Embodiments of the present invention relate generally to security systems, locks, devices, computer program products, and methods for protecting items from theft and/or the exchange of various types of information in a wireless network.
It is common practice for retailers to display relatively small, relatively expensive items of merchandise on a security device, such as a display hook or a display fixture, within security packaging commonly referred to as a “safer”, or otherwise on a display surface. The security device or safer displays an item of merchandise so that a potential purchaser may examine the item when deciding whether to purchase the item. The small size and relative expense of the item, however, makes the item an attractive target for shoplifters. A shoplifter may attempt to detach the item from the security device, or alternatively, may attempt to remove the security device from the display area along with the merchandise. Items of merchandise may also be secured using a display stand to allow users to sample the item for potential purchase. In some instances, the security device is secured to a display support using a lock operated by a key, for example, a mechanical lock. In other instances, the security device is secured to the display support using a lock operated by an electronic key to arm and disarm the security device.
Embodiments of the present application are directed towards security systems and methods for protecting items from theft. In one embodiment a security system for a fixture is provided and includes at least one lock configured to protect one or more items from theft from the fixture. The lock comprises a drive shaft configured to be moved between a latched position and an unlatched position, and the fixture is configured to be accessed in the unlatched position. The lock is configured to be moved between a locked state and an unlocked state for allowing the drive shaft to be moved between the latched position and the unlatched position when in the unlocked state. In addition, the lock includes a cam sleeve having an internal cam surface configured to transition the lock between the locked state and the unlocked state in response to movement of the cam sleeve. In some cases, a computing device is provided and is configured to transmit a wireless authorization signal to the lock to transition the lock between the locked state and the unlocked state
In another embodiment, a method for securing items from theft from a fixture is provided. The method includes providing at least one lock configured to protect one or more items from theft from the fixture, wherein the lock comprises a drive shaft and a cam sleeve. The method further includes causing the cam sleeve to move to transition the lock from a locked state to an unlocked state. In addition, the method includes causing the draft shaft to be moved between a latched position and an unlatched position while the lock is in the unlocked state, the fixture configured to be accessed in the unlatched position.
The following disclosure includes various embodiments of systems, devices, methods, and computer program products. It should be understood that any combination of embodiments disclosed herein have been envisioned. Thus, discussion of one particular embodiment is not intended to be made at the exclusion of any other embodiments.
Referring now to the associated figures, one or more embodiments of a security system are shown. In the embodiments shown and described herein, the system includes an electronic key and a merchandise security device. Examples of merchandise security devices suitable for use with the electronic keys include, but are not limited to, a security display (e.g. alarming stand or device), security fixture (e.g. locking hook, shelf, cabinet, etc.), cabinet locks, door locks, cable wraps, cable locks, or security packaging (e.g. merchandise keeper) for an item of merchandise. However, an electronic key (also referred to herein as a programmable key or generally as a key) may be useable with any security device or locking device that utilizes power transferred from the key to operate a mechanical and/or electronic lock mechanism and/or utilizes data transferred from the key to authorize the operation of a lock mechanism and/or arming or disarming an alarm circuit. In other words, an electronic key is useable with any security device or locking device that requires power transferred from the key to the device and/or data transferred from the key to the device. Further examples of security devices and locking devices include, but are not limited to, a door lock, a drawer lock or a shelf lock, as well as any device that prevents an unauthorized person from accessing, removing or detaching an item from a secure location or position. Although the following discussion relates to a system for use in a retail store, it is understood that the system is also suitable for other industries, such as hospital, restaurants, etc. In some embodiments, the merchandise security systems, merchandise security devices, and electronic keys are similar to those disclosed in U.S. application Ser. No. 17/668,931, entitled Merchandise Display Security Systems and Methods, PCT Publication WO 2020/227513 (and related U.S. application Ser. No. 17/261,757), entitled Merchandise Display Security Systems and Methods, U.S. Publication No. 2012/0047972, entitled Electronic Key for Merchandise Security Device, U.S. Pat. No. 10,258,172, entitled Systems and Methods for Acquiring Data from Articles of Merchandise on Display, U.S. Pat. No. 10,210,681, entitled Merchandise Display Security Systems and Methods, U.S. Publ. No. 2018/0365948, entitled Tethered Security System with Wireless Communication, and U.S. Publication No. 2016/0335859, entitled Systems and Methods for Remotely Controlling Security Devices, the entire disclosures of which are incorporated herein by reference in their entirety.
In some embodiments, each merchandise security device 14 and/or electronic key 12 is configured to store various types of data. For example, each merchandise security device 14 and/or key 12 may store a serial number of one or more merchandise security devices 14, a serial number of one or more items of merchandise, the data and time of activation of the key, a user of the key, a serial number of the key, a location of the security device, a location of the item of merchandise, a department number within a retail store, number of key activations, a type of activation (e.g., “naked” activation, activation transferring only data, activation transferring power, activation transferring data and power), and/or various events (e.g., a merchandise security device has been locked, unlocked, armed, or disarmed). For instance,
In some cases, the data may include battery analytics of an electronic key 12. For example, the battery analytics may include monitoring the battery voltage of an electronic key 12 when the key is placed on a charging station 18 and the time taken to reach full charge. These values may be used to determine depth of discharge. The battery analytics may be indicative of a battery that is nearing its end of life. A retailer or other authorized personnel may take various actions using this information, such as replacing the key or disabling the key to prevent battery swelling and housing failure.
In one embodiment, the electronic key 12 is configured to obtain data from a merchandise security device 14 (e.g., a security fixture). For example, the merchandise security device 14 may store various data regarding past communication with a previous electronic key 12 (e.g., key identification, time of communication, etc.), and when a subsequent electronic key communicates with the same merchandise security device, the data is transferred to the electronic key. Thus, the merchandise security device 14 may include a memory for storing such data. In some cases, the merchandise security device 14 includes a power source for receiving and storing the data, while in other cases, the power provided by the electronic key 12 is used for allowing the merchandise security device to store the data. The electronic key 12 may then communicate the data for collection and review, such as at a remote location or device 26. In some instances, communication between the electronic key 12 and the programming or authorization station 16 may allow data to be pulled from the electronic key and communicated, such as to a remote location or device 26. In other cases, the electronic key 12 may be configured to obtain data from merchandise security devices 14 (e.g., a security display), such as an identification of the merchandise security device, the type of item of merchandise on display, an identification of the item of merchandise, and/or the system health of the security device and/or the item of merchandise. The electronic key 12 may store the data and provide the data to a remote location or device 26 directly or upon communication with the programming or authorization station 16. As such, the electronic keys 12 may be a useful resource for obtaining various types of data from the merchandise security devices 14 without the need for wired connections or complex wireless networks or systems.
In one embodiment, the security device 14 may communicate its identifier using various techniques. For example, in some cases the security device 14 may have a memory configured to store a serial number and is able to communicate that serial number to the electronic key 12 using bi-directional communication. In instances where the security device 14 may not have a memory, power source, and/or the ability for bi-directional communication (e.g., a cable wrap or locking hook), the security device may have an RFID tag, an NFC tag, or the like that stores an identifier for the security device (e.g., a serial number). Such security devices may be similar to that disclosed in U.S. Pat. No. 9,133,649, entitled Merchandise Security Devices for Use with an Electronic Key, the entire disclosure of which is incorporated herein by reference in their entirety. In some examples, the tag may be attachable (e.g., via adhesive) to existing security devices 14 such that it is readily adaptable to current devices, or the tag may be integrated within the security device. The electronic key 12 may be configured to deliver power to the tag to read the identifier of the tag, such as for a passive tag, although the tags may be passive or active. The electronic key 12 may store a number of authorized identifiers in memory (e.g., via a look-up table) and may then determine if the read identifier is in its memory. Alternately, the electronic key 12 may be configured to wirelessly connect to a network device 26 with a look-up table. Either the electronic key 12 itself or the network device 26 can then determine if the particular key or user of that key is authorized to unlock the security device 14 with the read identifier. The identifier may be unique to the security device 14 or may be a more generic identifier, such as for example, a “6-sided box” or a department such as “healthcare” or all of the above. Once authorization has been obtained, only then will the electronic key be capable of delivering power to the security device 14 to successfully operate the lock and unlock it. If there is no authorization, the electronic key 12 does not continue this cycle, and the lock never unlocks. Thus, embodiments of the present invention may be configured to communicate with any type of security device 14 for performing various auditing, zone control, and planogram analysis based on identification of the security device.
In one embodiment, the electronic key 12 and security device 14 may communicate with one another via NFC to transmit data when the key and security device are positioned near one another or in direct contact with one another. An NFC tag may include various components, such as an antenna or a coil and one or more chips that define an electrical circuit. The antenna may be used for effectuating communication with an electronic key 12, which may be activated via a magnetic field. For example, a magnetic field may be generated by the electronic key 12 to communicate with an NFC tag.
In some embodiments where the electronic key 12 is configured to transfer power inductively, as explained in further detail below, and is equipped to communicate using NFC or RFID, the inductive coil of the key may be configured to use the same coil for both data transfer and power transfer. In some cases, the electronic key 12 is configured to switch the coil between an energy transfer mode and an NFC or RFID receiver circuit. In other examples, a plurality of security devices 14 may be “nested” with one another such that authorization to one of the nested security devices results in all security devices being disarmed or unlocked. For instance, a plurality of locks could be paired to one another such that successful communication between any one of the locks and the electronic key 12 results in all of the locks being unlocked.
In some embodiments, the merchandise security devices 14 include wireless functionality for communicating within the network. For example, the merchandise security devices may communicate wirelessly with each other, items of merchandise, electronic keys 12, computing devices 26, and/or nodes, including but not limited to communicating the various types of data discussed herein. Thus, in some cases, the computing devices 26 may communicate directly with the security devices 14 and/or electronic keys 12
One embodiment of such a wireless system includes various types of wireless networks capable of being used in conjunction with embodiments disclosed herein. In some cases, the wireless system includes fully integrated hardware, software, and data analytics which effectively eliminates or makes negligible the added hardware costs of a data integrated solution—all other features remaining constant. In some embodiments, the wireless system is configured to adapt to a changing market where an increasing number of smartphones leverage Qi based inductive charging and exposed data ports no longer exist. For instance, in an embodiment where the security device 14 includes a sensor 25 and a base or stand 35 (see, e.g.,
In some embodiments, wireless communication may occur using a proprietary wireless network, for example, each security device 14 may be configured to communicate with a central hub in a star network configuration. Each security device 14 may include a transceiver (e.g., a sub-GHz transceiver) configured to communicate data to and from a common central hub or “host” 24, such as the various types of information and data discussed herein, as well as information about power status and security breaches to the host without the need for a separate data connection to a smart hub or controller. It is understood that any number of nodes 20 could be employed to facilitate communication between the security devices 14 and the host, such one or more local nodes. In one embodiment, each security device 14 is configured to communicate its power and security status, security breaches (alarm notifications), as well as various other identification data for the security device and/or the item of merchandise, to the host 24. In some embodiments, an entire retail store may be serviced by a single host 24 without the need for repeaters and is not practically limited by the number of security devices in the network. In one embodiment, the host 24 may be configured to generate a security signal, such as an audible and/or a visible alarm signal. In some cases, the volume of the security signal is adjustable. When any security device 14 detects a security event, the security device is configured to send a signal to the host 24. The retailer has the option of choosing the level of notification for the security event, for example, a loud audible alarm, a lower volume, audible notification, or no audible alarm notification. Among other features, the system may include the ability to program alarm notifications. For instance, a retailer may choose silent alerts, optical alerts, and adjustable volume and tone audible alerts or combinations of these alerts. Additionally, the host 24 could be configured to indicate a security breach by changing colors (e.g., from gold to red and or by flashing intermittently). The audible and visual alert signals can be used independently or together.
As discussed herein, electronic keys 12 may be incorporated with the various system embodiments. Electronic keys 12 may be configured to disable any alarming security device 14 following a security event. However, the host 24 may be configured to continue to transmit a security signal, such as until the security device 14 is re-armed. Moreover, disabling a security signal on the host 24 may not affect the armed status of the remaining security devices 14 in the store, i.e., the security devices may operate one-to-one in every regard except for generation of security signals. Of course, a variety of types of electronic keys 12 as disclosed herein, including leveraging a secure application available on a smartphone, tablet or PC.
In some embodiments, a pre-emptive disarm for purposes of remerchandising items of merchandise or nightly removal of the item from an associated security device 14 may be employed. For example, a computing device 26 of the retailer (e.g., a mobile device) 26 may be configured to automatically disarm one or more security devices 14 at a predetermined period of time. In some cases, a secure software application may permit a temporary suspension of alerts for a specific position of a security device 14 for a programmable period to permit re-merchandising. One disarmed, the security device's transceiver will cease communicating until it is re-armed. For those customers operating in a “Non-IP Connected” mode can elect to silence the audible alarm of the security device 14 when remerchandising such that no audible alarm will sound, but the host may continue to generate a signal (e.g., light signal) until all security devices are re-armed.
As described herein, embodiments of the present invention may utilize a variety of wireless network configurations. In some cases, a common architecture would require two distinct network topologies. The first network may be a private wireless network for the exclusive use of the security devices 14 deployed instore. This network is separate from any private or public network operated by the retailer. The second network may be an IP Gateway between the private network and the Internet. This second network may be a connection on retailer's managed network or could be via a cellular modem. The gateway could be integrated into the host or be a separate device that connects to the host.
In some embodiments, the private network may be commonly used by all security devices 14 for internal data transfer and minimize frequency congestion for retailer managed networks. Moreover, in one example, the private network practically takes the form as a “star network”—with multiple individual nodes 20 performing individual functions and collecting and providing data. This data is wirelessly sent to and aggregated within a common “host”. The host allows nodes 20 providing data wirelessly via the private network to deliver functionality and value to the customer independent of an Internet connection to a cloud-based application, such as alerting and reporting functionality. In one implementation, the host rather than the security device 14 would be configured to provide notification (e.g., in response to a security event) via audio, visual, and/or haptic response.
Various considerations may be taken into account regarding the private network. For instance, in selecting the appropriate, common network architecture for the private network, considerations of the size of the data packets and data rate required, the needed wireless range, potential for interference, power consumption, size, and/or cost of the network may be taken into account. In some applications, intermittent transmission of small data packets, with no need for higher data rates, may be used, which may benefit from a network with low power needs and long data range. Examples of private networks include various RF networks, such as Wi-Fi (2.4 GHz), Bluetooth (2.4 GHz) and Sub GHz (less than 1.0 GHz) ISM band networks. Some network stacks (controlling software) such as Zigbee and LoRa can run on both sub GHz and 2.4 GHz networks.
Another example embodiment of a wireless network system includes various types of security devices 14 and electronic keys 12 that may cooperate with one or more nodes 20, hubs 24, and/or computing devices 26 in a wireless network (see, e.g.,
As shown in
In other embodiments, inventory information may be obtained regarding merchandise on a security device 14 such as a locking hook, information may be obtained regarding items of merchandise removed from a security device (e.g., a cabinet), and computing devices 26 may be used to obtain various types of information and provide various types of commands for controlling the security device and/or item of merchandise. Embodiments of wireless systems disclosed herein may provide for real time reporting of Who/What/When/Where/Why/How for interactions with security devices 14 and items of merchandise, be responsive/interactive, migrate from security focus to omni-channel experience enablement within the retail store, facilitate Trusted Customer engagement with security assets, allow to readily customize and expand the system, enable alternative business models such as SaaS models, connect local network of connected assets with central hub for local computing, and/or connect hub to cloud platform for providing alerts, reporting, system administration, daily operation. Embodiments may also provide a platform infrastructure having a centralized hub per retail store and several fit for purpose connected end security device assets such as stands, sensors, table managers, locks, cabinet sensors, inventory sensors, customer dwell sensors, etc. that all communicate with the hub. Due to the flexibility of wireless systems in some embodiments, customers do not need to pre-select which security devices 14 to purchase since the platform infrastructure is common. Furthermore, computing devices 26 and mobile devices used by retailers may allow retailers and store associates to dynamically interact with security devices 14 to make real-time decisions, such as responding to security events, restocking out of stock inventory, or responding to customer requests for assistance with secured items of merchandise.
In some cases, each electronic key 12 may be authorized for specific locations, departments, or merchandise security devices. For instance,
Various techniques may be used to initially program the electronic key 12. For example, the electronic key 12 may be initially presented to each authorized merchandise security device 14. Upon communication with the security device 14 or the cloud 22, the electronic key 12 will be paired with each security device. A programming station 16 may provide a code to the electronic key 12, and the key or cloud 22 may then communicate the code to each of its authorized security devices 14. Each key 12 may only need to be programmed once. In some embodiments, a programming station 16 may be located within each zone, and a key 12 may receive a code from each programming station that it is authorized. Thereafter, each key 12 may need to be “refreshed” at the programming station 16 or a charging station 18 following a predetermined period of time or in response to being disabled as described in various examples herein. In other embodiments, the electronic key 12 may be programmed directly via the cloud 22.
In another embodiment, each electronic key 12 may include a security code and a serial number for one or more merchandise security devices 14. For example, a key 12 may only be able to arm, disarm, lock, or unlock a merchandise security device 14 where the security codes and the serial numbers match one another. In one example, each serial number is unique to a merchandise security device 14 and could be programmed at the time of manufacture or by the retailer. This technique allows for greater flexibility in programming keys 12 and assigning keys to particular merchandise security devices 14 and/or zones. In one embodiment, a setup electronic key 12″ may be used to initially map particular merchandise security devices 14 and serial numbers. In this regard, the setup key 12″ may be used to communicate with each key 12 and obtain the serial number of each merchandise security device 14. The setup key 12″ may also obtain a location of the security devices 14, or a user of the setup key may provide a description for each merchandise security device (e.g., SN #123=merchandise security device #1). The setup key 12″ may communicate with a tablet or other computing device 26 for accumulating all of the information (see, e.g.,
In order to arm, disarm, lock, or unlock a merchandise security device 14, the electronic key 12 may communicate with a particular merchandise security device and determine whether the security codes and the serial numbers match. If the codes match, the electronic key 12 then arms, disarms, locks, or unlocks the merchandise security device 14. Upon refreshing an electronic key 12 and/or when a user requests an electronic key via programming or authorization station 16, any available electronic key may be used since the key may be programmed in real time with the appropriate level of authorization for that user (e.g., specific zones, departments, and/or merchandise security devices).
In one embodiment, the merchandise display security system 10 comprises an electronic key 12 and a merchandise security device 14 that is configured to be operated by the key. The system may further comprise an optional programming station 16 that is operable for programming the key 12 with a security code, which may also be referred to herein as a Security Disarm Code (SDC). In addition to programming station 16, the system may further comprise an optional charging station 18 that is operable for initially charging and/or subsequently recharging a power source disposed within the key 12. For example, the key 12 and merchandise security device 14 may each be programmed with the same SDC into a respective permanent memory. The key 12 may be provisioned with a single-use (i.e., non-rechargeable) power source, such as a conventional or extended-life battery, or alternatively, the key may be provisioned with a multiple-use (i.e. rechargeable) power source, such as a conventional capacitor or rechargeable battery. In either instance, the power source may be permanent, semi-permanent (i.e., replaceable), or rechargeable, as desired. In the latter instance, charging station 18 is provided to initially charge and/or to subsequently recharge the power source provided within the key 12. Furthermore, key 12 and/or merchandise security device 14 may be provided with only a transient memory, such that the SDC must be programmed (or reprogrammed) at predetermined time intervals. In this instance, programming station 16 is provided to initially program and/or to subsequently reprogram the SDC into the key 12. As will be described, key 12 may be operable to initially program and/or to subsequently reprogram the merchandise security device 14 with the SDC. Key 12 is then further operable to operate the merchandise security device 14 by transferring power and/or data to the device, as will be described.
In the exemplary embodiment of the system illustrated in
An available feature of a merchandise security system 10 according to one embodiment is that the electronic key 12 may include a time-out function. More particularly, the ability of the key 12 to transfer data and/or power to the merchandise security device 14 may be deactivated after a predetermined time period. By way of example, the electronic key 12 may be deactivated after about six to about twenty-four hours from the time the key was programmed or last refreshed. In this manner, an authorized sales associate typically must program or refresh the key 12 assigned to him at the beginning of each work shift. Furthermore, the charging station 18 may be configured to deactivate the electronic key 12 when the key is positioned within or otherwise engaged with a charging port 30 (see, e.g.,
In one embodiment, commands may be provided remotely for taking various actions. For example, where a theft has occurred, a command may be provided from a remote location or device 26 (e.g., a tablet or computer) to lock and/or arm all or a portion of the merchandise security devices 14. Similarly, a command may be provided from a remote location or device 26 to deactivate all or a portion of the electronic keys 12 and/or security devices 14. As such, the system 10 provides techniques for centralized security and control of the electronic keys 12, merchandise security devices 14, and other components within the system. As discussed above, the electronic keys 12 may also be controlled remotely. Furthermore, in some embodiments, such requests or commands may be made by the computing device 26 for individual security devices 14 or a plurality of security devices (e.g., sending a command to lock all security devices in response to a security event). Moreover, one or more of the security devices 14 may be configured to lock or alarm in response to a security event (e.g., automatically locking a sensor attached to an item of merchandise to a base removably supporting the sensor).
As shown in
In a particular embodiment, the logic control circuit of the programming station 16 performs an electronic exchange of data with a logic control circuit of the key, commonly referred to as a “handshake communication protocol.” The handshake communication protocol determines whether the key 12 is an authorized key that has not been programmed previously (e.g., a “new” key), or is an authorized key that is being presented to the programming station 16 a subsequent time to refresh the SDC. In the event that the handshake communication protocol fails, the programming station 16 will not provide the SDC to the unauthorized device attempting to obtain the SDC. When the handshake communication protocol succeeds, programming station 16 permits the SDC to be transmitted by the key 12. As will be readily apparent to those skilled in the art, the SDC may be transmitted from the programming station 16 to the key 12 by any suitable means, including without limitation, wireless, electrical contacts or electromechanical, electromagnetic or magnetic conductors, as desired. Moreover, in other cases the programming station 16 may simply provide the SDC to the electronic key 12 without first initiating any handshake communication protocol.
In some embodiments, the merchandise security device 14 is a “passive” device. As used herein, the term passive is intended to mean that the security device 14 does not have an internal power source sufficient to lock and/or unlock a mechanical lock mechanism. Significant cost savings are obtained by a retailer when the merchandise security device 14 is passive since the expense of an internal power source is confined to the key 12, and one such key is able to operate multiple security devices. If desired, the merchandise security device 14 may also be provided with a temporary power source (e.g., capacitor or limited-life battery) having sufficient power to activate an alarm, for example a piezoelectric audible alarm, that is actuated by a sensor, for example a contact, proximity or limit switch, in response to a security breach. The temporary power source may also be sufficient to communicate data, for example a SDC, from the merchandise security device 14 to the key 12 to authenticate the security device and thereby authorize the key to provide power to the security device. In other cases, the security device may be an electronic device, such as a sensor attached to the item of merchandise and a base that removably supports the sensor thereon. The sensor may be attached to the base with a tether or may be wireless (e.g., using ranging techniques as described in more detail below).
In some embodiments, the merchandise security device 14 further comprises a logic control circuit, similar to the logic control circuit disposed within the key 12, adapted to perform a handshake communication protocol with the logic control circuit of the key in essentially the same manner as that between the programming station 16 and the key. In essence, the logic control circuit of the key 12 and the logic control circuit of the merchandise security device 14 communicate with each other to determine whether the merchandise security device is an authorized device that does not have a security code, or is a device having a matching SDC. In the event the handshake communication protocol fails (e.g., the device is not authorized or the device has a non-matching SDC), the key 12 will not program the device with the SDC, and consequently, the merchandise security device will not operate. If the merchandise security device 14 was previously programmed with a different SDC, the device will no longer communicate with the key 12. In the event the handshake communication protocol is successful, the key 12 permits the SDC stored in the key to be transmitted to the merchandise security device 14 to program the device with the SDC. As will be readily apparent to those skilled in the art, the SDC may be transmitted from the key 12 to the merchandise security device 14 by any suitable means, including without limitation, via radiofrequency, one or more electrical contacts, electromechanical, electromagnetic or magnetic conductors, as desired. Furthermore, the SDC may be transmitted by inductive transfer of data from the electronic key 12 to the merchandise security device 14. Moreover, in other cases the electronic key 12 may simply provide the SDC to the merchandise security device 14 without first initiating any handshake communication protocol.
In one embodiment, when the handshake communication protocol is successful and the merchandise security device 14 is an authorized device having the matching SDC, the merchandise security device may be armed or disarmed, such as where the security device includes an alarm circuit. In other embodiments, the merchandise security device 14 may be armed or disarmed when the SDC codes match. In some embodiments, when the handshake communication protocol is successful and the SDC codes match, the logic control circuit of the key 12 causes an internal power source of the key to transfer electrical power to the device 14 to operate a mechanical lock mechanism. In other embodiments, the merchandise security device 14 may be locked or unlocked when the SDC codes match and power is transferred to the merchandise security device. It is understood that various information and codes may be exchanged in order to perform the desired function, such as arming, disarming, locking, or unlocking the merchandise security device 14. For example, the data exchanged may include a serial number of the merchandise security device alone and/or an SDC.
In some embodiments, the electronic key 120 comprises a housing 121 having an internal cavity or compartment that contains the internal components of the key, including without limitation the logic control circuit, memory, communication system and battery, as will be described. As shown, the housing 121 is formed by a lower portion 123 and an upper portion 124 that are joined together after assembly, for example by ultrasonic welding. The electronic key 120 further defines an opening 128 at one end for coupling the key to a key chain ring, lanyard or the like. The electronic key 120 may further comprise a transfer probe 125 located at an end of the housing 121 opposite the opening 128 for transferring data and/or power to the merchandise security device 140. The transfer probe 125 is also operable to transmit and receive a handshake communication protocol and the SDC from the programming station 16, as previously described, and to receive power from a charging station.
As best shown in
In some embodiments, an important aspect of an electronic key 120, especially when used for use in conjunction with a merchandise security device 140 as described herein, is that the key does not require a physical force to be exerted by a user on the key to operate the mechanical lock mechanism of the merchandise security device. By extension, no physical force is exerted by the key 120 on the mechanical lock mechanism. As a result, the key 120 cannot be unintentionally broken off in the lock, as often occurs with conventional mechanical key and lock mechanisms. Furthermore, neither the key 120 nor and the mechanical lock mechanism suffer from excessive wear as likewise often occurs with conventional mechanical key and lock mechanisms. In addition, in some cases there is no required orientation of the transfer probe 125 of the electronic key 120 relative to the ports on any one of the programming station, charging station, and/or the merchandise security device 140. Accordingly, any wear of the electrical contacts on the transfer probe 125 and ports may be minimized As a further advantage in some embodiments, an authorized person is not required to position the transfer probe 125 of the electronic key 120 in a particular orientation relative to the transfer port 142 of the merchandise security device 140 and thereafter exert a compressive and/or torsional force on the key to operate the mechanical lock mechanism of the device.
In another embodiment, a plurality of nodes are employed for peer-to-peer communication to facilitate the generation of an alarm signal, such as audible and/or visible signals. For example,
In some instances, a plurality of alarm nodes 30 may be used, and particular merchandise security device(s) 14 may be configured to activate specific alarm node(s). For example, in the instance where a retail store includes a plurality of display tables for a plurality of merchandise security devices 14, there may be an alarm node 30 associated with each table which would only be triggered by a “help me” signal from any one of the merchandise security devices associated with the same table. In this situation, an identifier (e.g., an ID code) could be added to the “help me” signal that corresponds to a code stored in the alarm node 30. Thus, the alarm node 30 may have to receive or identify its code in order to generate an alarm signal. This could be as simple as the code itself being the “help me” signal or some other instruction code could be added to or included with the identifier, for example, if more than one action (e.g., “alarm” or “stop alarming”) needed to be communicated to the alarm node. The merchandise security device 14 may be configured to generate this “help me” signal immediately upon a breach and only after sending the signal to the alarm node 30, would the merchandise security device then communication via the wireless communication to a hub and gateway that a breach has occurred. Thus, the latency delay should be minimized in such a breach scenario.
As discussed above, electronic keys 12, 120 and computing devices 26 may be configured to communicate and/or control various security devices 14.
Computing devices 26 may include wireless communications circuitry configured for BLE, Bluetooth, and/or NFC communication. The computing devices 26 may also or alternatively include a camera or a scanner for scanning images or information from the locks 202 as discussed in further detail below. Similarly, the locks 202 may include various wireless communications circuitry configured for BLE, Bluetooth, and/or NFC communication. The locks 202 may also or alternatively include a barcode or other identifier. In some cases, the computing devices 26 may be configured to be paired with one or more locks 202 (e.g., via Bluetooth communication) and/or include one or more additional communication protocols for operating the lock (e.g., NFC, camera, barcode, etc.).
In one example embodiment, the computing devices 26 are configured to communicate with one or more locks 202 using a first communication protocol (e.g., Bluetooth). In order to unlock a specific lock, the computing device 26 may further be configured to communicate with each lock using a second communication protocol (e.g., NFC or image scanning) The second communication protocol may be used to identify a specific lock 202 that the computing device 26 is authorized to unlock. For instance, an NFC tag may have an identifier that is unique to the lock 202 (similar to a serial number), and if the computing device 26 confirms that the identifiers match, then the computing device is authorized to unlock the lock. If the computing device 26 is authorized based on confirmation of identification of the lock 202, the computing device may then communicate an unlock command to the lock using the first communication protocol.
The locks 202 may take many different forms and configurations. The locks 202 may include various types of lock assemblies for different applications, such a plunger lock for sliding cabinet doors or a cam lock for drawers.
As noted above, the lock 202 may be configured to communicate with an electronic key 120 for unlocking the lock.
In some embodiments, the modularity of the power source (e.g., battery pack) may be dependent or independent of the operation of the lock 202. In this regard, theft of the power source may be problematic if it hinders the operation of the lock 202. In one example, the locking mechanism used to unlock the lock 202 may be dependent on a mechanism for accessing the internal power source. Thus, a user would need to use a computing device 26 or electronic key 120 to access the internal power source. The lock 202 may be required to be in an unlocked state before the internal power source may be accessed thereby requiring an authorized user to be present before being able to access the internal power source. In other embodiments, a second lock mechanism that is independent of the locking mechanism of the lock 202 may be employed for accessing the internal power source. The second lock mechanism may be configured to be operated by a computing device 26, electronic key 120, and/or other type of key. For example, a mechanical lock mechanism may be operable using a magnetic key or tool configured to unlock the lock mechanism for releasing or accessing the internal power source. In some cases, different user access levels may be used such that only certain users are authorized to unlock the second lock mechanism for accessing the internal power source (e.g., a manager may be assigned access privileges for such access but a retail associate is not). Such access levels could be used when assigning access privileges as disclosed above.
In operation,
In some embodiments, the user may be required to manually unlatch the lock 202 after using a computing device 26 or electronic key 120 to unlock the lock. Following a successful unlock command from a computing device 26,
As shown in
With respect to installation, the lock 302 may include a modular adapter 324 in some embodiments. The modular adapter 324 may allow for installation of the lock 302 in different sized holes and in different orientations. Thus, the drive shaft 306 is configured to mate with different sized and configured modular adapters 324 used to mount the lock 302 to the fixture. The modular adapter 324 may include a threaded exterior surface and/or one or more flats to facilitate installation in the fixture. As shown in
The foregoing has described one or more exemplary embodiments of various security systems. Embodiments of a security system have been shown and described herein for purposes of illustrating and enabling one of ordinary skill in the art to make, use and practice the invention. Those of ordinary skill in the art, however, will readily understand and appreciate that numerous variations and modifications of the invention may be made without departing from the spirit and scope thereof. Accordingly, all such variations and modifications are intended to be encompassed by the appended claims.
This application claims the benefit of priority to U.S. Provisional Application No. 63/194,301, filed on May 28, 2021, the entire contents of which are hereby incorporated by reference.
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