearing to carry the sweep, utilize the running gear of automobile body bottom can conveniently transport the assigned position with carrying the sweep and the vehicle that bears on it, make upper portion bracket can rise for the automobile body through elevating gear to can conveniently transport to the assigned height carrying sweep and vehicle. The lifting device drives the connecting arm to drive the lifting mechanism to lift by using the driving structure, and the connecting arm can share the load of the driving structure at the beginning of lifting, so that the lifting height of the upper bracket can be reliably controlled by using the same driving structure, and the vehicle carrying plate and the vehicle can be conveniently conveyed to parking spaces with different heights. The automatic guided vehicle has simple integral structure and convenient operation.

Drawings

Fig. 1 is a schematic structural view of a parking garage and a vehicle carrying board in an embodiment of the parking system of the present invention.

Fig. 2 is a perspective view of the automated guided vehicle according to the first embodiment of the present invention.

Fig. 3 is a front view of fig. 2, illustrating a state in which the upper bracket is raised with respect to the vehicle body.

Fig. 4 is a schematic view of the upper bracket of fig. 3 in a lowered state.

Fig. 5 is an exploded perspective view of fig. 2.

Fig. 6 is a sectional view a-a of fig. 3, showing the structure of only one end of the joist.

Fig. 7 is an exploded perspective view of the connecting arm of fig. 5.

Fig. 8 is a schematic view of the lifting mechanism of the lifting device in fig. 2 in a stowed state, in which the vehicle body and the running gear are omitted.

Fig. 9 is a schematic view of the connecting arm rotated to a first position on the basis of fig. 8.

Fig. 10 is a partial enlarged view of fig. 9 at B.

Fig. 11 is a schematic view of the connecting arm rotated to a second position on the basis of fig. 9.

Fig. 12 is a perspective view of the lifting device and the upper bracket of the second embodiment of the automated guided vehicle according to the present invention.

Fig. 13 is a perspective view of the lifting device and the upper bracket of the third embodiment of the automated guided vehicle according to the present invention.

Fig. 14 is an exploded perspective view of the connecting arm of fig. 13.

Fig. 15 is a schematic view of the connecting arm in the lifting device of fig. 13 in a first position.

Fig. 16 is a schematic view of the lifting device of fig. 13 with the connecting arm in a second position.

The reference numerals are explained below:

100. a lifting device;

1. a lifting mechanism; 11. a first lifting unit; 111. a first leg; 1111. a first hinge hole; 112. a first lower mounting shaft; 113. an upper mounting shaft; 114. a mounting seat; 115. an upper slide block; 12. a second lifting unit; 121. a second leg; 1211. a second hinge hole; 122. a second lower mounting shaft; 123. a support plate; 124. a lower slide block; 125. a hinged seat; 13. a limiting member; 131. a first limit plate; 132. a second limiting plate; 14. hinging shafts;

2. a connecting arm; 21. a connecting plate; 211. mounting holes; 212. connecting holes; 213. an end edge; 214. an extension end; 22. a connecting shaft; 23. a sleeve; 231. a sleeve body; 2311. sleeving a hole; 2312. a lifting part; 2313. an accommodating groove; 232. a gasket; 2321. lifting the surface; 233. a fastener; 234. a screw; 25. a fixing plate;

3. a drive structure; 31. a hydraulic cylinder; 311. a cylinder body; 312. a piston rod;

500. an upper bracket; 501. a butt joint plate; 502. a main frame; 5021. an upper rail; 503. a support beam; 504. a limiting block; 505. a support plate; 506. a fastener;

600. a traveling device; 601. a walking frame; 602. a drive member; 603. a traveling wheel;

700. a vehicle body; 701. a mounting cavity; 702. mounting a beam; 703. a lower rail;

800. a vehicle carrying board; 801. hanging a lug;

900. parking in a garage; 901. a column; 9011. hooking; 902. and parking spaces.

Detailed Description

Exemplary embodiments that embody features and advantages of the present invention will be described in detail in the following description. It is to be understood that the invention is capable of other and different embodiments and its several details are capable of modification without departing from the scope of the invention, and that the description and drawings are to be regarded as illustrative in nature and not as restrictive.

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be construed as limiting the present application. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

The utility model provides an automatic guided vehicle and have this automatic guided vehicle's parking system. The parking system mainly comprises a parking garage, a vehicle carrying plate and the automatic guided vehicle, wherein the vehicle carrying plate is used for carrying the vehicle, and the automatic guided vehicle can bear the vehicle carrying plate and convey the vehicle carrying plate to the parking garage.

Fig. 1 illustrates a state of a vehicle carrying board 800 placed in a parking garage 900 according to an embodiment of the present invention. The parking garage 900 comprises four uprights 901 arranged in two columns, between which two columns 901 there are two levels of parking spaces 902 spaced in height. Each upright column 901 is provided with two hooks 9011 protruding towards the other column 901 at intervals along the height direction, and the hooks 9011 on the two columns of upright columns 901 at the same height define a parking space 902.

In fig. 1, a parking space 902 is illustrated as being defined by four columns 901, namely two columns 901 in each row. In other embodiments not shown, each column of columns 901 may also include three or more columns 901. It should be noted that two columns of pillars 901 are illustrated to define the smallest parking unit of the parking garage 900, and a plurality of such parking units may be included in the actual parking garage 900, and by arranging a plurality of pillars 901 in an array, a parking space 902 may be formed between two adjacent columns of pillars 901.

The vehicle carrying plate 800 is used for carrying vehicles, the specific structure of the vehicle carrying plate can be designed according to actual conditions, the two sides of the vehicle carrying plate 800 are provided with the hanging lugs 801, and the hanging lugs 801 can be detachably hung on the hanging hooks 9011 of the upright columns 901, so that the vehicle carrying plate 800 is fixed on the corresponding parking spaces 902. The vehicle carrying board 800 can be fixed on any layer of parking spaces 902 according to the occupancy in the parking garage 900. The upper and lower layers of vehicle carrying plates 800 can respectively carry one vehicle, so that one more vehicle can be parked under the condition of a certain floor area.

Referring to fig. 2, the automated guided vehicle includes a vehicle body 700, a traveling device 600 disposed on the vehicle body 700, a lifting device 100 connected to the vehicle body 700, and an upper bracket 500 supported on the vehicle body 700 by the lifting device 100. The walking device 600 can drive the car body 700 to walk, the upper bracket 500 is used for supporting the car carrying plate 800, and the lifting device 100 can be unfolded or folded to drive the upper bracket 500 to lift relative to the car body 700.

Fig. 2 and 3 show the upper carriage 500 raised relative to the car body 700, in which case the upper carriage 500 has a greater height and can correspondingly transport the car carriers 800 supported thereon to the parking spaces 902 located in the upper level of the parking garage 900. Fig. 4 illustrates a state where the upper carriage 500 is lowered, in which the upper carriage 500 is substantially accommodated in the vehicle body 700, and in which the upper carriage 500 is at the lowest position, so that the position of the center of gravity of the automated guided vehicle can be lowered, and the automated guided vehicle can travel more safely.

With reference to fig. 1 to 4, the parking system operates substantially as follows.

During parking operation: the vehicle loading plate 800 on which the vehicle is parked is supported on the upper bracket 500 of the automated guided vehicle, the upper bracket 500 is maintained in a lowered state as shown in fig. 4, and the automated guided vehicle supports the vehicle loading plate 800 and the vehicle travels into the parking garage 900. The automated guided vehicle enters between the two columns of columns 901, and the lifting device 100 is deployed to raise the upper carriage 500 to the parking space 902 of the upper or lower floor. After the hanging lug 801 of the car carrying board 800 is hung on the hanging hook 9011 of the upright column 901, the lifting device 100 is retracted, the upper bracket 500 is lowered and retracted to the car body 700, the car is automatically guided to walk out of the parking space 902, and the car carrying board 800 together with the car thereon is fixed to the corresponding parking space 902. When the car carrying board 800 needs to be fixed to the lower parking space 902, the lifting device 100 is unfolded by a smaller angle to lift the upper bracket 500 to a lower height; when the car loading plate 800 needs to be fixed to the upper parking space 902, the lifting device 100 is unfolded to a larger angle to lift the upper bracket 500 to a higher height.

When the vehicle is taken: the automated guided vehicle travels below the parking space 902 where the vehicle is parked, and the lifting device 100 is unfolded to lift the upper bracket 500 until the upper bracket 500 contacts and supports the vehicle carrying board 800 and rises together to disengage the hook 9011. The traveling device 600 travels to cause the automated guided vehicle to exit the parking space 902. The lifting device 100 is retracted to lower the upper bracket 500 to be retracted to the vehicle body 700. The traveling device 600 travels to a predetermined vehicle taking position, the automatic guided vehicle places the vehicle carrying plate 800 together with the vehicle at the vehicle taking position, and the automatic guided vehicle exits.

In the parking system, in the parking garage 900 having multi-deck parking spaces 902, the automated guided vehicle lifts the upper bracket 500 by using the same lifting device 100 at different heights, thereby transporting the vehicle loading plate 800 and the vehicles loaded on the vehicle loading plate 800 to the parking spaces 902 at different heights. The automatic guided vehicle has simple integral structure and convenient operation.

The following describes the detailed structure of each part of the automated guided vehicle in detail through several embodiments.

First embodiment of automated guided vehicle:

fig. 2 illustrates a perspective view of the automated guided vehicle of the present embodiment, which includes a vehicle body 700, a traveling device 600, a lifting device 100, and an upper bracket 500, as described above.

Referring to fig. 5, body 700 is a generally rectangular frame structure that may be assembled from profiles. Four corners of the vehicle body 700 are respectively provided with an installation cavity 701 for installing the running gear 600. Two mounting beams 702 extending along the length direction of the vehicle body 700 are arranged in the vehicle body 700, the two mounting beams 702 are arranged on two sides of the vehicle body 700, each mounting beam 702 is provided with a lower rail 703 extending along the length direction of the vehicle body 700, and the lower rails 703 on the two mounting beams 702 are opposite.

The number of the traveling devices 600 is four, and the traveling devices are correspondingly mounted in four mounting cavities 701 of the vehicle body 700. The walking device 600 generally includes a walking frame 601, a driving member 602 mounted on the walking frame 601, and a walking wheel 603 driven by the driving member 602 to walk. The traveling frame 601 is correspondingly mounted on the vehicle body 700. In this embodiment, the four traveling devices 600 are all structures with driving members 602, and the driving members 602 can drive the traveling wheels 603 to rotate around their own axes or rotate around vertical axes, so that the automated guided vehicle can flexibly move forward, move backward, and steer. The driving member 602 may be a plurality of members, each of which drives the traveling wheel 603 to perform different motions. In other configurations not shown, a portion of the walking device 600 may have the driving member 602, and another portion of the walking device 600 may have no driving member 602.

Still referring to fig. 5, the upper bracket 500 mainly includes a main frame 502, an abutting plate 501 and a supporting beam 503 fixed on the main frame 502, and a stopper 504 protruding upward from the supporting beam 503.

The main frame 502 is a rectangular frame structure, and referring to fig. 6, two sides of the main frame 502 are respectively provided with an upper rail 5021, the upper rail 5021 extends along the length direction of the main frame 502, and the upper rails 5021 on the two sides are opposite. The main frame 502 may be formed by bending and splicing plates or assembling profiles.

As shown in fig. 5, the abutment plate 501 extends in the width direction of the main frame 502, and may be fixed to the main frame 502 by welding.

Referring to fig. 5 and 6, in the present embodiment, the number of the supporting beams 503 is two, the two supporting beams are respectively close to two ends of the main frame 502, each supporting beam 503 extends along the width direction of the main frame 502, and two ends of the supporting beam 503 respectively extend outwards beyond two sides of the main frame 502. The two sides of the main frame 502 are also connected to the bottom of the support beam 503 through support plates 505, respectively.

The stop block 504 is mounted on the upper surface of the joist 503 near the end of the joist 503. As shown in FIG. 6, the stop block 504 is removably attached to the joist 503 by fasteners 506.

The supporting beam 503 and the main frame 502 can bear the load of the vehicle carrying board 800 together, two ends of the supporting beam 503 exceed the main frame 502 to support the vehicle carrying board 800 in the width direction, and the limiting block 504 protrudes out of the supporting beam 503 to limit the vehicle carrying board 800, so that the position of the vehicle carrying board 800 on the upper bracket 500 is conveniently positioned. The limiting block 504 is detachably connected with the supporting beam 503, and when the limiting block 504 is damaged, the maintenance and the replacement can be facilitated.

Referring to fig. 2 and 5, the lifting device 100 of the present embodiment mainly includes a lifting mechanism 1, a connecting arm 2 hinged to the lifting mechanism 1, and a driving structure 3 connected to and driving the connecting arm 2 to rotate. The upper end of the lifting mechanism 1 is connected to the upper bracket 500, and the lower end of the lifting mechanism 1 is connected to the vehicle body 700. The driving structure 3 drives the lifting mechanism 1 to lift through the connecting arm 2, so as to drive the upper bracket 500 to lift relative to the vehicle body 700.

Specifically, the lifting mechanism 1 is of a scissor structure, and includes a first lifting unit 11 and a second lifting unit 12 hinged together, and a limiting member 13 disposed on the second lifting unit 12. The middle portion of the first elevation unit 11 and the middle portion of the second elevation unit 12 are hinged by a hinge shaft 14 so that the first elevation unit 11 and the second elevation unit 12 can be switched between the stowed state and the deployed state.

The first lifting unit 11 mainly includes two first legs 111 spaced apart from each other, a first lower mounting shaft 112 connected to lower ends of the two first legs 111, and an upper mounting shaft 113 connected to upper ends of the two first legs 111. The first leg 111, the first lower mounting shaft 112 and the upper mounting shaft 113 form a frame structure of a substantially rectangular shape for the first elevating unit 11.

The first leg 111 may be made of a square tube, a channel, or a plate by splicing. The middle part of each first leg 111 is provided with a first hinge hole 1111 which penetrates through, and the axes of the first hinge holes 1111 of the two first legs 111 are on the same straight line.

The first lower mounting shaft 112 is adapted to be hinged to the vehicle body 700. Both ends of the first lower mounting shaft 112 respectively extend outward beyond the two first legs 111. In the present embodiment, a mounting seat 114 for mounting the driving mechanism 3 is further disposed on the first lower mounting shaft 112, and the mounting seat 114 is located between the two first legs 111.

The upper mounting shaft 113 is used for connecting the upper bracket 500, two ends of the upper mounting shaft 113 respectively extend out of the two first legs 111, and two ends of the upper mounting shaft 113 are respectively provided with an upper slider 115 for sliding fit with the upper rail 5021 of the upper bracket 500.

The second lifting unit 12 includes two spaced apart second legs 121, a second lower mounting shaft 122 connected to lower ends of the two second legs 121, and a support plate 123 connected to upper ends of the two second legs 121. The second leg 121, the second lower mounting axle 122 and the fulcrum 123 allow the second lifting unit 12 to also form a generally rectangular frame structure.

The second leg 121 has a similar structure to the first leg 111, and a second hinge hole 1211 is formed through a middle portion of the second leg 121.

In this embodiment, the support plate 123 connects the upper ends of the two second legs 121 together to form a whole, and the upper ends of the two second legs 121 are further respectively connected with the hinge seats 125 for forming a hinge connection with the upper bracket 500.

The second lower mounting shaft 122 is used for connecting the vehicle body 700, two ends of the second lower mounting shaft 122 respectively extend out of the two second legs 121, and two ends of the second lower mounting shaft 122 are respectively provided with a lower slider 124 for sliding fit with the lower rail 703 of the vehicle body 700.

The limiting member 13 is connected to the two second legs 121 of the second lifting unit 12. In this embodiment, the limiting member 13 includes a first limiting plate 131 and a second limiting plate 132. The first and second stopper plates 131 and 132 are alternately arranged with respect to the second hinge hole 1211. In other embodiments, the limiting member 13 may only include the first limiting plate 131 or only include the second limiting plate 132.

The interval between the two second legs 121 of the second elevating unit 12 is smaller than the interval between the two first legs 111 of the first elevating unit 11 so that the two second legs 121 are installed between the two first legs 111. The second hinge hole 1211 of the second leg 121 communicates with the first hinge hole 1111 of the first leg 111 and is hinged by the hinge shaft 14. In the illustrated structure, the hinge shaft 14 is divided into two parts, and each hinge shaft 14 hinges a first leg 111 and a second leg 121 together to facilitate assembly. In other constructions, the hinge shaft 14 may be a unitary shaft extending through the two first legs 111 and the two second legs 121 to form a hinge.

Referring to fig. 7, the connecting arm 2 includes two connecting plates 21 arranged in parallel at intervals, a connecting shaft 22 connecting one ends of the two connecting plates 21, and a sleeve 23 sleeved on the connecting shaft 22.

The connecting plate 21 is provided with a mounting hole 211 to be hinged on the hinge shaft 14. One end of the connecting plate 21 is provided with a connecting hole 212 for connecting the connecting shaft 22, an end edge 213 of the end of the connecting plate 21 is approximately in the shape of an arc surface, and the central axis of the arc surface and the axis of the connecting hole 212 are on the same straight line. The other end of the connecting plate 21 is formed as an extended end 214 extending from the mounting hole 211 in a direction away from the connecting hole 212.

Both ends of the connecting shaft 22 extend into the connecting holes 212 of the two connecting plates 21, and are connected and fixed to the connecting plates 21 by bolts (not numbered in the figure) passing through the side surfaces of the connecting plates 21.

The sleeve 23 mainly includes a sleeve main body 231 and a spacer 232 detachably mounted on the outer periphery of the sleeve main body 231.

The sleeve main body 231 is provided with a through-hole 2311 to be fitted to the connecting shaft 22, and the sleeve main body 231 is fixedly connected to the connecting shaft 22 by a fastener 233 such as a bolt. The sleeve body 231 is provided at its outer periphery with a protruding hold-up portion 2312, the hold-up portion 2312 protruding outward beyond the end edge 213 of the connecting plate 21, the hold-up portion 2312 being adapted to abut the upper bracket 500 upward. The upper support portion 2312 is substantially rectangular in shape, and has a receiving groove 2313 on its surface.

The spacer 232 is fitted in the receiving groove 2313 and fixed to the sleeve body 231 by a screw 234. The surface of the shim 232 forms a planar ride-up surface 2321 to make planar contact with the upper bracket 500. In this embodiment, the gasket 232 and the sleeve main body 231 are detachably connected, and the gasket 232 can be replaced at any time according to the use condition. In other configurations not shown, the housing groove 2313 and the spacer 232 may be eliminated, and the surface of the lifting portion 2312 may be used as the lifting surface 2321.

Referring to fig. 2 and 5, the connecting arm 2 is integrally located between the two second legs 121 of the second lifting unit 12, the two connecting plates 21 of the connecting arm 2 are respectively opposite to the two second legs 121, and the connecting plates 21 are hinged to the hinge shaft 14 through mounting holes 211 formed therein. When the link plate 21 rotates with respect to the second lifting unit 12, the link plate 21 can be brought into contact with the stopper 13. When the connecting arm 2 abuts against the stopper 13, the lower end of the connecting arm 2 does not go beyond the second leg 121.

With continued reference to fig. 5, the drive structure 3 includes a hydraulic cylinder 31 and a corresponding hydraulic control system (not shown).

The hydraulic cylinder 31 includes a cylinder body 311 and a piston rod 312 embedded in the cylinder body 311, the hydraulic cylinder 31 is connected to a hydraulic control system through a hydraulic pipeline (not shown in the figure), and the hydraulic control system controls the hydraulic pressure in the cylinder body 311 to control the piston rod 312 to extend and retract relative to the cylinder body 311.

In the present embodiment, two parallel hydraulic cylinders 31 are provided. The lower ends of the cylinder bodies 311 of the two hydraulic cylinders 31 are hinged to the mounting seats 114 at the lower end of the first lifting unit 11, and the upper ends of the piston rods 312 of the two hydraulic cylinders 31 are hinged to the connecting shaft 22 of the connecting arm 2. The expansion and contraction of the piston rod 312 relative to the cylinder 311 drives the connecting arm 2 to rotate relative to the hinge shaft 14. In this embodiment, the hydraulic cylinder 31 and the first lifting unit 11 are assembled together to form an integral modular unit, which facilitates the integral installation of the lifting device 100 on the vehicle body 700.

When the lifting device 100 is attached to the upper bracket 500 and the vehicle body 700, the upper bracket 500 is connected to the upper end of the lifting mechanism 1, and the vehicle body 700 is connected to the lower end of the lifting mechanism 1. Specifically, the first lower mounting shaft 112 of the first lifting unit 11 is hinged to the vehicle body 700, the upper mounting shaft 113 of the first lifting unit 11 is movably mounted on the upper bracket 500 through the upper slider 115, and the upper slider 115 is in sliding fit with the upper rail 5021 of the upper bracket 500; the second lower mounting shaft 122 of the second lifting unit 12 is movably mounted on the vehicle body 700 through the lower slider 124, the lower slider 124 is slidably engaged with the lower rail 703 of the vehicle body 700, and the upper ends of the two second legs 121 of the second lifting unit 12 are hinged to the upper bracket 500.

Referring to fig. 8 to 11, the operation principle of the lifting device 100 of the present embodiment driving the upper bracket 500 to lift is as follows:

as shown in fig. 8, when the lifting mechanism 1 of the lifting device 100 is in the stowed state, the first lifting unit 11 and the second lifting unit 12 are stacked together, the piston rod 312 of the hydraulic cylinder 31 of the drive mechanism 3 is housed in the cylinder 311, and at this time, the upper bracket 500 is at the lowest position, and the link arm 2 is at the initial position where it does not contact with both the upper bracket 500 and the stopper 13.

When it is desired to lift the upper carriage 500, the drive mechanism 3 is activated, the piston rod 312 of the hydraulic cylinder 31 is extended, and the drive link arm 2 is rotated from the initial position shown in fig. 8 to the first position shown in fig. 9.

As shown in fig. 9, in the first position, the rising portion 2312 of the link arm 2 is just in contact with the abutment plate 501 of the upper bracket 500, and the rising portion 2312 abuts the upper bracket 500 upward. However, at this time, the lifting mechanism 1 is still in the stowed state, and the upper tray 500 is also still at the lowest position.

In the process of driving the connecting arm 2 to rotate from the initial position to the first position, the lifting mechanism 1 and the upper bracket 500 do not act, the hydraulic cylinder 31 only needs to drive the connecting arm 2 to rotate, and the pressure requirement on the hydraulic cylinder 31 is low. When the link arm 2 reaches the first position, the load of the upper bracket 500 is transmitted to the hinge shaft 14 of the lifter 1 via the abutment plate 501 and the lifter 2312, and the hydraulic cylinder 31 starts to receive a force.

Referring to fig. 10, at this time, an acting arm L0 of the load F0 of the upper bracket 500 on the hinge shaft 14 is a horizontal connecting line distance between the center of the lifting portion 2312 and the center of the hinge shaft 14, an acting arm L1 of the lifting force F1 of the hydraulic cylinder 31 on the hinge shaft 14 is a vertical distance between the center of the hinge shaft 14 and the central axis of the hydraulic cylinder 31, and F1 is F0 × L0/L1.

On the other hand, if no upper bracket 2312 contacts the upper bracket 500, the force arm L2 of the hinge shaft 14 by the load of the upper bracket 500 at the same position will be a horizontal line between the center of the hinge shaft 14 and the rotation axis of the lower end of the first elevation unit 11 hinged on the vehicle body 700, and the force arm L2 is schematically shown in fig. 9.

In contrast, since the upper bracket 2312 of the connecting arm 2 abuts the upper bracket 500 upward, the point of application of the load of the upper bracket 500 to the hinge shaft 14 of the lifting mechanism 1 is changed, and the arm L0 of the load F0 of the upper bracket 500 to the hinge shaft 14 of the lifting mechanism 1 is much shorter than the arm L2 when the upper bracket 2312 does not contact the upper bracket 500, so that the moment required for lifting the upper bracket 500 can be greatly reduced, and accordingly, the lifting force F1 required by the driving structure 3 to lift the upper bracket 500 is reduced, and therefore, the driving structure 3 can more easily break through the bottleneck position at the beginning of lifting to lift the upper bracket 500.

In this embodiment, the lifting portion 2312 is abutted to the abutting plate 501 of the upper bracket 500 through the lifting surface 2321 of the gasket 232, and the lifting surface 2321 is in planar contact with the abutting plate 501, so that the contact area is relatively large, and the stress can be dispersed. Simultaneously, gasket 232 can be dismantled with sleeve main part 231, can also conveniently change gasket 232 after gasket 232 wears out.

Referring next to fig. 11, further extension of the piston rod 312 of the hydraulic cylinder 31 of the drive structure 3 from the position shown in fig. 9 drives the connecting arm 2 from the first position shown in fig. 9 to the second position shown in fig. 11.

In the process of rotating the link arm 2 from the first position to the second position, the rising portion 2312 is always kept in contact with the upper bracket 500 by the spacer 232, and the upper bracket 500 is driven to rise by a small amount. At the same time, the connecting arm 2 is further rotated relative to the second lifting unit 12, and in the second position, the lower end of the connecting arm 2 abuts against a stopper 13 located on the second lifting unit 12. Specifically, in the present embodiment, a side edge of the connecting plate 21 abuts against the first stopper plate 131, and a side edge of the extending end 214 abuts against the second stopper plate 132.

Referring to fig. 11 and 8 in comparison with the situation of fig. 8, when the connecting arm 2 is in the second position shown in fig. 11, the central axis of the hydraulic cylinder 31 has a larger angle with the horizontal plane, and the hydraulic cylinder 31 has broken through the bottleneck position at the beginning of lifting. When the piston rod 312 of the hydraulic cylinder 31 continues to extend to drive the connecting arm 2 to rotate, the supporting portion 2312 of the connecting arm 2 is separated from the upper bracket 500, and since the connecting arm 2 abuts against the limiting member 13, the connecting arm 2 can drive the second lifting unit 12 to rotate, so that the first lifting unit 11 and the second lifting unit 12 gradually change to the unfolded state shown in fig. 3, and the upper bracket 500 is continuously lifted.

During the gradual expansion of the first lifting unit 11 and the second lifting unit 12, the upper mounting shaft 113 of the first lifting unit 11 slides along the upper rail 5021 of the upper bracket 500, and the second lower mounting shaft 122 of the second lifting unit 12 slides along the lower rail 703 of the vehicle body 700, respectively. When the upper bracket 500 reaches a predetermined height position, the position of the upper bracket 500 may be maintained by providing a limit structure on the vehicle body 700 and/or the upper bracket 500 to correspondingly limit the sliding of the upper mounting shaft 113 and/or the second lower mounting shaft 122, or by using another limit means.

When the upper bracket 500 needs to be lowered, the hydraulic cylinder 31 is relieved, the load of the upper bracket 500 causes the piston rod 312 of the hydraulic cylinder 31 to slowly retract into the cylinder body 311, and the first lifting unit 11 and the second lifting unit 12 rotate relatively to gradually retract until the retracted state shown in fig. 8 is restored.

In the present embodiment, a case where the lifting mechanism 1 includes two lifting units, i.e., the first lifting unit 11 and the second lifting unit 12, is exemplarily described, and the lifting mechanism 1 has a simple structure, a small number of structural members, and is convenient to assemble.

In other structures not shown, the lifting mechanism 1 may also include a greater number of lifting units, the lifting units are connected to form a scissors structure, a limiting member 13 may be disposed on one of the lifting units, and the driving structure 3 and the connecting arm 2 are used to drive the lifting units to rotate. In some embodiments, the driving structures 3 and the connecting arms 2 may also be provided in multiple sets, and the limiting members 13 are correspondingly provided on the plurality of lifting units, so that the driving structures 3 are connected to and drive the corresponding connecting arms 2 to rotate, and the connecting arms 2 drive the corresponding lifting units to rotate.

According to the above description of the operation principle of the lifting apparatus 100, the lifting apparatus 100 drives the connecting arm 2 to drive the lifting mechanism 1 to lift by using the driving structure 3, and the connecting arm 2 can share the load of the driving structure 3 at the beginning of lifting, so that the lifting height of the upper bracket 500 can be reliably controlled by using the same driving structure 3, so as to facilitate the vehicle carrying board 800 and the vehicle to be carried to the parking spaces 902 with different heights. In particular, when the driving mechanism 3 drives the connecting arm 2 to rotate to the first position at the beginning of lifting, the supporting part 2312 of the connecting arm 2 abuts against the upper bracket 500 upwards, the force application point of the load of the upper bracket 500 actually acting on the hinge shaft 14 of the lifting mechanism 1 is changed, the acting force arm of the load of the upper bracket 500 on the hinge shaft 14 of the lifting mechanism 1 is shortened, the moment required for lifting the upper bracket 500 is reduced, and accordingly, the lifting force required by the driving mechanism 3 for lifting the upper bracket 500 is reduced, so that the driving mechanism 3 can more easily break through the bottleneck position at the beginning of lifting to lift the upper bracket 500. The lifting device 100 does not generate extra load to the vehicle body 700 at the initial stage of lifting to cause structural deformation of the vehicle body 700, so that the structural stability of the vehicle body 700 is improved, and the safety of the whole automatic guided vehicle is further improved.

Second embodiment of automated guided vehicle:

referring to fig. 12, the automated guided vehicle of the present embodiment is different from the first embodiment in that the lifting device 100 is slightly different.

In this embodiment, the limiting member of the lifting device 100 only includes the first limiting plate 131. The two ends of the first limiting plate 131 are respectively connected to the two second legs 121 of the second lifting unit 12, and the two ends of the first limiting plate 131 have a larger width than the middle thereof and have a better connection strength with the second legs 121. Note that, in fig. 12, in order to clearly illustrate the structure of the connecting arm 2, only one of the legs is illustrated for each of the first lifting unit 11 and the second lifting unit 12, and the illustration of the other leg is omitted.

When the connecting arm 2 is driven to rotate by the driving structure 3, the lateral edges of the two connecting plates 21 can abut against the first limiting plate 131 to drive the second lifting unit 12 to rotate, and further drive the first lifting unit 11 and the second lifting unit 12 to relatively expand. The connecting arm 2 further comprises a fixing plate 25, and two ends of the fixing plate 25 are respectively connected with the extending ends 214 of the two connecting plates 21, so that the structure of the connecting arm 2 is more stable.

In this embodiment, the end of the connecting arm 2 connected to the driving structure 3 is also provided with a lifting portion 2312, and at the beginning of lifting the driving structure 3, the lifting portion 2312 is abutted upwards against the upper bracket 500 to facilitate lifting in the initial lifting stage. The specific operation principle refers to the first embodiment and will not be described in detail.

The automated guided vehicle of the embodiment can be applied to a parking system as well, and the specific working process can refer to the first embodiment.

The third embodiment:

referring to fig. 13 to 16, the automated guided vehicle of the present embodiment is different from the first embodiment in that the lifting device 100 is slightly different, and is embodied in a structure of the connecting arm 2.

Referring mainly to fig. 14, in the present embodiment, the connecting arm 2 includes two connecting plates 21 disposed in parallel and spaced apart, a connecting shaft 22 connecting one ends of the two connecting plates 21, and a sleeve 23 sleeved on the connecting shaft 22. The sleeve 23 is cylindrical and rotatably fitted over the connecting shaft 22. The rotational axis of the sleeve 23 is also the central axis of the connecting shaft 22.

Referring to fig. 14 and 15, in the present embodiment, the outer periphery of the sleeve 23 is substantially flush with the end edge 213 of the connecting plate 21. When the link arm 2 is driven to rotate by the drive structure 3 to the first position, i.e. the position shown in fig. 15, the outer circumferential surface of the sleeve 23 abuts the upper bracket 500 upwards, i.e. the outer circumferential surface of the sleeve 23 forms a raised portion for abutting the upper bracket 500. The point of application of the load of the upper bracket 500 actually acting on the hinge shaft 14 can also be changed by the contact of the sleeve 23 with the upper bracket 500, so that the lifting force required at the beginning of lifting of the actuating structure 3 can be optimized, facilitating the lifting operation.

When the connecting arm 2 is driven by the driving structure 3 to rotate from the first position shown in fig. 15 to the second position shown in fig. 16, the contact position of the sleeve 23 and the upper bracket 500 changes, and since the sleeve 23 can rotate, rolling contact can be formed between the sleeve 23 and the upper bracket 500, and the friction force is reduced. When the connecting arm 2 is in the second position shown in fig. 16, the lower end of the connecting arm 2 abuts against the limiting member 13 on the second lifting unit 12, so that when the driving mechanism 3 further drives the connecting arm 2 to rotate, the connecting arm 2 will drive the second lifting unit 12 to rotate together, and the sleeve 23 of the connecting arm 2 will be separated from the upper bracket 500.

This embodiment still makes use of the abutment of the sleeve 23 with the upper bracket 500, and the sleeve 23 can be replaced when the sleeve 23 becomes worn. In some embodiments, the outer circumference of the sleeve 23 may extend beyond the end edge 213 of the connection plate 21, so that a gap is formed between the connection plate 21 and the upper bracket 500, thereby better avoiding the wear of the connection plate 21.

The working principle of the automated guided vehicle of this embodiment may refer to the first embodiment, and the automated guided vehicle of this embodiment may also be applied to a parking system, and specifically refer to the above description, and will not be described herein again.

While the present invention has been described with reference to several exemplary embodiments, it is understood that the terminology used is intended to be in the nature of words of description and illustration, rather than of limitation. As the present invention may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the meets and bounds of the claims, or equivalences of such meets and bounds are therefore intended to be embraced by the appended claims.

Claims (10)

1. An automated guided vehicle, comprising:

a vehicle body;

the traveling device is arranged on the vehicle body to drive the vehicle body to travel;

the lifting device comprises a lifting mechanism in a scissor fork structure, a connecting arm hinged with the lifting mechanism and a driving structure connected with and driving the connecting arm to rotate; one end of the lifting mechanism is connected with the vehicle body; the driving structure can drive the connecting arm to rotate under the lifting stroke to drive the lifting mechanism to lift;

and the upper bracket is connected to the other end of the lifting mechanism, lifted by the lifting mechanism and capable of being lifted relative to the vehicle body, and is used for supporting a vehicle carrying plate.

2. The automated guided vehicle of claim 1, wherein the linkage arm is provided with a top mount at an end proximate the drive structure connection; when the driving structure drives the connecting arm to rotate to the first position under the lifting stroke, the upper supporting part is abutted to the upper bracket.

3. The automated guided vehicle of claim 2, wherein the upper carriage includes a main frame and an abutment plate secured to the main frame; when the upper support part is located at the first position, the upper support part is abutted to the abutting plate.

4. The automated guided vehicle of claim 2, wherein the connecting arm comprises two connecting plates arranged in parallel at intervals, a connecting shaft connecting one ends of the two connecting plates, and a sleeve detachably sleeved on the connecting shaft, and the upper supporting part is arranged on the periphery of the sleeve; the driving structure is hinged with the connecting shaft.

5. The automated guided vehicle of claim 2, wherein the lifting mechanism comprises a first lifting unit, a second lifting unit, a hinge shaft, and a limiting member; the middle parts of the two lifting units are hinged through the hinge shaft; the limiting piece is arranged on the second lifting unit; the connecting arm is hinged to the hinged shaft, and when the driving structure drives the connecting arm to rotate from the first position to the second position under the lifting stroke, the connecting arm is abutted to the limiting part to drive the second lifting unit to rotate.

6. The automated guided vehicle of claim 5, wherein the vehicle body is provided with lower rails on both sides thereof, and the upper bracket is provided with upper rails on both sides thereof; the lower end of the first lifting unit is hinged with the vehicle body, and the upper end of the first lifting unit is in sliding fit with the upper rail; the lower end of the second lifting unit is in sliding fit with the lower rail, and the upper end of the second lifting unit is hinged to the upper bracket.

7. The automated guided vehicle of claim 6, wherein the drive mechanism comprises a hydraulic cylinder, a lower end of the hydraulic cylinder is hinged to a lower end of the first lifting unit, and an upper end of the hydraulic cylinder is connected to the connecting arm.

8. The automated guided vehicle of claim 5, wherein the first lifting unit comprises two first legs spaced apart from each other, and the second lifting unit comprises two second legs spaced apart from each other, the two second legs being located between the two first legs; the limiting piece is connected with the two second supporting legs; the connecting arm is located between the two second support legs.

9. The automated guided vehicle of any one of claims 1-8, wherein the upper bracket comprises a support beam and a plurality of limit blocks protruding upwards from the support beam, the limit blocks are used for limiting the vehicle carrying board, and the limit blocks are detachably connected with the support beam.

10. A parking system, comprising:

the parking garage comprises a plurality of stand columns which are arranged in an array manner, and two layers of parking spaces which are spaced along the height direction are arranged between two columns of stand columns;

the vehicle carrying plate is used for carrying vehicles and can be detachably connected with the upright post to be fixed on any layer of parking space;

the automated guided vehicle of any one of claims 1-9, wherein an upper carriage of the automated guided vehicle supports the vehicle loading plate, and the automated guided vehicle is capable of entering the parking garage via its running gear.

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