The present invention relates to security management systems, and more particularly to security management systems for wireless asset monitoring.
Construction sites and other industrial job site locations are typically unsecured areas. Loss and theft of tools and other construction equipment is a common occurrence at such sites. For example, a job site may remain exposed to the threat of theft and/or vandalism at night. The tools and/or equipment at an industrial job site typically include very expensive power tools and construction materials. Theft of such items amounts to considerable losses and expenses. While contractors may utilize security guards or guard dogs to ensure the security of tools and other equipment at night, this is very expensive. Additionally, theft and/or vandalism may still occur during the day.
Contractors commonly utilize portable containers to house large numbers of tools and other construction equipment. For example, a contractor may utilize one or more metallic gang boxes. While the tools and/or equipment are not being used, a contractor may attempt to prevent unauthorized access to the insides of the containers. For example, the contractor may utilize devices such as locks, chains, and/or straps to secure the containers. However, such containers may remain open for a long time while the tools and equipment are being used. Therefore, such devices do not guarantee the security of the tools and equipment at all times of the day. Additionally, it is difficult to keep track of and maintain an inventory of tools and equipment on a job site.
In one approach, a contractor employs a rigorous check-in/check-out process with all of the tools and equipment on a job site. However, this requires additional time, personnel, and expenses. Alternatively, a contractor may take an inventory of tools and equipment at the end of a day. Depending on the number of tools and equipment at the job site, this can be very time consuming and expensive. Additionally, a contractor may not notice that tools or equipment are damaged and/or missing until the end of the day.
An asset monitoring and security system according to the present invention includes at least one asset assigned a unique identifier and operable to transmit an identification signal embodying the identifier over a wireless communications link. A data store maintains a list of the assets and privileges associated with the assets for authorized users of the assets. A control unit is adapted to receive identification signals from the assets and monitor positions of the assets within a defined area based on the identification signals. The control unit communicates with the data store and is further operable to initiate an alarm event when privileges associated with a given asset for authorized users of the asset are exceeded.
In other features, the data store maintains a list of users authorized to use the assets and privileges associated with the assets for each of the authorized users. The control unit is operable to initiate an alarm event when privileges associated with a given authorized user for a given asset are exceeded. A data input device is adapted to receive a personal identifier input by a user that uniquely identifies the user and a list of desired assets input by the user that the user desires to possess during an asset check-out process. The data input device is operable to transmit the personal identifier and the list of desired assets to the data store. The control unit associates a given asset with the user based on the personal identifier and the list of desired assets. A privilege associated with a given asset for authorized users of the asset limits authorized users to possession of the asset within the defined area. The control unit initiates the alarm event when the asset is located outside of the defined area.
In still other features of the invention, a privilege associated with an asset for a given authorized user limits the authorized user to possession of the asset within the defined area. The control unit initiates the alarm event when the given authorized user possesses the asset outside of the defined area. The control unit generates a departure time for an asset when the asset moves from within the defined area to outside of the defined area. The control unit stores the departure time in the data store. The control unit generates a return time for an asset when the asset moves from outside of the defined area to within the defined area. The control unit stores the return time in the data store. At least one user identification device is assigned a unique identifier and operable to transmit an identification signal embodying the identifier to the control unit over a wireless communications link.
In yet other features, the control unit is adapted to receive identification signals from the user identification devices and monitor positions of the user identification devices within the defined area based on the identification signals from the user identification devices. The control unit associates an asset with a user when the control unit detects a user identification device of the user within a predetermined distance of the asset. The user identification device includes an alarm indicator. The control unit activates the alarm indicator when a distance between the user identification device and the asset associated with the user identification device is greater than a second predetermined distance.
In still other features of the invention, the control unit activates at least one of an audible indicator and/or a visible indicator at least one of during and/or after the alarm event. The control unit includes a wireless transmitter operable to transmit an alarm message to a remote monitoring system at least one of during and/or after the alarm event. A camera communicates with the control unit and captures an image of an asset at an exit point of the defined area when the asset one of moves from within the defined area to outside of the defined area or moves from outside of the defined area to within the defined area. A camera communicates with the control unit and captures an image of a user at least one of during and/or after the asset check-out process.
In yet other features, each of the assets includes a lock-out mechanism that impedes use of the asset when the lock-out mechanism is activated. The control unit activates the lock-out mechanism of a given asset when the privileges associated with the asset for authorized users of the asset are exceeded. A privilege associated with a given asset for authorized users of the asset limits authorized users to possession of the asset within the defined area. The control unit activates the lock-out mechanism of the asset when the asset is located outside of the defined area.
In still other features of the invention, each of the assets includes a lock-out mechanism that impedes use of the asset when the lock-out mechanism is activated. The control unit deactivates the lock-out mechanism of a given asset when a user identification device of an authorized user of the asset is within a predetermined distance of the asset and activates the lock-out mechanism when a user identification device of an authorized user is not within the predetermined distance of the asset. The lock-out mechanism of a given asset is one activated or deactivated when the asset is associated with an authorized user of the asset and the asset is within a predetermined distance of an asset activation device. The lock-out mechanism of a given asset is one of activated or deactivated when a user identification device of an authorized user of the device is within a first predetermined distance of the asset and the asset is within a second predetermined distance of the asset activation device. The control unit verifies the presence of all of the assets within the defined area and initiates the alarm event when one of the assets is outside of the defined area.
In yet other features, the control unit is enclosed within a housing that is configured to be mounted on a surface of a container that houses the assets. The housing includes primary and backup power supplies that power the control unit. The backup power supply powers the control unit when the primary power supply fails. A tamper prevention mechanism fastens the backup power supply to the housing. The control unit initiates the alarm event when the backup power supply is removed from the housing while the tamper prevention mechanism is enabled. The primary power supply is one of a solar power panel or a fuel cell module and the backup power supply is a rechargeable battery. The primary power supply powers the control unit and maintains a charge voltage of the backup power supply. The primary and backup power supplies are rechargeable batteries. The primary power supply fails when the primary power supply discharges below a predetermined voltage.
In still other features of the invention, the control unit is enclosed within a housing that is configured to be utilized as hand-held device. The housing includes a vibrating indicator. The control unit activates the vibrating indicator at least one of during and/or after the alarm event. The assets are power tools and the defined area is an industrial job site location. A display module displays at least one of an illustration of a given asset and/or a personal identifier that uniquely identifies the asset when privileges associated with the asset for authorized users of the asset are exceeded.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses. As used herein, the term module and/or device refers to an application specific integrated circuit (ASIC), an electronic circuit, a processor (shared, dedicated, or group) and memory that execute one or more software or firmware programs, a combinational logic circuit, and/or other suitable components that provide the described functionality. An exemplary embodiment of the present invention is outlined below with respect to wireless monitoring of tools and construction equipment at an industrial job site. However, analogous operation of the present invention is contemplated with respect to monitoring of other objects and/or devices with appreciable value or importance. For example, the methods of the present invention may be utilized to monitor valuable items such as jewelry.
Referring now to
The master control device 12 detects positions of the assets 14 based on the unique identifiers. For example, the master control device 12 may estimate a distance to an asset based on the strength of the identification signal that is transmitted by the asset 14. The master control device 12 is capable of detecting when the assets 14 move outside of a defined area 17. In an exemplary embodiment, the defined area 17 is less than a maximum range of communications, indicated by 18, between the master control device 12 and the assets 14. This ensures that the master control device 12 has a sufficient opportunity to detect an asset 14 outside of the defined area 17 before the asset 14 is out of the range of communications for the master control device 12. For example, in
The master control device 12 includes a data storage device and maintains a database in the data storage device. The database includes listings of users that are authorized to possess and/or use the assets 14. Additionally, the database may include privileges associated with the assets 14 for each of the users. For example, a first user may have permission to use a first asset 14 within the defined area 17. However, the first user may not have permission to remove the asset 14 from the defined area. In the event that a user exceeds assigned privileges, the master control device 12 may initiate an alarm event. The alarm event may include activating an alarm indicator such as a siren or a light. The alarm event may also include transmitting an alarm message to a remote monitoring station. Additionally, in the case where the assets 14 are power tools, the alarm event may include locking the functional circuitry of one or more of the assets 14. Still other actions in response to a security breach are contemplated.
The master control device 12 may associate an asset 14 with a particular user in a number of ways. The master control device 12 may communicate with a control panel that allows users to check-out desired assets by entering a username and password. After the user checks out the asset 14, the master control device 12 monitors use of the asset 14 with respect to applicable predefined privileges granted to the user in relation to the asset 14. For example, two different users may have different privileges with respect to the same asset 14. Alternatively, the master control device 12 may associate an asset 14 with a user by detecting the user within a predetermined distance of the asset 14.
As shown in
The master control device 12 estimates positions of the user identification devices 16 based on the identification signals transmitted by the user identification devices 16. The master control device 12 may associate a user with an asset 14 by detecting a user identification device 16 of the user within a predetermined distance of the asset 14. For example, the master control device 12 may detect the user identification device 16 of the user within three feet of the asset 14 to associate the user with the asset 14. As shown in
Referring now to
While both users may be entitled to possess and use the asset 14 within the defined area 17, privilege “A” may entitle only the first user to remove the asset 14 from the defined area 17. In this case, the master control device 12 may initiate an alarm event if the second user attempts to remove the asset 14 from the defined area 17. The user identification database 19 also includes estimated distances to respective user identification devices 16. As with the assets 14, the master control device 12 may determine distances to user identification devices 16 based on the strength of identification signals received from the user identification devices 16.
Referring now to
The master control device 12 communicates with an alarm module 20. The alarm module 20 diagrammatically represents any of a number of alarms that the master control device 12 may activate when the master control device 12 initiates the alarm event. The alarm module 20 illustrated in
The master control device 12 also communicates with a remote monitoring system 22. The master control device 12 may transmit an alarm message to the remote monitoring system 22 to indicate that a security breach has been detected. An operator of the remote monitoring system 22 may take corrective action in response to the alarm message or may contact appropriate law enforcement authorities or site supervisors. The remote monitoring station may also automatically contact a supervisor at a local or remote location via telephone, pager, e-mail, text messaging, and/or other forms of communication.
The master control device 12 and a remote user device 26 communicate with a distributed communications system 28 such as the Internet. This allows the master control device 12 to transmit/receive data to/from the remote user device 26. For example, the remote user device 26 may be a mobile phone, a personal digital assistance (PDA), a personal computer, or another device. In an exemplary embodiment, the remote user device 26 controls the master control device 12 via an asset monitoring system with web-enabled functionality. The web site may graphically display a job site inventory as well as the current status and location of users and assets 14.
Referring now to
Those skilled in the art can appreciate that the transceiver 40 may wirelessly communicate with devices by other means including cellular and satellite communications systems. Additionally, while a single transceiver 40 is illustrated in
In an exemplary embodiment, the master control device 12 is enclosed within a housing. The housing may be configured to be mounted on a surface of a container. For example, the housing may be mounted on a surface of a storage container to monitor assets 14 that are stored in the container. Alternatively, the housing may be configured to be utilized as a hand-held device. In this case, the control module 38 may detect the positions of assets 14 and user identification devices 16 relative to the position of the control module 38 or relative to the defined area 17. In the event that the housing is used as a hand-held device, the master control device 12 may include an internal alarm module 42 that is different than the alarm module 20 in
The master control device 12 includes a primary power supply 45 and a backup power supply 46. For example, the primary power supply 45 may be AC mains from a utility provider or a generator. Alternatively, the primary power supply 45 may be a portable power source such as a battery module, a solar power module, or a fuel cell module. The backup power supply 46 supplies power to the control module 38 when the primary power supply 45 fails or is depleted beyond a predetermined capacity. For example, the backup power supply 46 may also be a battery module or another power source. The backup power supply 46 communicates with a tampering prevention mechanism 48. The tampering prevention mechanism 48 prevents unauthorized tampering with the backup power supply 46. For example, the control module 38 may initiate an alarm event when the backup power supply 46 is removed from the master control device 12 and while the tampering prevention mechanism 48 is enabled.
The control module 38 communicates with a display module 50 and one or more input devices 52. For example, the display module 50 may be part of a control panel when the housing is mounted on a surface of a storage container. In an exemplary embodiment, the display module 50 displays an identifying picture and identifiable name of an asset 14 during an alarm event associated with the asset to aid in identifying and locating the asset. In the event that the housing is configured as a hand-held device, the display module 50 may include a liquid crystal display (LCD) screen. The input devices 52 may include a touch screen, a mouse, a keyboard, or another input device when the housing is mounted on the surface of a storage container. In the event that the housing is configured as a hand-held device, the input devices 52 may include actuator buttons, a touch screen, or other input devices.
As discussed above, users may manipulate the input devices 52 during an asset 14 check-out process to become associated with a particular asset 14. For example, a user may be required to select a desired asset(s) 14 followed by input of a username and password. Since the control module 38 includes a list of authorized users and associated privileges for the assets 14, the master control device 12 immediately detects when a user attempts to check-out an asset 14 that the user is not authorized to posses and/or use. Therefore, depending on the privileges afforded to a user for a particular asset 14, the master control device 12 may initiate an alarm event whenever the user exceeds the privileges for a given asset 14.
As discussed above, the master control device 12 may determine approximate distances to assets 14 or user identification devices 16 based on the signal strength of an identification signal. Additionally, the master control device 12 may determine relative directions of the assets 14 and user identification devices 16 in a number of ways. The master control device 12 may utilize multiple antennas that are positioned in an antenna array to cover assigned portions of the defined area 17 and/or to utilize triangulation location methods. A single directional antenna may also be used. In this case, the antenna may need to be pointed in the general direction of the target to obtain a reading. Additionally, a more accurate positioning system such as a global positioning system (GPS) may be utilized to locate the assets 14 and user identification devices 16. Other methods for determining distances between devices that establish wireless communications are well-known in the art.
Referring now to
In an exemplary embodiment, the asset 14 is a tool for use on an industrial job site location. The exemplary asset includes a lock-out mechanism 68. When activated, the lock-out mechanism 68 impedes use of the tool. For example, in the case of a power tool, the lock-out mechanism 68 may be a circuit that disables functional circuitry 70 of the power tool by interrupting current between a power supply 72 and the functional circuitry 70 of the power tool. It may be beneficial to ensure that an authorized user of a power tool is always within a predetermined distance of the power tool while in operation. Therefore, the master control device 12 may activate the lock-out mechanism 68 of the power tool when the authorized user of the power tool is not within a predetermined distance of the power tool. In the case of a non-power tool, the lock-out mechanism 68 may interrupt at least a portion of the mechanical motion or another feature of the tool.
In the case of the power tool and as shown in
Alternatively, the lock-out mechanism 68 may be implemented to interface with an analog speed control circuit. In this case, the control module communicates with a circuit component in the analog speed control circuit to disable the motor. For example, the control module 60 may transmit a lock-out request signal to an interface circuit that communicates with a power semiconductor in the analog speed control circuit. The signal from the interface circuit may prevent on/off gating of the power semiconductor or the interface circuit may be configured to gate the power semiconductor off. For example, the power semiconductor may be implemented as a silicon-controller rectifier (SCR), a field-effect transistor (FET), and/or a triac.
In the case where an electronic asset 14 sign-out process is not implemented, the master control device 12 automatically detects a user that currently has possession of a given asset 14. In this case, the master control device 12 detects a user identification device 16 within a predetermined distance of an asset 14 to associate the asset 14 with a user to whom the user identification device 16 is assigned.
Referring now to
The control module 82 may then activate an alarm indicator associated with the alarm module 87 to alert the user. For example, the alarm module 78 may activate a visible indicator such as an LED, an audible indicator such as a siren, or another alarm indicator on the user identification device 16. In the case of an LED, the user may wear the user identification device 16 so that the LED is clearly visible to the user. For example, the user may wear the user identification device 16 on a wrist. The control module 82 may also activate an alarm indicator associated with the alarm module 87 when other privileges are exceeded by the user. For example, the control module 82 may activate an alarm indicator when the user moves outside of the defined area 17 with an asset 14 when the user is not authorized to remove the asset 14 from the defined area 17.
In an exemplary embodiment, a user manually specifies the predetermined distance an asset 14 may be located from the user before the control module 82 activates an alarm indicator. For example, the user may adjust the predetermined distance with a dial or switch on the user identification device 16. Other than the alarm module 87, the components of the user identification device 16 shown in
Referring now to
In an exemplary embodiment, the master control device 12 determines whether assets 14 are within the defined area 17 by cycling through known assets 14 in a predetermined order. Alternatively, the master control device 12 may cycle through the assets 14 in an order determined by priority. As shown in
An asset 14 is set as absent when the master control device 12 has determined that the asset 14 is outside of the defined area 17. If false, control returns to step 116. If true, the master control device 12 sets the asset 14 as present and records the current date and time in step 124. The master control device 12 first sets an asset 14 as present when the asset 14 is returned to the defined area 17 from outside of the defined area 17. Control proceeds from step 124 to step 116. For example, the current date and time may be stored by the master control device 12 in the database stored in the data storage device.
In step 120, control determines whether the asset 14 is set as absent. If false, the master control device 12 records the user to whom the asset 14 is currently checked-out to or assigned in step 126. For example, the master control device 12 may determine that a particular user is assigned to an asset 14 when the user identification device 16 of the user is within a predefined distance of the asset 14. For example, a minimum distance of three feet may be required between the asset 14 and user identification device 16 before the master control device 12 assigns the asset 14 to the user. Alternatively, the master control device 12 may already have the name of the user to whom the asset 14 is assigned stored in a database from an electronic sign-out process. The master control device 12 also sets the asset 14 as absent in step 126 and records the current date and time.
Control proceeds from step 126 to step 128. Additionally, if the asset 14 is already set as absent in step 120, control bypasses step 126 and proceeds to step 128. In step 128, control determines whether the user to whom the asset 14 is assigned has exceeded any allowed privileges. If true, control returns to step 116. If false, the master control device 12 initiates an alarm event in step 130 and control returns to step 116.
Referring now to
The master control device 12 may utilize multiple defined areas to monitor tools 132 in different locations. For example, a first defined area 138 may be approximately equal to the size of a storage container 140, and a second defined area 17 may be approximately equal to the size of a job site location. Two or more monitoring areas may be close in size so that the master control device 12 is capable of providing a warning when a tool 132 is approaching the boundary of a larger monitoring area. Additionally, the master control device 12 may utilize monitoring areas of different sizes for different tools 132.
The master control device 12 is capable of performing an inventory check on all local tools 132 at a time when the tools 132 are intended to be stored in the container 140. For example, the master control device 12 may be mounted on a surface of the container 140. In this case, a control panel or hand-held device may be utilized to communicate with the master control device 12. In an exemplary embodiment and in the case of power tools 132, the master control device 12 communicates with a tool activation device 141. The tool activation device 141 may also be mounted on a surface of the container 140. Alternatively, the tool activation device 141 may be a stand-alone device or may be integrated into a single device with the master control device 12.
The tool activation device 141 is capable of activating and/or deactivating lock-out mechanisms 68 in power tools 132. In the case where an electronic sign-out process for power tools 132 is utilized, the tool activation device 141 activates/deactivates the lock-out mechanisms 68 of power tools 132 when the power tools 132 are checked-out by authorized users. A user may bring a tool 132 within a predetermined distance of the tool activation device 141 to activate/deactivate the lock-out mechanism 68 of the power tool 132. For example, a minimum distance of six inches may be required. The lock-out mechanism 68 may include an internal magnetic switch that is triggered by the tool activation device 141 or another mechanism.
In another exemplary embodiment, the master control device 12 detects whether an authorized user is within a predetermined distance of the power tool 132 before the tool activation device 141 activates/deactivates the lock-out mechanism 68 of the power tool 132. In this case, an electronic sign-out process for power tools 132 may not be required. In another exemplary embodiment, the tool activation device 141 is not required. In this case, the master control device 12 periodically detects the presence of an authorized user of the power tool 132 within a predetermined distance of the power tool 132. The lock-out mechanism 68 remains deactivated while an authorized user of the power tool 132 is within the predetermined distance of the power tool 132. The master control device 12 activates the lock-out mechanism 68 when an authorized user is not within the predetermined distance of the power tool 132.
The master control device 12 communicates with a camera module 142. The camera module 142 may be mounted on a surface of the container 140 or may be a stand-alone device. The camera module 142 includes one or more digital cameras that are positioned to capture a digital image of a user when the user removes a tool 132 from the predefined monitoring area 138. For example, one or more cameras may be directed towards the opening of a storage container 140 or a trailer that houses a plurality of tools 132. The master control device 12 monitors a position of a tool 132, and the camera module 142 captures a digital image of a user of the tool 132 when the user moves the tool 132 beyond the predefined monitoring area 138. Additionally, when the electronic sign-out process is implemented, the camera module 142 may capture a digital image of a user as the user checks out one or more assets 14. For example, capturing a digital image of the user may be a required step in the electronic check-out process.
Referring now to
The asset status database 144 includes an activation status for each asset 14. The activation status indicates whether the lock-out mechanisms 68 of individual power tools 132 are activated or deactivated. An availability status indicates whether the asset 14 is checked out under the electronic sign-out process described above or currently assigned to a user. For example, the master control device 12 may initiate an alarm event when an asset 14 is not checked out and greater than a predetermined distance from the master control device 12. A distance status indicates estimated distances to respective assets 14.
A status field indicates whether the master control device 12 has initiated an alarm event with respect to an individual asset 14. For example, the master control device 12 may initiate an alarm event relating to an individual power tool when the power tool is out-of-range and the lock-out mechanism 68 of the power tool has not been deactivated. A return time field indicates the last date and time that an asset 14 was returned to the defined area 17 from outside of the defined area 17. An operating time field indicates the current consecutive amount of time that the functional circuitry 70 of an asset 14 has been running. For example, due to operating tolerances of specific assets 14, it may be beneficial to limit the operating time of functional circuitry 70 for particular assets 14. A departure time field indicates the last date and time that an asset 14 was either electronically checked-out or removed from the defined area 17.
A due date field indicates a date and time by which an asset 14 must either be electronically checked-in or returned within the defined area 17 before the master control device 12 initiates an alarm event with respect to the asset 14. For example, an authorized user may have permission to remove one or more assets 14 from the defined area 17 for a limited amount of time. Those skilled in the art can appreciate that the master control device 12 may utilize any or all of the database fields illustrated in
Referring now to
In an exemplary embodiment, the camera module 142 captures an image of a user of a tool 132 when the user removes the tool 132 from the defined area 17 and also moves the tool 132 back within the predefined monitoring area 138. In this case, the master control device 12 also records the current date and time to store in the database. The master control device 12 may transmit the image captured by the camera module 142 to the remote monitoring station 22 and/or the remote user device 26 to inform a supervisor when a tool 132 is removed from and/or returned to the container 140. As shown in
In step 152, control determines whether the tool 132 is within the predefined monitoring area 138. If true, control proceeds to step 154. If false, control determines whether the tool 132 is set as absent in step 156. If true, control returns to step 150. If false, the master control device 12 sets the tool 132 as absent in step 158. Additionally, the master control device 12 instructs the camera module 142 to capture a digital image in step 158 and control returns to step 150. In step 154, the master control device 12 determines whether the tool 132 is set as absent. If false, control returns to step 150. If true, the master control device 12 sets the asset 14 as present in step 160. Additionally, the master control device 12 instructs the camera module 142 to capture a digital image in step 160 and control returns to step 150.
Referring now to
If false, the tool activation device 141 activates the lock-out mechanism 68 of the tool 132 in step 176. Additionally, the master control device 12 records the current date and time to store in the database of the data storage device in step 176 and control proceeds to step 177. In step 177, the master control device 12 delays for a predetermined period of time before returning control to step 170. The master control device 12 initiates the delay period in step 177 to prevent a lock-out mechanism 68 of a tool 132 from continuously being activated and then deactivated while the tool 132 is in communications with the tool activation device 141.
In step 174, the master control device 12 detects a user within a predetermined distance of the tool 132. Alternatively, control may bypass step 174 when an electronic sign-out process is utilized. In this case, the master control device 12 already knows to which user a tool 132 is assigned. In step 178, control determines whether the user is authorized to possess and/or use the tool 132. If false, control proceeds to step 180. If true, the tool activation device 141 deactivates the lock-out mechanism 68 of the tool 132 in step 182. Additionally, the master control device 12 records the user of the tool 132 and the current date and time to store in the database in step 182 and control proceeds to step 177. In step 180, the master control device 12 initiates an alarm event associated with the tool 132 and control returns to step 170.
As shown in
Referring now to
As long as a user that has privileges to operate the tool 132 is within the predetermined radius, the lock-out mechanism 68 of the tool 132 remains deactivated. As an added security measure, the master control device 12 may automatically deactivate the lock-out mechanism 68 of a tool 132 when the tool moves outside of the defined area 17. This prevents an unauthorized user from obtaining a tool 132 with a deactivated lock-out mechanism 68 while the tool 132 is outside of the defined area 17. As shown in
In step 194, the master control device 12 detects a user identification device 16 that is within a predetermined distance of the tool 132. In step 196, control determines whether the user to whom the user identification device 16 is assigned is authorized to use and/or possess the tool 132. If false, control proceeds to step 198. If true, control determines whether the lock-out mechanism 68 of the tool 132 is activated in step 200. If false, control returns to step 192. If true, the master control device 12 deactivates the lock-out mechanism 68 of the tool 132 in step 202 and control returns to step 192.
In step 198, control determines whether the lock-out mechanism 68 of the tool 132 is activated. If true, control returns to step 192. If false, the master control device 12 activates the lock-out mechanism 68 of the tool 132 in step 204 and control returns to step 192. Therefore, the master control device 12 periodically determines the presence of authorized users 16 within a predetermined distance of tools 132. The master control device 12 enables the functional circuitry 70 of the tools 132 when an authorized user is present and disables the functional circuitry 70 of the tools 132 when an authorized user is not present.
Referring now to
Due to the portable nature of the container 140 and the housing 234, the primary power supply 45 may not always be an AC mains provided by a utility provider or a generator. In an exemplary embodiment, both the primary power supply 45 and the backup power supply 46 are rechargeable battery devices. In this case, the master control device 12 communicates with an auxiliary power source 235. The auxiliary power source 235 provides power to the primary power supply 45 and the backup power supply 46 in order to prevent a discharge condition in the primary power supply 45 and the backup power supply 46. The auxiliary power source 235 allows the primary power supply 45 and the backup power supply 46 to be charged when no AC mains is available. For example, the auxiliary power source 235 may be a solar power panel that generates current based on energy from the sun.
Voltage conversion circuitry located in either the housing 234 or the auxiliary power source 235 regulates the voltage output by the auxiliary power source 235 to a level suitable for the primary power supply 45 and the backup power supply 46. Alternatively, the auxiliary power source 235 may be a fuel cell that generates current from hydrogen. For example, a fuel cell may convert hydrogen and oxygen into electricity and water. However, a reliable and/or affordable source of hydrogen may not be available. In this case, an alternative fuel such as methanol may be utilized.
In an alternative exemplary embodiment, the auxiliary power source 235 functions solely as the primary power supply 45 with a rechargeable battery device as the backup power supply 46. In this case, the auxiliary power source 235 may power the master control device 12 while maintaining the backup power supply 46 at a float voltage. In this case, the master control device 12 may initiate an alarm event when the auxiliary power source 235 fails. This allows a user to repair or replace the auxiliary power source 235 or disconnect the backup power supply 46 before the backup power supply 46 enters a deep discharge condition.
Additionally, an authorized user may consult with the remote monitoring system 22 to determine the availability of specialized assets 14 such as tools 132 at other job site locations. For example, a contractor that operates at multiple job site locations may maintain a limited supply of a specific power tool 132. If the tool 132 is not being used while residing at a first job site location, an authorized user at a second job site location may request use and/or delivery of the power tool 132.
Referring now to
The hand-held device 242 preferably executes an asset monitoring software program. In an exemplary embodiment, the hand-held device 242 is manufactured and/or sold with a plurality of associated RFID tags. The RFID tags may be fastened to or embedded in assets 14 such as power tools and construction materials. Additionally, peel-and-stick RFID tags may be used to monitor non-power tools. An exemplary main menu 254 for the asset monitoring program is shown in
A user selects the protection option 256 to monitor the status of assets 14 that are currently associated with the hand-held device 242. A user selects the detection option 258 to pin-point the exact location of an asset 14. For example, the strength of a signal that is received from an asset 14 may be displayed on the LCD screen 246 to assist in finding the exact location of the asset 14. A user selects the settings option 260 to adjust settings and preferences associated with operation of the asset monitoring software. A user of the device manipulates the directional buttons 250 and an interactive button 252 to select a desired option.
Referring now to
Referring now to
Referring now to
Referring now to
In an exemplary embodiment, the hand-held device 242 communicates with and is used in combination with the master control device 12. For example, the master control device 12 may monitor the positions of assets 14 relative to a central location. Once an asset 14 is identified as being located outside of the predetermined monitoring area 138, the hand-held device 242 may be used as a portable instrument to locate the asset 14. For example, the hand-held device 242 may also independently communicate with the assets 14 and determine positions of the assets 14 relative to the hand-held device 242.
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.
This application is a divisional of U.S. patent application Ser. No. 10/997,164 filed on Nov. 24, 2004 and claims the benefit of U.S. Provisional Application Nos. 60/524,811, 60/524,822, and 60/524,829, all filed on Nov. 24, 2003, and U.S. Provisional Application No. 60/626,758 “WIRELESS ASSET MONITORING AND SECURITY SYSTEM”, filed on Nov. 11, 2004. The disclosures of the above references are all hereby incorporated by reference in their entireties.
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Number | Date | Country | |
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Parent | 10997164 | Nov 2004 | US |
Child | 11899567 | US |