The present invention relates to electronic seals generally and more particularly to tamper-resistant electronic seals.
The following U.S. Patents are believed to be representative of the prior art:
U.S. Pat. Nos. 4,750,197; 5,056,837; 5,097,253; 5,127,687; 5,169,188; 5,189,396; 5,406,263; 5,421,177; 5,587,702; 5,656,996 and 6,069,563.
The present invention seeks to provide an improved electronic seal.
There is thus provided in accordance with a preferred embodiment of the present invention a tamper-resistant remotely monitorable electronic seal including a shaft portion, a sensor, a socket arranged to engage the shaft portion and the sensor in a monitorable manner and a wireless communicator associated with at least one of the shaft portion, the sensor and the socket and being operative to provide a remotely monitorable indication of at least one monitorable event, the sensor being operative to sense application of force to the electronic seal in an attempt to separate the shaft portion from the socket and to indicate the application of force as one of the at least one monitorable event.
Preferably, the sensor is also operative to sense disengagement of the shaft portion and the sensor and to indicate the disengagement as one of the at least one monitorable event.
In accordance with another preferred embodiment of the present invention, the tamper-resistant remotely monitorable electronic seal also includes a sensing cap mounted on the shaft portion and supporting the sensor. Additionally or alternatively, the sensor includes a temperature sensor which is operative to monitor heating of the socket and to indicate heating thereof beyond a predetermined threshold as one of the at least one monitorable event.
In accordance with another preferred embodiment of the present invention, the tamper-resistant remotely monitorable electronic seal also includes at least one retaining ring engaging the socket and the shaft portion for retaining the sensing cap in the socket independently of the shaft portion and wherein the shaft portion includes a frangible portion, whereby application of a force to separate the shaft portion from the socket causes breakage between the sensing cap and the shaft portion at the frangible portion, which breakage is one of the at least one monitorable event.
In accordance with still another preferred embodiment of the present invention, the socket includes a single-use socket. Alternatively, the socket is a mechanically lockable socket.
In accordance with another preferred embodiment of the present invention, the socket includes a transponder and the shaft portion includes an inductor, the transponder being operative to transmit information relating to the socket, via the inductor, to the wireless communicator. Preferably, the transponder includes an RF transponder and the inductor includes an RF receive/transmit inductor and wherein the inductor communicates via at least one conductor extending through the shaft portion to the wireless communicator.
In accordance with yet another preferred embodiment of the present invention, the shaft portion includes at least one conductor which is interrupted in response to disengagement of the shaft portion and the sensor and wherein the disengagement results in one of the at least one monitorable event.
Preferably, the communicator is located in a sensing circuitry and communicator housing integrally formed with the shaft portion.
In accordance with still another preferred embodiment of the present invention, there is associated with the at least one conductor at least one propinquity switch which is operated by an actuator associated with the socket whereby when the shaft portion is separated from the socket the switch is opened and the at least one conductive path is broken, producing one of the at least one monitorable event. Preferably, the at least one propinquity switch includes at least one magnetic switch and the actuator includes a magnet.
Further in accordance with another preferred embodiment of the present invention, the shaft portion includes a frangible shaft portion having a lockable portion and the socket includes a locking element arranged to engage the lockable portion in a removable manner, whereby disengagement of the locking element and the shaft portion results in one of the at least one monitorable event.
The present invention will be understood and appreciated more fully from the following detailed description, taken in conjunction with the drawings in which:
Reference is now made to
As seen in
Shaft portion 10 preferably includes weakened frangible portions 22, 24 and 25. Frangible portions 22, 24 and 25 typically have a lesser thickness than the remainder of the shaft portion 10. Frangible portion 22 is preferably located intermediate sensing circuitry and transceiver portion 12 and most of shaft portion 10. Frangible portions 24 and 25 are preferably located in shaft portion 10 at a location adjacent tip 14. Typical locations of frangible portions 22, 24 and 25 are illustrated in
At least one conductive loop 26 preferably extends from sensing circuitry and transceiver portion 12 through shaft portion 10, preferably extending into recess 17, and is configured and mounted in shaft portion 10, such that breakage of the shaft portion 10 produces a disconnection or significant change in the properties, such as the electromagnetic, mechanical and/or thermal properties, of the conductive loop 26. In accordance with a preferred embodiment of the present invention, sensing cap 16 is attached to press-fit tip 14 such that it is in contact, preferably electrical contact, with conductive loop 26. Sensing cap 16 preferably includes at least one sensor 28, such as a temperature sensor or any other suitable sensor. Sensor 28 is preferably connected to conductive loop 26, such as by crimping. Conductive loop 26 is operative to transmit information from the sensor 28 to sensing circuitry 30, forming part of sensing circuitry and transceiver portion 12.
It is appreciated that, even though in the illustrated embodiment sensor 28 is located on sensing cap 16, one or more sensors 28 may alternatively be located at any suitable location in communication with conductive loop 26.
Socket 18 also preferably comprises a sealing ring 32, which preferably engages a recess defining frangible portion 24, and a sealing ring 34, which preferably engages a recess defining frangible portion 25. Sealing rings 32 and 34 preferably provide press-fit engagement between press-fit tip 14 and socket 18.
In accordance with a preferred embodiment of the present invention, a transceiver, preferably an RF transceiver 38, also forms part of sensing circuitry and transceiver portion 12. Sensing circuitry 30 preferably is electrically coupled to conductive loop 26 and senses the integrity thereof. In another preferred embodiment, sensing circuitry 30 is also operative to receive indications from sensor 28, such as changes in temperature, which might be caused, for example, by someone attempting to tamper with the electronic seal by heating the socket 18. Alternatively, sensing circuitry 30 may be operative to receive indications of engagement or disengagement of shaft portion 10 with respect to sealing rings 32 and 34 or socket 18.
Transceiver 38 receives an output from sensing circuitry 30, which is operative to provide transmitted information indicating whether the conductive loop 26 is intact as well as other information received from sensor 28 via conductive loop 26. Conventional wireless monitoring circuitry (not shown) may be employed to receive information which is transmitted by RF transceiver 38 indicating tampering with the seal, which results in breakage of the conductive loop 26 and/or any other information received from sensor 28, such as heating of the socket 18 or engagement or disengagement of the shaft portion 10.
In accordance with another preferred embodiment, sealing ring 34 includes at least one engagement protrusion 40 and frangible portion 25 includes at least one corresponding engagement recess 42. In this embodiment, frangible portion 25 is locked by sealing ring 34, such that a low level force causes the disconnection of the sensing cap 16 and the part of tip 14 adjacent thereto from the shaft portion 10, as described hereinbelow with reference to
Reference is now made to
It is appreciated that the breaks shown in
Reference is now made to
It is appreciated that any significant change in the properties, such as the electromagnetic, mechanical and/or thermal properties, or disconnection of conductive loop 26 is sensed by sensing circuitry 30 and transmitted by RF transceiver 38.
Reference is now made to
As seen in
Shaft portion 50 preferably includes weakened frangible portions 63, 64 and 65, preferably having a lesser thickness than the remainder of the shaft portion 50. Frangible portion 63 is preferably located intermediate sensing circuitry and transceiver portion 52 and most of shaft portion 50. Frangible portions 64 and 65 are preferably located in shaft portion 50 at a location adjacent tip 54. Typical locations of frangible portions 63, 64 and 65 are illustrated in
At least one conductive loop 66 preferably extends through shaft portion 50 and is configured and mounted in shaft portion 50, such that breakage of the shaft portion 50 produces a disconnection or significant change in the properties, such as the electromagnetic, mechanical and/or thermal properties, of the conductive loop 66. Preferably connected in series with conductive loop 66 there is provided a propinquity switch which is operated when the actuator in the socket is separated therefrom by at least a threshold distance. Preferably, the propinquity switch is a magnetically operated switch 68, which is closed only when in propinquity to magnet 61, such as when shaft portion 50 is in lockable or locked engagement with lock 60.
It is appreciated that shaft portion 50 may comprise one or more additional conductive loops, each of which may include a switch, the operation of which may or may not be linked to the operation of lock 60 and may provide additional information regarding the integrity of the electronic seal.
Additionally, in accordance with a preferred embodiment of the present invention, sensing cap 62 is in electrical contact with conductive loop 66. Sensing cap 62 preferably includes at least one sensor 70, such as a temperature sensor or other suitable sensor, and communicates via conductive loop 66 with sensing circuitry 72.
It is appreciated that, even though in the illustrated embodiment sensor 70 is located adjacent lockable tip 54, one or more sensors 70 may alternatively be located at any suitable location in communication with conductive loop 66.
In accordance with a preferred embodiment of the present invention, sensing circuitry 72 and an RF transceiver 74 are housed within sensing circuitry and transceiver portion 52. Sensing circuitry 72 is electrically coupled to conductive loop 66 and senses the integrity thereof. Additionally, sensing circuitry 72 is also operative to receive indications from sensor 70, such as a change in temperature, which might be caused, for example, by someone attempting to tamper with the electronic seal by heating the lock 60. Transceiver 74 preferably receives an output from sensing circuitry 72, which is operative to provide transmitted information indicating whether the conductive loop 66 is intact as well as information received from sensor 70 via conductive loop 66.
Conventional wireless monitoring circuitry (not shown) may be employed to receive information which is transmitted by RF transceiver 74 and indicates when the shaft portion 50 is located in lockable or locked engagement with lock 60 and when the shaft portion 50 is separated from lock 60 due to either tampering with the seal, which may or may not result in breakage of the shaft portion 50, or mutual disengagement of shaft portion 50 and lock 60 by using a key to unlock lock 60.
It is appreciated that the provision of the switch 68 enables sensing circuitry 72 to sense when the shaft portion 50 is located in lockable engagement with lock 60 and when the shaft portion 50 is separated from lock 60 for any reason, and allows for recording of engagements and disengagements of shaft portion 50 and lock 60.
It is appreciated that the switch shown in the illustrated embodiments of
Reference is now made to
As seen in
Shaft portion 150 preferably includes weakened frangible portions 163, 164 and 165, preferably having a lesser thickness than the remainder of the shaft portion 150. Frangible portion 163 is preferably located intermediate sensing circuitry and transceiver portion 152 and most of shaft portion 150. Frangible portions 164 and 165 are preferably located in shaft portion 150 at a location adjacent tip 154. Typical locations of frangible portions 163, 164 and 165 are illustrated in
At least one conductive loop 166 preferably extends through shaft portion 150 and is configured and mounted in shaft portion 150, such that breakage of the shaft portion 150 produces a disconnection or significant change in the properties, such as the electromagnetic, mechanical and/or thermal properties, of the conductive loop 166. Preferably connected in series with conductive loop 166 there is provided a propinquity switch which is operated when the actuator in the socket is separated therefrom by at least a threshold distance. Preferably, the propinquity switch is a magnetically operated switch 168, which is closed only when in propinquity to magnet 161, such as when shaft portion 150 is in lockable or locked engagement with lock 160.
It is appreciated that shaft portion 150 may comprise one or more additional conductive loops, each of which may include a switch, the operation of which may or may not be linked to the operation of lock 160 and may provide additional information regarding the integrity of the electronic seal.
Additionally, in accordance with a preferred embodiment of the present invention, sensing cap 162 is in electrical contact with conductive loop 166. Sensing cap 162 preferably includes at least one sensor 170, such as a temperature sensor or other suitable sensor, and communicates via conductive loop 166 with sensing circuitry 172.
It is appreciated that, even though in the illustrated embodiment sensor 170 is located adjacent lockable tip 154, one or more sensors 170 may alternatively be located at any suitable location in communication with conductive loop 166.
In accordance with a preferred embodiment of the present invention, sensing circuitry 172 and an RF transceiver 174 are housed within sensing circuitry and transceiver portion 152. Sensing circuitry 172 is electrically coupled to conductive loop 166 and senses the integrity thereof. In another preferred embodiment, sensing circuitry 172 is also operative to receive indications from sensor 170, such as a change in temperature, which might be caused, for example, by someone attempting to tamper with the electronic seal by heating the lock 160. Transceiver 174 preferably receives an output from sensing circuitry 172, which is operative to provide transmitted information indicating whether the conductive loop 166 is intact as well as information received from sensor 170 via conductive loop 166.
Conventional wireless monitoring circuitry (not shown) may be employed to receive information which is transmitted by RF transceiver 174 and indicates when the shaft portion 150 is located in lockable or locked engagement with lock 160 and when the shaft portion 150 is separated from lock 160 due to either tampering with the seal, which may or may not result in breakage of the shaft portion 150, or mutual disengagement of shaft portion 150 and lock 160 by using a key to unlock lock 160.
As seen in
It is appreciated that the provision of the transponder 180 and the inductor 182 enables sensing circuitry 172 to record information transmitted by transponder 180 relating to the lock 160, such as, for example, a serial number of the lock 160, and the fact that shaft portion 150 is in locking engagement therewith. It is further appreciated that the provision of the transponder 180 and the inductor 182 enables sensing circuitry 172 to sense when the shaft portion 150 is located in lockable or locked engagement with lock 160 or when the shaft portion 150 is separated from lock 160 for any reason, and allows for recording of engagements and disengagements of shaft portion 150 and lock 160.
Additionally, it is appreciated that the provision of the switch 168 enables sensing circuitry 172 to sense when the shaft portion 150 is located in lockable engagement with lock 160 and when the shaft portion 150 is separated from lock 160 for any reason, and allows for recording of engagements and disengagements of shaft portion 150 and lock 160.
Reference is now made to
As seen in
Shaft portion 250 preferably includes a weakened frangible portion 263, located intermediate the sensing circuitry and transceiver portion 252 and the tip 254. Frangible portion 263 typically has a lesser thickness than the remainder of the shaft portion 250. Additional frangible portions (not shown) may also be included at suitable locations along shaft portion 250.
At least one conductive loop 266 preferably extends from sensing circuitry and transceiver portion 252 through shaft portion 250 and tip 254 and is configured and mounted in shaft portion 250, such that breakage of the shaft portion 250 produces a disconnection or significant change in the properties, such as the electromagnetic, mechanical and/or thermal properties, of the conductive loop 266. In accordance with a preferred embodiment of the present invention, sensing cap 256 is attached to tip 254 such that it is in electrical contact with conductive loop 266. Sensing cap 256 preferably includes at least one sensor 270, such as a temperature sensor or any other suitable sensor. Sensor 270 is preferably electrically connected to conductive loop 266 and is operative to transmit information via conductive loop 266 to sensing circuitry 272.
It is appreciated that, even though in the illustrated embodiment sensor 270 is located adjacent sensing cap 256, one or more sensors 270 may alternatively be located at any suitable location in communication with conductive loop 266.
In accordance with a preferred embodiment of the present invention, sensing circuitry 272 and a transceiver, such as an RF transceiver 274, are housed within sensing circuitry and transceiver portion 252. Sensing circuitry 272 preferably is electrically coupled to conductive loop 266 and senses the integrity thereof. Additionally, sensing circuitry 272 is preferably also operative to receive indications from sensor 270, such as changes in temperature, which might be caused, for example, by someone attempting to tamper with the electronic seal by heating the single-use locking socket 258. Alternatively, sensing circuitry 272 may be operative to receive indications of engagement or disengagement of shaft portion 250 from single-use locking socket 258, as described hereinbelow.
Transceiver 274 receives an output from sensing circuitry 272, which is operative to provide information indicating whether the conductive loop 266 is intact as well as information received from sensor 270 via conductive loop 266. Conventional wireless monitoring circuitry (not shown) may be employed to receive information which is transmitted by RF transceiver 274 indicating tampering with the seal, which results in breakage of the conductive loop 266 and/or any other information received from sensor 270, such as heating or removal of the single-use locking socket 258.
As seen in
It is appreciated that the switch shown in the illustrated embodiments of
It will be appreciated by persons skilled in the art that the present invention is not limited by what has been particularly shown and described hereinabove. Rather the scope of the present invention includes both combinations and subcombinations of the various features described hereinabove as well as variations and modifications which would occur to persons skilled in the art upon reading the specification and which are not in the prior art.
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Number | Date | Country | |
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20040113782 A1 | Jun 2004 | US |