The field of the present invention relates to security devices used to protect merchandise or other objects and, more particularly, to security devices having one or more adjustable cables used to wrap around the objects such that the security devices are secured to the objects.
Electronic article surveillance (EAS) systems are often used to deter and detect shoplifting. Typically, an EAS security system includes an EAS tag, a transmitter, a receiver, and an alarm. The EAS tag is attached to a piece of merchandise. The transmitter and the receiver are positioned at the exit of a retail establishment and configured to establish a detection zone in which a consumer must pass through as he or she exits the retail establishment. The transmitter is configured to send signals through the detection zone. When an EAS tag enters the detection zone, the EAS tag responds and creates a signal or a change or disturbance in the original signal transmitted by the transmitter, which is detectable by the receiver. Upon detection of the EAS tag, the alarm is triggered in order to notify the store personnel that someone is trying to exit the retail establishment with merchandise that has an attached and active EAS tag.
In an EAS system, it is the actual EAS tag that is being detected and not the merchandise itself. Therefore, an EAS system can be circumvented by removing the EAS tag from the merchandise. To prevent the unauthorized removal of the EAS tag, security devices have been developed. A typical security device is configured to house the EAS tag and attach the EAS tag to the merchandise in a manner that limits the likelihood that a consumer or a would-be thief could tamper with or otherwise remove the EAS tag from the merchandise.
As an example, one particular type of security device is a cable wrap security device such as the one disclosed in U.S. Pat. No. 7,497,101, which is incorporated herein by reference in its entirety. Typically, a cable wrap security device includes a first housing for a ratchet mechanism, a second housing for an EAS tag, and a cable that is routed through both the first and second housings and configured to wrap around the package of the merchandise. The ratchet mechanism is configured to tighten the cable around the package such that the security device is not removable from the package without being loosened. The security device further includes a locking mechanism that prevents loosening or release of the cable without a specifically configured key or other specialized equipment that is controlled by the employees of the retail establishment. In some applications, the cable of the cable wrap security device also prevents a consumer or would-be thief from opening or otherwise tampering with the package to get to the merchandise within the package.
While this type of security device has proven effective at protecting merchandise, it has been found that additional security features are desirable in order to further improve the effectiveness of such security devices.
Embodiments of the present invention are directed to a security device which is securable to an object, such as merchandise. The security device includes features which prevent unauthorized removal of the security device from the object and/or tampering with the security device.
In a first separate aspect of the present invention, a security device includes: a housing having a plug receptacle; a spool rotatably coupled to the housing and rotatable in both a first direction and a second direction with respect to the housing; a locking mechanism alterable between a locked state and an unlocked state, wherein the locking mechanism in the locked state prevents the spool from rotating in the first direction, and the locking mechanism in the unlocked state permits the spool to rotate in the first direction and in the second direction; a plug having an inserted position and a removed position with respect to the plug receptacle, wherein in the inserted position, the plug maintains the locking mechanism in the locked state so that the spool is rotatable in the second direction with respect to the plug, and in the removed position, the locking mechanism is alterable from the locked state to the unlocked state; a cable having a first end coupled to the spool and a second end coupled to the plug; and an alarm circuit configured to activate an alarm upon sensing at least one of discontinuity of the cable and movement of the plug from the inserted position to the removed position.
In a second separate aspect of the present invention, a security device includes: a housing having a plug receptacle; a plug having an inserted position and a removed position with respect to the plug receptacle; a spool rotatably coupled to the housing and rotatable in both a first direction and a second direction with respect to both the housing and the plug; a cable having a first end coupled to the spool and a second end coupled to the plug; a locking ring coupled to the spool to rotate with respect to the housing and with respect to the plug, the locking ring being moveable between a locked position and an unlocked position, wherein the locking ring in the locked position engages the housing to prevent the spool from rotating in the first direction, and with the locking ring in the unlocked position, the spool is rotatable in the first direction and in the second direction; and an alarm circuit coupled to the spool to rotate with respect to the housing and with respect to the plug when the plug is in the inserted position, the alarm circuit including a resilient contact member, which is alterable between a first state with the plug in the removed position and a second state with the plug in the inserted position, and a wireless receiver, which is configured to receive an alarm disable signal, wherein the alarm circuit is configured to activate an alarm upon sensing movement of the plug from the inserted position to the removed position without first receiving the alarm disable signal.
In a third separate aspect of the present invention, a security device includes: a housing having a plug receptacle; a spool rotatably coupled to the housing and rotatable in both a first direction and a second direction with respect to the housing; a locking mechanism coupled to the housing and alterable between a locked state and an unlocked state, wherein the locking mechanism in the locked state prevents the spool from rotating in the first direction, and with the locking mechanism in the unlocked state, the spool is rotatable in the first direction and in the second direction; a plug having an inserted position and a removed position with respect to the plug receptacle, wherein in the inserted position, the plug maintains the locking mechanism in the locked state so that the spool is rotatable in the second direction with respect to the plug, and in the removed position, the locking mechanism is alterable from the locked state to the unlocked state; a cable having a first end coupled to the spool and a second end coupled to the plug; and an alarm circuit coupled to the spool to rotate with respect to the housing and with respect to the plug when the plug is in the inserted position, the alarm circuit including: a first sensing circuit configured to sense discontinuity of the cable; a second sensing circuit having a resilient contact member movable between a first state in which the second sensing circuit is open and a second state in which the second sensing circuit is closed, wherein the contact member is in the second state when the plug is in the inserted position, and the contact member moves to the first state when the plug is moved from the inserted position to the removed position, wherein the alarm circuit is configured to activate an alarm upon sensing at least one of discontinuity of the cable and movement of the contact member from the first state to the second state.
Accordingly, an improved security device is disclosed. Advantages of the improvements will be apparent from the drawings and the description herein.
The foregoing summary, as well as the following detailed description of the exemplary embodiments, will be better understood when read in conjunction with the appended drawings. It should be understood, however, that the invention is not limited to the precise arrangements and instrumentalities shown in the following figures:
The description of illustrative embodiments according to principles of the present invention is intended to be read in connection with the accompanying drawings, which are to be considered part of the entire written description. In the description of embodiments of the invention disclosed herein, any reference to direction or orientation is merely intended for convenience of description and is not intended in any way to limit the scope of the present invention. Relative terms such as “lower,” “upper,” “horizontal,” “vertical,” “above,” “below,” “up,” “down,” “left,” “right,” “top” and “bottom” as well as derivatives thereof (e.g., “horizontally,” “downwardly,” “upwardly,” etc.) should be construed to refer to the orientation as then described or as shown in the drawing under discussion. These relative terms are for convenience of description only and do not require that the apparatus be constructed or operated in a particular orientation unless explicitly indicated as such. Terms such as “attached,” “affixed,” “connected,” “coupled,” “interconnected,” and similar refer to a relationship wherein structures are secured or attached to one another either directly or indirectly through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise. Moreover, the features and benefits of the invention are illustrated by reference to the preferred embodiments. Accordingly, the invention expressly should not be limited to such preferred embodiments illustrating some possible non-limiting combinations of features that may exist alone or in other combinations of features; the scope of the invention being defined by the claims appended hereto.
The present invention is directed toward a security device which may be secured to an object, such as an article of merchandise, to prevent unauthorized removal, access to, or tampering with the object. The security device is includes a cable which enables the security device to be secured to the object, by wrapping the cable around the object, in such a way so as to prevent removal of the security device from the object and to prevent unwanted access to the object. The security device may include one or more alarm features, with each alarm feature set to activate an alarm in response to one or more predefined conditions, which may include removal of the security device from the object, damage caused to the security device, and/or removal of the object from a predefined locality (such as through the use of an EAS system).
The security device may include multiple features to help make removal of the security device from the object difficult without use of specified tools, which are intended to facilitate removal of the security device from the object. Several of such features are described below, with the extent of such features incorporated into the security device, and the configuration of such features, being limited only by the scope of the claims below. Where those features are known from the prior art, such as in U.S. Pat. No. 8,087,269, the known features are only briefly described without being described in detail.
Turning in detail to the drawings,
In certain embodiments, the cable 171 may attached at one end to the first housing 111 and at a second end to the plug 181, such that when the plug 181 is coupled to the first housing 111, the cable 171 forms a single loop.
In
Those skilled in the art of merchandise security will appreciate that, in addition to securing the security device 101 to the object 191, the cable 171 wrapped around the object 191 may also inhibit or prevent tampering with or accessing the contents of the object. The security device 101 includes mechanisms which aid in preventing the security device 101 from being removed from the object 191. Such mechanisms are discussed in detail in connection with
As one security feature of the security device 101, the second housing 141 may include an EAS tag 147 (see
In the embodiment shown, the first housing 111 contains a rotatable spool configured to loosen and tighten the cable 171, and the second housing 141 contains the EAS tag 147. In certain embodiments, the second housing 141 may be omitted, such that the EAS tag 147 may be omitted from the security device 101, or alternatively, the EAS tag 147 may be incorporated into the first housing 111.
The security features of the security device 101 are shown schematically in
An alarm circuit 209 is also included within the first housing 111 of the security device 101. The alarm circuit 209 is configured to monitor the continuity of the cable 171 and the inserted position of the plug 181. The alarm circuit 209 may also be configured to monitor the state of other security features of the security device 101, such as the state of the locking mechanism 203, the state of the latch 207, and the like. As shown, the alarm circuit 209 includes a first sensing circuit 211a and a second sensing circuit 211b to accomplish each of these monitoring tasks, with the first sensing circuit 211a sensing the continuity of the cable, and the second sensing circuit 211b sensing the inserted position of the plug 181. A piezo-electric device (see
In addition, the alarm circuit 209 may include a wireless receiver 213 for receiving an alarm disable signal. When the alarm circuit 209 receives an alarm disable signal, via the wireless receiver 213, the alarm function of the alarm circuit 209 is at least temporarily deactivated. Thus, at the time of removing the security device 101 from an object 191 using an authorized/proscribed tool, an alarm disable signal may be sent to the alarm circuit 209 to disable the alarm function. In certain embodiments, the authorized/proscribed tool may be the source of the alarm disable signal. In certain other embodiments, the alarm disable signal may be generated other equipment, so that removal of the security device 101 from the object must happen in proximity to the equipment generating the alarm disable signal.
Referring collectively to
A handle 225 is pivotably coupled to the cap 221 and is accessible through the central opening of the annular rim 219 in the first housing part 215. The handle 225 may be placed in a folded position, so that it is substantially flush with the top of the first housing part 215, or it may be placed in a flipped-up position, so that it may be used to rotate the spool 201.
Within the interior space formed by the two housing parts 215, 217, the spool 201 is rotatable with respect to the first housing 111 in both a first direction and a second direction (i.e., clockwise and counter-clockwise) about a rotational axis RA. The spool 201 is captive within a cavity formed by the outer walls of the first housing 111. The spool 201 has a cylindrical side wall 229 and two cylindrical flanges 231, 233 extending outwardly from the top and bottom of the side wall 229. The side wall 229 and flanges 231, 233 form a cylindrical channel 235 in which a portion of the cable may be stored or held. One end of the cable is secured to the spool 201, and the other end of the cable is secured to the first housing 111. Rotation of the spool 201 in the second direction winds the cable around the spool 201 and rotation of the spool 201 in the first direction allows the cable to be unwound from the spool 201.
A locking ring 243 is coupled to one side of the spool 201 so that the locking ring 243 rotates with the spool 201. The locking ring 243, like the spool 201, is centered about the rotational axis RA. The locking ring 243 is also able to translate along the rotational axis RA toward and away from the spool 201. Springs 245 are held in receptacles 247 formed in the central portion 249 of the spool 201, the central portion being 249 bounded by the cylindrical side wall 229, and the springs 245 bias the locking ring 243 in a position away from the spool 201, with the extent of the translational movement being limited by the first housing 111. The surface of the locking ring 243 facing away from the spool 201 includes locking teeth 251. The surface in the first housing 111 which faces the locking teeth 251 of the locking ring 243 likewise includes complementary locking teeth 253. In combination, the locking teeth 251 of the locking ring 243 and the locking teeth 253 of the first housing 111 form a locking mechanism 203 for the security device 101. When the locking ring 243 is in a position biased away from the spool 201, the locking teeth 251 of the locking ring 243 engage the locking teeth 253 of the first housing 111, and the respective geometries of the interlocking teeth 251, 253 enables the spool 201 to rotate with a ratcheting action. Engagement between the respective locking teeth 251, 253, referred to herein as the locked state of the locking mechanism 203, prevents the spool 201 from rotating in the first direction, while still allowing the spool 201 to rotate in the second direction. When the respective locking teeth 251, 253 are not engaged, referred to herein as the unlocked state of the locking mechanism 203, the spool 201 may be freely rotated in both directions.
A button 261 is coupled to the first housing 111 and is movable in a direction parallel to the rotational axis RA. Movement of the button 261 in the direction toward the spool 201 causes the locking ring 243 to move toward the spool 201, thus placing the locking mechanism 203 in the unlocked state. Movement of the button 261 in the direction away from the spool 201 allows the locking ring 243 to move toward its biased position away from the spool 201, thus placing the locking mechanism 203 in the locked state. The first housing 111 includes an opening 263 in the annular rim 219 which gives a user access to the button 261.
The alarm circuit 209 includes a circuit board 271 which is mounted on the side of the spool 201 opposite the locking ring 243, and the circuit board 271 rotates with and is in a fixed position with respect to the spool 201. The circuit board 271 is electrically coupled to a battery 273 and to a piezo-electric device 275, which is used by the alarm circuit 209 to sound an audible alarm. The battery 273 and the piezo-electric device 275 are both positioned, at least partially, within the central portion 249 of the spool 201, and both also rotate with the spool 201. While the battery 273 is in a fixed position with respect to the spool 201, the piezo-electric device 275 is coupled to the spool 201 so that it is able to translate along the rotational axis RA toward and away from the battery 273. The spool 201 includes channels 281 which receive arms 283 extending from the body of the piezo-electric device 275. The channels 281 guide the piezo-electric device 275 as it translates along the rotational axis RA between a first position and a second position, wherein the piezo-electric device 275 in the second position is closer to the battery 273 as compared to the first position. Springs 287 are seated within the channels 281 to bias the piezo-electric device 275 into the first position.
As indicated above, the alarm circuit 209 includes at least two sensing circuits, the first for sensing continuity of the cable 171, and the second for sensing the plug 181 being moved from the inserted position to the removed position. The alarm circuit 209 includes, as part of the second sensing circuit, a resilient contact member 291, which extends from the circuit board 271 to a position between the battery 273 and the piezo-electric device 275. The resilient contact member 291 rotates with the spool 201 and includes two states. In a first state, the resilient contact member 291 is not in contact with the battery 273, thus leaving the second sensing circuit is open. In the second state, the resilient contact member 291 is in contact with the battery 273, so that the second sensing circuit is closed. When the piezo-electric device 275 is in the first position, which is further from the battery 273, the resilient contact member 291 resiliently returns to its first state. When the piezo-electric device 275 is in the second position, which is closer to the battery 273, the piezo-electric device 275 engages the resilient contact member 291 to place the resilient contact member 291 into the second state.
The plug receptacle 117 is formed so that the plug 181 may be inserted into the housing and into a position between the button 261, on the one hand, and the spool 201 and the piezo-electric device 275, on the other hand. When the plug 181 is not inserted in the plug receptacle 117, the piezo-electric device 275 is biased into the first position by the springs 287, thus also leaving the resilient contact member 291 in the first state. When the plug 181 is inserted into the plug receptacle 117, the plug 181 engages the piezo-electric device 275 to place the piezo-electric device 275 in the second position, which also places the resilient contact member 291 in the second state to close the second sensing circuit. Also, the plug 181 inserted into the plug receptacle 117 prevents the button 261 from being moved in the direction toward the spool 201, and so the locking ring 243 will be in its biased position away from the spool 201, thus placing the locking mechanism 203 in the locked state. When the plug 181 is removed from the plug receptacle 117, the button 261 may be used to move the locking ring 243 and place the locking mechanism 203 in the unlocked state.
As indicated above, the latch 207 interacts with and engages the plug 181 when the plug 181 is inserted into the plug receptacle 117. The first housing 111 includes a latch channel 301 in which the latch 207 and a coil spring 303 are disposed. The latch channel 301 is fully internal to the first housing 111. Within the latch channel 301, the latch 207 is moveable between the engaged position, in which the latch 207 extends into plug receptacle 117, and the disengaged position, in which the latch 207 is withdrawn from the plug receptacle 117. The coil spring 303 is positioned between the latch 207 and an end of the latch channel 301 to bias the latch 207 toward the engaged position. As the plug 181 is inserted into the plug receptacle 117, the plug 181 engages the latch 207 to first push the latch 207 toward the disengaged position. When the plug 181 is fully inserted into the plug receptacle 117, a catch 305 formed as part of the plug 181 aligns with the latch 207 and permits the latch 207 to return to the engaged position. Engagement of the latch 207 with the catch 305 prevents the plug 181 from being removed from the plug receptacle 117.
The latch 207 may be formed as an elongated body made from a magnetic material, e.g., iron, nickel, or nickel-plated steel. Thus, the latch 207 may be moved within the latch channel 301 by placing an appropriate magnetic field near the first housing 111. By placing such an appropriate magnetic field near the first housing 111 when the plug 181 is inserted within the plug receptacle 117 and engaged by the latch 207, the latch 207 may be moved from the engaged position to the disengaged position, thereby allowing the plug 181 to be removed from the plug receptacle 117.
A second embodiment of a security device 401 is shown in
Referring collectively to
A handle 427 is pivotably coupled to the cap 423 and is accessible through the central opening of the annular rim 421 in the first housing part 415. The handle 427 may be placed in a folded position, so that it is substantially flush with the top of the first housing part 415, or it may be placed in a flipped-up position, so that it may be used to rotate the spool 419.
Within the interior space formed by the two housing parts 215, 217, the spool 419 is rotatable with respect to the first housing 403 in both a first direction and a second direction (i.e., clockwise and counter-clockwise) about a rotational axis RA. The spool 419 is captive within a cavity formed by the outer walls of the first housing 403. The spool 419 has a cylindrical side wall 431 and two cylindrical flanges 433, 435 extending outwardly from the top and bottom of the side wall 431. The side wall 431 and flanges 433, 435 form a cylindrical channel 437 in which a portion of the cable may be stored or held. One end of the cable is secured to the spool 419, and the other end of the cable is secured to the first housing 403. Rotation of the spool 419 in the second direction winds the cable around the spool 419 and rotation of the spool 419 in the first direction allows the cable to be unwound from the spool 419.
A locking ring 443 is coupled to one side of the spool 419 so that the locking ring 443 rotates with the spool 419. The locking ring 443, like the spool 419, is centered about the rotational axis RA. The locking ring 443 is also able to translate along the rotational axis RA toward and away from the spool 419. Springs 445 are held in receptacles 447 formed in the central portion 449 of the spool 419, the central portion 449 being bounded by the cylindrical side wall 431, and the springs 445 bias the locking ring 443 in a position away from the spool 419, with the extent of the translational movement being limited by the first housing 403. The surface of the locking ring 443 facing away from the spool 419 includes locking teeth 451. The surface in the first housing 403 which faces the locking teeth 451 of the locking ring 443 likewise includes complementary locking teeth 453. In combination, the locking teeth 451 of the locking ring 443 and the locking teeth 453 of the first housing 403 form a locking mechanism for the security device 401. When the locking ring 443 is in a position biased away from the spool 419, the locking teeth 451 of the locking ring 443 engage the locking teeth 453 of the first housing 403, and the respective geometries of the interlocking teeth 451, 453 enables the spool 419 to rotate with a ratcheting action. Engagement between the respective locking teeth 451, 453, referred to herein as the locked state of the locking mechanism, prevents the spool 419 from rotating in the first direction, while still allowing the spool 419 to rotate in the second direction. When the respective locking teeth 451, 453 are not engaged, referred to herein as the unlocked state of the locking mechanism, the spool 419 may be freely rotated in both directions.
A button 461 is coupled to the first housing 403 and is movable in a direction parallel to the rotational axis RA. Movement of the button 461 in the direction toward the spool 419 causes the locking ring 443 to move toward the spool 419, thus placing the locking mechanism in the unlocked state. Movement of the button 461 in the direction away from the spool 419 allows the locking ring 443 to move toward its biased position away from the spool 419, thus placing the locking mechanism in the locked state. The first housing 403 includes an opening 463 in the annular rim 421 which gives a user access to the button 461.
The alarm circuit includes a circuit board 471 which is mounted on the side of the spool 419 opposite the locking ring 443, and the circuit board 471 rotates with and is in a fixed position with respect to the spool 419. The circuit board 471 is electrically coupled to a battery 473 and to a piezo-electric device 475, which is used by the alarm circuit to sound an audible alarm. The battery 473 is positioned within the central portion 449 of the spool 419, and the battery 473 also rotates with the spool 419. As indicated above, the alarm circuit includes at least two sensing circuits, the first for sensing continuity of the cable, and the second for sensing the plug 409 being moved from the inserted position to the removed position. The alarm circuit includes, as part of the second sensing circuit, a resilient contact member 481, which extends from the circuit board 471 to a position on the opposite side of the battery 473 from the circuit board 471. The resilient contact member 481 includes two states. In the first state, the resilient contact member 481 is not in contact with the battery 473, thus leaving the second sensing circuit is open. In the second state, the resilient contact member 481 is in contact with the battery 473, so that the second sensing circuit is closed. When the plug 409 is in the removed position, the resilient contact member 481 resiliently returns to its first state by extending into the space that would be otherwise occupied by the plug 409 within the first housing 403. When the plug 409 is in the inserted position, the plug 409 engages the resilient contact member 481 to place the resilient contact member 481 into the second state. Thus, the second sensing circuit is closed by the plug 409 being in the inserted position, and open when the plug 409 is in the removed position.
The plug receptacle 411 is formed so that the plug 409 may be inserted into the housing and into a position between the button 461, on the one hand, and the spool 419 and the resilient contact member 481, on the other hand. In addition to engaging the resilient contact member 481 when in the inserted position, the plug 409 in the inserted position prevents the button 461 from being moved in the direction toward the spool 419, so that the locking ring 443 will be in its biased position away from the spool 419, thus placing the locking mechanism in the locked state. When the plug 409 is in the removed position, the button 461 may be used to move the locking ring 443 and place the locking mechanism in the unlocked state.
As indicated above, the latch 491 interacts with and engages the plug 409 when the plug 409 is inserted into the plug receptacle 411. The first housing 403 includes a latch channel 493 in which the latch 491 and a coil spring 495 are disposed. The latch channel 493 is fully internal to the first housing 403. Within the latch channel 493, the latch 491 is moveable between the engaged position, in which the latch 491 extends into plug receptacle 411, and the disengaged position, in which the latch 491 is withdrawn from the plug receptacle 411. The coil spring 495 is positioned between the latch 491 and an end of the latch channel 493 to bias the latch 491 toward the engaged position. As the plug 409 is inserted into the plug receptacle 411, the plug 409 engages the latch 491 to first push the latch 491 toward the disengaged position. When the plug 409 is fully inserted into the plug receptacle 411, a catch 497 formed as part of the plug 409 aligns with the latch 491 and permits the latch 491 to return to the engaged position. Engagement of the latch 491 with the catch 497 prevents the plug 409 from being removed from the plug receptacle 411.
The latch 491 may be formed as an elongated body made from a magnetic material, e.g., iron, nickel, or nickel-plated steel. Thus, the latch 491 may be moved within the latch channel 493 by placing an appropriate magnetic field near the first housing 403. By placing such an appropriate magnetic field near the first housing 403 when the plug 409 is inserted within the plug receptacle 411 and engaged by the latch 491, the latch 491 may be moved from the engaged position to the disengaged position, thereby allowing the plug 409 to be removed from the plug receptacle 411.
While the invention has been described with respect to specific examples including presently preferred modes of carrying out the invention, those skilled in the art will appreciate that there are numerous variations and permutations of the above described systems and techniques. It is to be understood that other embodiments may be utilized and structural and functional modifications may be made without departing from the scope of the present invention. Thus, the spirit and scope of the invention should be construed broadly as set forth in the appended claims.