BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is an exploded, perspective view of an electronic article surveillance marker in accordance with the present invention.
FIG. 2 is an exploded, end-on, cross-sectional view of the electronic article surveillance marker of FIG. 1.
FIG. 3 is a plan view of one embodiment of an electronic article surveillance marker cavity of the invention.
FIG. 4 is a graph of the DC magnetic field deactivation of an electronic article surveillance marker of the present invention.
FIG. 5 is an illustration of the behavior of one embodiment of the present invention.
FIG. 6 is a graph of enhanced performance characteristics of an electronic article surveillance marker according to present invention.
FIG. 7 is block diagram of an electronic article surveillance system utilizing electronic article surveillance markers of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
Referring to FIGS. 1-3, a marker 10 for use in an electronic article surveillance system has a housing 12 composed of sheet-form plastic material in which an indentation or cavity 14 is formed. Housing 12 has the shape of a rectangular prism and is open on one of its large faces. Cavity 14 is sized to accommodate a magnetomechanical element, such as two resonator strips 16 and 18 placed therein in stacked registration. Resonator strips 16 and 18 can have a width, for example of 6 mm. Optionally, small projections 20 are molded into the long sides and/or ends of cavity 14. Projections 20 facilitate centering resonator strips 16 and 18 in cavity 14 without unduly constraining them mechanically. Housing 12 has lips 22 surrounding cavity 14 on all four sides. The depth of cavity 14 is defined generally by the spacing between the plane of the bottom of the cavity 14 and the parallel plane of the surfaces of lips 22. A layer of flat polymer sheet or lidstock 24 is placed over cavity 14 and sealed to lips 22 to encase resonator strips 16 and 18 within cavity 14, while permitting resonator strips 16 and 18 to mechanically vibrate freely. Preferably, lidstock 24 is heat sealed to lips 22, although the use of glue or other like adhesive agent, ultrasonic welding, or other attachment means can also be used. One suitable material for lidstock 24 is polyethylene-polyester laminate.
A bias magnet 26 for providing a DC bias field is associated with housing 12 by being placed on lidstock 24, which separates bias magnet 26 from resonator strips 16 and 18. Preferably, bias magnet 26 is in the form of an acute-angle parallelogram or rectangle. A cover 28, which is coated on both sides with a pressure-sensitive adhesive, is applied to secure bias magnet 26 to lidstock 24 and permit attachment of marker 10 to, for example, a merchandise item. For convenience of automated manufacture, handling, distribution, and subsequent end use, marker 10 is removably attached by the adhesive on the exterior surface of cover 28 to a release liner 30. Exemplary material for release liner 30 is paper or thin polyester.
The magnetomechanical element preferably consists essentially of two rectangular strips of an amorphous metal alloy sold commercially as ribbon by Metglas, Inc., Conway, S.C., under the trade name METGLAS® 2826MB. The magnetostrictive amorphous metal alloy comprises on an elemental weight basis about 2.8 to about 5 weight % boron, about 0 to about 9.5 weight % molybdenum, about 41 to about 55 weight % nickel, and about 33 to about 48 weight percent iron, and, for example, can have a nominal composition (atom percent) Fe40Ni38Mo4B18. The 2826MB alloy is a magnetostrictive, soft ferromagnetic material, having a saturation magnetostriction constant (λs) of about 12×10−6, a saturation magnetization (Bs) of about 0.8 T, and a coercivity (Hc) of about 8 A/m (0.1 Oe). The resonator strips are used in the as-received condition from the manufacturer and are not subjected to any further heat-treatment. The resonating strips in a preferred implementation are about 1.5 inches long, resulting in acoustomagnetic resonance for an electromagnetic exciting frequency of about 56-60 kHz.
In one embodiment, bias magnet 26 is composed of Arnokrome 4, which is the trade name for a bias material having a composition of between about 1 and about 12 weight percent chromium with the balance being iron, sold by Arnold Magnetics, Marengo, Ill. When measured in a Hysteresis Loop Tracer with peak excitation field level of 250 Oe, and operating drive field frequency of 60 Hz, a sample 6.0 mm wide, 76.2 mm long, and 25.4 μm thick exhibits the following semi-hard magnetic properties: (i) a Remanence Br: 1.4±0.1 tesla; (ii) Coercivity Hc: 19±5 oersteds; and (iii) Remanent Flux Fr: 390±60 nano-webers, wherein Fr=Br*A and A is the cross sectional area of the ribbon sample. The Arnokrome 4 material additionally has the following properties when magnetized in a uniform solenoidal DC field of applied to a sample 6.0 mm wide×28.6 mm long: (i) the sample is magnetized to within 2% of its saturated remanent flux in a field of 100 Oe; (ii) the sample retains >12% of its saturated remanent flux after exposure to a demagnetizing DC field of strength 8 Oe; (iii) after exposure to a 25 Oe demagnetizing AC field, the saturated sample retains no more than 30% of its saturated remanent flux, the demagnetizing field having an exponentially decreasing waveform; and (iv) a saturated sample, when bent around a radius of 13.5 mm does not exhibit a loss of magnetism of greater than 12% of the saturated remanent flux.
In another embodiment bias magnet 26 is composed of Arnokrome 5, which is the trade name for a bias material having a composition of between about 8 and 18 weight percent manganese with the balance being iron, sold by Arnold Magnetics, Marengo, Ill.
FIG. 4 illustrates the marker deactivation curve for a marker of the present invention having a bias material of Arnokrome 4, which is illustrated by curve 40, and Arnokrome 5, which is illustrated by curve 42. Both markers had dual resonator strips in registration with the 2826 MB resonator material. The frequency of the marker is provided on the vertical axis in hertz, and the DC magnetic field is provided on the horizontal axis in ampere-turns per meter. This curve was generated by applying a DC field to a marker of the present invention in the degaussing direction. This field was supplied by the DC coils of the label tester. After applying the degaussing DC, field, the frequency was recorded. The DC field was applied in increments of 100 A/m in order to generate the DC demagnetization curve for the given markers. As the marker is degaussed, the frequency of the marker will increase in proportion to the reduction in the remanent magnetic field of the bias material. In effect, the label acts like a gauss meter. The demagnetization curves describe a more gradual decay in remanent magnetization frequency starts to increase at 900 A/m for the marker with the Arnokrome 4 bias material. This is expected because the Arnokrome 4 bias material has more of a sheared hysteresis loop which makes the bias less abrupt than the Arnokrome 5 bias material. The Arnokrome 5 bias material starts to decay later than the Arnokrome 4 bias material at 1500 A/m but decays much more quickly at 2000 A/m, thereby illustrating the more abrupt nature of the hysteresis loop of the Arnokrome 5 bias material.
The Arnokrome 4 bias material, when used as bias magnet 26, imparts a field which is based upon the position of the magnet relative to the resonator strips between 450 and 550 A/m (5.65 to 7.0 Oe) upon dual resonator strips 16 and 18, which is near the frequency minimum of the curve. At the frequency minimum the entire frequency shift is utilized upon degaussing bias magnet 26 during deactivation, which enhances the deactivation behavior of marker 10. At the frequency minimum, the slope of the frequency vs. magnetic field curve is minimized. When marker 10 is in the active condition, this low slope imparts frequency stability in the presence of stray magnetic fields such as the earth's magnetic field. The active response of marker 10 should be enhanced in all orientations within an AC interrogation field. The Arnokrome 4 bias material also provides a low coercivity bias magnet with a high degree of squareness in its flux density (B) versus DC magnetization field (H) curve, which will provide a rapid shift of marker 10 from the active state to the deactivated state.
It has been found that utilizing the nonlinear, amorphous METGLAS® 2826 MB resonator material in the dual resonator configuration illustrated in FIG. 5 imparts a stress, which is indicated by arrows 50, upon resonator strip 18 due to the forces of gravity and magnetic attraction. It has been further found that this stress field influences the frequency response of the dual resonator label such that the frequency well is shifted to a higher field level as illustrated by the graph in FIG. 6. The resonant frequency in hertz of a marker for use in an electronic article surveillance system is provided on the left-hand vertical axis. The amplitude in volts of the signal from a marker for use in an electronic article surveillance system in response to an interrogating magnetic field is provided on the right-hand vertical axis. The DC bias in amperes per meter is provided on the horizontal axis. The curves were generated from a composite of actual marker measurements taken on a coil tester. Curve 62 illustrates the frequency verses dc bias curve of a single nonlinear amorphous resonator composed of the METGLAS® 2826 MB resonator material and a bias magnet composed of the Arnokrome 4 bias material. Curve 64 illustrates the frequency verses DC bias curve of a dual nonlinear amorphous resonator composed of the METGLAS® 2826 MB resonator material and a bias magnet composed of the Arnokrome 4 bias material according to the present invention. Arrows 66 indicate the shift in the frequency curve sustained when two resonator strips are stacked in a dc bias field. Curve 68 is the voltage amplitude signal generated by the dual resonator embodiment of the present invention. Curve 70 is the signal generated by a single resonator embodiment. As discussed above, the Arnokrome 4 bias material, when used as bias magnet 26, imparts a field between 450 and 550 A/m upon dual resonator strips 16 and 18, which is near the frequency minimum of the curve. It should also be noted that the signal maximum for this configuration also occurs between the 450 to 550 A/m bias range, thereby providing maximum signal output at the bias point. This shift in resonant frequency minimum allows for increased deactivation and centers the frequency minimum on the imposed bias field of the magnet. The frequency curve shift caused by the dual resonator configuration is different than the frequency shift caused by deactivation. The frequency change created by the dual resonator interaction is a frequency curve shift not a frequency shift. In deactivation, the bias is degaussed which shifts or lowers the bias field level imposed by the magnet and increases the frequency response of the label while lowering the amplitude response. For the dual resonator nonlinear label with 2826 MB and Arnokrome 4 or Arnokrome 5 bias material, the range for biasing the marker at or near its frequency minimum and is defined by the slope of the resonant frequency versus the applied DC bias curve which should be less than about 250 Hz/Oe.
FIG. 7 is a block diagram illustrating an electronic article surveillance system 70 using marker 70, which is an electronic article surveillance marker made in accordance with the present invention. System 70 includes interrogating antenna 74, receiving antenna 7, energizing circuit 78, control circuit 80, receiver circuit 82, and indicator 84. In operation, energizing circuit 78, under control of control circuit 80, generates an interrogation signal and drives interrogating antenna 74 to radiate the interrogation signal within an interrogation zone disposed between interrogating antenna 74 and receiving antenna 76. Receiver circuit 82 via receiving antenna 76 receives signals present in the interrogation zone. Receiver circuit 82 conditions the received signals and provides the conditioned signals to control circuit 80. Control circuit 80 determines, from the conditioned signals, whether an active marker 72 is present in the interrogation zone. If an active marker 72 is in the interrogation zone, marker 72 will respond to the interrogation signal by generating a marker signal. The marker signal will be received via receiving antenna 76 and receiver circuit 82, and be detected by control circuit 80, which will activate indicator 84 to generate an alarm indication that can be audible and/or visual.
It is to be understood that variations and modifications of the present invention can be made without departing from the scope of the invention. It is also to be understood that the scope of the invention is not to be interpreted as limited to the specific embodiments disclosed herein, but only in accordance with the appended claims when read in light of the foregoing disclosure.