AUTOMATED LOCKER SYSTEM FOR DELIVERY AND COLLECTION OF INVENTORY ITEMS

- Grey Orange Inc.

Provided is a locker system that includes a plurality of lockable doors, a security lock mechanism, and a plurality of compartments. Opening of each lockable door is controlled based on a corresponding security parameter. The security lock mechanism controls opening and closing of each lockable door based on the corresponding security parameter. Each compartment is accessible from a front side and a rear side of the locker system. An access to each compartment from the front side is controlled by a corresponding lockable door. Each compartment is open from the rear side. When a robotic apparatus, transporting one or more items associated with a process at a storage facility, aligns with the locker system from the rear side, the one or more items are accessible from the front side based on opening of one or more corresponding lockable doors of one or more compartments of the plurality of compartments.

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Description
CROSS-RELATED APPLICATIONS

This application claims priority of Indian Provisional Application No. 202111015301, filed Mar. 31, 2021, the contents of which are incorporated herein by reference.

FIELD

The present disclosure relates generally to a locker management system, and more particularly, to a system and a method for an automated locker system for delivery and collection of inventory items.

BACKGROUND

Modern storage facilities handle a large number of inventory items on a daily basis. The inventory items are handled within the storage facility for the fulfilment of an order or brought inside the storage facility for replenishment of inventory stock. Throughputs of such storage facilities have a direct bearing on various business metrics such as time taken to complete orders, the total number of orders completed within a time duration, customer satisfaction, or the like.

In certain scenarios, such storage facilities include locker systems having multiple compartments where consolidated orders are stored to be collected by delivery personnel or customers. In order to store consolidated orders in the locker system, operators at the storage facility open compartment doors of the locker system, place the consolidated orders in the compartments and then close the compartment doors. The compartment doors are then operated by the delivery personnel or customers for collecting their orders. As for a single order, the compartment door is required to be operated twice; first—for storing the order, and second—for collecting the order. Thus, such locker systems are inefficient and decrease the throughput of order deliveries, resulting in the order collection being suboptimal.

In light of the foregoing, there exists a need for a technical solution that overcomes the abovementioned problems.

Limitations and disadvantages of conventional and traditional approaches will become apparent to one of skill in the art, through comparison of described systems with some aspects of the present disclosure, as set forth in the remainder of the present application and with reference to the drawings.

SUMMARY

Embodiments of the present disclosure provide an automated locker management system. The system includes a locker system including a plurality of compartments and a plurality of lockable doors. Each compartment of the plurality of compartments is accessible from a front side and a rear side of the locker system. An access to each compartment of the plurality of compartments from the front side is controlled by a corresponding lockable door of the plurality of lockable doors. Each compartment of the plurality of compartments is open from the rear side. The system further includes a plurality of robotic apparatuses. A first robotic apparatus of the plurality of robotic apparatuses is configured to transport one or more first items associated with a first process at a storage facility. The system further includes a control server. The control server is configured to allocate one or more first compartments of the plurality of compartments to the first process. Further, the control server is configured to communicate a first set of instructions to the first robotic apparatus to cause the first robotic apparatus to align with the locker system from the rear side. Based on the alignment of the first robotic apparatus with the locker system at the rear side, the one or more first items transported by the first robotic apparatus may be accessible from the front side of the one or more first compartments based on opening of corresponding lockable doors of the one or more first compartments.

Embodiments of the present disclosure provide an automated locker system. The system includes a plurality of lockable doors. Opening of each lockable door of the plurality of lockable doors is controlled based on a corresponding security parameter of each lockable door. The system further includes a security lock mechanism configured to control opening and closing of each lockable door based on the corresponding security parameter. The system further includes a plurality of compartments. Each compartment of the plurality of compartments is accessible from a front side and a rear side of the locker system. An access to each compartment of the plurality of compartments from the front side is controlled by a corresponding lockable door of the plurality of lockable doors. Each compartment of the plurality of compartments is open from the rear side. When a robotic apparatus, transporting one or more items associated with a process at a storage facility, aligns with the locker system from the rear side, the one or more items are accessible from the front side of the locker system based on the opening of one or more corresponding lockable doors of one or more compartments of the plurality of compartments.

In some embodiments, a second robotic apparatus of the plurality of robotic apparatuses is configured to transport one or more second items associated with a second process at the storage facility. The control server may be further configured to allocate the one or more first compartments to the second process. Further, the control server is configured to communicate a second set of instructions to the second robotic apparatus to cause the second robotic apparatus to align with the locker system from the rear side. The second robotic apparatus is configured to align with the locker system from the rear side based on the second set of instructions when the one or more first items are successfully collected from the one or more first compartments. Based on the alignment of the second robotic apparatus with the locker system at the rear side, the one or more second items transported by the second robotic apparatus are accessible from the front side of the one or more first compartments based on opening of the corresponding lockable doors of the one or more first compartments.

In some embodiments, a second robotic apparatus of the plurality of robotic apparatuses is configured to transport one or more second items associated with a second process at the storage facility. The control server may be configured to allocate one or more second compartments of the plurality of compartments to the second process. The one or more second compartments are different from the one or more first compartments. The control server is configured to communicate a second set of instructions to the second robotic apparatus to cause the second robotic apparatus to align with the locker system from the rear side concurrently with the first robotic apparatus. Based on the alignment of the second robotic apparatus with the locker system at the rear side, the one or more second items transported by the second robotic apparatus are accessible from the front side of the one or more second compartments based on opening of corresponding lockable doors of the one or more second compartments.

In some embodiments, the control server is further configured to control opening of each lockable door of the plurality of lockable doors based on a corresponding security parameter.

In some embodiments, the corresponding security parameter is at least one of a password, a machine-readable optical code, or biometric information of a user.

In some embodiments, the control server is further configured to control the corresponding lockable doors of the one or more first compartments to open concurrently based on one security parameter.

In some embodiments, the control server is further configured to receive, from the locker system, the one or more security parameters provided by a user to open the corresponding lockable doors of the one or more first compartments. Further, the control server is configured to compare the one or more security parameters provided by the user with one or more stored security parameters of the corresponding lockable doors of the one or more first compartments. Further, the control server is configured to control the corresponding lockable doors of the one or more first compartments to open based on the comparison of the one or more security parameters provided by the user with the one or more stored security parameters of the corresponding lockable doors.

In some embodiments, the system may include a set of storage systems such that a first storage system of the set of storage systems is configured to store the one or more first items on one or more shelves thereof. The first robotic apparatus is configured to transport the one or more first items by lifting and transporting the first storage system.

In some embodiments, when the first robotic apparatus aligns with the locker system based on the first set of instructions, the one or more shelves storing the one or more first items are aligned with the one or more first compartments.

In some embodiments, the first robotic apparatus may include one or more conveyors such that the one or more first items are placed on the one or more conveyers. When the first robotic apparatus aligns with the locker system based on the first set of instructions, the one or more conveyors, having the one or more first items thereon, are aligned with the one or more first compartments.

In some embodiments, the first robotic apparatus is further configured to actuate the one or more conveyors based on the first set of instructions to transfer the one or more first items from the one or more conveyers to the one or more first compartments.

In some embodiments, the first robotic apparatus includes one or more levels such that the one or more first items are placed on the one or more levels. When the first robotic apparatus aligns with the locker system based on the first set of instructions, the one or more levels of the first robotic apparatus are aligned with the one or more first compartments.

These and other features and advantages of the present disclosure may be appreciated from a review of the following detailed description of the present disclosure, along with the accompanying figures in which like reference numerals refer to like parts throughout.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings illustrate the various embodiments of systems, methods, and other aspects of the disclosure. It will be apparent to a person skilled in the art that the illustrated element boundaries (e.g., boxes, groups of boxes, or other shapes) in the figures represent one example of the boundaries. In some examples, one element may be designed as multiple elements, or multiple elements may be designed as one element. In some examples, an element shown as an internal component of one element may be implemented as an external component in another, and vice versa.

Various embodiments of the present disclosure are illustrated by way of example, and not limited by the appended figures, in which like references indicate similar elements:

FIG. 1 is a diagram that illustrates an exemplary environment of a storage facility, in accordance with an exemplary embodiment of the present disclosure;

FIG. 2A is a diagram that illustrates a front side of a locker system, in accordance with an exemplary embodiment of the disclosure;

FIG. 2B is a diagram that illustrates a rear side of the locker system, in accordance with an exemplary embodiment of the present disclosure;

FIG. 3 is a block diagram that illustrates a control server, in accordance with an exemplary embodiment of the present disclosure;

FIG. 4 is a diagram that illustrates an implementation of a processing station in the storage facility, in accordance with an exemplary embodiment of the disclosure;

FIGS. 5A-5C are diagrams that illustrate exemplary scenarios for operating the locker system, in accordance with an exemplary embodiment of the disclosure;

FIG. 6 is a diagram that illustrates transfer of inventory items to the locker system using a robotic apparatus, in accordance with an exemplary embodiment of the present disclosure;

FIGS. 7A and 7B are diagrams that illustrates an alignment of one of the fourth robotic apparatus with the rear side of the locker system, in accordance with another embodiment of the present disclosure;

FIG. 8 is a diagram that illustrates collection of inventory items from the locker system, in accordance with another embodiment of the present disclosure;

FIGS. 9A and 9B are diagrams that illustrate an exemplary scenario for collection of inventory items from the locker system, in accordance with another embodiment of the present disclosure;

FIG. 10 is a block diagram that illustrates a system architecture of a computer system for inventory management in a storage facility, in accordance with the embodiments of the present disclosure;

FIG. 11 is a flow chart that illustrates an automated locker management method for delivery and collection of inventory items using the automated locker system, in accordance with an exemplary embodiment of the disclosure; and

FIG. 12 is a flow chart that illustrates a method for controlling opening of lockable doors of one or more compartments of the automated locker system, in accordance with an exemplary embodiment of the disclosure.

Further areas of applicability of the present disclosure will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description of exemplary embodiments is intended for illustration purposes only and is, therefore, not intended to necessarily limit the scope of the disclosure.

DETAILED DESCRIPTION

The present disclosure is best understood with reference to the detailed figures and description set forth herein. Various embodiments are discussed below with reference to the figures. However, those skilled in the art will readily appreciate that the detailed descriptions given herein with respect to the figures are simply for explanatory purposes as the methods and systems may extend beyond the described embodiments. In one example, the teachings presented and the needs of a particular application may yield multiple alternate and suitable approaches to implement the functionality of any detail described herein. Therefore, any approach may extend beyond the particular implementation choices in the following embodiments that are described and shown.

References to “an embodiment”, “another embodiment”, “yet another embodiment”, “one example”, “another example”, “yet another example”, “for example”, and so on, indicate that the embodiment(s) or example(s) so described may include a particular feature, structure, characteristic, property, element, or limitation, but that not every embodiment or example necessarily includes that particular feature, structure, characteristic, property, element or limitation. Furthermore, repeated use of the phrase “in an embodiment” does not necessarily refer to the same embodiment.

Certain embodiments of the disclosure may be found in disclosed systems and methods for an automated locker system for delivery and collection of inventory items. Exemplary aspects of the disclosure provide methods and systems for the automated locker systems. The systems and methods of the disclosure provide a solution for automated handling of inventory items within the storage facility. Specifically, the disclosed systems and methods include an automated locker system that allows for consolidated orders to be made accessible for collection without requiring various doors of the locker system to be opened and closed for storing the consolidated orders.

FIG. 1 is a diagram that illustrates an exemplary environment of a storage facility 102, in accordance with an exemplary embodiment of the present disclosure. The storage facility 102 includes a storage area 104, a processing area 106, a locker system 108, an access control interface 109, robotic apparatuses 110, a control server 112, and a communication network 114. The storage area 104 includes a plurality of storage systems 116a-116n. The processing area 106 includes a plurality of processing stations (for example, a first processing station 118a and a second processing station 118b). The robotic apparatuses 110 may include multiple robotic apparatuses of different architecture, operating principles, or the like. For example, the robotic apparatuses 110 may include a plurality of first robotic apparatuses 120a-120n, a plurality of second robotic apparatuses 122a-122n, a plurality of third robotic apparatuses 124a-124n, and a plurality of fourth robotic apparatuses 126a-126n. The plurality of first robotic apparatuses 120a-120n may be configured to transport the plurality of storage systems 116a-116n within the storage facility 102. The plurality of second robotic apparatuses 122a-122n may have multiple level conveyors and may be configured to transport one or more inventory items or consolidated orders within the storage facility 102. The plurality of third robotic apparatuses 124a-124n may include storage shelves and movable trays, and may be configured to transport the inventory items or consolidated orders within the storage facility 102. The plurality of fourth robotic apparatuses 126a-126n may have one or more robotic arms and may be configured to pick the inventory items or consolidated orders from a first location and may put the inventory items or consolidated orders at a second location within the storage facility 102. The robotic apparatuses 110 may receive one or more instructions from the control server 112 for their operation. The control server 112 may communicate with the robotic apparatuses 110 by way of the communication network 114. The locker system 108, the access control interface 109, the robotic apparatuses 110, the control server 112, the communication network 114, and the plurality of storage systems 116a-116n may collectively form an automated locker management system for the storage facility 102.

The storage facility 102 is a facility where inventory items or packages of inventory items are stored for order fulfillment and/or selling. Examples of the storage facility 102 may include, but are not limited to, a forward warehouse, a backward warehouse, a fulfillment center, or a retail store (e.g., a supermarket, an apparel store, a departmental store, a grocery store, or the like). Examples of the inventory items may include, but are not limited to, groceries, apparel, electronic goods, mechanical goods, or the like. The storage facility 102 has the storage area 104 where the plurality of storage systems 116a-116n (hereinafter, collectively referred to and designated as “the storage systems 116”) are placed for storing the inventory items or the packages. In an embodiment, the storage area 104 may further serve as a resting place for the robotic apparatuses 110. The storage systems 116 may be arranged in the storage area 104 in any arrangement that may be optimal for storage and retrieval of the storage systems 116 as well as the inventory items stored in the storage systems 116. Various plans for arrangement of the storage systems 116 within the storage area 104 may be known in the art. Arrangement of the storage systems 116 in the storage area 104 may be automatic, semi-automatic, or manual. Storage of the inventory items in the storage systems 116 may be automatic, semi-automatic, or manual.

The storage systems 116 may be movable storage systems that store various inventory items and/or various packages, e.g., totes of different dimensions, types, shapes, materials, and capacity. In an embodiment, the storage systems 116 may further store therein various packages of consolidated orders. Each of the storage systems 116 may include multiple shelves, which enable the storage systems 116 to store multiple inventory items or packages. Each of the storage systems 116 may further include a reference marker associated therewith for uniquely identifying a corresponding storage system. Examples of the reference marker may include, but are not limited to, a barcode, a quick response (QR) code, a radio frequency identification device (RFID) tag, or the like. It will be apparent to those of skill in the art that the storage systems 116 may further include additional structural features that aid in transporting the storage systems 116, without deviating from the scope of the disclosure.

The storage facility 102 may further include the processing area 106. The processing area 106 may refer to a portion of the storage facility 102 where one or more pick/put operations are performed for handling the inventory items. The processing area 106 may have a plurality of processing stations (hereinafter, collectively referred to and designated as “the processing stations 118”) for executing one or more pick/put operations on the inventory items. The processing stations 118 may be associated with corresponding operators assigned to perform the pick/put operations on the inventory items. In an embodiment, the processing stations 118 may also utilize the plurality of fourth robotic apparatuses 126a-126n for performing the pick/put operations on the inventory items along with the human operators. The pick/put operations may be performed at the processing stations 118 for various processes such as, item replenishment in the storage systems 116, item retrieval from the storage systems 116 for order fulfillment, order consolidation, performing one or more value-added services on the inventory items, performing quality check on the inventory items, or the like. Each of the processing stations 118 may have a user interface for presenting one or more instructions to assigned operators for handling the inventory items. The processing stations 118 may further include one or more optical sensors that may be configured to capture one or more images or videos to monitor the pick/put operations, alignment and positioning of the inventory items being handled, state of the inventory items, or the like. In an embodiment, the processing area 106 or the processing stations 118 may serve as resting locations for the robotic apparatuses 110.

The storage facility 102 may further include various locker systems and access control interfaces, such as the locker system 108 and the access control interface 109. In an embodiment, the locker system 108 and the access control interface 109 may be utilized for order collection and delivery. For example, the locker system 108 may serve as a curbside locker where consolidated orders are stored for delivery and collection by delivery personnel or customers. The access control interface 109 may serve as a curbside kiosk including an interactive interface. The access control interface 109 may be used by the delivery personnel or the customers for collecting their order from the locker system 108. In other words, the access control interface 109 may enable the delivery personnel or the customers to access the locker system 108 for collecting their consolidated orders. In another embodiment, the locker system 108 and the access control interface 109 may be utilized in the storage facility 102 for providing controlled access to inventory items. For example, the locker system 108 may serve as a locker where inventory items are stored for collection by operators. In such a scenario, the access control interface 109 may be used by the operator for collecting the requisite inventory items from the locker system 108.

The locker system 108 includes a plurality of compartments and a plurality of lockable doors that control access to the plurality of compartments, respectively. Each compartment of the plurality of compartments is accessible from a front side and a rear side of the locker system 108. An access to each compartment from the front side is controlled by a corresponding lockable door positioned at the front side of the corresponding compartment whereas each compartment is open from the rear side. The rear side of the locker system 108 serves as an access point for storing inventory items in the plurality of compartments and the front side of the locker system 108 serves as an access point for collecting the stored inventory items from the plurality of compartments. Since the plurality of compartments are open from the rear side, inventory items may be stored in the locker system 108 without the need of opening any compartment door. In other words, the plurality of lockable doors are only opened for collecting inventory items from the locker system 108, thereby improving the throughput of various processes in the storage facility 102.

The inventory items may be stored in the plurality of compartments by the robotic apparatuses 110 under the control of the control server 112. For example, the robotic apparatuses 110 may access the locker system 108 from the rear side and store the inventory items in the plurality of compartments. Various embodiments where the robotic apparatuses 110 are used to store the inventory items in the locker system 108 from the rear side of the locker system 108 are described later in conjunction with FIGS. 5A-5C and 6-9.

In some embodiments, two or more lockable doors of the plurality of lockable doors may be opened concurrently (for example, at the same time) to provide simultaneous access to respective compartments. In an embodiment, each of the plurality of lockable doors may be associated with a unique security parameter that controls the opening of the respective lockable door. For example, a first lockable door may be associated with a first security parameter and a second lockable door may be associated with a second security parameter. In such a scenario, when the first security parameter is inputted to the access control interface 109, the first lockable door is automatically opened and when the second security parameter is inputted to the access control interface 109, the second lockable door is automatically opened. In a scenario, if an incorrect security parameter is inputted to the access control interface 109, no lockable door is opened. In other words, opening of the plurality of lockable doors may be controlled based on corresponding security parameters.

In some embodiments, two or more lockable doors of the locker system 108 may be associated with the same security parameter. For example, the first and second lockable doors may be associated with the same security parameter. In such a scenario, when the security parameter is inputted to the access control interface 109, the first and second lockable doors are automatically opened concurrently or at the same time.

In some embodiments, the security parameters of the plurality of lockable doors may be dynamic parameters that are updated periodically by the control server 112. Examples of the dynamic parameters may include, but are not limited to, a one-time password (OTP), barcodes, and quick response (QR) codes. In another embodiment, the security parameters of the plurality of lockable doors may be static parameters that do not change with time. Examples of the static parameters may include, but are not limited to, personal identification numbers (PINs), machine-readable optical codes such as barcodes or QR codes, or biometric information of a user.

The locker system 108 may further include a plurality of security lock mechanisms for the respective plurality of lockable doors. The plurality of security lock mechanisms may be configured to open or close the respective plurality of lockable doors. In other words, a security lock mechanism is configured to secure a corresponding lockable door in a closed position until a correct security parameter is inputted at the access control interface 109 for opening the lockable door. In some embodiments, the plurality of security lock mechanisms may receive instructions to lock or unlock the respective plurality of lockable doors from the control server 112 and/or the access control interface 109. The security lock mechanisms may be implemented by way of electromagnetic locks such as solenoid and/or actuators.

In some embodiments, the plurality of compartments and the plurality of lockable doors of the locker system 108 may have same size, shape, dimensions, and weight bearing capacity. In some embodiments, the plurality of compartments and the plurality of lockable doors of the locker system 108 may have different sizes, shapes, dimensions, and weight bearing capacities.

The locker system 108 may further include a plurality of sensors such as weight sensors, infrared sensors, ultrasonic sensors, or the like for each of the plurality of compartments. The weight sensors in a compartment may be configured to generate sensor data that indicates weight of items placed in the compartment. Hereinafter, the terms “inventory items” and “items” are used interchangeably. For example, when no inventory item is placed in the first compartment of the plurality of compartments, the sensor data generated by the weight sensors of the first compartment indicate that the weight is zero. The infrared sensors or the ultrasonic sensors may be coupled to the rear side and the front side of each of the plurality of compartments and may be configured to generate sensor data that indicates whether the plurality of compartments are being accessed from the front side or whether any of the robotic apparatuses 110 is aligned with the compartments from the rear side. For example, when a user attempts to access the first compartment from the front side, the infrared sensors or the ultrasonic sensors coupled to the front side of the first compartment generate sensor data that indicates that a hand of the user is inside the first compartment. Similarly, when one of the robotic apparatuses 110 is aligned with the first compartment from the rear side, the infrared sensors or the ultrasonic sensors coupled to the rear side of the first compartment generate sensor data that indicates that one of the robotic apparatuses 110 is aligned with the first compartment from the rear side. In some embodiments, the sensor data generated by the infrared sensors or the ultrasonic sensors coupled to the rear side of the first compartment may further indicate whether the robotic apparatus is incorrectly or correctly aligned with the first compartment.

The locker system 108 may have a fixed or a dynamic location within the storage facility 102. For the sake of brevity, the storage facility 102 is shown to include a single locker system 108 and a single access control interface 109. In other embodiments, the storage facility 102 may include any number of locker systems having a similar or different architecture. The locker system 108 is described in detail in conjunction with FIGS. 2A and 2B.

Examples of the access control interface 109 may be an electronic kiosk or any user interaction entity (e.g., a human machine interface, HMI). The electronic kiosk refers to a computer-based information delivery system generally accessible to some segment of the public for retrieving information or initiating some processes. The access control interface 109 may include a display screen for presenting information to the customer and some form of computer input device for the customer such as a touch screen or keypad, although a full keyboard or mouse may also be provided. The type of kiosk system of interest here may be an interactive system that may have multiple kiosk sites (for example, the access control interface 109) accessible by customers. The access control interface 109 may present multiple selectable options to a user (e.g., a customer or an operator), for example, a first option for placing a new order, a second option to search information regarding a previously placed order, a third option for viewing an inventory item catalog of the storage facility 102, a fourth option for collecting the inventory items for a previously placed order or for executing a process in the storage facility 102, or the like. Upon selection of the fourth option by the user, the access control interface 109 may be configured to prompt the customer to enter the security parameter associated with the previously placed order. If the security parameter provided by the customer is correct, lockable doors corresponding to the inputted security parameter are opened for item or order collection.

Although the access control interface 109 and the locker system 108 are shown as separate entities, in some embodiments, the access control interface 109 may be integrated with the locker system 108 without deviating from the scope of the disclosure.

Transportation of the inventory items or consolidated orders within the storage facility 102 may be performed by the robotic apparatuses 110. The robotic apparatuses 110 may be configured to receive one or more instructions from the control server 112. Based on the received one or more instructions, the robotic apparatuses 110 may be configured to transport the inventory items or the consolidated orders within the storage facility 102, for example, from the processing area 106 to the locker system 108.

The control server 112 may include suitable logic, circuitry, interfaces, and/or code, executable by the circuitry, to facilitate various inventory management operations in the storage facility 102. Examples of the control server 112 may include, but are not limited to, personal computers, laptops, mini-computers, mainframe computers, any non-transient and tangible machine that can execute a machine-readable code, cloud-based servers, distributed server networks, or a network of computer systems. The control server 112 may be realized through various web-based technologies such as, but not limited to, a Java web-framework, a .NET framework, a personal home page (PHP) framework, or any other web-application framework. The control server 112 may be maintained by a storage facility management authority or a third-party entity that facilitates inventory management and handling operations for the storage facility 102. It will be understood by a person having ordinary skill in the art that the control server 112 may execute other storage facility management operations as well along with the inventory management operations.

The control server 112 may be configured to communicate with the locker system 108, the access control interface 109, and the robotic apparatuses 110 by way of the communication network 114. The control server 112 may be further configured to remotely control the robotic apparatuses 110 and the locker system 108. The control server 112 may be further configured to store, in a memory of the control server 112, a virtual map of the storage facility 102 and inventory storage data of inventory stock. The virtual map is indicative of current locations of the robotic apparatuses 110, entry and exit points of the storage facility 102, various reference markers in the storage facility 102, a current location of each inventory item, a current location of each storage system 116, locations of the first and second processing stations 118a and 118b, location of the locker system 108, or the like. The inventory storage data is indicative of associations between the inventory items stored in the storage facility 102 and the storage systems 116 in the storage facility 102. The inventory storage data may further include historic storage locations of each inventory item. The inventory storage data may further include parameters (for example, weight, shape, size, color, dimensions, or the like) associated with each inventory item. The control server 112 may be further configured to manage allocation of the plurality of compartments to various processes in the storage facility and allocation of the robotic apparatuses 110 for transporting the inventory items associated with the processes. The control server 112 may be further configured to generate and store therein the security parameters of the plurality of lockable doors of the locker system 108 so as to control the opening of the plurality of lockable doors. The control server 112 may be configured to receive security parameters inputted by a user (e.g., a customer, delivery personnel, or an operator of the storage facility 102) from the access control interface 109 and match the received security parameters with stored security parameters. When the inputted security parameters match any of the stored security parameters, the control server 112 may be configured to control unlocking of one or more lockable doors of one or more compartments corresponding to the matched security parameters.

The communication network 114 is a medium through which instructions and messages are transmitted between the control server 112, the robotic apparatuses 110, the locker system 108, and the access control interface 109. Examples of the communication network 114 may include, but are not limited to, a wireless fidelity (Wi-Fi) network, a light fidelity (Li-Fi) network, a local area network (LAN), a wide area network (WAN), a metropolitan area network (MAN), a satellite network, the Internet, a fiber optic network, a coaxial cable network, an infrared (IR) network, a radio frequency (RF) network, and a combination thereof. Various entities (such as the robotic apparatuses 110, the locker system 108, the access control interface 109, and the control server 112) in the storage facility 102 may be coupled to the communication network 114 in accordance with various wired and wireless communication protocols, such as Transmission Control Protocol and Internet Protocol (TCP/IP), User Datagram Protocol (UDP), Long Term Evolution (LTE) communication protocols, or any combination thereof.

In operation, the control server 112 may be configured to receive a process request for executing a first process. The first process may be associated with one or more first inventory items of the plurality of inventory items stored in the storage facility 102 and may require the first inventory items to be made accessible to a delivery personnel, a customer, or an operator in the storage facility 102. In one example, the first process may correspond to providing an access to a consolidated order via the locker system 108 so that the delivery personnel or the customer may be able to collect the consolidated order. In another example, the first process may correspond to an internal process of the storage facility 102 where the first inventory items are to be made accessible to a specific operator via the locker system 108. Here, the internal process may refer to any process (for example, quality check process, item replenishment process, order fulfilment process, or the like) that is executed within the storage facility 102 for carrying out one or more operations in the storage facility 102.

Based on the received process request, the control server 112 may be configured to allocate one or more first compartments of the plurality of compartments of the locker system 108 to the first process. The control server 112 may further communicate instructions to a robotic apparatus of the robotic apparatuses 110 to transport the first inventory items from a current storage location to the locker system 108. The robotic apparatus may be any of the plurality of first robotic apparatuses 120a-120n, the plurality of second robotic apparatuses 122a-122n, the plurality of third robotic apparatuses 124a-124n, and the plurality of fourth robotic apparatuses 126a-126n. The control server 112 may be configured to select the robotic apparatus from the robotic apparatuses 110 based on an availability of the robotic apparatus, a type of the first process, compatibility of the robotic apparatus with the first process, or the like. Based on the instructions from the control server 112, the robotic apparatus may be configured to transport the first inventory items associated with the first process to the locker system 108. The control server 112 may be further configured to communicate a set of instructions to the robotic apparatus to cause the robotic apparatus to align with the locker system 108 from the rear side. In an embodiment, the set of instructions may include path information of a first path that the robotic apparatus is to travel in the storage facility 102 to reach the location of the locker system 108 to align with the one or more first compartments. The first set of instructions may further include unique identifiers of the one or more first compartments that enable the robotic apparatus to identify the one or more first compartments from the plurality of compartments.

Based on the received set of instructions, the robotic apparatus may travel along the first path and align with the one or more first compartments from the rear side of the locker system 108. The first inventory items transported by the robotic apparatus are accessible from the front side of the one or more first compartments upon opening of corresponding lockable doors of the one or more first compartments.

In some embodiments, the robotic apparatus may transfer the first inventory items to the one or more first compartments after successfully aligning with the one or more first compartments and once the transfer is complete, the robotic apparatus may become available for executing one or more other operations in the storage facility 102.

In other embodiments, the robotic apparatus may not transfer the first inventory items to the one or more first compartments and may remain aligned with the one or more first compartments until the first inventory items are collected from the robotic apparatus by a designated entity by opening the corresponding lockable doors of the one or more first compartments from the front side of the locker system 108. In such an embodiment, the robotic apparatus may become available for executing one or more other operations in the storage facility 102 after the first inventory items are successfully collected by the designated entity.

The control server 112 may be further configured to store therein security parameters of the plurality of lockable doors. In a first exemplary scenario where the first inventory items correspond to a consolidated order of a customer, the control server 112 may be configured to communicate security parameters of the one or more first compartments, that provide access to the first inventory items, to a customer device (for example, a smartphone, a laptop, a wearable device, a mobile phone, or the like) of the customer or a delivery personnel. The customer or the delivery personnel may then input the security parameters into the access control interface 109 at the storage facility 102. The access control interface 109 may communicate the inputted security parameters to the control server 112. The control server 112 may compare the received security parameters with the stored security parameters and when the received security parameters match any of the stored security parameters, the control server 112 may communicate an unlock signal to the locker system 108 or the access control interface 109.

In some embodiments, the control server 112 may communicate the unlock signal to the locker system 108 or the access control interface 109 when the sensor data generated by the infrared sensors or the ultrasonic sensors coupled to the rear side of the one or more first compartments indicate that the robotic apparatus is correctly aligned with the one or more first compartments from the rear side. However, if the sensor data generated by the infrared sensors or the ultrasonic sensors coupled to the rear side of the one or more first compartments indicates that the robotic apparatus is incorrectly aligned with the one or more first compartments, the control server 112 may communicate an instruction to the robotic apparatus to correct the alignment with the one or more first compartments. Here, the instruction communicated to the robotic apparatus may include distance, rotation, or height adjustment information. The robotic apparatus may move as per the instruction and may get correctly aligned with the one or more first compartments. Since the infrared sensors or the ultrasonic sensors generate sensor data periodically, new sensor data generated by the infrared sensors or the ultrasonic sensors may indicate that the robotic apparatus is now correctly aligned with the one or more first compartments from the rear side.

In some embodiments, the control server 112 may communicate the unlock signal to the access control interface 109 and the access control interface 109 may actuate the security lock mechanism of the one or more first compartments to open the lockable doors of the one or more first compartments. In other embodiments, the control server 112 may communicate the unlock signal directly to the locker system 108 to actuate the security lock mechanism of the one or more first compartments for opening the lockable doors of the one or more first compartments. In other words, the control server 112 may control the opening of the lockable doors of the one or more first compartments based on the comparison of the received security parameters with the stored security parameters. Upon opening of the lockable doors of the one or more first compartments, the customer or the delivery personnel may collect the consolidated order from the one or more first compartments and the security lock mechanism may then close the opened lockable doors.

In some embodiments, the security lock mechanism may close the opened lockable doors when sensor data generated by the weight sensors of the one or more first compartments indicate that the weight of items placed in the one or more first compartments has changed to zero due to retrieval of the first inventory items by the customer or the delivery personnel.

In some embodiments, the security lock mechanism may not close the opened lockable doors until the sensor data generated by the infrared sensors or the ultrasonic sensors at the front side of the one or more first compartments indicate that a human hand is present inside the one or more first compartments.

In some embodiments, the control server 112 may change or update the security parameters associated with the one or more first compartments once the order is collected, to enhance the security of the locker system 108.

In a second exemplary scenario where the first inventory items correspond to an internal process of the storage facility 102, the control server 112 may be configured to communicate security parameters of the one or more first compartments from where the first inventory items could be collected, to an operator device of the operator executing the internal process. The first inventory items are collected by the operator from the one or more first compartments in the same manner as described above in the first exemplary scenario.

FIG. 2A is a diagram that illustrates a front side 200A of the locker system 108, in accordance with an exemplary embodiment of the disclosure. In FIG. 2A, two of the compartments 202a and 202b of the locker system 108 are labelled and three of the lockable doors 204a, 204b, and 204c of the locker system 108 are labelled. Labelling of other compartments and lockable doors is omitted for the sake of brevity. In an embodiment, the locker system 108 includes a plurality of shelves that are spaced in a vertical direction and a plurality of walls that are disposed on each of the plurality of shelves to define the plurality of compartments on each shelf. The walls and the shelves, in combination, define the plurality of compartments of the locker system 108.

As shown in FIG. 2A, the lockable doors 204a and 204b are open at the same time. The compartments 202a and 202b and items stored in the compartments 202a and 202b are accessible to users 206a and 206b from the front side 200A. Here, the users 206a and 206b may be operators, delivery personnel, or customers. Further, the lockable door 204c is closed, and hence a compartment 202c (shown in FIG. 2B) of the lockable door 204c is not accessible from the front side 200A. The users 206a and 206b may have provided the security parameters to the access control interface 109 (shown in FIG. 1) for requesting access to the compartments 202a and 202b, respectively.

FIG. 2B is a diagram that illustrates a rear side 200B of the locker system 108, in accordance with an exemplary embodiment of the present disclosure. As shown in FIG. 2B, the plurality of compartments (e.g., the compartments 202a, 202b, and 202c) remain open at the rear side 200B.

It will be apparent to a person skilled in the art that the exemplary usage of locker system 108 is for illustration purposes and does not limit the scope of the disclosure. As shown in FIGS. 2A and 2B, the plurality of compartments of the locker system 108 have dedicated shelves; however, the scope of the disclosure is not limited to it. In other embodiments, the plurality of compartments of the locker system 108 may not have dedicated shelves (as described in FIGS. 7A-9), and therefore may only serve as access points instead of access and storage points.

FIG. 3 is a block diagram that illustrates the control server 112, in accordance with an exemplary embodiment of the present disclosure. The control server 112 may include processing circuitry 302, a memory 304, and a transceiver 306. The processing circuitry 302 may include a security parameter generator 308, an allocation manager 310, a comparator 312, and an access controller 313. It will be apparent to a person having ordinary skill in the art that the control server 112 is for illustrative purposes and not limited to any specific combination of hardware circuitry and/or software.

The processing circuitry 302 may execute and manage various operations (such as allotting compartments to processes, generating and updating security parameters, remotely controlling opening and closing of the plurality of lockable doors, inventory management, or the like) in the storage facility 102. The processing circuitry 302 may execute the operations using the security parameter generator 308, the allocation manager 310, the comparator 312, and the access controller 313.

The security parameter generator 308 may include suitable logic, instructions, circuitry, interfaces, and/or code for generating unique security parameters for the plurality of lockable doors (e.g., the lockable doors 204a, 204b, and 204c) of the locker system 108. In an embodiment, the generated security parameters for the plurality of lockable doors may be static. In another embodiment, the generated security parameters for the plurality of lockable doors may be dynamic. In an example, the dynamic security parameters may be time-limited parameters which the security parameter generator 308 updates after a specific time period. In another example, the dynamic security parameters may be process-based which the security parameter generator 308 updates after completion of the process. The opening of the plurality of lockable doors is controlled based on the unique security parameters. In some embodiments, the security parameter generator 308 may generate a single security parameter for multiple lockable doors. For example, when two or more compartments of the plurality of compartments are allocated to a single process, the security parameter generator 308 may generate a single security parameter for the two or more compartments. Thus, the security parameter generator 308 may be configured to generate the security parameters for the plurality of lockable doors based on allotment of the plurality of compartments to various processes. The security parameter generator 308 may be configured to store the generated security parameters in the memory 304.

The allocation manager 310 may include suitable logic, instructions, circuitry, interfaces, and/or code for dynamically and continuously allocating and re-allocating the robotic apparatuses 110 for inventory item transportation. The allocation manager 310 may be further configured to manage the allocation of the plurality of compartments to various processes. The allocation manager 310 may allocate one or more compartments of the locker system 108 to a process based on the availability of the one or more compartments and compatibility between the one or more compartments and one or more inventory items associated with the process. For example, different compartments of the locker system 108 may have different sizes. In such a scenario, the allocation manager 310 may allocate those compartments to a process that have sufficient size to accommodate the inventory items of the process. For example, for a large size order, the allocation manager 310 may either allocate a single compartment of the locker system 108 that matches a size of the order or may split the consolidated order into two or more sub-orders and allocate two or more compartments that match the size of the two or more sub-orders, respectively. The allocation manager 310 may manage allocation of the robotic apparatuses 110 to transport inventory items based on a compatibility between the robotic apparatuses 110 and the inventory items. In one example, the allocation manager 310 may allocate the first robotic apparatus 120a to transport a batch of inventory items when a weight handling capacity, a size, dimensions, or the like of the first robotic apparatus 120a are sufficient to transport the batch of inventory items. However, if the weight handling capacity, the size, the dimensions, or the like of the first robotic apparatus 120a are not sufficient to transport the batch of inventory items, the allocation manager 310 may select another robotic apparatus for the task.

The comparator 312 may include suitable logic, instructions, circuitry, interfaces, and/or code for comparing security parameters received from the access control interface 109 with the security parameters stored in the memory 304. Opening of the plurality of lockable doors of the locker system 108 is controlled based on comparison results generated by the comparator 312. The comparator 312 may be further configured to provide the comparison results to the access controller 313.

The access controller 313 may include suitable logic, instructions, circuitry, interfaces, and/or code for controlling opening of the plurality of lockable doors of the locker system 108. The access controller 313 may be configured to receive the comparison results generated by the comparator 312. In an example, when a comparison result generated by the comparator 312 indicates that a received security parameter does not match any of the stored security parameters, the access controller 313 generates an error notification and communicates the error notification to the access control interface 109. In another example, when a comparison result generated by the comparator 312 indicates that a received security parameter matches any of the stored security parameters, the access controller 313 generates an unlock signal and communicates the unlock signal to the access control interface 109 or the security lock mechanism of the locker system 108. The unlock signal may indicate which lockable doors of the plurality of lockable doors are to be opened. For example, if the received security parameter matches the stored security parameter of the lockable door 204a, the access controller 313 generates an unlock signal that indicates that the lockable door 204a is to be opened. In another example, if the received security parameter matches the stored security parameter of the two or more lockable doors, the access controller 313 generates an unlock signal that indicates that the two or more lockable doors are to be opened concurrently.

Examples of the security parameter generator 308, the allocation manager 310, the comparator 312, and the access controller 313 may include, but are not limited to, an application-specific integrated circuit (ASIC) processor, a reduced instruction set computing (RISC) processor, a complex instruction set computing (CISC) processor, a field-programmable gate array (FPGA), a microcontroller, a combination of a central processing unit (CPU) and a graphics processing unit (GPU), or the like.

The memory 304 may include suitable logic, instructions, circuitry, interfaces to store one or more instructions that are executed by entities such as the security parameter generator 308, the allocation manager 310, the comparator 312, and the access controller 313 for performing one or more operations. Additionally, the memory 304 may be configured to store therein an inventory list 314, inventory storage data 316, layout information 318, robotic apparatus data 320, and security parameters 322. Examples of the memory 304 may include a random access memory (RAM), a read only memory (ROM), a removable storage drive, a hard disk drive (HDD), a flash memory, a solid-state memory, and the like.

The inventory list 314 may include a list of inventory items and packages stored in the storage facility 102 and a number of units of each inventory item stored in the storage facility 102. The layout information 318 may include information regarding the layout of the storage facility 102, such as location data of the storage systems 116, the first and second processing stations 118a and 118b, the locker system 108, or the like. The layout information 318 may further include real-time path availability information of various paths in the storage facility 102. For example, a first path in the storage facility 102 may be under maintenance, and hence may be unavailable for traversing.

The inventory storage data 316 is indicative of storage locations of the inventory items stored in the storage systems 116. The inventory storage data 316 may further include the reference markers of the storage systems 116. The reference identifiers are unique codes assigned to each of the storage systems 116. In one example, the reference markers are radio frequency identification (RFID) tags that are readable by the robotic apparatuses 110. Thus, based on the inventory storage data 316, the control server 112 is aware of the locations of all inventory items stored in the storage facility 102.

The security parameters 322 may act as a repository of security parameters associated with the plurality of lockable doors of the locker system 108. The comparator 312 may refer to the security parameters 322 for generating comparison results. The security parameters 322 may be dynamically updated by the security parameter generator 308. In one example, the security parameters 322 may be a look-up table that stores security parameters generated by the security parameter generator 308 in association with identifiers of the plurality of compartments and/or the plurality of lockable doors of the locker system 108. The unlock signal generated by the access controller 313 may include identifiers of those compartments and/or lockable doors whose security parameters matched the security parameters provided by a user.

The transceiver 306 may include suitable logic, instructions, circuitry, interfaces to transmit and receive data over the communication network 114 using one or more communication network protocols. The transceiver 306 may transmit various messages and commands to the robotic apparatuses 110, the locker system 108, and the access control interface 109 and receive data from the one or more optical sensors deployed in the storage facility 102, the robotic apparatuses 110, the locker system 108, and the access control interface 109. Examples of the transceiver 306 may include, but are not limited to, an antenna, a radio frequency transceiver, a wireless transceiver, a Bluetooth transceiver, an ethernet-based transceiver, a universal serial bus (USB) transceiver, or any other device configured to transmit and receive data.

Though the processing circuitry 302 is depicted as a hardware component in FIG. 3, a person skilled in the art will appreciate that the scope of the disclosure is not limited to realizing the processing circuitry 302 as the hardware component. In another embodiment, the functionality of the processing circuitry 302 may be implemented by way of a computer-executable code or a set of computer-readable instructions stored in the memory 304, without deviating from the scope of the disclosure.

FIG. 4 is a diagram 400 that illustrates an implementation of the first processing station 118a in the storage facility 102, in accordance with an exemplary embodiment of the disclosure. The control server 112 may receive a first process request for executing a first process. In a non-limiting example, it is assumed that the first process corresponds to an order collection process and is associated with one or more first inventory items (e.g., items I1 and I2). The first inventory items I1 and I2 may be stored in the storage system 116a in the storage area 104 and may need to be transported to the first processing station 118a in the processing area 106 for order consolidation. The control server 112 may be configured to select one of the plurality of first robotic apparatuses 120a-120n (for example, the first robotic apparatus 120a) that is available and compatible for transporting the storage system 116a from the storage area 104 to the first processing station 118a. The control server 112 may be further configured to communicate a first instruction to the first robotic apparatus 120a. The first instruction may be indicative of the storage system 116a that stores the first inventory items I1 and I2, a path to reach a location of the storage system 116a in the storage area 104, and a path to be followed by the first robotic apparatus 120a to reach the first processing station 118a where the first inventory items I1 and I2—are to be handled. Based on the first instruction, the first robotic apparatus 120a may transport the storage system 116a from the storage area 104 to the first processing station 118a. As shown in FIG. 4, the first robotic apparatus 120a has successfully transported the storage system 116a to the first processing station 118a.

The control server 112 may be further configured to allocate one or more first compartments of the plurality of compartments of the locker system 108 to the first process based on the first process request. The allocation of the one or more first compartments to the first process may be based on compatibility of the first inventory items I1 and I2 with the plurality of compartments, for example, size, weight, and dimension compatibility, and availability of the one or more first compartments.

In an exemplary scenario, each of the plurality of compartments may have a weight-bearing capacity of 20 kilograms and the first inventory items I1 and I2 may have a collective weight of 15 kilograms. In such a scenario, the control server 112 may allocate any of the plurality of compartments that is currently unoccupied or is available, to the first process. In another exemplary scenario, the plurality of compartments may have different weight-bearing capacities and only two compartments may have a weight-bearing capacity greater than 15 kilograms. In such a scenario, the control server 112 may allocate one of the two compartments that is available and has a weight-bearing capacity greater than 15 kilograms, to the first process. In another exemplary scenario, none of the plurality of compartments may have a weight-bearing capacity greater than or equal to 15 kilograms. In such a scenario, the control server 112 may allocate two different compartments that are available to the first inventory items I1 and I2 such that each compartment has a weight bearing capacity greater than or equal to a weight of the corresponding item. In another exemplary scenario, none of the plurality of compartments may have a size that is sufficient to collectively hold the first inventory items I1 and I2. In such a scenario, the control server 112 may allocate two different compartments that are available to the first inventory items I1 and I2 such that each compartment has a size that is compatible with a size of the corresponding item.

The control server 112 may be further configured to select one of the robotic apparatuses 110 that is available and compatible for collecting the first inventory items I1 and I2 from the first processing station 118a and transporting the collected first inventory items I1 and I2 to the locker system 108. In an exemplary scenario, the control server 112 may select one of the plurality of second robotic apparatuses 122a-122n (e.g., the second robotic apparatus 122a) to collect and transport the first inventory items I1 and I2 to the locker system 108.

The second robotic apparatus 122a may have a plurality of levels L1, L2, and L3. Each level of the plurality of levels L1, L2, and L3 may have one or more conveyors for receiving inventory items. In an exemplary illustration, each level L1, L2, and L3 is shown to include two conveyors that are rotatable in clockwise or anti-clockwise directions. Further, each level of the plurality of levels L1, L2, and L3 may have same or different physical attributes. The physical attributes of each level of the plurality of levels L1, L2, and L3 may include a weight-bearing capacity, a size, one or more dimensions, a height, and a count of conveyors. The conveyors of each level may be actuated independent of each other.

The control server 112 may then communicate a second set of instructions to the second robotic apparatus 122a. The second set of instructions may be indicative of a path to be followed by the second robotic apparatus 122a to reach a location of the first processing station 118a for the collection of the first inventory items I1 and I2 and a subsequent path to be followed by the second robotic apparatus 122a to reach the locker system 108 from the first processing station 118a. Based on the second set of instructions, the second robotic apparatus 122a may reach the first processing station 118a for collection of the first inventory items I1 and I2. As shown in FIG. 4, the second robotic apparatus 122a has successfully reached the first processing station 118a and is waiting to receive the first inventory items I1 and I2.

The control server 112 may be further configured to render, via a user interface 402, information (for example, a position, a shape, a size, a weight, or the like) of the first inventory items I1 and I2 that are to be handled at the first processing station 118a. The rendered information may further indicate a shelf of the storage system 116a on which the first inventory items I1 and I2 are stored. Based on the rendered information, a first set of pick/put operations may be performed by an operator 404 present at the first processing station 118a for handling the first inventory items I1 and I2. The first set of pick/put operations may include picking of the first inventory items I1 and I2 from the storage system 116a and putting the first inventory items I1 and I2 on a target level (for example, the level L1) of the second robotic apparatus 122a. In an embodiment, the target level may be indicated to the operator 404 via the user interface 402. In an embodiment, the first processing station 118a may further include a pick/put to light (PPTL) device or a projector for providing visual cues to indicate the target level and/or the shelf of the storage system 116a storing the first inventory items I1 and I2 to the operator 404.

The first inventory items I1 and I2 and the target level of the second robotic apparatus 122a may be identified by the operator 404 based on the information rendered via the user interface 402 and/or the visual cues. Subsequently, the first inventory items I1 and I2 may be placed on the target level (for example, the level L1) of the second robotic apparatus 122a by the operator 404.

In some embodiments, the second robotic apparatus 122a and/or the control server 112 may be configured to determine a correct placement of the first inventory items I1 and I2 on the target level. The second robotic apparatus 122a and/or the control server 112 may determine the correct placement based on one of one or more images or videos captured by one or more optical sensors deployed at the first processing station 118a, a weight of the first inventory items I1 and I2, or the like.

In an exemplary scenario, the one or more images or videos captured by the optical sensors deployed at the first processing station 118a may indicate that the first inventory items I1 and I2 are only partially placed on the target level of the second robotic apparatus 122a. In such a scenario, the control server 112 may instruct the operator 404 via the user interface 402 to adjust the placement of the first inventory items I1 and I2 so as to ensure that the first inventory items I1 and I2 are completely placed on the target level. In another exemplary scenario, one or more weight sensors placed on or beneath the conveyors of the target level may detect that the weight of the first inventory items I1 and I2 is not evenly distributed on the target level. In such a scenario, the second robotic apparatus 122a may either generate an audio/visual or haptic signal to alert the operator 404 regarding the incorrect placement of the first inventory items I1 and I2 or communicate an error signal to the control server 112 to indicate the incorrect placement of the first inventory items I1 and I2 on the target level. The second robotic apparatus 122a may not follow the subsequent path indicated in the second set of instructions until the first inventory items I1 and I2 are correctly placed on the target level by the operator 404.

Based on the determination that the first inventory items I1 and I2 are placed correctly on the target level, the second robotic apparatus 122a may start following the subsequent path indicated in the second set of instructions to reach the locker system 108. As shown in FIG. 4, the second robotic apparatuses 122c and 122d are also present at the first processing station 118a for other operations.

Although FIG. 4 is described in conjunction with the control server 112 selecting one of the plurality of first robotic apparatuses 120a-120n to transport the storage system 116a storing the first inventory items I1 and I2, the scope of the disclosure is not limited to it. In another embodiment, the control server 112 may select any of the plurality of third robotic apparatuses 124a-124n or any of the plurality of fourth robotic apparatuses 126a-126n to transport the first inventory items I1 and I2 from the storage area 104 to the first processing station 118a.

Although FIG. 4 is described in conjunction with the control server 112 selecting one of the plurality of second robotic apparatuses 122a-122n to transport the first inventory items I1 and I2, the scope of the disclosure is not limited to it. In another embodiment, the control server 112 may select any of the plurality of third robotic apparatuses 124a-124n or any of the plurality of fourth robotic apparatuses 126a-126n to transport the first inventory items I1 and I2 from the first processing station 118a to the locker system 108. The transfer of the first inventory items I1 and I2 to the locker system 108 by the second robotic apparatus 122a is described in conjunction with FIGS. 5A-5C.

In some embodiments, the control server 112 may instruct the operator 404 to put the first inventory items I1 and I2 picked from the storage system 116a onto a shelf of another storage system carried by one of the plurality of first robotic apparatuses 120b-120n. In some embodiments, the control server 112 may instruct the first robotic apparatus 120a to directly transport the storage system 116a from the storage area 104 to the location of the locker system 108.

FIGS. 5A-5C are diagrams that illustrate exemplary scenarios 500A-500C for operating the locker system 108, in accordance with an exemplary embodiment of the disclosure. Referring now to FIG. 5A, the second robotic apparatus 122a is shown to have reached the location of the locker system 108. Further, based on the second set of instructions, the second robotic apparatus 122a may be configured to identify the one or more first compartments (for example, a compartment 502a) that are allocated to the first process. Upon identification of the compartment 502a, the second robotic apparatus 122a may align with the compartment 502a.

Alignment of the second robotic apparatus 122a with the compartment 502a may include alignment of a conveyor 504a of the level L1 on which the first inventory items I1 and I2 are placed with a shelf of the compartment 502a from the rear side 200B of the locker system 108. In other words, when the second robotic apparatus 122a aligns with the locker system 108 based on the second set of instructions, the level L1 of the second robotic apparatus 122a is also aligned with the compartment 502a.

The infrared sensors or the ultrasonic sensors coupled to the rear side 200B of the compartment 502a may generate sensor data indicating the alignment of the second robotic apparatus 122a with the compartment 502a and may communicate the sensor data to the control server 112.

The control server 112 may receive the sensor data from the infrared sensors or the ultrasonic sensors coupled to the rear side 200B of the compartment 502a and/or one or more images or videos captured by one or more image sensors deployed on at least one of the locker system 108 and the second robotic apparatus 122a. Based on the received sensor data and/or the one or more images, the control server 112 may be configured to determine whether the second robotic apparatus 122a is correctly aligned with the compartment 502a.

In an exemplary scenario, based on the received sensor data, the control server 112 may determine that the second robotic apparatus 122a is incorrectly aligned with the compartment 502a. The incorrect alignment may be due to an incorrect height of the level L1 (for example, the level L1 may not be at the same height as the shelf of the compartment 502a), a gap between the level L1 and the shelf of the compartment 502a, or a left or right offset between the conveyor 504a of the level L1 and the shelf of the compartment 502a. In such a scenario, the control server 112 may be configured to instruct the second robotic apparatus 122a to adjust the alignment with the compartment 502a by lowering or raising the level L1, eliminating the gap between the level L1 and the shelf of the compartment 502a, or eliminating the left or right offset between the conveyor 504a of the level L1 and the shelf of the compartment 502a. In another exemplary scenario, based on the received sensor data, the control server 112 may determine that the second robotic apparatus 122a is correctly aligned with the compartment 502a. In such a scenario, the control server 112 may be configured to instruct the second robotic apparatus 122a to transfer the first inventory items I1 and I2 to the compartment 502a.

For transferring the first inventory items I1 and I2 to the compartment 502a, the second robotic apparatus 122a may be configured to actuate (for example, rotate) the conveyor 504a at the level L1 in a clockwise direction (as shown by arrow 506) so that the first inventory items I1 and I2 are transferred onto the shelf of the compartment 502a. In an embodiment, while the first inventory items I1 and I2 are being transferred from the conveyor 504a to the compartment 502a, another item I3 placed at a conveyor 504b of the level L2 may also be transferred to another compartment 502b that is allocated to another process associated with the item I3. In other words, same robotic apparatus may be utilized by the control server 112 to transfer inventory items of different processes to different compartments of the locker system 108 concurrently.

In some embodiments, the control server 112 may be further configured to determine whether a correct item has been transferred into the compartment 502a. In an example, the weight sensor placed on or beneath the shelf of the compartment 502a may be able to sense the weight of the first inventory items I1 and I2. The sensor data of the weight sensor may be communicated to the control server 112, which compares the sensed weight with the actual weight of the first inventory items I1 and I2. Further, a code scanner (for example, a barcode scanner, a QR code scanner, or a radio frequency identifier (RFID) reader) present at the compartment 502a may be configured to scan identifiers of the first inventory items I1 and I2 and communicate the scanned identifiers to the control server 112. Based on the weight data and/or the scanned identifiers, the control server 112 may determine whether the items transferred to the compartment 502a are correct. In other words, the control server 112 may determine whether the transfer of the first inventory items I1 and I2 is a success or a failure. In an event of a failure of transfer, the control server 112 may determine a cause of the operational failure and generate correction-based instructions to correct the operational failure. In an example, the failure may have occurred due to a placement of an incorrect item in the compartment 502a. In such a scenario, the control server 112 may generate correction-based instructions for the second robotic apparatus 122a to transfer the correct first inventory items I1 and I2 to the compartment 502a and may instruct an operator to remove the incorrect item from the compartment 502a. In an event of success, the control server 112 may communicate a transfer success signal to the second robotic apparatus 122a to indicate the successful transfer of the first inventory items I1 and I2.

Upon successful transfer of the first inventory items I1 and I2 and other inventory items carried by the second robotic apparatus 122a into the locker system 108, the control server 112 may further provide instructions to the second robotic apparatus 122a to pick-up other inventory items from the first or second processing stations 118a or 118b for transfer.

The first inventory items I1 and I2 transported by the second robotic apparatus 122a are accessible from the front side 200A of the compartment 502a upon opening of a corresponding lockable door of the compartment 502a.

In FIG. 5A, another second robotic apparatus 122b is shown to be transporting one or more second inventory items I4 associated with a second process that is different from the first process. In an embodiment, the control server 112 may have allocated the compartment 502a to the second process and may have communicated a third set of instructions to the second robotic apparatus 122b to facilitate collection and transport of the second inventory items I4 by the second robotic apparatus 122b. In a scenario where the same compartment 502a is allocated to both the first and second processes, the second robotic apparatus 122b may only align with the locker system 108 from the rear side 200B based on the third set of instructions, when the first inventory items I1 and I2 are successfully collected from the compartment 502a and the second robotic apparatus 122a has moved away from the locker system 108. The second robotic apparatus 122b may align with the compartment 502a from the rear side 200B of the locker system 108 in a similar manner as the second robotic apparatus 122a had aligned with the compartment 502a. Based on the alignment of the second robotic apparatus 122b with the locker system 108 at the rear side 200B, the second inventory items I4 transported by the second robotic apparatus 122b are accessible from the front side 200A of the compartment 502a based on opening of the corresponding lockable door of the compartment 502a.

In another embodiment, the control server 112 may allocate another compartment 502c that is different from the compartment 502a to the second process. In such a scenario, where different compartments 502a and 502c are allocated to the first and second processes, the second robotic apparatus 122b may align with the locker system 108 from the rear side 200B concurrently with the second robotic apparatus 122a. Based on the alignment of the second robotic apparatus 122b with the locker system 108 at the rear side 200B, the second inventory items I4 transported by the second robotic apparatus 122b are accessible from the front side 200A of the compartment 502c based on opening of a corresponding lockable door of the compartment 502c.

Collection of an inventory item from a compartment of the locker system 108 is described in conjunction with FIG. 5B.

Referring now to FIG. 5B, a schematic diagram for collection of an item from the front side 200A of the locker system 108, in accordance with an exemplary embodiment of the present disclosure, is shown. A user (for example, an operator, a delivery personnel, or a customer) is able to collect inventory items associated with a process from the front side 200A of the locker system 108.

For the sake of brevity, the ongoing exemplary scenario is described for a user 508a who has placed an order (for example, a process request) and now wants to collect ordered inventory items 510. To collect the ordered inventory items 510, the user 508a may input a security parameter at the access control interface 109 (shown in FIG. 1). The security parameter may have been communicated to a user device of the user 508a by the control server 112 when the user 508a had placed the order. The security parameter communicated to the user device is associated with a compartment (for example, the compartment 202a) in which the inventory items 510 ordered by the user 508a are transferred for collection by the user 508a. In other words, the control server 112 may communicate the security parameter of the compartment 202a that is allocated to the order of the user 508a to the user device. In an embodiment, the security parameter may be a barcode and the user 508a may scan the barcode using a barcode scanner of the access control interface 109. In another embodiment, the security parameter may be a QR code and the user 508a may scan the QR code using a QR code scanner of the access control interface 109. In another embodiment, the security parameter may be an OTP and the user 508a may input the OTP using a keypad of the access control interface 109.

The access control interface 109 may communicate the inputted security parameter to the control server 112 over the communication network 114. The control server 112 may determine whether the received security parameter matches any of the security parameters stored in the memory 304. Based on a match of the received security parameter with at least one of the stored security parameters, the control server 112 may be configured to provide an unlock signal to the locker system 108 or the access control interface 109. The unlock signal may include an identifier of a compartment (for example, the compartment 202a) whose stored security parameter matched the received security parameter. The unlock signal is then communicated to the security lock mechanism of the compartment 202a. Upon receiving the unlock signal, the security lock mechanism of the compartment 202a opens the lockable door 204a of the compartment 202a such that the inventory items 510 placed in the compartment 202a become accessible to the user 508a from the front side 200A of the locker system 108. The user 508a is thus able to collect the inventory items 510 from the compartment 202a. Upon successful collection of the inventory items 510 from the compartment 202a, the security lock mechanism of the compartment 202a locks or closes the lockable door 204a. After the lockable door 204a is closed, new inventory items may be stored in the compartment 202a by the robotic apparatuses 110.

In an embodiment, the security parameter provided by the user 508a may be associated with multiple compartments due to the ordered inventory items being stored in multiple compartments. In such a scenario, the unlock signal generated by the control server 112 is capable of concurrently (e.g., at the same time) unlocking lockable doors of all the compartments that are allocated to the order of the user 508a. In an embodiment, when the security parameter is inputted to the access control interface 109 by the user 508a, the access control interface 109 may present an identifier of the compartment 202a to the user 508a. The identifier of the compartment 202a may be included in the unlock signal communicated by the control server 112 to the access control interface 109.

Further, as shown in FIG. 5B, multiple robotic apparatuses (for example, the second robotic apparatuses 122a and 122b) may be configured to store inventory items in different compartments of the locker system 108 concurrently.

Further, as shown in FIG. 5B, multiple users (for example, the user 508a and another user 508b) may concurrently collect corresponding inventory items from the locker system 108. For example, as shown, the lockable doors 204a and 204b are open at the same time so that the users 508a and 508b may concurrently collect their ordered inventory items 510 and 512 from the locker system 108.

Referring to FIG. 5C, a schematic diagram that illustrates a side view of the locker system 108, in accordance with an embodiment of the present disclosure, is shown. In FIG. 5C, the plurality of compartments of the locker system 108 are shown to have slanting shelves. For example, as shown, a compartment 502d of the locker system 108 has a slanting shelf 514 such that an elevated side of the slanting shelf 514 is positioned towards the rear side 200B of the locker system 108, whereas a slanting side of the slanting shelf 514 is positioned towards the front side 200A of the locker system 108. Once an inventory item 516 is transferred to the compartment 502d by the second robotic apparatus 122c, the slanting shelf 514 may cause the inventory item 516 to slide towards the front side 200A of the compartment 502d from the rear side 200B. Further, the compartment 502d may have a mechanical stopper and/or a plate coupled to the front side 200A of the compartment 502d that prevents the inventory item 516 from falling off the compartment 502d when a lockable door 518 of the compartment 502d is opened. It will be apparent to a person skilled in art that the scope of the disclosure is not limited to the slanting shelf 514, but any other form of mechanism that may assist in the movement of the inventory items from the rear side 200B to the front side 200A may be implemented, without deviating from the scope of the disclosure.

FIG. 6 is a diagram 600 that illustrates transfer of inventory items to the locker system 108 using a robotic apparatus, in accordance with an embodiment of the present disclosure. As shown in FIG. 6, the fourth robotic apparatus 126a has a robotic arm 602 with multiple degrees of freedom and a spatula-shaped end effector 604 coupled to the robotic arm 602. The spatula-shaped end effector 604 may include a conveyor 606 that could be rotated (e.g., actuated) in clockwise or anti-clockwise direction. In an example, the fourth robotic apparatus 126a may be selected by the control server 112 to transfer inventory items 608 associated with a process to an allocated compartment (e.g., the compartment 502a) of the locker system 108. The control server 112 may communicate instructions to the fourth robotic apparatus 126a to place the inventory item 608 in the compartment 502a. Based on the instructions, the fourth robotic apparatus 126a carrying the inventory items 608 may align with the compartment 502a at the rear side 200B after identifying the compartment 502a. The instructions may further include position and identifier of the compartment 502a and a degree of movement required for the robotic arm 602 to move the spatula-shaped end effector 604 from an original position to a desired height to place the inventory item 608 in the compartment 502a. Once the spatula-shaped end effector 604 has attained the desired position, the fourth robotic apparatus 126a actuates the conveyor 606 to transfer the inventory item 608 into the compartment 502a.

As shown in FIG. 6, while the fourth robotic apparatus 126a is transferring the inventory item 608 into the compartment 502a, another fourth robotic apparatus 126b may concurrently transfer another inventory item into a different compartment 610 of the locker system 108.

Although FIG. 6 shows two fourth robotic apparatuses 126a and 126b concurrently transferring the inventory items to different compartments 502a and 610 of the locker system 108, the scope of the disclosure is not limited to it. In other embodiments, different types of robotic apparatuses 110 may concurrently transfer inventory items into different compartments of the locker system 108, without deviating from the scope of the disclosure.

FIGS. 7A and 7B are diagrams 700A and 700B that illustrate a locker system 702 to be used in the storage facility 102 for delivery and collection of inventory items, in accordance with another embodiment of the present disclosure.

Referring now to FIG. 7A, the locker system 702 is operationally similar to the locker system 108 shown in FIGS. 2A and 2B but differs in structure, for example, the locker system 702 includes a plurality of compartments that do not have any shelves and a plurality of lockable doors that control access to the plurality of compartments, respectively. Each compartment of the plurality of compartments is accessible from a front side 704a and a rear side (shown in FIG. 7B) of the locker system 702. An access to each compartment from the front side 704a is controlled by a corresponding lockable door positioned at the front side 704a, and each compartment is open from the rear side. In other words, the locker system 702 is a frame-like structure that has a plurality of openings that are formed in longitudinal axis and vertical axis where each opening defines a compartment without shelf and the compartment is secured at the front side 704a with a lockable door. For the sake of brevity, three of the compartments 706a, 706b, and 706c of the plurality of compartments and four of the lockable doors 708a, 708b, 708c, and 708d of the plurality of lockable doors, are labelled.

As shown in FIG. 7A, access to the compartments 706a, 706b, and 706c is controlled by the lockable doors 708a, 708b, and 708c, respectively. Since the lockable doors 708a, 708b, and 708c are open, the respective compartments 706a, 706b, and 706c are accessible from the front side 704a; however, the lockable door 708d is closed and as a result, a corresponding compartment is not accessible from the front side 704a.

In an embodiment, the plurality of compartments may have same size and dimensions. In another embodiment, the plurality of compartments may have different sizes and dimensions. For example, as shown in FIG. 7A, the compartments 706a, 706b, and 706c are of the same size; however, the compartment of the lockable door 708d is larger in size and dimensions as compared to the compartments 706a, 706b, and 706c.

Referring now to FIG. 7B, the rear side 704b of the locker system 702, in accordance with an embodiment of the present disclosure, is shown. The rear side 704b of the locker system 702 serves as an access point for the robotic apparatuses 110 whereas the front side 704a serves as an access point for collecting the inventory items from the plurality of compartments.

The robotic apparatuses 110 may collect the inventory items associated with different processes from the first and second processing stations 118a and 118b and transport the collected inventory items to the locker system 702 under the control of the control server 112 (as described in the foregoing description of FIGS. 1-6). Upon reaching a location of the locker system 702, the robotic apparatuses 110 may align with those compartments that are allocated to the respective processes by the control server 112. As the plurality of compartments of the locker system 702 do not have any storage shelves, the robotic apparatuses 110 remain aligned with the respective compartments until the inventory items are collected by corresponding users from the front side 704a upon opening of the lockable doors of the respective compartments.

For example, as shown in FIG. 7B, the second robotic apparatus 122a is aligned with the compartments 706b and 706c so that inventory items 710a and 710b placed on the level L1 of the second robotic apparatus 122a could be accessed from the front side 704a of the locker system 702 when the lockable doors 708b and 708c are opened. In FIG. 7B, the lockable doors 708b and 708c are shown to be open and a user 712 is collecting the inventory items 710a and 710b from the level L1 of the second robotic apparatus 122a via the compartments 706a and 706b, respectively. Opening and closing of the plurality of lockable doors of the locker system 702 are controlled by the control server 112 in a similar manner as the plurality of lockable doors of the locker system 108 (as described in the foregoing description of the FIGS. 1-6). In the exemplary scenario of FIG. 7B, the inventory items 710a and 710b of the user 712 are made accessible concurrently by concurrent opening of the lockable doors 708b and 708c. Thus, the user 712 may collect both the inventory items 710a and 710b from the second robotic apparatus 122a at the same time. Similarly, FIG. 7B shows another second robotic apparatus 122b, carrying inventory items 710c and 710d, aligned with the compartments 706a and 706d. The inventory item 710c may be collected from the front side 704a of the compartment 706a and the inventory item 710d may be collected from the front side 704a of the compartment 706d. At a current time-instance, the lockable door 708a of the compartment 706a is open, and hence the inventory item 710c may be collected from the second robotic apparatus 122b by a corresponding user (not shown) via the compartment 706a. However, the lockable door of the compartment 706d is closed, and hence the inventory item 710d is inaccessible from the front side 704a. Such controlled opening and closing of the plurality of lockable doors of the locker system 702 prevents unauthorized access to the inventory items.

In an embodiment, based on a size of a compartment, multiple conveyors on a level of a second robotic apparatus (e.g., any of the plurality of second robotic apparatuses 122a-122n) could be aligned with a single compartment of the locker system 702. For example, two conveyors at the level L2 of the second robotic apparatus 122a may concurrently align with a compartment corresponding to the lockable door 708d (shown in FIG. 7A). Therefore, any inventory items placed on the two conveyors of the level L2 of the second robotic apparatus 122a may be accessed concurrently from the same compartment upon opening of the lockable door 708d (shown in FIG. 7A).

FIG. 8 is a diagram 800 that illustrates collection of inventory items from the locker system 702, in accordance with another embodiment of the present disclosure. As shown in FIG. 8, the fourth robotic apparatus 126a may be selected by the control server 112 to make an inventory item 802a associated with a process accessible from an allocated compartment (e.g., the compartment 706b) of the locker system 702. The control server 112 may communicate instructions to the fourth robotic apparatus 126a to align with the compartment 706b at the rear side 704b of the locker system 702. The instructions may further include a position and an identifier of the compartment 706b and a degree of movement required for the robotic arm 602 to move the spatula-shaped end effector 604 from an original position to a desired height of the compartment 706b. Once the spatula-shaped end effector 604 has attained the desired position, the fourth robotic apparatus 126a remains aligned with the compartment 706b until the inventory item 802a is collected by a corresponding user 804. As shown in FIG. 8, the lockable door 708b of the compartment 706b is open and the user 804 is stretching their hand to collect the inventory item 802a. Upon successful collection of the inventory item 802a by the user 804, the lockable door 708b closes and the fourth robotic apparatus 126a becomes available for executing a next operation.

FIGS. 9A and 9B are diagrams that illustrate an exemplary scenario 900 for collection of inventory items from the locker system 702, in accordance with another embodiment of the present disclosure.

Referring now to FIG. 9A, the first robotic apparatus 120a is shown to have transported a storage system 901 to a location of the locker system 702. The storage system 901 is structurally and functionally similar to the storage systems 116 shown in FIG. 1. The storage system 901 may have a plurality of shelves 902a-902d each storing inventory items corresponding to a unique process. For example, the shelf 902a may store thereon inventory items 904 associated with an order of a customer 906. The control server 112 may have instructed the first robotic apparatus 120a to transport the inventory items 904 to the location of the locker system 702 by lifting and transporting the storage system 901, and aligning with the locker system 702 from the rear side 704b. When the first robotic apparatus 120a aligns with the locker system 702 from the rear side 704b, the shelf 902a storing the inventory items 904 is aligned with the compartment 706b which is allocated to the process associated with the inventory items 904. The first robotic apparatus 120a may be configured to adjust a height of the storage system 901 such that the shelf 902a is aligned with the compartment 706b from the rear side 704b of the locker system 702. The first robotic apparatus 120a may remain aligned with the locker system 702 until the inventory items 904 are collected by the customer 906 via the compartment 706b.

Referring now to FIG. 9B, the front side 704a of the locker system 702 is shown while the first robotic apparatus 120a carrying the storage system 901 is aligned with the locker system 702 from the rear side 704b. In FIG. 9B, the lockable door 708b is shown to be open and the customer 906 is attempting to collect the inventory items 904 from the shelf 902a via the compartment 706b. Upon successful collection of the inventory items 904 by the customer 906, the lockable door 708b is closed and the first robotic apparatus 120a transports the storage system 901 to another location for executing a next operation. Opening and closing of the plurality of lockable doors of the locker system 702 are controlled by the control server 112 in a similar manner as the plurality of lockable doors of the locker system 108 (as described in the foregoing description of the FIGS. 1-6).

FIG. 10 is a block diagram that illustrates a system architecture of a computer system 1000 for inventory management in the storage facility 102, in accordance with an exemplary embodiment of the disclosure. An embodiment of the disclosure, or portions thereof, may be implemented as computer readable code on the computer system 1000. In one example, the control server 112 of FIG. 1 may be implemented in the computer system 1000 using hardware, software, firmware, non-transitory computer-readable media having instructions stored thereon, or a combination thereof and may be implemented in one or more computer systems or other processing systems. Hardware, software, or any combination thereof may embody modules and components used to implement the methods of FIGS. 11 and 12. The computer system 1000 may include a main memory 1002, a secondary memory 1004, a processor 1006, a communication interface 1008, an input/output (I/O) port 1010, and a communication infrastructure 1012.

Examples of the main memory 1002 may include random access memory (RAM), read-only memory (ROM), and the like. The secondary memory 1004 may include a hard disk drive or a removable storage drive (not shown), such as a floppy disk drive, a magnetic tape drive, a compact disc, an optical disk drive, a flash memory, or the like. Further, the removable storage drive may read from and/or write to a removable storage device in a manner known in the art. In an embodiment, the removable storage system may be a non-transitory computer-readable recording media.

The processor 1006 may be a special purpose or a general-purpose processing device. The processor 1006 may be a single processor or multiple processors. The processor 1006 may have one or more processor “cores.” Further, the processor 1006 may be coupled to the communication interface 1008 such as a bus, a bridge, a message queue, the communication network 114, multi-core message-passing scheme, or the like.

The I/O port 1010 may include various input and output devices that are configured to communicate with the processor 1006. Examples of the input devices may include a keyboard, a mouse, a joystick, a touchscreen, a microphone, and the like. Examples of the output devices may include a display screen, a speaker, headphones, and the like. The communication infrastructure 1012 may be configured to allow data to be transferred between the computer system 1000 and various devices that are communicatively coupled to the computer system 1000. Examples of the communication infrastructure 1012 may include a modem, a network interface, i.e., an Ethernet card, a communication port, and the like. Data transferred via the communication infrastructure 1012 may be signals, such as electronic, electromagnetic, optical, or other signals as will be apparent to a person skilled in the art. The signals may travel via a communications channel, such as the communication network 114, which may be configured to transmit the signals to the various devices that are communicatively coupled to the computer system 1000. Examples of the communication channel may include a wired, wireless, and/or optical medium such as cable, fiber optics, a phone line, a cellular phone link, a radio frequency link, and the like. The main memory 1002 and the secondary memory 1004 may refer to non-transitory computer-readable mediums that may provide data that enables the computer system 1000 to implement the method illustrated in FIGS. 11 and 12.

FIG. 11 is a flow chart 1100 that illustrates an automated locker management method for delivery and collection of inventory items using the locker system 108 or the locker system 702 in the storage facility 102, in accordance with an exemplary embodiment of the disclosure. At 1102, one or more first compartments of a plurality of compartments in the locker system 108 or the locker system 702 are allocated to a first process in the storage facility 102. The control server 112 may be configured to allocate the one or more first compartments of the plurality of compartments in the locker system 108 or the locker system 702 to the first process in the storage facility 102. Allocation of the one or more first compartments of the locker system 108 or the locker system 702 to the first process by the control server 112 is described in the foregoing description of FIGS. 1-9. Each compartment of the plurality of compartments may be accessible from a front side and a rear side of the locker system 108 or the locker system 702. An access to each compartment of the plurality of compartments from the front side is controlled by a corresponding lockable door of a plurality of lockable doors of the locker system 108 or the locker system 702. Each compartment of the plurality of compartments is open from the rear side.

At 1104, a first set of instructions is communicated to a robotic apparatus (e.g., any of the robotic apparatuses 110) to cause the robotic apparatus to align with the locker system 108 or the locker system 702 from the rear side. The control server 112 may be configured to communicate the first set of instructions to the robotic apparatus (e.g., any of the robotic apparatuses 110) to cause the robotic apparatus to align with the locker system 108 or the locker system 702 from the rear side. Based on the alignment of the robotic apparatus with the locker system 108 or the locker system 702 from the rear side, one or more first items transported by the robotic apparatus are accessible from the front side of the one or more first compartments based on opening of corresponding lockable doors of the one or more first compartments. The one or more first items are associated with the first process allocated to the one or more first compartments.

At 1106, opening of corresponding lockable doors of the one or more first compartments of the locker system 108 or the locker system 702 is controlled, so that the one or more first items of the first process are accessible from the front side of the locker system 108 or the locker system 702. The control server 112 may be configured to control opening of the corresponding lockable doors of the one or more first compartments, so that the one or more first items of the first process are accessible from the front side of the locker system 108 or the locker system 702. A method for controlling the opening of the corresponding lockable doors by the control server 112 is described later in conjunction with FIG. 12.

At 1108, the one or more first compartments or one or more second compartments are allocated to a second process. The control server 112 may be further configured to allocate the one or more first compartments or the one or more second compartments to the second process.

At 1110, a second set of instructions are communicated to another robotic apparatus (any of the remaining robotic apparatuses 110) to cause the other robotic apparatus to align with the locker system 108 or the locker system 702 from the rear side. The control server 112 may be configured to communicate the second set of instructions to the other robotic apparatus (e.g., any of the robotic apparatuses 110) to cause the other robotic apparatus to align with the locker system 108 or the locker system 702 from the rear side. Based on the second set of instructions, the other robotic apparatus aligns with the locker system 108 or the locker system 702 from the rear side. Based on the alignment of the other robotic apparatus with the locker system 108 or the locker system 702 from the rear side, one or more second items transported by the other robotic apparatus are accessible from the front side of the one or more first compartments or the one or more second compartments based on opening of corresponding lockable doors of the one or more first compartments or the one or more second compartments, respectively.

FIG. 12 is a flow chart 1200 that illustrates a method for controlling opening of lockable doors of one or more compartments of the automated locker system 108 or 702, in accordance with an exemplary embodiment of the disclosure. At 1202, one or more security parameters provided by a user is received by the control server 112. The control server 112 may be configured to receive the security parameters provided by the user from the access control interface 109 over the communication network 114.

At 1204, the one or more security parameters provided by the user are compared with one or more stored security parameters of the plurality of lockable doors of the locker system 108 or 702. The control server 112 may be configured to compare the one or more security parameters provided by the user with the one or more security parameters stored in the memory 304 (as shown in FIG. 3).

At 1206, corresponding lockable doors of the one or more first compartments are controlled to open based on the comparison of the one or more security parameters provided by the user with the one or more stored security parameters of the corresponding lockable doors. The control server 112 may be further configured to control opening of the corresponding lockable doors of the one or more first compartments based on the comparison of the one or more security parameters provided by the user with the one or more stored security parameters of the corresponding lockable doors.

The disclosed embodiments encompass numerous advantages. Exemplary advantages of the disclosed methods include, but are not limited to, an automated locker system management for delivery and collection of inventory items. The disclosed methods and systems significantly reduce manual labor requirement (e.g., conventionally a compartment needs to be opened twice, one for transporting item into the compartment and then to retrieve the item) during handling of the inventory items in the storage facilities. For example, the disclosed methods and systems offer a no-walk solution for the storage facility 102 where operators are not required to move from one location to another for any operation. Therefore, the disclosed methods and systems significantly reduce a time required for processing an order. Consequently, the disclosed methods and systems increase the throughput of the storage facility 102. Further, the disclosed methods and systems significantly reduce inconvenience caused to operators and users in the storage facility 102 during collection of inventory items associated with a process. The locker system 108 or the locker system 702 enables a physical partition between a non-man zone (e.g., an area in a storage facility where the robotic apparatuses 110 are deployed) and a manned zone (e.g., an area where human presence is allowed) for delivery and collection of inventory items. The disclosed methods and systems significantly reduce chances of human errors during transportation and delivery of orders. Since the delivery and collection of inventory items is automated by the control server 112, a likelihood of an incorrect order or items being presented to a user is eliminated. The disclosed methods and systems enable automated handling of inventory items without having to make any significant change to existing infrastructure of the storage facility 102. Hence, the disclosed methods and systems are cost-efficient and provide an optimal solution for hassle-free handling of the inventory items.

Further, the locker system 108 or the locker system 702 is portable and can be moved from one location to another location by any of the plurality of first robotic apparatuses 120a-120n. The portability feature of the locker system 108 or the locker system 702 enables easy and convenient set up of a delivery and collection area in the storage facility 102.

A person of ordinary skill in the art will appreciate that embodiments and exemplary scenarios of the disclosed subject matter may be practiced with various computer system configurations, including multi-core multiprocessor systems, minicomputers, mainframe computers, computers linked or clustered with distributed functions, as well as pervasive or miniature computers that may be embedded into virtually any device. Further, the operations may be described as a sequential process, however some of the operations may in fact be performed in parallel, concurrently, and/or in a distributed environment, and with program code stored locally or remotely for access by single or multiprocessor machines. In addition, in some embodiments, the order of operations may be rearranged without departing from the scope of the disclosed subject matter.

Techniques consistent with the disclosure provide, among other features, systems and methods for automated delivery and collection of inventory items in a storage facility. While various exemplary embodiments of the disclosed systems and methods have been described above, it should be understood that they have been presented for purposes of example only, and not limitations. It is not exhaustive and does not limit the disclosure to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practicing the disclosure, without departing from the breadth or scope.

While various embodiments of the disclosure have been illustrated and described, it will be clear that the disclosure is not limited to these embodiments only. Numerous modifications, changes, variations, substitutions, and equivalents will be apparent to those skilled in the art, without departing from the scope of the disclosure, as described in the claims.

Claims

1. An automated locker management system, comprising:

a locker system including a plurality of compartments and a plurality of lockable doors, wherein each compartment of the plurality of compartments is accessible from a front side and a rear side of the locker system, wherein an access to each compartment of the plurality of compartments from the front side is controlled by a corresponding lockable door of the plurality of lockable doors, and wherein each compartment of the plurality of compartments is open from the rear side;
a plurality of robotic apparatuses, wherein a first robotic apparatus of the plurality of robotic apparatuses is configured to transport one or more first items associated with a first process at a storage facility; and
a control server configured to:
allocate one or more first compartments of the plurality of compartments to the first process; and
communicate a first set of instructions to the first robotic apparatus to cause the first robotic apparatus to align with the locker system from the rear side, wherein based on the alignment of the first robotic apparatus with the locker system at the rear side, the one or more first items transported by the first robotic apparatus are accessible from the front side of the one or more first compartments upon opening of corresponding lockable doors of the one or more first compartments.

2. The automated locker management system of claim 1, wherein a second robotic apparatus of the plurality of robotic apparatuses is configured to transport one or more second items associated with a second process at the storage facility, and wherein the control server is further configured to:

allocate the one or more first compartments to the second process; and
communicate a second set of instructions to the second robotic apparatus to cause the second robotic apparatus to align with the locker system from the rear side, wherein the second robotic apparatus is configured to align with the locker system from the rear side based on the second set of instructions when the one or more first items are successfully collected from the one or more first compartments, and wherein based on the alignment of the second robotic apparatus with the locker system at the rear side, the one or more second items transported by the second robotic apparatus are accessible from the front side of the one or more first compartments based on opening of the corresponding lockable doors of the one or more first compartments.

3. The automated locker management system of claim 1, wherein a second robotic apparatus of the plurality of robotic apparatuses is configured to transport one or more second items associated with a second process at the storage facility, and wherein the control server is further configured to:

allocate one or more second compartments of the plurality of compartments to the second process, wherein the one or more second compartments are different from the one or more first compartments; and
communicate a second set of instructions to the second robotic apparatus to cause the second robotic apparatus to align with the locker system from the rear side concurrently with the first robotic apparatus, wherein based on the alignment of the second robotic apparatus with the locker system at the rear side, the one or more second items transported by the second robotic apparatus are accessible from the front side of the one or more second compartments based on opening of corresponding lockable doors of the one or more second compartments.

4. The automated locker management system of claim 1, wherein the control server is further configured to control opening of each lockable door of the plurality of lockable doors based on a corresponding security parameter.

5. The automated locker management system of claim 4, wherein the corresponding security parameter is at least one of a password, a machine-readable optical code, or biometric information of a user.

6. The automated locker management system of claim 1, wherein the control server is further configured to control the corresponding lockable doors of the one or more first compartments to open concurrently based on one security parameter.

7. The automated locker management system of claim 1, wherein the control server is further configured to:

receive, from the locker system, one or more security parameters provided by a user to open the corresponding lockable doors of the one or more first compartments;
compare the one or more security parameters provided by the user with one or more stored security parameters of the corresponding lockable doors of the one or more first compartments; and
control the corresponding lockable doors of the one or more first compartments to open based on the comparison of the one or more security parameters provided by the user with the one or more stored security parameters of the corresponding lockable doors.

8. The automated locker management system of claim 1, further comprising a set of storage systems such that a first storage system of the set of storage systems is configured to store the one or more first items on one or more shelves thereof, and wherein the first robotic apparatus is configured to transport the one or more first items by lifting and transporting the first storage system.

9. The automated locker management system of claim 8, wherein when the first robotic apparatus aligns with the locker system based on the first set of instructions, the one or more shelves storing the one or more first items are aligned with the one or more first compartments.

10. The automated locker management system of claim 1, wherein the first robotic apparatus includes one or more conveyors such that the one or more first items are placed on the one or more conveyers, and wherein when the first robotic apparatus aligns with the locker system based on the first set of instructions, the one or more conveyors having the one or more first items thereon are aligned with the one or more first compartments.

11. The automated locker management system of claim 10, wherein the first robotic apparatus is further configured to actuate the one or more conveyors based on the first set of instructions to transfer the one or more first items from the one or more conveyers to the one or more first compartments.

12. The automated locker management system of claim 1, wherein the first robotic apparatus includes one or more levels such that the one or more first items are placed on the one or more levels, and wherein when the first robotic apparatus aligns with the locker system based on the first set of instructions, the one or more levels of the first robotic apparatus are aligned with the one or more first compartments.

13. An automated locker management method, comprising:

allocating, by a control server, one or more first compartments of a plurality of compartments in a locker system to a first process in a storage facility, wherein each compartment of the plurality of compartments is accessible from a front side and a rear side of the locker system, wherein an access to each compartment of the plurality of compartments from the front side is controlled by a corresponding lockable door of a plurality of lockable doors of the locker system, and wherein each compartment of the plurality of compartments is open from the rear side; and
communicating, by the control server, a first set of instructions to a first robotic apparatus to cause the first robotic apparatus to align with the locker system from the rear side, wherein based on the alignment of the first robotic apparatus with the locker system at the rear side, one or more first items transported by the first robotic apparatus are accessible from the front side of the one or more first compartments based on opening of corresponding lockable doors of the one or more first compartments; and wherein the one or more first items are associated with the first process allocated to the one or more first compartments.

14. The automated locker management method of claim 13, further comprising:

allocating, by the control server, one or more first compartments to a second process; and
communicating, by the control server, a second set of instructions to a second robotic apparatus configured to transport one or more second items associated with the second process at the storage facility, wherein the second set of instructions cause the second robotic apparatus to align with the locker system from the rear side, and wherein the second robotic apparatus aligns with the locker system from the rear side based on the second set of instructions when the one or more first items are successfully collected from the one or more first compartments, and wherein based on the alignment of the second robotic apparatus with the locker system at the rear side, the one or more second items transported by the second robotic apparatus are accessible from the front side of the one or more first compartments based on opening of the corresponding lockable doors of the one or more first compartments.

15. The automated locker management method of claim 13, further comprising controlling, by the control server, opening of each lockable door of the plurality of lockable doors based on a corresponding security parameter.

16. The automated locker management method of claim 15, wherein the corresponding security parameter is at least one of a password, a machine-readable optical code, or biometric information of a user.

17. The automated locker management method of claim 13, further comprising controlling, by the control server, the corresponding lockable doors of the one or more first compartments to open concurrently based on one security parameter.

18. The automated locker management method of claim 13, further comprising:

receiving, by the control server, from the locker system, one or more security parameters provided by a user to open the corresponding lockable doors of the one or more first compartments;
comparing, by the control server, the one or more security parameters provided by the user with one or more stored security parameters of the corresponding lockable doors of the one or more first compartments; and
controlling, by the control server, corresponding lockable doors of the one or more first compartments to open based on the comparison of the one or more security parameters provided by the user with the one or more stored security parameters of the corresponding lockable doors.

19. An automated locker system, comprising:

a plurality of lockable doors, wherein opening of each lockable door of the plurality of lockable doors is controlled based on a corresponding security parameter of each lockable door;
a security lock mechanism configured to control opening and closing of each lockable door based on the corresponding security parameter; and
a plurality of compartments, wherein each compartment of the plurality of compartments is accessible from a front side and a rear side of the locker system, wherein an access to each compartment of the plurality of compartments from the front side is controlled by a corresponding lockable door of the plurality of lockable doors, wherein each compartment of the plurality of compartments is open from the rear side, wherein when a robotic apparatus, transporting one or more items associated with a process at a storage facility, aligns with the locker system from the rear side, the one or more items are accessible from the front side of the locker system based on opening of one or more corresponding lockable doors of one or more compartments of the plurality of compartments.

20. The automated locker system of claim 19, further comprising:

an input/output interface configured to receive one or more security parameters provided by a user to open the corresponding lockable doors of the one or more compartments, wherein the security lock mechanism is further configured to open the corresponding lockable doors of the one or more compartments when the one or more security parameters provided by the user matches one or more stored security parameters of the corresponding lockable doors.
Patent History
Publication number: 20220315341
Type: Application
Filed: Feb 10, 2022
Publication Date: Oct 6, 2022
Applicant: Grey Orange Inc. (Roswell, GA)
Inventors: Tihut Degfae (Richmond, VA), Siddharth Malhotra (New Delhi), Jai Thakkar (Dhanbad), Mohit Kumar (Meerut), Sumit Kr. Tiwary (Gorakhpur)
Application Number: 17/668,938
Classifications
International Classification: B65G 1/137 (20060101); B66F 9/19 (20060101); B65G 1/06 (20060101); G06Q 10/08 (20060101); G06F 21/31 (20060101);