US20260182765A1
2026-07-02
19/437,861
2025-12-31
Smart Summary: A new storage system is designed to be secure and easy to use. It has special ways to attach it to buildings or other structures, making it both safe and affordable. Users will find it convenient, with features that help them operate it easily and check how much space is available. The system also allows for real-time updates on its status, which is useful for both users and delivery services. Additionally, it can work with drones for deliveries, ensuring that the storage compartment is securely closed during package transfers. 🚀 TL;DR
A secure storage system featuring enhancements for simplified and cost-effective tethering, user convenience, and aesthetic appeal. The system includes innovative tethering methods and mechanisms for securely attaching the storage system to external structures, ensuring ease of use and robust security at a low cost. Additional features focus on improving user experience, including simplified operation, enhanced delivery efficiency, and real-time monitoring of storage capacity and system status. The disclosed methods and systems enable secure and efficient access while providing valuable feedback and capacity information to users and delivery services. In some embodiments, the system supports coordinated aerial delivery in which access to a storage compartment is controlled in coordination with an aerial delivery device, including embodiments in which a delivery opening is physically covered during package transfer.
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A47G29/20 » CPC main
Supports, holders, or containers for household use, not provided for in groups - or  ; Deposit receptacles for food, e.g. breakfast, milk, or large parcels ; Similar receptacles for large parcels with appliances for preventing unauthorised removal of the deposited articles with appliances for preventing unauthorised removal of the deposited articles
A47G29/141 » CPC further
Supports, holders, or containers for household use, not provided for in groups - or  ; Deposit receptacles for food, e.g. breakfast, milk, or large parcels ; Similar receptacles for large parcels with appliances for preventing unauthorised removal of the deposited articles comprising electronically controlled locking means
A47G2029/145 » CPC further
Supports, holders, or containers for household use, not provided for in groups - or  ; Deposit receptacles for food, e.g. breakfast, milk, or large parcels ; Similar receptacles for large parcels with appliances for preventing unauthorised removal of the deposited articles comprising electronically controlled locking means the receptacle comprising means for identifying a deposit; Deposits carrying identification means, e.g. a bar code
A47G29/14 IPC
Supports, holders, or containers for household use, not provided for in groups - or  Deposit receptacles for food, e.g. breakfast, milk, or large parcels ; Similar receptacles for large parcels with appliances for preventing unauthorised removal of the deposited articles
Certain embodiments of the present invention relate to storage systems that incorporate mechanisms and locks for securing a storage device to external structures. In some embodiments, such storage systems further incorporate monitoring, communication, or control features associated with package delivery and storage.
In many conventional package storage systems, an additional lock or mechanical linkage is required, thereby complicating the overall design. For example, in some existing package storage systems, a lock is used to secure the package storage compartment and an additional, secondary, lock is used to secure the package storage system itself to a doorknob or handle to impede would-be thieves from stealing the entire unit. This reliance on multiple locks drives up both cost and complexity, which present a meaningful challenge for producing systems at scale. Additionally, secondary locks can introduce extra points of failure, rendering some storage solutions unwieldy or prone to user error. Consequently, there is a demand for storage systems that reduce or eliminate the need for additional locks while still providing the desired security, affordability, and reliability.
In many conventional approaches, storage systems attach directly to the door or its handle via cables or other external hardware. Such setups can block or hinder normal door entry and exit, and the aesthetic impact of lengthy cables can discourage widespread use. At the same time, users often desire an added sense of security—some are willing to accept more complex locking methods to ensure the package storage system is firmly secured to the dwelling. Consequently, there is a recognized need for multi-functional locking and attachment options that balance convenience, visual appeal, and the robust security demanded in modern delivery environments. In addition, delivery personnel may have difficulty locating, identifying, or confirming an intended delivery receptacle, creating a need for systems that can provide status or guidance indications without compromising security or privacy.
Existing package storage systems face significant challenges in reliably and securely managing the opening and closing of storage compartments. For example, achieving fully automated mechanisms remains particularly difficult due to cost constraints and the technical demands of robust locking systems that prevent unauthorized access. Many designs struggle to balance security, affordability, and user convenience, resulting in systems that are either overly complex, insufficiently secure, or entirely manual. Moreover, the lack of integrated control features capable of monitoring and communicating storage status further limits their effectiveness and appeal in modern delivery environments. These limitations have hindered the widespread adoption of cost-effective, hands-free solutions that meet the needs of both security-conscious and budget-conscious users. These challenges are further compounded in delivery scenarios that benefit from coordinated or automated access to the storage compartment.
Despite the growing demand for convenient, automated solutions, implementing hands-free or fully automated opening and closing mechanisms in package storage systems has proven challenging in practice. Cost constraints often limit the feasibility of incorporating the necessary mechanical and electronic components for automation. Moreover, prioritizing affordability frequently leaves concerns about robust locking mechanisms unaddressed, further complicating the design process. As a result, many current systems still rely on manual or partially manual methods, failing to meet user expectations for security and convenience in modern delivery environments.
Another issue in the field of package storage security is that the degree of protection is often directly related to the motivation and resources of potential thieves. In other words, sufficiently determined individuals can often circumvent even rigorous security measures. This creates a persistent challenge for storage systems, which must strike a balance between practical security features and the limitations of cost, complexity, and user convenience. Accordingly, there is a need for innovative, cost-effective features that raise the effort threshold for unauthorized access while maintaining or enhancing accessibility for authorized users. In some cases, there is also a need to detect tampering or unauthorized interference and to provide notification or deterrence without adding undue cost or complexity.
Another issue is that when a storage system reaches capacity and can no longer accommodate new packages, subsequent deliveries are often left outside the system instead of being delivered into the secure package storage compartment. This bypasses the intended security features, increasing the likelihood of theft and undermining the system's effectiveness. Moreover, the inability to manage overflow situations creates additional logistical challenges for users and delivery personnel, highlighting the need for systems that can intelligently monitor, communicate, and manage storage capacity to ensure continuous security and usability. Such limitations can also impede verification of delivered packages and communication of remaining storage availability to users or delivery services.
In response to these challenges, various embodiments of the disclosed package storage system provide secure and efficient management of storage compartments. For example, the system can integrate robust locking mechanisms, automated opening and closing features, and advanced control subsystems that monitor and communicate storage status, thereby addressing several limitations of existing systems.
In some embodiments, the present disclosure is directed to a securement system for a package storage unit that enables the unit to be secured to a dwelling structure while reducing or eliminating the need for a separate external lock dedicated solely to securement of the unit. Such embodiments can integrate securement of the storage unit with access control for the storage compartment, thereby reducing hardware redundancy, installation complexity, and user error while maintaining resistance to unauthorized removal.
In some embodiments, the present disclosure is directed to systems and methods for assessing the contents or remaining capacity of a package storage compartment. Such assessment can support determination of whether additional packages can be received, estimation of remaining storage capacity, verification of delivered packages, or communication of storage availability to users or delivery services.
In some embodiments, the present disclosure is directed to package storage systems that include one or more indicators or signaling features configured to assist delivery personnel or users in locating, identifying, or confirming a delivery receptacle or delivery status. Such indicators can be configured to provide guidance or confirmation while preserving security and privacy.
In some embodiments, the present disclosure is directed to coordinated or automated delivery in which access to a package storage compartment is controlled in coordination with an external delivery device. Such coordination can include sequencing of access events, controlled opening of a delivery door, or interaction with delivery equipment in a manner that limits unauthorized access to the storage compartment.
In certain embodiments, the present disclosure provides a storage security system that balances affordable features with enhanced security features that promote user confidence. By increasing the effort required for unauthorized individuals to steal or remove packages from the system, the invention discourages unauthorized access while remaining accessible and convenient for authorized users.
In one embodiment, the package storage system includes a tethering cable that securely connects the storage unit to an external structure, such as a door. The system employs a dual-bracket configuration, with one bracket anchoring the cable externally and another securing the cable internally within the storage unit. This arrangement ensures robust attachment to the external structure while protecting the cable termination inside the storage compartment. A digital lock further enhances security by controlling access to both the package storage compartment and the tethering cable, preventing unauthorized removal.
For example, in certain embodiments, the external bracket clips onto the door and may incorporate a spring element and felt liner to accommodate doors of varying thicknesses, ensuring a stable and damage-free attachment. The tethering cable extends through the external bracket and into the storage system, where it is terminated at an internal bracket. This internal bracket facilitates tensioning of the cable to anchor the storage unit securely to the external structure. To further enhance security, the internal bracket can be reinforced by a securing rod and protected by the digital lock, reducing the risk of tampering or unauthorized access.
In another embodiment, the package storage system incorporates locking guides and a spring mechanism to facilitate the operation of the lid. When the lid is pressed closed, the locking guides compress the spring until the latch securely engages. Upon release, the stored energy in the spring is used to automatically lift the lid, providing convenient and hands-free access to the storage compartment.
In additional embodiments, the system may include one or more sensor systems and associated control logic to detect packages within the storage compartment. For example, the system may utilize an optical image sensor or a time-of-flight sensor to measure the height of packages placed inside. Sensor data can be analyzed using optical image processing and/or artificial intelligence (AI) algorithms to determine the package height and overall fill level of the storage system. In certain embodiments, a height indicator molded or etched within the internal compartment (e.g., on an internal leg support or side panel) serves as a reference point for optical measurements, improving the accuracy of package detection and fill-level assessment.
The package storage system can include an actuator system to open and close the lid. In some embodiments, a dual actuator system includes an actuator placed on each side opposite the hinge. In other embodiments, a single actuator is utilized in concert with a latch that can secure both sides of the lid. One side is secured with the latch and the other with the force of the actuator. This configuration offers a solid lid closure that supports hands-free delivery or drone delivery, authenticated via digital communications.
In some embodiment, one or more solar cells can be used to recharge the package storage system power source, e.g., one or more rechargeable batteries. The package storage system can be powered by one or more suitable rechargeable batteries, such as nickel-metal hydride (NiMH) or lithium-ion batteries. For lithium-ion battery embodiments, a lithium-ion charging circuit may be included. In some embodiments, a charging circuit can limit current to safe levels for charging standard batteries (e.g., nickel-metal hydride (NiMH) or other rechargeable battery chemistries). The solar panel's voltage and associated circuitry can be configured to prolong the usable battery life.
In some embodiments, the package storage system includes a tether trigger system to activate an alarm. The system monitors the tether's electrical properties, such as an open or closed circuit or a specific resistance level, to detect tampering. For example, resistance wire can be used to set a particular resistance value, and the voltage across the tether can be divided to an analog-to-digital (A/D) input. This setup reduces the risk of defeating the alarm through shorting. The system may also pair the resistance wire with a capacitor to measure decay time, enabling detection of pulses or timing patterns. Abnormal readings, such as changes in resistance or signal decay, trigger the alarm if the tether is removed, replaced, or shorted. This allows the microprocessor to detect tampering and promptly activate the alarm.
Some embodiments include an auxiliary output for an alarm (e.g., a siren) that can be triggered in response to trigger event, such as the tether trigger system. The system can be configured to continue the siren in response to the trigger event until the alarm is deliberately reset. For example, while the package storage system is in motion the microprocessor can be configured to keep alarming, even if the original tether trigger is resolved such that the alarm remains active until the alarm is deliberately reset.
In some embodiments, the package storage system may include optional safety features to address specific use cases. For example, if the compartment is configured to be large enough for a person to enter, an illuminated or glow-in-the-dark button may be included inside the storage compartment to allow the lid to be opened from within.
Some embodiments include means to detect motion and interrupt or wake up the system. Using a simple ultralow power motion detector allows the microprocessor to sleep saving power until motion is detected.
Some embodiments provide a motion detection system that can interrupt or wake other electrical components of the system from a low-power state. By way of example, the microprocessor and other electrical components of the system can be configured to enter a low power state (e.g., sleep mode) after a period of inactivity to conserve energy. This provides normal and low power consumption modes. During the low power mode, an activity detection circuitry can be configured to detect activity periodically or continuously (e.g., with a signal to noise detector, radio signal detector, an accelerometer, or an optical sensor, along with suitable accompanying logic circuitry). This activity detection circuitry can trigger a wake-up signal that is transmitted to one or more components of the system that are configured to be asleep during low power consumption mode. Once awakened, the system can verify the presence of activity (e.g., via detection of movement, detection of a radio signal (e.g., a Bluetooth signal), or other credentials indicative of activity), thereby supporting both power efficiency and secure access.
FIG. 1 illustrates a perspective view of an example door-mounted security bracket for a package storage system.
FIG. 2 illustrates a perspective front-side view of the door-mounted security bracket of FIG. 1 positioned on a door in an example installation configuration.
FIG. 3 illustrates another perspective front-side view of the door-mounted security bracket of FIG. 1 positioned on the door in the installation configuration of FIG. 2.
FIG. 4 illustrates a top view of the door-mounted security bracket of FIG. 1 positioned on a door.
FIG. 5 illustrates a perspective view of an alternative door-mounted security bracket for a package storage system.
FIG. 6 illustrates a perspective view of a tethering cable routed through a door-mounted security bracket and into a package storage system, showing exemplary alternative routing paths relative to the package storage system.
FIG. 7 illustrates a rear view of a package storage system showing a tethering cable opening and a section line corresponding to FIG. 8.
FIG. 8 illustrates a partial sectional view of the package storage system taken along the section line of FIG. 7, showing an internal security bracket and a tethering cable routed therethrough.
FIG. 9 illustrates a perspective view of an internal security bracket showing a tethering cable routed through the internal security bracket in an exemplary securing arrangement.
FIG. 10 illustrates a perspective view of a door-mounted security bracket, an internal security bracket, and a tethering cable arranged in an exemplary tethering configuration.
FIG. 11 illustrates a perspective view of an internal security bracket and a tethering cable, shown without surrounding structure, with the tethering cable routed around an external object and returned to the internal security bracket.
FIG. 12 illustrates a plan view of an exemplary internal security bracket having tether routing openings.
FIG. 13 illustrates a plan view of another exemplary internal security bracket having multiple sets of tether routing openings.
FIG. 14 illustrates a perspective view of a package storage system having an internal security bracket extending through a wall slit and coupled to a chain and a lock.
FIG. 15 illustrates a perspective view of a door-mounted security bracket showing a chain routed through an opening in the door-mounted security bracket.
FIG. 16 illustrates a partial view of a package storage system showing a lid-side latch assembly and spring-interface components.
FIG. 17 illustrates a partial view of the package storage system showing a receiver-side latch assembly and spring-loading cylinder structure corresponding to the lid-side components of FIG. 16.
FIG. 18A illustrates a partial sectional view of the package storage system showing a spring-loading cylinder structure with a lid-side pin positioned therein in a latched position.
FIG. 18B illustrates another partial sectional view of the package storage system showing the spring-loading cylinder structure of FIG. 18A with the lid-side pin in a released position.
FIG. 19A illustrates a sectional view of one embodiment of a package storage system showing packages within a storage compartment and an exemplary sensing arrangement for determining a level or position of the packages within the storage compartment.
FIG. 19B illustrates a sectional view of another embodiment of a package storage system showing packages within a storage compartment and an exemplary sensing arrangement for determining a level or position of the packages within the storage compartment.
FIG. 20A illustrates a front view of a package storage system having a lid in a closed position and a single actuator and latch arrangement.
FIG. 20B illustrates a front view of the package storage system of FIG. 20A with the lid in an open position and the actuator extended.
FIG. 21 illustrates an exemplary solar charging circuit associated with a package storage system.
FIG. 22 illustrates an exemplary alarm circuit associated with a tether or cable of a package storage system.
FIG. 23 illustrates a schematic view of an auxiliary alarm output connection associated with a control system of a package storage system.
FIG. 24 illustrates a schematic view of an emergency release pushbutton providing an input to a control system of a package storage system.
FIG. 25 illustrates a schematic view of a motion detection component associated with a control system of a package storage system.
FIG. 26 illustrates a first portion of a flowchart representing control logic for a package storage system.
FIG. 27 illustrates a second portion of the flowchart of FIG. 26 representing continued control logic for the package storage system.
FIG. 28 illustrates a package storage system positioned adjacent to a door and associated with one or more lighting indicators.
FIG. 29 illustrates an perspective view of a package delivery system showing an aerial delivery device delivering a package to a package drop interface.
FIG. 30 illustrates another perspective view of a package drop system configured for coordinated aerial delivery using a tethered package carrier.
FIG. 31 illustrates a schematic view of a package storage system associated with a hub or router having multiple wireless communication interfaces.
FIG. 1 illustrates one embodiment of a system for easily connecting a multi-functional door security bracket 100 to an open door and using the door structure to capture the door security bracket physically to the structure. The door security bracket acts as a locking plate that can be easily installed on a door. Closing the door secures the plate. Specifically, closing the door captures the door security bracket 100 between the door and an associated door frame or door jamb such that removal of the bracket 100 requires reopening the door. The design allows the full use and convenience of using the door while offering security and low-profile aesthetic impact to the dwelling or building owner. The door security bracket 100 can flex from a minimum size to a maximum size door thickness and spring between. The bracket 100 can have a felt liner 102 to prevent scratching the door during installation and use. The door security bracket 100 can include a large hex opening 104 and a slot 106 to allow chain and large locking cables to easily fit within this bracket 100. The larger opening 104 accommodates combination-type bike locks if needed or desired. In the depicted embodiment, the securing end for the chain or cable can be a folded piece of metal for additional security and difficulty to cut or damage. The door-mounted installation configuration is illustrated, by way of example, in FIGS. 2-4.
As used herein, a “tether” refers to an elongated flexible member configured to secure the package storage system to an external structure, and may include, by way of example and without limitation, a cable (including a tethering cable), chain, rope, strap, or other flexible securing member.
FIG. 5 illustrates a low-cost variation of the multi-functional door bracket 100 shown in FIG. 1. This version features a single hole 108 designed to accommodate a cable stop (e.g., a stainless steel cable stop at the end of a tethering cable). The hole 108 is precisely sized to fit the cable stop, enabling a single pass of the cable without requiring an additional lock. The bracket 100 can include a contact area lined with felt tape or a liner 102 to prevent damage to the door surface during use. A double-thickness construction at the secure end enhances durability, making it more resistant to cutting or tampering. The locking mechanism is achieved through the physical configuration of the bracket 100, which retains the cable via the cable stop, and is further locked when the storage device is in a closed an locked state.
FIGS. 2-4 illustrate how the door security bracket 100 can be easily and securely installed on a door. The door security bracket 100 is designed with a low-profile configuration to reduce exterior projection visibility and accessibility when installed, thereby reducing opportunities for tampering by potential thieves. This streamlined design also enhances the aesthetic appeal of the system by concealing the cable and connection regions, ensuring that the attachment to the physical dwelling structure is both functional and visually unobtrusive. By configuring the door security bracket 100 in this manner, the system provides a robust security solution while maintaining a clean, professional appearance suitable for residential or commercial environments.
FIG. 1 depicts an example of the fabricated multi-functional door bracket 100. Two distinct options for securing or tethering the package storage system to the bracket 100 are highlighted. The hexagonal opening 104 is designed to accommodate a chain or other tether, providing a robust and versatile attachment method. Alternatively (or additionally), the circular hole 108 is sized to securely hold a cable stop, enabling the use of a cable for tethering. These dual attachment options enhance the flexibility of the bracket, allowing it to adapt to various security requirements and user preferences. Additionally, the bracket 100 can feature reinforced edges for added durability and can be fabricated from a sturdy material, such as stainless steel, to resist tampering and wear. Angled flanges and curved contact surfaces can help ensure a secure fit on the door while reducing the risk of damage to the door surface. This embodiment demonstrates the practical versatility and strength of the bracket 100.
FIG. 6 illustrates an example installed configuration of the package storage system 300 secured to a door using the door security bracket 100 and the tethering cable 110. In the illustrated configuration, the door is in a closed position, capturing the door security bracket 100 between the door and an associated door frame such that the door security bracket 100 and an attached portion of the cable 110 are inaccessible from an exterior side of the door. The cable 110 extends from the door security bracket 100 to the package storage system 300, where the cable 110 is routed internally as described below. In this installed state, removal of the door security bracket 100 or disengagement of the cable 110 requires opening the door and accessing an interior of the package storage system 300, thereby providing a locking retention arrangement without requiring a separate padlock or discrete locking mechanism. In the illustrated configuration, the package storage system 300 may include one or more entry/exit portals 302 through which the cable 110 enters the package storage system 300, with the particular portal 302 used depending on the installation orientation and routing path selected, as described in further detail below. In the illustrated configuration, the cable 110 may be routed through the package storage system 300 along different paths, including paths entering the package storage system 300 at upper or lower portions thereof, as schematically indicated by dashed lines, to accommodate different installation orientations and routing constraints.
FIG. 10 illustrates an exemplary bracket and cable assembly, demonstrating a cost-effective tethering solution. The assembly includes a cable 110, e.g., a stainless steel cable, with a crimped ball-end stop 112 secured on one end. The cable 110 is configured to pass through the hole 108 in the door security bracket 100, while the ball-end stop 112 has a transverse dimension larger than the hole 108 such that the ball-end stop 112 is prevented from passing through the hole 108, thereby retaining the cable 110 relative to the door security bracket 100. The opposite end of the cable is equipped with a section of heat-shrink tubing 114, which facilitates threading through one or more openings 210 of the storage security bracket 200 within the package storage system. The heat-shrink tubing enhances handling and prevents fraying, ensuring smooth installation and reliable performance. This assembly highlights the practical and economical approach to securing the storage system while maintaining durability and ease of use.
FIG. 9 illustrates the heat-shrink tubing-covered end of the cable 110 from FIG. 10 being threaded through the storage security bracket 200, creating a simple yet effective locking retention configuration. This configuration highlights that merely threading the cable through the bracket 200 establishes a locking retention path that resists withdrawal of the cable 110 when the cable end is inaccessible, thereby effectively securing the cable 110 relative to the storage security bracket 200. The vinyl coating and natural spring tension of the cable 110 further enhance the locking retention effect by increasing friction and resistance, eliminating the need for additional locking mechanisms commonly used in other systems. As used herein, locking configurations may include retention arrangements in which removal is prevented or resisted due to inaccessibility, routing, or geometric interference, without requiring a discrete locking mechanism.
The storage security bracket 200 can be securely mounted within the storage system and held in place by a vertical support rod 202, as depicted in FIG. 8, which passes through the center alignment opening 204 of the bracket. This ensures the bracket remains stable and aligned during use. Additionally, this method allows any excess cable to be easily managed by pulling it into the storage system through the retention loop(s) 210, creating a clean cable profile. This streamlined approach not only simplifies installation but also enhances the aesthetic and functional aspects of the storage system.
FIG. 11 illustrates a simple loop-and-return cable configuration for securing the storage system 300 to a pole or other secure object. In the illustrated embodiment, the ball-end stop 112 of the cable 110 is threaded through the storage security bracket 200 and passed through the package storage system 300, as shown in FIG. 7. The cable 110 is then wrapped around the pole or object to be secured, with the heat-shrink tubing-covered end 114 of the cable 110 is returned back through the storage system 300 and threaded through one or more openings 210 of the storage security bracket 200, as shown in FIG. 9. By pulling the cable 110 through the openings 210, slack in the cable 110 is reduced and tension along the cable path is increased, thereby establishing a locking retention configuration that retains the cable 110 in place while maintaining a clean and minimal cable profile both inside and outside the package storage system 300.
This method is particularly effective for securing the storage system around a pole or similar object, as it leverages the locking retention path within the storage security bracket 200 to eliminate the need for additional locks or complex mechanisms. Furthermore, the alignment opening 204 in the bracket 200 can be engaged with a vertical support rod 202 within the package storage system, ensuring the stability and alignment of the bracket during use.
FIG. 7 shows one embodiment of the entry/exit portals 302 for connecting the storage system 300 securely to a structure. In the illustrated embodiment, the package storage system includes multiple entry/exit portals 302 positioned on opposing sides of the storage system, each portal 302 providing a pathway for routing a cable 110, chain, or other connector into and out of the storage system. This arrangement allows a storage security bracket 200 to be installed on either side of the storage system 300, or on both sides, depending on installation requirements and the location of the external structure. By providing multiple entry/exit portals 302, the system 300 supports flexible routing paths and installation configurations while maintaining secure internal retention of the connector once routed through the storage security bracket 200.
FIG. 8 illustrates a sectional view of an exemplary package storage system 300 in accordance with the present disclosure. The corner structures include a vertical support rod 202 to secure the top and bottom sections of the system together, enhancing overall structural strength. The vertical support rod 202 passes through an alignment opening 204 of the storage security bracket 200, further reinforcing the connection and providing additional structural stability and alignment.
The storage security bracket 200 can be strategically positioned near an entry/exit port 302 for cables 110, chains, or other connectors, enabling versatile attachment options. For example, a padlock can be used in conjunction with a chain inside the storage system to provide an alternative securing method. Additionally, one or more openings 210 on the storage security bracket 200 can be configured to accommodate a padlock, if needed, allowing for further customization of the connection system. In some embodiments, multiple storage security brackets 200 can be provided and positioned near corresponding entry/exit ports 206 on different sides of the storage system, supporting a variety of tethering and locking configurations to meet diverse security requirements.
FIGS. 6, 7, and 11 illustrate embodiments of the entry/exit portals 302 for securely connecting the storage system to an external structure. These portals 302 provide pathways for cables 110, chains, or other tethers to enter and exit the package storage system 300, supporting robust attachment to brackets, doors, poles, walls, or other fixed objects. In the illustrated embodiments, the portals 302 cooperate with internal routing and retention features to maintain alignment of the tether and limit unintended cable movement, thereby reducing wear while maintaining a secure connection. These configurations support a variety of tethering methods and installation scenarios.
FIG. 9 illustrates an exemplary threaded routing of the cable 110 through the storage security bracket 200 to establish a locking retention path. In the illustrated embodiment, the cable 110 is routed through one or more openings 210 of the storage security bracket 200 such that slack can be taken up by pulling the cable 110 through the openings 210, reducing the external cable profile. By routing the cable 110 through multiple openings 210, withdrawal of the cable 110 is resisted when access to the storage security bracket 200 is restricted, thereby retaining the cable 110 without requiring a discrete locking mechanism. Additional openings 210 may be provided to support alternative routing or retention configurations.
FIG. 12 illustrates an example of using indicia (e.g., letters, descriptors, or numbers) to label the package storage tether bracket. These indicia can be paired with written, visual, or audio instructions that guide the user through the process of threading the cable in various configurations. For instance, one configuration can involve starting from below the storage security bracket, threading the cable up through labeled hole “D,” and then back down through hole “E” to securely capture the cable, similar to the configuration shown in FIG. 9.
FIG. 13 illustrates an example of a storage security system with multiple additional configurations. This embodiment features indicia for providing guidance on several loops designed for securing the system using various locking methods, including a padlock configuration for attaching a chain or other tethering media. The steel bracket is labeled with clear indicia to guide the user through the securing process, indicating the correct locations for threading cables or chains and enhancing the system's flexibility for different security needs. In the illustrated embodiment, multiple holes labeled with the same indicium (e.g., two holes labeled “C”) provide alternative routing paths for the cable or chain, allowing the user to select either hole based on desired routing direction, available clearance, or installation orientation, while still achieving the same locking retention function. This versatile setup supports multiple attachment methods, making it adaptable to various environments and security requirements.
FIG. 15 illustrates an embodiment of the multi-functional door security bracket 100 configured to support multiple tethering options. In the illustrated embodiment, the door security bracket 100 includes a first opening 108 sized to receive a tethering cable 110 having a ball-end stop 112, such that the cable 110 can pass through the opening while the ball-end stop 112 is retained to prevent withdrawal (see e.g., FIG. 10). The door security bracket 100 further includes a second opening 104 having a larger internal diameter, which is configured to accommodate thicker cables, chains 111, or bike-style locks. The larger internal diameter opening allows a user to thread a larger lock or tether through the door security bracket 100 when additional security or compatibility with commercially available locking devices is desired. By providing both a ball-end cable retention opening and a larger opening for alternative locking devices, the door security bracket 100 offers flexible attachment options while maintaining a low-profile, door-captured installation.
Further illustrating FIG. 15, the multi-functional slot and larger hole in the door tether bracket, designed to accommodate chain or larger locks. The larger hole 104 and slot 106 provide flexibility in selecting various locking mechanisms, allowing users to secure the storage system with chains, heavy-duty locks, or other tethering solutions. This design enhances the system's versatility, enabling secure attachment to a wide range of objects or fixed points. The multi-functional slot simplifies the process of securing the storage unit while maintaining a clean and minimal profile.
The storage security bracket 200 can be installed in an alternative configuration in which the bracket 200 extends through an entry/exit portal 302 formed in a wall of the package storage system 300, such that the bracket 200 is at least partially externally accessible. This external-access configuration can facilitate routing, tightening, or reconfiguration of a tethering element or locking element, and allows the bracket 200 to be partially externally mounted, ensuring easy access to the connection interface while securely holding the package storage system 300 in place. This configuration offers greater flexibility in installation, particularly when the package storage system 300 is positioned in environments where external access to the connection interface is preferred for ease of access or enhanced security.
FIG. 14 illustrates the storage security bracket 200 in this external-access configuration, being used externally to the package storage system 300, thereby providing an alternative multi-functional connection option. In the illustrated embodiment, a padlock 400 is received through an opening 210 of the storage security bracket 200 and is coupled to a chain 411, such that the padlock 400 secures the package storage system 300 to a fixed object. The combination of a chain 411 and padlock 400 provides a robust alternative to the cable-based locking retention configurations described above, offering additional flexibility for installations in which a discrete external locking device is desired or required. The storage security bracket 200 accommodates a variety of chain sizes, cables, and padlocks, allowing users to select a desired security approach while maintaining compatibility with the package storage system's overall connection architecture.
In addition to the tethering and securement configurations described above, the package storage system 300 can include structural features that facilitate controlled access to the storage compartment. The following embodiments relate to lid opening and assist features that enable convenient user access while maintaining a low-profile, tamper-resistant exterior, independent of whether the package storage system 300 is tethered or secured to an external structure.
FIG. 16 illustrates an example arrangement of lid opening assist components integrated into the package storage system 300. In the illustrated embodiment, a plurality of compression pins 310 are coupled to the lid 304 and positioned to engage corresponding spring-loaded assemblies when the lid is closed. The compression pins 310 are arranged such that downward movement of the lid 304 causes the pins 310 to translate into spring-receiving structures, as described in further detail below. It should be noted that the spring-loaded assembly ensures easy lid operation without the need for external handles or access points. This configuration reduces potential pry areas or security vulnerabilities commonly associated with handles, enhancing the overall integrity of the security system. By forgoing external handles, the system maintains a sleek, tamper-resistant design that reduces the risk of unauthorized access.
FIG. 17 illustrates a latch assembly 316 positioned centrally relative to the lid 304, along with two spring-loading cylinders 314 arranged on opposing sides of the latch assembly 316. The latch assembly 316 is configured to retain the lid 304 in a closed position, while the spring-loading cylinders 314 house springs 312 that store mechanical energy when the lid 304 is closed. In this configuration, the spring-loading cylinders 314 apply a pre-loading force to the lid 304 that assists opening once the latch assembly 316 is released. Upon disengagement of the latch assembly 316, the stored energy in the springs 312 urges the lid 304 toward an open position, providing smooth and effortless access to the package storage compartment. This arrangement provides reliable lid retention when closed and assisted opening when released, enhancing both security and user convenience.
FIGS. 18A and 18B illustrate the interaction between the compression pins 310, the springs 312, and internal guides 318 within the spring-loading cylinders 314. As shown in FIG. 18A, when the lid is in a closed position, the compression pins 310 engage the guides 318, causing the springs 312 to compress and store energy. As shown in FIG. 18B, upon release of the latch assembly 316, the stored energy in the springs 312 drives the compression pins 310 upward, thereby urging the lid toward an open position.
The spring-assisted configuration described above applies a pre-loading force to the lid that enables the lid to partially open automatically once unlatched, allowing a user to easily lift the lid using a hand or finger. This arrangement facilitates convenient access to the storage compartment while avoiding abrupt or uncontrolled lid motion.
In some embodiments, a damping pad (e.g., urethane, foam, or other cushioning material) can be positioned adjacent to a guide or compression pin to absorb excess energy released by the springs during lid opening. The damping pad can reduce lid bounce, noise, or abrupt motion as the lid transitions toward an open position, thereby promoting smooth and controlled lid movement. The damping pad may be die-cut, adhesive-backed, insert-molded, or otherwise secured in place, and can be implemented without altering the overall spring-assisted lid opening arrangement described above.
The package storage system 300 can include features for assessing packages contained within a storage compartment, including determining a quantity, height, volume, dimensional characteristics, or occupancy state of one or more packages, as well as for confirming or verifying delivery events. FIGS. 19A-19B illustrate embodiments of the package storage system 300 configured to assess storage capacity and delivery status using information obtained from an upper region of the storage compartment. In the illustrated embodiments, package assessment can be performed using non-imaging distance measurements, imaging-based analysis, or combinations thereof, allowing the package storage system 300 to determine whether the storage compartment is empty, partially filled, or full, and to evaluate characteristics of individual delivered packages.
FIG. 19A illustrates an embodiment in which package assessment is performed using a sensing device 330 positioned at an upper region of the package storage system 300. In the illustrated embodiment, the sensing device 330 is mounted on or adjacent to a latch assembly associated with a lid 304, such that the sensing device 330 is oriented to obtain information regarding packages located within the storage compartment. The sensing device 330 can be configured to obtain distance information, image information, or both, directed downwardly into the storage compartment toward a topmost package or a bottom reference surface.
In some embodiments, the sensing device 330 operates as a non-imaging ranging device configured to measure a distance between the lid 304 and a topmost package or a bottom surface 334 of the storage compartment. By way of example and without limitation, the sensing device 330 can include an ultrasonic sensor, infrared sensor, lidar sensor, radar sensor, time-of-flight sensor, or combinations thereof. Distance measurements obtained by the sensing device 330 can be used to determine whether the storage compartment is empty, partially filled, or full, and can further be used to estimate remaining available storage capacity based on known internal dimensions of the package storage system 300.
Positioning the sensing device 330 at the lid 304 provides a consistent measurement reference independent of package placement and allows the sensing device 330 to leverage power, control, and communication resources associated with the latch assembly. This integrated placement simplifies installation, avoids the need for additional internal wiring or power sources, and provides a stable vantage point for repeated capacity measurements over time.
In some embodiments, the sensing device 330 captures image data of the storage compartment from the upper region of the package storage system 300. Image data obtained by the sensing device 330 can be analyzed to determine package height, volume, or occupancy state, either alone or in combination with distance measurements. For example, image data can be used to identify a topmost package surface and correlate that information with known enclosure dimensions to determine remaining capacity.
To facilitate image-based interpretation, a visual reference element 334, such as a ruler, scale, or datum mark, can be formed on an interior surface of the storage compartment, including on a sidewall, leg support, or internal structural element. The visual reference element 334 can be laser-etched, molded, printed, applied as a label or sticker, or otherwise formed as part of the enclosure and provides a known dimensional reference visible within captured images. By comparing the apparent height of a package relative to the visual reference element 334, the package storage system 300 can determine package height and infer remaining available capacity.
In some embodiments, the visual reference element includes or is supplemented by one or more fiducial markers, such as an AprilTag, ArUco marker, QR-type marker, or other machine-readable visual marker, positioned on an interior surface of the storage compartment. Fiducial markers provide known geometric features that can be detected within captured image data and used to calibrate image measurements, correct for perspective or camera orientation, or improve accuracy of package dimension and capacity estimation. Use of fiducial markers can be particularly beneficial when image capture is performed using an external imaging device, such as a mobile phone, or when images are captured from varying positions or angles relative to the storage compartment.
FIG. 19B illustrates an embodiment in which image data of the storage compartment is captured using an external imaging device 354, such as a camera of a user mobile device, positioned above an optically transmissive region 352 formed in the lid 304 of the package storage system 300. In this embodiment, the external imaging device 354 is not permanently integrated into the package storage system 300, but is temporarily aligned with the optically transmissive region 352 to obtain a downward view into the storage compartment. The optically transmissive region 352 can include a transparent or translucent window, lens, or cover that provides a known viewing geometry allowing image capture of both the stored packages 350 and interior surfaces of the storage compartment while maintaining enclosure security.
In some embodiments, image-based analysis accounts for a known or determinable geometric relationship between an imaging device and the interior of the storage compartment. For example, when an imaging device is fixed relative to the enclosure or positioned at a defined location with respect to the optically transmissive region, one or more parameters such as camera angle, field of view, lens characteristics, or relative position may be known in advance or inferred from enclosure geometry.
Such known or inferred imaging geometry may be used to correct for perspective distortion, scaling variation, or camera pose when interpreting captured images. In some embodiments, image measurements are normalized based on the known camera angle and lens characteristics so that apparent dimensions observed in an image can be translated into real-world dimensions within the storage compartment. This enables accurate estimation of package height, lateral dimensions, or volume even when images are captured at an angle or from a non-orthogonal viewpoint. In some embodiments, the known enclosure dimensions and camera geometry are used together to establish a mapping between image coordinates and enclosure coordinates for measurement purposes.
In some embodiments, image data captured by the external imaging device is used in addition to information obtained from an integrated sensing device 330, for example to verify, augment, or refine capacity determinations based on distance measurements. In other embodiments, image data captured by the external imaging device is used as an alternative to data obtained from the sensing device 330, allowing storage capacity or package characteristics to be determined without reliance on an integrated sensor
Image data captured by the external imaging device can be analyzed to determine package height, length, width, volume, or remaining available capacity. Visibility of the interior walls of the storage compartment within the captured image allows known enclosure dimensions (e.g., internal length and width) to be used in conjunction with image analysis to estimate corresponding dimensions of a delivered package. This enables confirmation or verification of what package has been delivered based on observed dimensions, in addition to determining remaining storage capacity, and can further be used to confirm delivery of a particular package by comparing observed package dimensions or characteristics against expected delivery information.
In some embodiments, image data captured over multiple delivery events can be analyzed collectively to track changes in package count, package dimensions, or remaining available capacity over time. By comparing successive images of the storage compartment, the package storage system 300 can identify newly delivered packages 350, estimate dimensions of individual packages 350, and maintain an updated representation of remaining capacity as packages 350 accumulate within the storage compartment. As illustrated, for example, in FIG. 19A, a previously delivered package 350 can be represented by a first outline, while a subsequently delivered package 350 is represented by a second outline (e.g., shown in broken lines), thereby visually indicating changes in package stack height or configuration over time.
Image capture using either an integrated sensing device 330 or an external imaging device 354 can occur automatically or in response to a user action, such as positioning a mobile device near the optically transmissive region 352 or issuing a capture command via a user interface. Manual image capture can be used to confirm secure placement of packages 350 or verify delivery events, while automated capture can be used for periodic or event-driven capacity assessment.
In some embodiments, acquisition of distance measurements or image data is triggered in response to one or more system events, including a lid opening event, lid closing event, latch state change, delivery confirmation, or expiration of a predefined time interval. Event-triggered acquisition allows the package storage system 300 to capture relevant data at meaningful points during use, such as immediately after a delivery or upon closure of the lid 304, while minimizing unnecessary sensing or image capture operations.
In some embodiments, image data and/or distance measurements are analyzed using image processing or machine-learning techniques to estimate remaining capacity, identify individual packages, detect delivery anomalies, or infer user interactions with the package storage system 300. Such analysis can provide a more complete understanding of package status within the storage compartment and support advanced delivery verification or monitoring features.
In some embodiments, storage capacity or package assessment results are confirmed using multiple measurements or multiple sensing modalities. For example, distance measurements obtained using the sensing device 330 can be verified or refined using image-based analysis, or vice versa. Redundant or corroborative assessment can improve confidence in capacity determinations, reduce measurement error, and mitigate false positives resulting from irregular package shapes or placement within the storage compartment.
In some embodiments, output from the sensing device 330 or image analysis is communicated via an application programming interface (API) to a user device or remote system, enabling a user or delivery service to monitor storage capacity, delivery status, or availability for additional deliveries. Metadata exchange using near-field communication (NFC), Bluetooth Low Energy (BTLE), or other communication techniques can be used to associate captured data with a device identifier, lock status, user identifier, or delivery event. An indicator, such as an LED, can provide a visual cue regarding lock status or storage availability.
In some embodiments, determined storage capacity, remaining available volume, or package occupancy state is compared against one or more threshold values to generate notifications or status indicators. For example, the package storage system 300 can generate an indication that additional deliveries are permitted, that the storage compartment is nearing capacity, or that the storage compartment is full. Such indications can be communicated to a user device, delivery service, or logistics system, or can be provided locally via a visual indicator or audible alert. In some embodiments, when a threshold indicating that the storage compartment is nearing capacity or full is reached, the notification explicitly prompts a user to empty or retrieve contents from the package storage system in advance of additional deliveries.
In some embodiments, the package storage system is configured to compare observed package characteristics against expected delivery information. For example, dimensional data associated with an expected delivery—such as package length, width, height, weight, or cubic volume—may be received from a delivery service, retailer, or logistics system prior to or contemporaneously with delivery, for example via an application programming interface (API) or associated metadata.
After placement of a package within the storage compartment, the package storage system can determine one or more observed characteristics of the delivered package using distance measurements, image-based analysis, or combinations thereof. In some embodiments, such observed characteristics are evaluated relative to a previously established baseline corresponding to a prior state of the storage compartment, thereby enabling the system to isolate characteristics attributable to a newly delivered package.
By establishing and updating such baselines on a per-delivery basis, the package storage system can derive quantized delivery results corresponding to individual delivery events. For example, a first delivery may establish an initial occupied height or volume within the storage compartment, and a subsequent delivery comprising one or more additional packages may be identified by detecting an incremental change relative to the prior baseline. This differential approach allows the system to distinguish between successive deliveries and to attribute measured dimensional changes to specific delivery events.
In some embodiments, estimation of package volume further incorporates determination of one or more lateral dimensions of a delivered package. Such lateral dimensions may be inferred based on known internal dimensions of the storage compartment, determined from image-based analysis of the package relative to visible enclosure boundaries, or derived using one or more visual reference elements positioned within the storage compartment, such as rulers, scales, fiducial markers, or other features having known dimensions. By combining lateral dimension information with sensed height information, the package storage system can estimate a cubic volume associated with a delivered package or delivery event.
In some embodiments, the package storage system accounts for variability in package orientation within the storage compartment. Delivered packages may be placed on different faces, edges, or sides, and therefore may not consistently present a particular dimension as a vertical height relative to the storage compartment. Accordingly, observed height measurements may correspond to different physical dimensions of a package depending on its orientation at the time of delivery.
To address such variability, the package storage system may employ object identification and orientation analysis to determine a likely orientation of a delivered package. For example, image-based analysis may be used to identify package boundaries, edges, faces, labels, or surface features, and to infer which dimension of the package is oriented vertically. In some embodiments, the system evaluates multiple candidate orientations and selects an orientation that best fits observed dimensional data, expected delivery information, or known packaging characteristics. By normalizing observed measurements based on inferred orientation, the package storage system can more accurately estimate package dimensions and volume, even when packages are placed on non-standard faces. In some embodiments, orientation determination is performed using confidence scoring or probabilistic analysis, allowing volume estimation to proceed even when orientation cannot be determined with certainty.
By way of example, if a delivery service indicates that a package having nominal dimensions of 12Ă—12Ă—12 inches is expected, the package storage system can determine whether an incremental change in measured height or estimated volume following a delivery event is consistent with that expected package. If multiple packages are delivered during a single delivery event, corresponding incremental changes may be aggregated and compared against expected delivery information associated with that event.
In some embodiments, when a discrepancy is detected between expected delivery information and observed package characteristics, the package storage system generates a notification, alert, or verification prompt to a user. Such notification may indicate, for example, that a delivered package does not match an expected size, that fewer or more packages were delivered than anticipated, or that an unexpected package may be present within the storage compartment.
Providing such discrepancy or verification information proximate in time to a delivery event allows a user to make timely decisions regarding package retrieval, investigation, or follow-up with a delivery service. By enabling near-real-time confirmation of delivery accuracy, the package storage system reduces uncertainty associated with unattended deliveries and improves user responsiveness in scenarios involving high-value items, time-sensitive deliveries, or potential delivery errors.
In some embodiments, the package storage system is configured to classify access events associated with the storage compartment into different event types based on observed changes in package occupancy, volume, or configuration. Such event types may include, for example, a delivery event, a retrieval event, a return event, or a mixed event involving both removal and addition of packages.
A delivery event may be identified, for example, when an authorized access event is followed by an increase in measured package height, volume, or occupancy relative to a prior baseline. In response to identifying a delivery event, the package storage system may update internal baselines, associate observed package characteristics with expected delivery information, record delivery metadata, and generate one or more delivery confirmation outputs.
A retrieval event may be identified when an authorized access event is followed by a decrease in measured package height, volume, or occupancy relative to a prior baseline. In some embodiments, retrieval events are associated with user access and may trigger updating of internal baselines, clearing of expected delivery records, or generation of notifications indicating that packages have been removed from the storage compartment.
In some embodiments, the package storage system is configured to support return events in which one or more packages are placed into the storage compartment for pickup. A return event may be identified, for example, when an access event is associated with an increase in measured package occupancy and is accompanied by return-related metadata, user input, or a return authorization state. In response, the system may generate a return-available indication for delivery personnel or logistics systems.
In some scenarios, a single access event may include both removal and placement of packages, resulting in a mixed or compound event. In such cases, the package storage system may evaluate incremental changes relative to a prior baseline to separately account for retrieved packages and newly added packages, and may update internal records accordingly.
Classification of access events into delivery, retrieval, return, or mixed events may be used to control subsequent system behavior, including notification generation, indicator activation, metadata logging, or communication with external systems. By maintaining state-aware handling of access events, the package storage system provides more accurate tracking of package flow and supports distinct workflows for delivery and return scenarios.
In some embodiments, the delivery events, retrieval events, return events, and proximity-based interactions described above collectively define recognizable operational patterns associated with use of the package storage system. Such patterns may include, for example, characteristic sequences of access, package placement or removal, proximity detection, and indicator activation that recur across multiple delivery cycles. The package storage system may use identification of such patterns to refine event classification, adjust interaction behavior, or improve accuracy of delivery verification and user notifications over time.
In some embodiments, the package storage system is configured to detect proximity or presence of a delivery person, user, or authorized device in relation to the storage system. Proximity detection may be based on one or more signals, including location information (e.g., location information derived from GPS, cellular positioning, or network-based location service), radio-frequency (RF) signal strength, Bluetooth Low Energy (BLE) signal characteristics, near-field communication (NFC) interaction, timing relative to an expected delivery window, or combinations thereof.
Detection of proximity or presence may be used to trigger interactive system behavior, including activation of one or more visual indicators, audible indicators, or other signaling features associated with the package storage system. In some embodiments, such interaction is enabled only when the system is in a delivery-related state, such as when a delivery event is expected or authorized, thereby limiting unnecessary signaling outside of delivery contexts.
In some embodiments, indicator behavior is dynamically modulated based on proximity, signal strength, duration of presence, or confidence associated with detected presence. For example, a visual indicator may increase in brightness, change color, or alter a flashing pattern as a delivery person approaches the storage system, and an audible indicator may increase in volume, repetition rate, or prominence as proximity increases or persists.
Visual and audible indicators may be used independently or in combination, and may be adapted based on environmental conditions, user preferences, or contextual risk factors. For example, audible indicators may be suppressed in certain environments, while visual indicators are emphasized, or vice versa. Indicator behavior may further be adjusted based on historical delivery accuracy, detected anomalies, or prior security events.
In some embodiments, activation and visibility of proximity-based indicators is conditioned on detection of a trusted signal or authorization state. When a trusted presence is not detected, indicator behavior may be reduced, altered, or disabled to avoid drawing attention to the presence of stored packages. In this manner, the package storage system balances delivery guidance with discretion and security.
Proximity-based interaction may further operate as a feedback loop in which continued presence, movement patterns, or user interaction refine system behavior over time. For example, indicator behavior may escalate when a delivery person remains near the storage system without completing a delivery event, or may de-escalate upon detection of a completed delivery or exit from the proximity region.
Proximity-based interaction logic may be integrated with event classification logic such that indicator behavior differs between delivery events, return events, retrieval events, or mixed events. By coupling proximity detection with state-aware event handling, the package storage system provides context-appropriate guidance while maintaining accurate tracking of package flow.
The sensing and imaging approaches described above allow the package storage system 300 to assess remaining storage capacity, verify delivered packages based on observed dimensions, and provide feedback regarding delivery status using information obtained from an upper region of the storage compartment, without requiring manual inspection of the storage compartment contents.
FIGS. 20A-20B illustrate an embodiment of a package storage system 300 configured for a hands-free delivery process in which a lid 304 of the package storage system 300 is automatically unlocked and opened in response to a delivery authorization. In the illustrated embodiment, a delivery person uses a mobile application or other electronic interface to initiate an unlock operation, causing a latch 360 associated with the lid 304 to transition from a locked state to an unlocked state.
Upon unlocking of the latch 360, a powered actuator 362 coupled to the lid 304 is energized to move the lid 304 from a closed position toward an open position, thereby providing hands-free access to the storage compartment for package placement. After a package is placed within the storage compartment, the delivery person can provide a confirmation input (e.g., via the mobile application or by interacting with the package storage system 300), causing the actuator 362 to return the lid 304 toward the closed position and the latch 360 to re-engage, thereby securing the package within the package storage system 300. In some embodiments, a photograph or status record of the closed and locked lid 304 is generated to confirm secure delivery.
In the illustrated embodiment, the lid 304 is secured using a latch 360 and a single powered actuator 362, each positioned at respective locations about the lid 304. In some configurations, as illustrated in FIGS. 20A-20B, the latch 360 and the actuator 362 are positioned on generally opposing sides of the lid 304, while in other configurations the latch 360 and the actuator 362 are positioned at non-opposing or partially offset locations (e.g., closer to a midline of the lid 304) depending on enclosure geometry, desired opening kinematics, or packaging constraints. The actuator 362 is configured to provide opening and closing motion, while the latch 360 is configured to provide positive locking when the lid 304 is in the closed position. By utilizing a single actuator 362 in combination with a latch 360, the package storage system 300 reduces component count, cost, and risk of actuator failure relative to multi-actuator designs.
When the lid 304 is closed and locked, the lid 304 is mechanically constrained at multiple locations, including at a hinge 364 and the latch 360, and in some embodiments further supported at an actuator coupling region associated with the powered actuator 362. During opening, the latch 360 is released and the actuator 362 applies force to move the lid 304, while during closing the actuator 362 returns the lid 304 and the latch 360 re-engages. This arrangement provides reliable automatic opening and closing of the lid 304 while maintaining secure retention in the closed state, thereby balancing ease of delivery with system robustness and security.
FIG. 21 illustrates a solar charging system 400 for the package storage system 300. The solar charging system 400 can be used to augment the operating life of batteries 420, such as standard alkaline or rechargeable batteries. The system 400 incorporates a solar panel 410, a charging and protection circuit, and a battery storage unit 420, which cooperate to provide supplemental energy while avoiding battery overcharging.
The solar panel 410, which may be provided as a low-power solar option (e.g., approximately 6 VDC at about 1 watt), collects sunlight and generates electrical energy that is routed through a terminal or connector 412 and a protective circuit. A diode 414 is used to prevent reverse current flow from the battery 420 back into the solar panel 410. In some embodiments, a current-limiting resistor 416 is included in the charging path to control charging current and maintain appropriate battery-charging conditions, while in other embodiments the resistor 416 may be omitted or implemented as a low-resistance connection depending on system design requirements.
To protect downstream electronics from voltage spikes or over-voltage conditions, a Zener diode 418 or other voltage-clamping element can be set to a system operating voltage. In some embodiments, the Zener diode 418 operates in conjunction with a resistor 417 that limits current and conditions a solar-derived signal prior to input to a microprocessor 424 or an associated lock circuit 426. This arrangement ensures that suitable voltage levels are provided to the microprocessor 424 and lock circuit 426. In some embodiments, the circuit provides a binary solar-status signal 428 indicative of whether the solar panel 410 is actively producing usable voltage (e.g., solar voltage present=1, absent=0), which can be used to indicate charging status or day/night conditions.
A system regulator 422, such as a Kerong system regulator or another suitable power-management device, controls power flow between the solar panel 410 and the battery 420, optimizing charging to enhance battery longevity. The battery 420 supplies power to the system when solar energy is unavailable (e.g., during nighttime conditions). The regulator 422 can be integrated with, or operatively coupled to, the lock system 426 to maintain system functionality while reducing reliance on conventional battery power.
In summary, the solar charging system 400 leverages solar energy to supplement battery power and extend operational life of the package storage system 300. The combination of the solar panel 410, diode 414, resistor 416, and regulator 422 enables energy-efficient charging, while the microprocessor 424 monitors system operation, including the binary indication of solar availability provided by the solar-status signal 428.
FIG. 22 illustrates a tether or cable alarm system 430 for enhancing security of the package storage system 300. In the illustrated embodiment, a tether or cable 440 is electrically coupled to the package storage system 300 via a connector 442 and forms part of a sensing path monitored by a microprocessor 424. The tether 440 can be configured to exhibit one or more expected electrical characteristics, such as continuity, resistance, capacitance, or signal behavior, which are used by the microprocessor 424 to detect potential tampering or removal of the tether 440.
In some embodiments, the microprocessor 424 monitors a voltage level, signal transition, or interrupt input 450 associated with the tether 440, for example via a pull-up or bias resistor 444, one or more diodes 446, and a voltage-clamping element such as a Zener diode 448. If the monitored signal deviates from an expected range or pattern—such as due to cutting, shorting, bypassing, or disconnecting the tether 440—the microprocessor 424 identifies a tamper condition and generates an alarm output 452. The alarm output 452 can trigger a local alert and/or be communicated via an application programming interface (API) to provide real-time notification of potential unauthorized interference with the package storage system 300.
FIG. 23 illustrates an auxiliary alarm interface 460 integrated with a control system of the package storage system 300. The auxiliary alarm interface 460 enables coupling of an external auxiliary alarm device 464, which is configured to generate an audible, visual, or other alert, in addition to or as an alternative to any internal alarm provided by the package storage system 300.
In the illustrated embodiment, the auxiliary alarm device 464 is electrically connected to the package storage system 300 via a terminal or connector 466 and is powered by an auxiliary power source, such as a low-voltage DC supply (for example, approximately 6 VDC at about 30-100 mA). Activation of the auxiliary alarm device 464 is controlled by an auxiliary alarm output 461 generated by a microprocessor 424 of the package storage system 300, allowing the system to selectively trigger the auxiliary alarm device 464 in response to a detected security event.
The auxiliary alarm output 461 controls a switching device 462, such as an N-channel field-effect transistor (FET) or an NPN bipolar transistor, which selectively completes a power path between the auxiliary power source and the auxiliary alarm device 464. This arrangement allows the microprocessor 424 to control activation of the auxiliary alarm device 464 without directly supplying alarm current, thereby supporting auxiliary alarm devices 464 having higher current or output requirements while maintaining reliable and secure system operation. The auxiliary alarm interface 460 is particularly useful in embodiments where a high-output external alarm (e.g., louder alarm) is desired to provide enhanced user notification.
FIG. 24 illustrates an optional safety feature for the package storage system 300, in which an internal emergency release pushbutton 470 is provided to allow release of a lock from within the storage compartment. In the illustrated embodiment, the emergency release pushbutton 470 is mounted on an interior surface of the lid 304 and is electrically coupled to a control system of the package storage system 300 via a connector or wiring harness 472.
In some embodiments, the emergency release pushbutton 470 is configured to generate an emergency release input 474 to a microprocessor 424, which in turn causes a latch 360 to transition to an unlocked state, thereby permitting the lid 304 to be opened from within the storage compartment. The emergency release pushbutton 470 can include a visibility feature, such as glow-in-the-dark phosphor material, to facilitate identification and actuation in low-light conditions. This internal emergency release feature provides an additional safety option without interfering with normal external operation of the package storage system 300. In other embodiments, the emergency release pushbutton 470 is mechanically coupled to the latch 360 to permit direct release without electronic control.
FIG. 25 illustrates an optional motion detection system 480 configured to reduce power consumption of the package storage system 300. In some embodiments, the package storage system 300 operates in a low-power or sleep mode when not actively in use. The motion detection system 480 can include a low-power motion sensor that remains active while a microprocessor and associated lock and control electronics are in a reduced-power state, allowing the system to detect motion while conserving energy.
In one example implementation, the motion detection system 480 includes a passive infrared (PIR) motion sensor module, such as a BS412-type sensor available from Nanyang Senba Optical and Electronic Co., Ltd. However, it is worth noting that any suitable low-power motion sensor configured to generate a wake-up or interrupt signal may be employed. Suitable motion sensors can include PIR sensors, microwave motion sensors, accelerometers, vibration sensors, or other motion-sensing devices capable of operating at low power.
In the illustrated embodiment, the motion detection system 480 is electrically coupled to the package storage system 300 via a connector 482 and is configured to generate a wake-up signal at a wake-up interrupt input of the microprocessor upon detection of motion. Receipt of the wake-up signal causes the microprocessor to transition from the sleep mode to an active mode, enabling communication functions (e.g., Bluetooth connectivity) or lock control operations. When motion is no longer detected for a period of time, the microprocessor can return to the low-power state to conserve energy.
In some embodiments, the motion detection system 480 is used solely to wake the microprocessor, while in other embodiments motion detection can additionally be used to initiate security monitoring, alert generation, or preparatory activation of communication interfaces. The motion detection system 480 is optional and can be omitted entirely in embodiments where continuous operation or alternative wake-up mechanisms are preferred.
FIGS. 26-27 illustrate an example control flow for operating the package storage system 300 in a low-power monitoring mode while maintaining security monitoring, alarm handling, and user-notification functionality. The flowcharts represent example operational logic executed by a control system of the package storage system 300.
As shown at block 502, the control system enters a sleep or reduced-power state in which battery status and one or more data accumulators are periodically logged, while one or more wake sources are monitored. At decision block 504, example wake sources include detection of motion, keypad activity, or communication activity via an NFC interface or a Bluetooth Low Energy (BTLE) interface.
When a wake event is detected, the control system exits the sleep state and transitions to an active state at block 506, where an indication is provided that the system is active (e.g., a status message or indicator output). Following wake-up, the control system concurrently monitors for (i) receipt of a valid authorization input and (ii) detection of a potential security event.
As shown at decision block 508, the control system determines whether a valid authorization input is received, such as via an NFC interface, a Bluetooth Low Energy (BTLE) interface, or a keypad code. If a valid authorization input is received, the control system proceeds along a normal access path in which opening and closing of the lid 304 are treated as authorized activity.
In parallel with monitoring for valid authorization, the control system monitors for unauthorized conditions, including whether the lid 304 is opened without prior authorization or whether an excessive motion condition is detected, as evaluated at decision block 516. If an unauthorized condition is detected before receipt of valid authorization, the control system enters an alarm-handling path and executes block 518, triggering an alarm and generating a notification output indicating a potential security event.
As further illustrated at block 542, the control system provides an explicit alarm-reset path in which an active alarm is reset or disabled in response to receipt of valid user authorization, such as entry of a keypad code, authentication via a Bluetooth Low Energy (BTLE) interface, or interaction via a near-field communication (NFC) interface. Upon successful authorization, the control system disables the alarm, updates system status indicators, and transitions to the authorized access path, in which subsequent opening and closing of the lid 304 are treated as authorized activity. The control system then continues execution along the normal access and monitoring flow, including evaluation of lid state, timing conditions, and re-locking operations as described above.
Upon entering the authorized access path, the control system evaluates the state of the lid 304 at decision block 510 to determine whether the lid 304 is open. If the lid 304 is not open, the control system executes block 520, in which any active alarm is disabled, an unlocked status is indicated, and a countdown timer is initiated to monitor a time-to-door-open condition.
At decision block 524, the control system determines whether the time-to-door-open countdown has expired while the lid 304 remains closed. If the countdown expires without the lid 304 being opened, the control system executes block 526 to automatically re-lock the package storage system 300, and the control system proceeds to post-closure handling. If the countdown has not expired, the control system continues monitoring the lid state at decision block 510.
If the lid 304 is determined to be open at decision block 510, the control system proceeds to decision block 512 to determine whether the lid 304 has been closed. If the lid 304 is not closed, the control system executes block 522, in which an opened status is indicated and a time-to-door-closed countdown is initiated. The control system then enters the door-open escalation path illustrated in FIG. 27.
As shown in FIG. 27, the control system evaluates at decision block 534 whether the time-to-door-closed countdown has exceeded a predefined threshold while the lid 304 remains open. If the threshold is exceeded, the control system executes block 536, generating an audible alarm and notifying a user. The control system continues monitoring at decision block 538 until the lid 304 is detected as closed.
Upon detecting that the lid 304 has been closed, whether before or after execution of the door-open escalation path, the control system executes block 540, resetting any audible alarm and generating a notification that the condition has been resolved. The control system then returns to the authorized access flow.
After completion of the authorized access sequence, the control system executes block 514, in which the alarm is armed or maintained, a closed/secured indication is provided, and in some embodiments metadata (e.g., NFC/BTLE metadata) and/or an image capture event is recorded.
The control system then executes block 528, monitoring for continued user presence based on RSSI, motion detection, or keypad activity. At decision block 530, the control system determines whether a user is present. If no user is present and a sleep timer exceeds a predefined threshold at decision block 532, the control system returns to the reduced-power sleep state at block 502.
In accordance with the proximity-based interaction and indicator control logic described above, FIG. 28 illustrates an example package storage system having one or more visual indicators configured to provide delivery guidance and status information. Specifically, FIG. 28 illustrates the integration of lighting indicators on a package storage system 300, designed to facilitate delivery authentication and ensure proper placement and security. Upon delivery, the package storage system 300 can trigger lighting indicators in one or more stages on both a top portion of the unit, such as an upper visual indicator 510, and on a user interface region (e.g., a keypad), as illustrated. These lighting cues signal to delivery personnel that the correct delivery location has been identified and that the package storage system 300 is ready to receive a delivery. In some embodiments, the package storage system is intentionally configured not to indicate the presence of a delivered package except when such indication is relevant to a trusted or authorized entity.
As further illustrated, the package storage system 300 can include lighting on a bottom portion of the unit, such as a lower visual indicator 514, which assists in providing a clear visual indication of the storage system's location and status. In some embodiments, the lower visual indicator 514 provides localized or directional illumination to guide placement of the package relative to the package storage system 300. The lower visual indicator 514 can be particularly useful in low-light conditions, when the package storage system 300 is partially obscured, or when additional guidance is needed to confirm proper placement of a delivered package relative to the unit. The lighting indicators 510, 514 can also assist a homeowner in verifying that a delivery has been authorized and completed.
Additionally, the package storage system 300 can be connected to a home control system configured to activate designated exterior lighting 516 to facilitate access to the delivery location. For example, exterior lighting 516 such as porch lights or entryway lights can be activated in coordination with the lighting indicators 510, 514 during a delivery event. The exterior lighting 516 can remain active for a set period of time, allowing the homeowner to confirm that the package has been delivered correctly, and can subsequently turn off or reset to original lighting settings after the package storage system 300 is locked and secured.
In some embodiments, the lighting indicators 510, 514 operate in different illumination behaviors (e.g., color, intensity, or pattern) to convey different system states, such as indicating readiness to accept a delivery, confirmation that a delivery has been completed, or indication that a return package is present for pickup. For example, a return-available indication may be presented only when delivery personnel associated with a return pickup are detected nearby. In further embodiments, activation or visibility of the lighting indicators 510, 514 and/or exterior lighting 516 can be dynamically controlled based on detected presence or proximity of delivery personnel or a user, so that delivery-related indications are provided when useful while avoiding unnecessary broadcast of package presence after delivery. In this manner, the lighting features enhance convenience, security, and visibility during deliveries while maintaining controlled disclosure of system status.
While the embodiments described above emphasize visual indicators, the package storage system 300 can additionally or alternatively employ audible indicators to provide delivery guidance and status information. For example, the package storage system 300 can generate tones, chimes, spoken prompts, or other audio cues to assist delivery personnel in locating the correct delivery location or confirming delivery authorization. In some embodiments, audible indicators are used in combination with visual indicators 510, 514, while in other embodiments audible indicators are used selectively or exclusively, depending on environmental conditions or user preferences. In some embodiments, audible indicators are enabled only when a trusted presence is detected, and are otherwise suppressed to maintain discretion.
In some embodiments, the package storage system 300 is configured to dynamically balance visibility and discretion by controlling when and how indicators are activated. For example, indicator activation can be temporally limited to periods when delivery personnel are expected or detected nearby, and can be reduced, altered, or disabled when delivery personnel are no longer present. This approach allows the package storage system 300 to provide strong, unambiguous guidance during delivery while avoiding unnecessary illumination or signaling that could draw attention to the presence of a delivered package after the delivery event has concluded.
Indicator behavior can further be modulated based on contextual information or metadata available to the package storage system 300. For example, illumination or audio patterns can be adjusted based on whether a delivery is associated with a first-time delivery driver, a newly installed package storage system, a recent change in the physical location of the package storage system 300, or a change in delivery authorization credentials. In some embodiments, indicator behavior is adapted based on historical delivery data, user-configured preferences, or delivery-service-specific metadata to improve delivery accuracy and user awareness over time.
In some embodiments, indicator behavior is further influenced by contextual risk information or security-related conditions associated with an environment of the package storage system 300. For example, if recent unauthorized access attempts, tamper events, or other anomalous activity have been detected in proximity to the package storage system 300, the system can reduce, suppress, or modify indicator behavior to operate in a more discreet mode. In such embodiments, visual or audible indicators may be limited, disabled, or replaced with lower-profile signaling unless a trusted presence is detected.
In some embodiments, activation of delivery-related indicators is conditioned on detection of a trusted signal or presence, such as a delivery-service radio-frequency (RF) identifier, a Bluetooth Low Energy (BTLE) signal associated with delivery personnel, a user device associated with a homeowner, or another authenticated proximity signal. In this manner, the package storage system 300 can selectively provide delivery guidance when a delivery person or authorized user is nearby, while minimizing visibility or signaling in the absence of such trusted presence, thereby balancing delivery assistance with security and discretion.
In this manner, the package storage system 300 provides a context-aware signaling framework that is not limited to static on/off indicators, but instead delivers adaptive, multi-modal feedback—visual, audible, or both—based on delivery timing, proximity, authorization state, and metadata. This adaptive signaling approach improves delivery success and user confidence while minimizing unnecessary exposure of package presence and maintaining a desired balance between convenience and security.
FIG. 29 illustrates an embodiment of a package drop system 600 designed for secure, unattended delivery of a package into a protected storage region. In this embodiment, the package drop system 600 includes a delivery opening 604 controlled by a movable or hinged delivery door 606, which is normally closed to prevent unauthorized access and is selectively opened during a delivery event. When a package is delivered, the delivery door 606 opens to permit the package to pass through the delivery opening 604 and into a downstream secure storage area or designated home storage lock region.
As illustrated, the package is delivered by an aerial delivery device 614, such as a drone, which remains airborne during delivery and supports the package using a flexible line or tether 616 coupled to a gripping or release assembly 618. In the illustrated embodiment, the aerial delivery device 614 positions the package above a fixed funnel 602 associated with the delivery opening 604, and actuates the gripping or release assembly 618 to lower and release the package into the funnel 602. The funnel 602 guides the package toward and through the delivery opening 604 while the delivery door 606 is in an open state, reducing sensitivity to positioning error and assisting controlled transfer of the package into the downstream storage region.
In alternative embodiments, the package may be released directly through the delivery opening 604 without use of the funnel 602, for example when sufficient alignment accuracy can be achieved by the aerial delivery device 614. In further alternative embodiments, the funnel 602 and the delivery door 606 are integrally formed or operatively coupled such that movement of the delivery door 606 from the closed position to the open position defines or creates a funnel-like guide structure that directs the package toward and through the delivery opening 604 during release.
The package drop zone defined downstream of the delivery opening 604 is configured to guide the package safely into the storage system once the delivery door 606 opens. In some embodiments, the package drop system 600 includes one or more sensing elements 605 positioned along or below the delivery opening 604 to detect entry of the package, monitor its movement, and determine when the package has cleared the delivery opening 604. Such sensing allows the system to count delivered packages, confirm that the package has been successfully transferred into the storage region, and coordinate closure of the delivery door 606 only after the package has fully passed through the opening.
By automatically detecting the package and managing operation of the delivery door 606, the package drop system 600 streamlines the package delivery process, reduces reliance on precise manual timing by delivery personnel or aerial delivery systems, and reduces the risk of incomplete delivery, interference, or human error. The package drop system 600 thereby enhances overall security, reliability, and convenience of aerial package delivery.
In some embodiments, after a package has passed through the delivery opening 604 and entered the storage region, the package storage system assesses the delivered package using the orientation-aware measurement and verification techniques described above. For example, the system may determine package orientation, dimensions, or volume and associate such measurements with an expected delivery event to confirm successful delivery. In this manner, the FIG. 29 embodiment supports post-delivery verification without requiring precise pre-release alignment by the aerial delivery device.
The embodiment illustrated in FIG. 29 represents a general aerial package drop interface suitable for use with a variety of aerial delivery devices and release mechanisms. As described in further detail below with reference to FIG. 30, additional embodiments extend this concept to coordinated, sealed delivery interfaces in which the aerial delivery device physically covers or seals a funnel or delivery opening during delivery and cooperates with sensor-based confirmation to further limit third-party access and environmental exposure during the delivery process.
FIG. 30 illustrates a further embodiment of the package drop system 600 configured for coordinated aerial delivery using a tethered package drop approach. In the embodiment of FIG. 30, an aerial delivery device 614, such as a drone, delivers a package 612 while remaining airborne and lowers the package 612 toward the package drop system 600 using a flexible tether 616. The package 612 can be enclosed within a package carrier or drop container 618 that is configured to protect the package during lowering and release.
As illustrated, the package drop system 600 includes a funnel 602 defining a delivery opening 604, with a delivery door 606 positioned below the funnel 602. The aerial delivery device 614 is configured to position itself over the funnel 602 such that the package 612 and package carrier 618 are aligned with the delivery opening 604. In this embodiment, the aerial delivery device 614 cooperates with the package drop system 600 so that the delivery door 606 is opened only when the aerial delivery device 614, via the package carrier 618, is positioned over and substantially covering the delivery opening 604.
As illustrated in FIG. 30, a sealed package drop system 700 includes a funnel or delivery interface 702 defining an openable delivery opening 704 that is normally closed to block access to an interior storage region. The delivery opening 704 is selectively openable to permit passage of a package 712 only during an authorized delivery event.
In the illustrated embodiment, an aerial delivery device 714 lowers a package carrier 718 toward the delivery interface 702 using a tether 716. The package carrier 718 includes a carrier release opening or door 719 that is selectively openable to release the package 712 from the carrier 718.
During delivery, the package carrier 718 is positioned over the delivery interface 702 such that it covers the delivery opening 704. Once the package carrier 718 is in position and covering the delivery opening 704, the sealed package drop system 700 coordinates opening of the delivery opening 704 with opening of the carrier release opening 719, allowing the package 712 to pass from the package carrier 718, through the delivery opening 704, and into the interior storage region while the delivery opening 704 remains physically covered by the package carrier 718.
After the package 712 has been released and has fully cleared the delivery opening 704, the delivery opening 704 is closed and the carrier release opening 719 is closed before the aerial delivery device 714 raises the package carrier 718 away from the delivery interface 702. In this manner, the delivery opening 704 is never exposed except while physically blocked by the package carrier 718, providing a layered security approach that relies on coordinated physical coverage and sequencing of openable elements.
Physical coverage of the delivery opening 704 may be provided in different degrees depending on implementation. In some embodiments, the package carrier 718 substantially covers the delivery opening 704 such that third-party access, pests, or debris are blocked during delivery while allowing minor gaps or tolerances consistent with aerial alignment. In other embodiments, the package carrier 718 cooperates with the delivery interface 702 to form a substantially sealed delivery interface during release of the package, such that the interior storage region is isolated from the external environment while the delivery opening 704 and carrier release opening 719 are open.
In the embodiment of FIG. 30, the sealed package drop system 700 can further include a landing or docking area 706 surrounding, flanking, or integrated with the delivery interface 702. The landing area 706 is configured to receive and support the package carrier 718 when the package carrier 718 is lowered by the aerial delivery device 714, thereby stabilizing the carrier 718 while it covers the delivery opening 704. The landing area 706 can be shaped, contoured, or dimensioned to complement an exterior profile of the package carrier 718, assisting repeatable positioning and coverage of the delivery opening 704 during delivery.
In some embodiments, the package carrier 718 physically contacts and is supported by the landing area 706 during delivery. In other embodiments, the aerial delivery device 714 maintains the package carrier 718 in a hovering position immediately above the delivery interface 702 such that the package carrier 718 substantially covers the delivery opening 704 without requiring physical contact with the landing area 706. In both cases, the package carrier 718 can provide physical coverage of the delivery opening 704 during coordinated opening and release.
To facilitate accurate approach, alignment, and positioning of the package carrier 718 relative to the delivery interface 702, the sealed package drop system 700 can include one or more visual indicia, fiducial markers, or optical targets 708 positioned on or near the delivery interface 702 and/or the landing area 706. The indicia 708 can be used by the aerial delivery device 714 to localize, orient, and align the package carrier 718 as it approaches the delivery interface 702, enabling reliable coverage of the delivery opening 704 prior to opening of the delivery opening 704 or the carrier release opening 719. Such alignment may be achieved while the package carrier 718 remains airborne or hovering above the delivery interface 702, without requiring physical contact. In some embodiments, the markers can be electronic, such as radio-frequency or other signaling sources that can be used for navigation. Further, in some embodiments, the delivery interface 702 can include docking interface elements, such as magnets or gripping elements, to optionally facilitate a clean and repeatable aligned docking when physical seating of the package carrier 718 is desired.
In some embodiments, the visual indicia, fiducial markers, or optical targets 708 provide non-contact guidance cues that enable the aerial delivery device 714 to maintain the package carrier 718 in a desired position and orientation relative to the delivery interface 702 while hovering. In such embodiments, the aerial delivery device 714 uses the indicia 708 to regulate lateral position, height, and orientation of the package carrier 718 such that the package carrier 718 substantially covers the delivery opening 704 during coordinated opening and release, without the package carrier 718 physically contacting the delivery interface 702 or landing area 706.
In some embodiments, the visual indicia, fiducial markers, or optical targets 708 collectively define an optical orientation zone associated with the delivery interface 702. The optical orientation zone provides a known visual reference frame that can be used by the aerial delivery device 714 to determine relative position, orientation, and approach trajectory with respect to the delivery opening 704 and landing area 706.
The visual indicia, fiducial markers, or optical targets 708 may be provided as permanent features of the delivery interface 702 or landing area 706, or may be dynamically activated only during an expected delivery event. In some embodiments, the indicia 708 are passively visible features, while in other embodiments the indicia 708 are illuminated, electronically activated, or otherwise selectively enabled to assist approach and alignment of the package carrier 718 only when delivery is authorized.
The aerial delivery device 714 may employ image capture and perception algorithms to identify the optical orientation zone and to align the package carrier 718 such that it covers the delivery opening 704 prior to opening of the delivery opening 704 or the carrier release opening 719. By relying on a defined optical orientation zone, the FIG. 30 embodiment enables repeatable, autonomous alignment and coordinated sealing without requiring mechanical guides or physical contact prior to docking.
Docking interface elements associated with the landing area 706 may be configured to partially stabilize, align, or damp movement of the package carrier 718 during delivery without rigidly locking the package carrier 718 to the delivery interface 702. Such stabilization may assist in maintaining coverage of the delivery opening 704 during release while accommodating minor positional variation or hover-based delivery.
In some embodiments, the package carrier 718 is configured as a rigid or semi-rigid container having a closable bottom opening, trap door, or release panel corresponding to the carrier release opening 719. The package carrier 718 can be dimensioned to fully cover the delivery opening 704 when seated on the landing area 706, thereby forming a physical barrier that seals the delivery interface 702 from above during delivery. Such a package carrier 718 can be similar in form and operation to aerial delivery containers used in tethered delivery systems, including containers configured to protect packages during lowering and to release packages downward upon actuation. By way of example, the package carrier 718 can be similar in form and operation to tethered aerial delivery containers used in commercial drone delivery systems, such as those employed by Zipline International, Inc., however the package carrier 718 can take any suitable form consistent with the delivery techniques described herein.
The package carrier 718 may take any suitable form capable of lowering a package toward the delivery interface 702 and releasing the package into the protected interior storage region. While the illustrated embodiment shows a package carrier 718 having a bottom-facing release opening 719 that cooperates with a generally horizontal delivery opening 704, other carrier configurations may be used, including carriers having side-facing release panels, articulated release members, or other openable interfaces that permit controlled deposit of the package. The specific carrier configuration may be selected based on delivery constraints, package geometry, or aerial delivery system capabilities without departing from the coordinated delivery principles described herein.
In operation, the aerial delivery device 714 lowers the package carrier 718 until the package carrier 718 is seated on the landing area 706 and covers the delivery opening 704 or otherwise positioned to cover the delivery opening 704. While the package carrier 718 remains covering the delivery opening 704, the sealed package drop system 700 selectively opens the delivery opening 704 and coordinates release of the package 712 from the carrier release opening 719. Because the delivery opening 704 is physically covered throughout the release sequence, third-party access, pests, debris, or environmental ingress are prevented during delivery.
After the package 712 has fully cleared the delivery opening 704 and the delivery opening 704 and carrier release opening 719 are closed, the aerial delivery device 714 raises the package carrier 718 away from the delivery interface 702. In this manner, the sealed package drop system 700 maintains a closed delivery interface 702 before, during, and after delivery, except while physically blocked by the package carrier 718, thereby providing a robust, layered security approach well suited for unattended aerial delivery across a variety of installation configurations.
In some embodiments, the package drop interfaces and storage regions described above are integrated into different portions of a structure, including exterior walls, façades, or elevated openings. For example, the delivery interface may be positioned at an upper-floor window, balcony, or wall-mounted location that is not readily accessible from ground level. Such configurations may be advantageous for aerial delivery scenarios in which conventional ground-based access to the storage system is limited, impractical, or undesirable.
In some embodiments, packages delivered through a delivery opening or drop interface are transported from the delivery interface to a downstream storage region using a guided conveyance path. The conveyance path may include, for example, a conveyor, belt, slide, chute, gravity-assisted guide, or other transport mechanism configured to move a delivered package away from the delivery opening after entry. Conveyance may be particularly useful in installations involving vertical, angled, or offset delivery interfaces, including wall-mounted or window-aligned configurations. Operation of the conveyance path may be coordinated with sensing, orientation determination, and delivery verification logic described above to confirm successful transfer and trigger closure of the delivery interface.
In some embodiments, packages delivered through a delivery opening or drop zone are transported from the delivery interface to a downstream storage region using a guided conveyance mechanism. The conveyance mechanism may include, for example, a conveyor, belt, slide, chute, rotating element, gravity-assisted guide, or other transport structure configured to move a delivered package away from the delivery opening after entry. Such conveyance may be used to accommodate vertical, angled, or offset delivery paths, including delivery through windows or wall-mounted interfaces.
FIG. 31 illustrates an embodiment of a security architecture configured to protect a package storage system 300 from malicious interference, such as intentional radio-frequency (RF) jamming by an unauthorized actor. As illustrated, a jamming device 802 attempts to disrupt wireless communication associated with the package storage system 300.
In the illustrated embodiment, the package storage system 300 is communicatively coupled to a hub or router 800 that supports multiple RF communication technologies. The hub or router 800 can communicate using different wireless modalities, such as Wi-Fi, Bluetooth Low Energy (BTLE), long-range or low-frequency communication protocols, or combinations thereof. By employing multiple RF technologies operating on different frequency bands, the system reduces reliance on any single communication channel.
The hub or router 800 is configured to monitor the health and availability of communication with the package storage system 300. Loss of expected communication, degradation of signal quality, or other abnormal communication behavior can be treated as a security-relevant condition. In some embodiments, the hub or router 800 includes a watchdog or monitoring function that detects such communication anomalies.
In response to detection of RF interference, communication failure, or other anomalous communication conditions, the hub or router 800 can trigger an alarm or notification indicating a potential tampering or attack on the package storage system 300. In this manner, attempts to suppress wireless communication do not result in silent failure, but instead generate a detectable security event, thereby enhancing the overall robustness and security of the package storage system 300.
Directional terms, such as “vertical,” “horizontal,” “top,” “bottom,” “upper,” “lower,” “inner,” “inwardly,” “outer” and “outwardly,” are used to assist in describing the invention based on the orientation of the embodiments shown in the illustrations. The use of directional terms should not be interpreted to limit the invention to any specific orientation(s).
The above description is that of current embodiments of the invention. Various alterations and changes can be made without departing from the spirit and broader aspects of the invention as defined in the appended claims, which are to be interpreted in accordance with the principles of patent law including the doctrine of equivalents. This disclosure is presented for illustrative purposes and should not be interpreted as an exhaustive description of all embodiments of the invention or to limit the scope of the claims to the specific elements illustrated or described in connection with these embodiments. For example, and without limitation, any individual element(s) of the described invention may be replaced by alternative elements that provide substantially similar functionality or otherwise provide adequate operation. This includes, for example, presently known alternative elements, such as those that might be currently known to one skilled in the art, and alternative elements that may be developed in the future, such as those that one skilled in the art might, upon development, recognize as an alternative. Further, the disclosed embodiments include a plurality of features that are described in concert and that might cooperatively provide a collection of benefits. The present invention is not limited to only those embodiments that include all of these features or that provide all of the stated benefits, except to the extent otherwise expressly set forth in the issued claims. Any reference to claim elements in the singular, for example, using the articles “a,” “an,” “the” or “said,” is not to be construed as limiting the element to the singular.
1. A tethering system for securing a package storage system, the tethering system comprising:
a tether having a first end and a second end;
a door tethering security bracket configured to attach to a door, the door tethering security bracket including at least one opening configured to receive the first end of the tether;
a package storage system tethering security bracket mounted within the package storage system, the package storage system tethering security bracket including a plurality of openings configured to receive and route the second end of the tether, wherein the second end of the tether passes through the plurality of openings of the package storage system tethering security bracket to form a retention path that resists withdrawal; and
a lock configured to secure the package storage system in a closed condition, thereby restricting access to the package storage system tethering security bracket and the retention path formed by routing the second end of the tether through the plurality of openings.
2. The tethering system of claim 1, wherein the door tethering security bracket further comprises a double-thickness structure to resist cutting attempts.
3. The tethering system of claim 1, wherein the package storage system tethering security bracket is configured to permit routing of the tether through different combinations of the plurality of openings to provide multiple selectable retention configurations.
4. The tethering system of claim 1, wherein the lock includes a digital lock operable remotely via a network communication system.
5. The tethering system of claim 1, wherein the tether includes a section of heat-shrink tubing positioned at or near the second end of the tether to facilitate routing through the plurality of openings and to reduce fraying.
6. The tethering system of claim 1, wherein the door tethering security bracket includes multiple openings configured to receive different forms of the tether, including a tether having an enlarged termination and a tether in the form of a chain or lock.
7. The tethering system of claim 1, further comprising an adhesive-backed pad or felt liner applied to the door tethering security bracket to prevent damage to a door to which the bracket is attached.
8. The tethering system of claim 1, wherein the package storage system tethering security bracket is configured to align with a vertical structural rod within the package storage system.
9. The tethering system of claim 1, wherein the tether is tensionable by pulling the second end of the tether through the plurality of openings of the package storage system tethering security bracket.
10. The tethering system of claim 1, wherein the package storage system tethering security bracket includes a quick-release feature accessible only when the package storage system is unlocked, the quick-release feature being configured to allow authorized disengagement of the tether without requiring additional tools.
11. The tethering system of claim 1, wherein the package storage system tethering security bracket is mounted such that at least a portion of the package storage system tethering security bracket extends through an opening in a wall of the package storage system to permit external attachment of a chain or lock.
12. A tethering system for securing a package storage system to an external object, the tethering system comprising:
a tether having a first end and a second end;
a package storage system tethering security bracket mounted within the package storage system, the package storage system tethering security bracket including a plurality of openings configured to receive and route the tether;
wherein the tether extends outward from the package storage system, is looped around an external object, and returns into the package storage system;
wherein the first end and the second end of the tether are routed through the plurality of openings of the package storage system tethering security bracket to form a retention path that resists withdrawal of the tether; and
a lock configured to secure the package storage system in a closed condition, thereby restricting access to the package storage system tethering security bracket and to internal routing points of the retention path that permit reconfiguration or removal of the tether.
13. The tethering system of claim 12, wherein the external object comprises a pole, post, railing, or fence.
14. The tethering system of claim 12, wherein the tether is tensionable by pulling at least one of the first end or the second end of the tether through the plurality of openings of the package storage system tethering security bracket after looping around the external object.
15. The tethering system of claim 12, wherein the package storage system tethering security bracket is configured to permit routing of the tether through different combinations of the plurality of openings to provide multiple selectable retention configurations.
16. The tethering system of claim 12, wherein the tether includes a section of heat-shrink tubing positioned at or near at least one of the first end or the second end of the tether to facilitate routing through the plurality of openings and reduce fraying.
17. The tethering system of claim 12, wherein the tether comprises a cable having an enlarged termination at one end of the cable, the enlarged termination having a transverse dimension larger than a selected opening of the plurality of openings such that the enlarged termination is retained relative to the package storage system tethering security bracket.
18. The tethering system of claim 12, wherein the package storage system tethering security bracket includes indicia associated with the plurality of openings to guide routing of the tether in different retention configurations.
19. The tethering system of claim 12, wherein the package storage system tethering security bracket includes a quick-release feature accessible only when the package storage system is unlocked, the quick-release feature being configured to permit authorized disengagement of the tether without requiring additional tools.
20. The tethering system of claim 12, wherein the tether includes an electrically conductive element monitored by a control system of the package storage system to detect tampering with the tether, and wherein the control system is configured to generate an alarm in response to a detected change in an electrical characteristic of the tether.
21.-80. (canceled)