Device for retrieving components from a storage systemTechnical Field
The present invention relates to an apparatus for retrieving components from a storage system. In particular, the present invention relates to a robotic device for handling storage containers or bins within a store containing a grid of stacked parts.
Background
Certain commercial and industrial activities require systems capable of storing and retrieving a large number of different products. One known system for storing and retrieving items in multiple product lines includes placing storage bins or containers on rows of shelves that are positioned across aisles. Each box or container holds a plurality of like products. The aisles between rows of racks may be used for retrieval of desired products by operators or robots walking around (circulation) in the aisles. However, the need to provide aisle space to access the products means that the storage density of such systems is relatively low. In other words, the space usage actually used to store the products is relatively small compared to the space usage required by the entire storage system.
An alternative approach to significantly increase storage density is to stack the containers one on top of the other in a stack and then place the stack in rows and access the containers from above, thus eliminating the need for aisles between rows of containers and allowing more containers to be stored in a given space.
Methods for handling stacked containers in rows have been known for decades. In some such systems, as described in US 2,701,065, individual containers are stacked in rows to reduce storage volume so that while storing such containers, dedicated containers can still be accessed as needed. A given container may be accessed by a relatively complex lifting mechanism for stacking or removing the given container from the stack of containers. In many cases, however, such systems are not cost effective and most of them have been commercialized for storage and handling of large shipping containers.
Solutions have been developed to provide mechanical means for retrieving and storing special containers using stacks of individual containers, as described in EP 0767113B (Cimcorp). Cimcorp discloses a mechanism for retrieving a plurality of stacked containers using a rectangular tube robotic load handler that is lowerable around the stack of containers and configured to grasp a container at any level in the stack. In this way, several containers can be lifted simultaneously from a stack. The movable rectangular tube can move several containers from the top of one stack to the top of another or from one stack to an external location or vice versa. Such systems are particularly useful when all of the containers in a stack hold the same product (also referred to as a single item stack). The load handler may be used to move containers between single item stacks, such as placing multiple containers containing the same product into a warehouse, and picking one or more containers from two or more single item stacks and generating a multiple item output stack. For example, crates for vegetables are picked in a central warehouse and a multi-item order is generated for distribution to retail stores.
In the system described in the Cimcorp patent, the rectangular tube must be at least as tall as the largest stack of containers so that the highest stack of containers can be removed in one operation. Accordingly, if applied to enclosed spaces such as warehouses, the maximum height of the stack is limited by the need to accommodate rectangular tubes of the load handlers. In addition, the system is less suitable for picking individual containers from a stack of items.
Online retail establishments that sell multiple product lines (e.g., online retailers and supermarkets) require systems that can store tens or even hundreds of thousands of different product lines. In such cases, it is impractical to use a single item stack because of the large footprint required to accommodate all of the required stacks. Furthermore, it is desirable to be able to store only a small number of individual items, such as perishable goods or infrequently ordered goods, which makes the single item stacking scheme inefficient.
Therefore, in some applications, multiple stacks of items (with different products in the containers forming each stack) may be preferred to maximize the storage density of the system. The stored items must be accessible at a reasonable speed and ease of use in order to efficiently sort out from the storage system a number of different kinds of items required for fulfilling a customer order, even if some of the required items are stored in a lower level of a stack on which several other containers are stacked.
The contents of international patent WO 98/049075a (autostore), which is incorporated herein by reference, describes a system for placing a stack of multiple item containers in a frame-like structure. The system is schematically illustrated in figures 1-4 of the accompanying drawings.
As shown in fig. 1 and 2, stackable containers, boxes 10, are stacked one on top of the other to form a stack 12. The stack 12 is placed in a grid framework structure 14 in a warehouse or production environment. Fig. 1 is a perspective view of the frame structure 14, and fig. 2 is a top view of a stack 12 of boxes 10 stacked in the frame structure 14. Each box 10 typically contains a plurality of product items (not shown), and the products in each box 10 may be the same type of product or different types of products, depending on the application.
The frame structure 14 includes a plurality of vertical members 16, the plurality of vertical members 16 supporting horizontal members 18, 20. A first set of parallel horizontal members 18 is vertically disposed relative to a second set of parallel horizontal members 20 forming a plurality of horizontal grid structures supported by the vertical members 16. The members 16, 18, 20 are typically made of metal. The boxes 10 are stacked between the members 16, 18, 20 of the frame structure 14 such that the frame structure 14 prevents horizontal movement of the stack 12 of boxes 10 and guides vertical movement of the boxes 10.
The topmost layer of the frame structure 14 includes rails 22, the rails 22 being arranged in a grid pattern across the top of the stack 12. As further shown in fig. 3 and 4, the track 22 supports a plurality of robotic load handling devices 30. A first set 22a of parallel rails 22 guide the load handling apparatus 30 for movement in a first direction (X-axis direction) on top of the frame structure 14, and a second set 22b of parallel rails 22, perpendicular to the first set 22a, guide the load handling apparatus 30 for movement in a second direction (Y-axis direction) perpendicular to the first direction. In this way, the load handling apparatus 30 can be moved laterally on the rails 22 in an X-Y two-dimensional horizontal plane to a position above any of the stacks 12.
The load handling device 30 is further described in norwegian patent No. 317366, the content of which is incorporated by reference into the present application. Fig. 3 (a) and 3 (b) are perspective views of the rear and front of the load handling device 30, respectively, and fig. 3 (c) is a perspective view of the front of the load handling device 30 lifting the box 10.
Each load handling device 30 comprises a carrier 32 arranged to slide in an X-direction and a Y-direction on the rails 22 on the frame structure 14 above the stack 12. The first set of wheels 34 comprises a pair of wheels 34 on the front of the vehicle 32 and a pair of wheels 34 on the rear of the vehicle 32, arranged to engage (engage) two adjacent tracks of the first set 22a of the tracks 22. Similarly, the second set of wheels 36 comprises a pair of wheels 36 on each side of the vehicle 32, arranged to engage with two adjacent rails of the second set 22b of the rails 22. Each set of wheels 34, 36 can be raised or lowered so that the first set of wheels 34 or the second set of wheels 36 can engage the tracks 22a and 22b, respectively, at any time.
When the first set of wheels 34 engages the first set of tracks 22a, the second set of wheels 36 are lifted off the tracks 22. The wheels 34 are driven by a transmission mechanism (not shown) built into the carrier 32 to move the load handling apparatus 30 in the X-axis direction. To move the load handling device 30 in the Y-axis direction, the first set of wheels 34 is raised off the rails 22 and the second set of wheels 36 is lowered into engagement with the second set of rails 22 b. The transmission mechanism then drives the second set of wheels 36 in the Y-axis direction.
The load handling device 30 is also provided with a lifting device 40. The lifting device 40 includes a boom 42 extending laterally from the top of the vehicle 32. The grab plate 44 is suspended from the boom 42 by four cables 46. The cable 46 is connected to a winding mechanism (not shown) built into the vehicle 32. The cable 46 may extend up or down from the boom 42 so that the position of the grab plate 44 may be adjusted in the Z-axis direction relative to the vehicle 32.
The catch plate 44 is adapted to engage the top of the case 10. For example, the gripping plate 44 may include prongs (not shown) that engage corresponding holes (not shown) in the rim forming the upper surface of the case 10, and a sliding clamp (not shown) that is engageable with the rim for gripping the case 10. The gripper is driven by a suitable transmission mechanism built into the gripper plate 44, engaging the case 10, driven and controlled by a signal transmitted by the cable 46 or a separate control cable (not shown).
To remove a box 10 from the top of the stack 12, the load handling apparatus 30 is moved in the X and Y directions as necessary to position the gripper plate 44 over the stack 12. The catch plate 44 is then lowered vertically downward in the Z-axis direction to engage the box 10 at the top of the stack 12, as shown in fig. 3 (c). The grab plate 44 grabs the case 10 and is then lifted upward by the cable 46 to remove the case 10. After moving vertically to the top, the case 10 is stowed under the boom 42 and above the level of the track 22. In this way, the load handling apparatus 30 can carry the box 10 to a different location, moving along the X-Y plane, and transport the box 10 to another location. The cable 46 is of sufficient length to allow the load handling apparatus 30 to retrieve and place boxes at any level of the stack 12, including the bottom most level. The vehicle 32 also has sufficient weight to counterbalance the weight of the case 10 and remain stable during lifting. The weight portion of the vehicle 32 contains the weight of the batteries driving the drive mechanism of the wheels 34, 36.
As shown in fig. 4, a plurality of identical load handling devices 30 may be provided, each load handling device 30 being operable simultaneously to increase the overall processing capacity of the system. The system shown in fig. 4 includes two specific locations, namely, the job port 24, through which the boxes 10 are transported into and out of the system 24. Associated with each port 24 is an additional conveyor system (not shown) by which cases 10 delivered to the port 24 by the load handling apparatus 30 may be transported to another location, for example, to a picking station (not shown). Similarly, the boxes 10 may be transported by the conveyor system from an external location to a job port 24, for example, from a box loading station (not shown), and transported by the load handling apparatus 30 to the stack 12 to replenish the system inventory.
Each load handling device 30 can lift and move one case 10 at a time. If the box 10 to be retrieved ("target box") is not on top of the stack 12, the box 10 covered thereon ("non-target box") must first be removed to access the target box 10.
Each of the load handling devices 30 is controlled by a central computer. Each individual case 10 in the system can be tracked so that the appropriate case 10 can be retrieved, transported and placed as needed.
The system as shown in fig. 1-4 has many advantages and is suitable for various storage and retrieval operations. The system particularly allows for high density storage of products, storing various items in the boxes 10 in a very economical manner, while also providing for reasonably economical access to all of the boxes 10 when picking is required.
For high capacity systems where operating speed is critical, it is important to maximize the performance of each of the load handling devices, such as operating speed, battery life, reliability, boost capability, and stability. It is therefore desirable to provide load handling devices with improved performance in one or more of these areas.
It may also be desirable to increase the number of load handling devices in use at any one time, increasing the speed at which items are retrieved from the storage system. For example, our co-pending international patent No. PCT/GB2013/051215 (the contents of which are also incorporated herein by reference) describes a storage system that provides a plurality of two different types of load handling devices. One type of load handling apparatus is adapted to lift multiple bins from a stack in one operation, enabling a second type of single item bin load handling apparatus to acquire a target bin in the stack. In such cases, it is desirable to reduce the size of the load handling apparatus to minimize the obstruction of the optimal path of travel of one piece of equipment by other operating equipment.
Against this background, the present invention has been devised.
Disclosure of Invention
In one aspect, the invention relates to a load handling device for use in a storage system comprising a grid framework containing a plurality of stacks of containers. The load handling apparatus is arranged above the stack of containers and is capable of lifting a container from the stack and moving it laterally to another position. Preferably, each load handling device occupies substantially only one grid space in the storage system.
Accordingly, the present invention provides a load handling apparatus for lifting and moving containers stacked in a storage system comprising a plurality of rails or tracks arranged in a grid structure above the container stack. The grid structure includes a plurality of grid spaces, each stack occupying substantially only one grid space area. The load handling apparatus being configured to move laterally on rails or tracks above the stack, the load handling apparatus comprising a container receiving space which in use is located above the rails or tracks, and lifting means for lifting a container from the stack and into the container receiving space; wherein the load handling device, when in use, occupies substantially only one grid space area in the storage system.
A load handling apparatus according to one embodiment of the invention comprises a container receiving space for receiving a lifted container. The container receiving space is disposed below a vehicle module that houses, for example, a power supply component, a control component, a drive component, and a lifting component.
In a preferred embodiment of the invention, the load handling apparatus has a housing which substantially surrounds the container receiving space. The housing is preferably cuboidal.
By placing the high-volume components of the load handling apparatus above the container-receiving space, which are placed in the vehicle module on one side of the container-receiving space, the footprint of the load handling apparatus is reduced as compared to the cantilevered design described in patent No. 317366, which is shown in fig. 3 (a) -3 (c). The load handling apparatus of the present invention occupies space above only one stack of containers in the frame structure, which is an advantage over the cantilevered design that occupies space above two stacks as shown in fig. 3 (a) -3 (c). This means that by the present invention the operating efficiency of the storage system can be increased as the reduced footprint can accommodate more load handling equipment, thereby reducing the likelihood that one piece of equipment will obstruct the optimal path of another piece of equipment.
The load handling apparatus preferably comprises a set of wheels for supporting the load handling apparatus above the stack. For example, rails above the frame structure may guide the load handling apparatus to move laterally. The track may be of a grid structure, allowing the load handling apparatus to move in two dimensions in a horizontal plane. The wheels may engage the track. Two sets of wheels may be provided, one set engaging the first set of tracks to guide movement of the load handling apparatus in a first direction, and the other set engaging the second set of tracks to guide movement of the load handling apparatus in a second direction.
In one embodiment of the invention, the wheels are arranged at the periphery of the container receiving space. The wheels may be driven by one or more motors housed by the vehicle module. The driving force generated by the motor in the vehicle module may be transmitted to the wheel through a driving force transmitting means provided around the container receiving space. For example, the drive force transmitting means may comprise suitably configured pulleys and belts.
Alternatively, the wheel may comprise an integrated motor, for example, by integrating the motor in the hub. Thus, each wheel is a self-contained drive mechanism and no drive belt is required. This arrangement is advantageous because it reduces the size of the load handling apparatus, facilitating maintenance.
One or both sets of wheels may be configured to be raised and lowered relative to the other set of wheels. One or more wheel lift motors or other wheel lift devices may be built into the vehicle module for this purpose.
The carrier module may have a hoist or crane built therein to lift the container into the container receiving space. The lifting means may comprise one or more motors for lifting the container, each motor of the crane may be built into the carrier module.
The lifting device may comprise a gripping device configured to grip the container from above. The grasping device is suspended by a cable that can be extended and retracted from the vehicle, moving the grasping device vertically.
In another embodiment, the load handling apparatus is provided with lifting means configured to lift a container from a stack and place it into the container receiving space. The lifting means may comprise a pair of lifting arms arranged on either side of the container receiving space, in which case the lifting means may comprise gripping means mounted between the ends of the lifting arms for gripping a container from above.
The load handling apparatus preferably has a centre of mass which is substantially directly above the gripper means when the gripper means is lowered below the container receiving space.
In another embodiment, the lifting means comprises a bar or cable to engage with a vertical channel formed in the side wall of the container. The channel is accessible through an opening in the upper surface of each container. In this case, a space extending vertically is not required in the storage system.
The bar or cable may carry an anchoring mechanism for releasably engaging with the container. For example, the anchoring mechanism may comprise one or more laterally extendable arms for engaging with the container surface. The anchoring mechanism may be remotely operated, for example, by a wire passing through the bar or cable tubular bore.
A load handling device according to another embodiment of the invention comprises an upper portion, a lower portion including a container receiving space, and a hoist to lift a container into the container receiving space. The winding means preferably comprises a winding motor built into the upper portion above the container receiving space. The lower portion preferably includes a wheel assembly for assisting lateral movement of the load handling apparatus relative to the frame structure. The upper portion further includes at least one motor for driving one or more wheels of the wheel assembly.
The lower portion may comprise a frame structure for supporting the wheels of the wheeled landing gear. The frame structure may be arranged around the container receiving space. For example, the container receiving space may be fixed to four sides of the frame structure. One or more elements of the frame structure may be movable to raise and lower the first set of wheels relative to the second set of wheels to facilitate engagement of the first and second sets of wheels with the first and second sets of tracks or rails, respectively. The movable element of the frame structure may be driven by a motor built into the upper part of the load handling apparatus.
The load handling device of the invention is preferably a self-propelled robotic vehicle.
In another aspect, the invention relates to a storage system comprising a frame structure containing a plurality of stacks of containers, and one or more of the above load handling devices. Each load handling device occupies substantially one grid space, corresponding to the area occupied by only one container stack.
Accordingly, the present invention provides a storage system comprising: a first set of parallel rails or tracks and a second set of parallel rails or tracks extending transversely (transverse) to the first set in a substantially horizontal plane forming a grid structure comprising a plurality of grid spaces; a plurality of stacks of containers positioned below the track, each stack being configured to occupy substantially one grid space area; a load handling apparatus as described above, which moves laterally on said track above said stack, said load handling apparatus comprising a container receiving space which in use is located above the track or rails and lifting means for lifting containers from the stack and into said container receiving space; wherein the load handling device, when in use, occupies substantially only one grid space area in the storage system.
In another aspect, the invention relates to a storage system comprising a frame structure containing a stack of a plurality of containers, a first handling device capable of lifting a plurality of containers from the stack in one operation, and a second handling device capable of lifting one container and moving it laterally. The first processing device and the second processing device are arranged above the frame structure and can move independently to access different stacks. The second processing device is the same as the load processing device described above, and occupies substantially the same space as the space occupied by only one stack of containers.
In this respect, when it is desired to retrieve containers located in the middle or at the bottom of a stack, the first handling device is able to lift a plurality of containers from a stack in one operation, while the second handling device is able to lift a container and move it laterally, which provides an optimal solution. In this case, the target container can be retrieved by performing the lifting operation twice, which greatly improves the speed and efficiency of the retrieving process, compared to the prior art in which only one container can be lifted at a time.
The storage system also includes one or more port locations through which containers may be removed from and/or replenished to the storage system. The load handling apparatus of the present invention is capable of transporting a target container from a stack to a jobsite location. The container may comprise an open-topped box. The containers may be arranged to interlock or snap in a vertical direction when forming the stack.
Typically, multiple processing devices may be used to lift or move multiple containers simultaneously. The treatment devices may be of different types and may be selected based on cost and system energy consumption balance, and speed and flexibility of operation. One advantage of the present invention is that the load handling apparatus occupies space above only one stack, which can improve the efficiency of a multi-device system compared to the prior art where the load handling apparatus occupies two or more stack spaces. In a given system, efficiency may be increased by accommodating more load handling equipment, by optimizing the device movement path using space freed up by reducing the device footprint, or by combining both factors.
Preferred and/or optional features of the aspects of the invention described herein may be used alone or in appropriate combination with the other aspects of the invention described herein.
Drawings
FIG. 1 is a perspective view of a frame structure for storing a stack of boxes in a known storage system;
FIG. 2 is a schematic plan view of a portion of the frame structure of FIG. 1;
figures 3 (a) and 3 (b) are rear and front perspective views, respectively, of a known load handling apparatus for use with the frame structure shown in figures 1 and 2, and figure 3 (c) is a perspective view of the known load handling apparatus in use lifting a box;
fig. 4 is a schematic perspective view of a conventional storage system, which includes a plurality of load handling devices shown in fig. 3 (a), 3 (b) and 3 (c), and is disposed on the frame structure shown in fig. 1 and 2.
Embodiments of the invention are described, by way of example only, with reference to the remaining figures, in which like reference numerals correspond to like features.
FIG. 5 is a schematic perspective view of a load handling apparatus according to an embodiment of the present invention;
fig. 6 (a) and 6 (b) are perspective views of the load handling apparatus shown in fig. 5, and as shown in fig. 6 (a) and 6 (b), the load handling apparatus is partially divided to show the internal configuration of the device, and fig. 6(c) shows a possible system architecture of the device.
FIG. 7 is a schematic perspective view of a storage system including a plurality of known load handlers shown in FIGS. 3 (a), 3 (b), and 3 (c), and a plurality of load handlers shown in FIG. 5, disposed on the frame structure shown in FIGS. 1 and 2;
fig. 8, 9 and 10 are a side view, a perspective view and a top view, respectively, of a load handling apparatus according to another embodiment of the present invention, without the housing;
FIG. 11 is a schematic perspective view of the load handling apparatus of FIGS. 8-10, without the housing;
FIG. 12 is a side view of the load handling apparatus shown in FIGS. 8-11;
figure 13 is a schematic perspective view of a wheel suitable for use with the load handling apparatus of figures 8-12;
FIG. 14 is a schematic perspective view of a portion of a load handling apparatus according to another embodiment of the present invention;
FIGS. 15 and 16 are perspective and side views, respectively, of the internal components of the load handling apparatus of FIG. 14;
fig. 17 is a perspective view of a load handling apparatus according to a further embodiment of the present invention.
Detailed description of embodiments of the invention
Fig. 5 illustrates a load handling device 100 according to an embodiment of the invention. The load handling device 100 includes a vehicle 102 equipped with a hoisting or lifting mechanism 104 for lifting a storage container or box 106 (also referred to as a lift box) from above. The hoisting mechanism 104 includes a hoisting cable 108 and a grab plate 110. The gripping plate 110 is used to grip the top of the container 106 and lift it from the stack of containers 106 in the storage system shown in fig. 1 and 2.
As shown in fig. 6 (a) and 6 (b), the vehicle 102 includes an upper portion 112 and a lower portion 114.
The lower portion 114 is provided with two sets of wheels 116, 118 which run on tracks on top of the frame structure of the storage system. At least one wheel of each set of wheels 116, 118 may be driven to move the vehicle 102 along the X-axis and Y-axis directions, respectively, on the track. As described below, one or both sets of wheels 116, 118 may be moved vertically to lift each set of wheels off its respective track, thereby moving the vehicle 102 in a desired direction.
The wheels 116, 118 are disposed about the periphery of a chamber or recess 120 in the lower portion 114, i.e., a container receiving recess. The recess 120 is sized to receive the box 106 when the lifting mechanism 104 lifts the box 106, as shown in fig. 6 (a). While in the notch 120, the box 106 is lifted off the underlying track so that the vehicle 102 can be moved laterally to different positions. Once a target location is reached, such as another stack, an access point in the storage system, or a conveyor belt, the box 106 is lowered from the recess 120 (as shown in fig. 6 (b)) and released from the gripper plate 110.
The upper portion 112 of the vehicle 102 houses all of the important bulky components of the load handling equipment, as shown in fig. 6 (c). The upper portion 112 houses the batteries and associated electronics, controller and communication means, motors for driving the wheels 116, 118, motors for driving the lifting mechanism 104, and other sensors and systems.
Thus, the footprint of the vehicle 102 is larger than the size of the case 106, just enough to accommodate the wheels 116, 118 on either side of the recess 120. In other words, the loading tool 102 occupies a grid space in the storage system. Thus, the vehicle 102 occupies the smallest space possible in the X-Y plane, with an area approximately equal to half the area occupied by the prior art cantilevered design shown in FIG. 3. For comparison, fig. 7 illustrates the load handling apparatus 100 of the present invention used in the storage system of fig. 1 and 2, alongside the existing cantilevered load handling apparatus 30 of fig. 3. It can be seen that the prior art device 30, although shorter, occupies two stacked spaces, whereas the device 100 of the present invention, although taller, occupies a smaller area.
The load handling apparatus 100 of the present invention also provides better stability, greater load handling capability, and lighter weight than the existing cantilevered load handling apparatus 30 because, in the present invention, the load of the container is suspended between pairs of wheels on each side of the vehicle. In contrast, the prior art apparatus 30 requires relatively heavy vehicle modules to balance the load of the cantilevered configuration.
Fig. 8-12 illustrate one embodiment of the present invention. The upper portion 112 of the vehicle 102 has three primary motors built into it: a Z-axis drive motor 150 for raising and lowering the hoist line 108, the hoist line 108 being wound on spools 109 mounted on drive shafts on opposite sides of the vehicle 102; an X-axis drive motor 152 for driving the first set of wheels 116; and a Y-axis drive motor 154 for driving the second set of wheels 118. The upper portion 112 of the vehicle also houses a battery 156 that powers the motor, controller, sensors and other components described above and shown in fig. 6 (c).
The driving force generated by the X-axis and Y-axis drive motors 152, 154 is transmitted to the respective sets of wheels 116, 118 through belt transmissions. The X-axis drive motor 152 drives a pulley 160, which pulley 160 is connected to a short drive shaft 162 that traverses the vehicle body. The driving force generated by the short drive shaft 162 is transmitted to each wheel of the first set of wheels 116 via an X-axis drive belt 164. The Y-axis drive motor 154 drives a pulley 170, and the pulley 170 is coupled to a long drive shaft 172 that traverses (in a direction perpendicular to the short drive shaft 162) the vehicle body. The drive force generated by the long drive shaft 172 is transmitted to each of the second set of wheels 118 via a Y-axis drive belt 174.
The belt drive wheels 116, 118 are mounted at the bottom of the lower portion 114 of the vehicle 102. The motors 152, 154 can be mounted on the upper portion 112 of the vehicle using drive belts 164, 174 that transmit the drive of the motors to the wheels.
In this embodiment, the first set of wheels 116 can be raised and disengaged from the track or the first set of wheels 116 can be lowered and engaged with the track by the wheel alignment mechanism, as best shown in fig. 9, 11 and 12. Each wheel 116 is mounted on an arm 180 (the arms 180 are pivotally mounted at their outer ends). The inner end of each arm 180 is connected to the lower end of a respective linkage 182. The upper ends of the two linkages 182 are connected to the lower end of a common linkage 184. And the upper end of the common linkage 184 is connected to a movable arm 186 that is moved by a motor 188. By operating the motor 188 to pull the common linkage 184 upward and lift the first set of wheels 116, the second set of wheels 118 alone engage the track to move the vehicle 102 in the Y-axis direction. The common linkage 184 is pushed downwardly by operation of the motor 188 to move the first set of wheels 116 down into engagement with the track and lift the vehicle and thus the second set of wheels 118 off the track, as shown in fig. 9, 11 and 12. The vehicle 102 may then move in the X-axis direction.
The second set of wheels 118 are mounted on a stationary T-shaped member 190, the T-shaped members 190 being provided at each end of the lower portion 114 of the vehicle 102.
Figures 8, 9 and 12 show the load handling apparatus 100 lifting a box 106 into the recess 120. Fig. 11 shows the box 106 carried under the load handling apparatus 100, the grab plate 110 to be engaged with the box 106. The wheels 116, 118 and associated support members, linkages, and drive belts 164, 174 are disposed about the edges of the recess 120 to securely support the upper portion 112 of the vehicle 102.
Figure 13 illustrates a wheel 200 suitable for use as either of the wheels 116, 118 of the load handling apparatus 100. The wheel 200 has a toothed central groove 202 forming a pulley cooperating with the belts 164, 174. The edges of the groove 202 are defined by two rubber tyres 204, the rubber tyres 204 in use being pressed against the track. The wheel 200 may be mounted on the arm 180 by an axle (not shown) that may extend through an axle hole 206 in the wheel 200. This wheel design is compact and stable, minimizes wear, and maintains the belts 164, 174 in alignment during use by the tire 204.
Figure 14 shows two wheels 200 mounted in a load handling apparatus frame structure 210 in accordance with another embodiment of the present invention. As in the previous embodiment, the load handling apparatus comprises a vehicle, which consists of an upper part 112 with built-in main components of the apparatus and a lower part containing a recess 120 for receiving a box, with wheels 200 mounted on four sides of the recess (fig. 14 shows only one side of the mounted wheels).
In this case, the frame structure 210 comprises two parallel plates for receiving the wheel 200 therebetween. The present invention provides a transmission belt 212 for transmitting the driving force generated by the motor built in the upper part 112 of the vehicle to the wheel 200.
As further shown in fig. 15 and 16, the wheels 200 of this embodiment may be raised or lowered by moving the frame structure 210 relative to the upper portion 112 of the vehicle. The frame structure 210 is mounted to the body 230 of the vehicle upper portion 112 by rails 232. The rails 232 are fixed to the main body 230 in a vertical direction, and the frame structure 210 is slidably mounted on the rails 232.
The frame structure 210 is maintained by a pair of linkages 240 extending between the plates. The linkage 240 is connected at each end of its bottom surface to respective shafts 242 which set up the spaces between the plates. The top end of the linkage 240 is rotatably connected to a threaded coupling 246 mounted on a threaded horizontal drive shaft 244. The hub 246 is slidably connected to a horizontal track 248.
The drive shaft 244 is driven by a motor 250 via a drive belt (not shown). When the drive shaft 244 is rotated in a first direction, the top ends of the linkages 240 separate, pushing the frame structure 210 downward, thereby lowering the wheels 200 onto the track. When the drive shaft 244 is rotated in a second (opposite) direction, the top ends of the linkages 240 come together, pulling the frame structure 210 upward, thereby lifting the wheels 200.
Although only one frame structure 210 with two wheels 200 is shown in fig. 14 and 16, it will be appreciated that the other side of the vehicle is provided with an identical frame structure 210. The two frame structures 210 can be raised and lowered by a common motor, and thus, the four wheels 200 can be raised and lowered simultaneously to control the engagement of the first set of wheels 200 with the track extending in the first direction through the frame structures. Although not shown in fig. 14 and 16, the vehicle includes another set of wheels for engaging a track extending in a second (vertical) direction through the frame structure when the first set of wheels is elevated.
It will be understood that many different variations and modifications are possible. For example, two sets of wheels may be driven by a single motor, with drive being transmitted to the appropriate set of wheels by suitable transmission means. In other embodiments, one or more of the wheels may include an integrated motor or a motor adjacent to the wheel, as shown for example in fig. 17.
Fig. 17 also illustrates a load handling device 252 according to a further embodiment of the present invention. The load handling device 252 has a cubical housing 254 with a plurality of wheels 256 mounted proximate a lower edge 258 of the housing 254. The wheels 256 are motorized hub wheels, and each wheel 256 has an electric motor integrated into the hub 260 of the wheel 256. The motor is used to directly drive the wheels 256, and therefore, this embodiment does not require a belt to connect the wheels to the drive motor.
In this example, the motor is driven by a battery built into the side wall 262 of the lower portion 264 of the housing 254, adjacent the receptacle receiving space 266 of the device 252. The battery is mounted at a low position to lower the center of gravity of the device 252, which has an advantageous effect of improving the stability of the device and achieving faster acceleration and deceleration. The device 252, or similar to the devices of the previous embodiments, includes a similar mechanism for raising and lowering the wheels 256 and a similar lifting device for raising a container and placing it into the container receiving space 266. Batteries disposed in the side walls 262 may also be used to power these components.
In any of the preceding embodiments, the mechanism for lifting and placing a container into the container receiving space may be of any suitable form. For maximum stability and load capacity, it is desirable to provide four hoisting ropes, one near each corner of the installation. But it is also possible to use fewer cables for different fittings, if desired. Preferably, all of the cables are wound and unwound using one motor, but more than one motor may be used, if desired.
The mechanism for lifting the wheels may use a linear actuator instead of an electric motor, such as a linear motor or a hydraulic ram. It will be apparent to those skilled in the art that other means of powering the load handling apparatus may be used instead of batteries, for example, using overhead power or supplying power through rails on which the apparatus operates.
It should be appreciated that features described in relation to one particular embodiment may be interchanged with features described in relation to other embodiments. For example, the motorized hub wheel of fig. 17 may be used in any other embodiment, and/or in any embodiment, the battery may be placed in a low position adjacent to the container receiving space to improve stability and speed up/down. Other variations and modifications not listed above will be apparent to those skilled in the art.