Method of Detecting and Deterring Microphone Sabotage
[0001] The invention relates to the field of sound microphones, and more specifically to a method and apparatus for detecting and deterring microphone sabotage.
[0002] In the field of apparatus for securing a premises, one measure of security is to provide a microphone for so- called "glassbreak" protection. It is known in the art, by both protectors and intruders, to monitor the frames of access portals, e.g., doors or windows, against motion that may indicate an intrusion. Therefore, an intruder might attempt to enter secured premises by breaking the glass of a window, rather than opening it. Such attempts to intrude the premises, by breaking a window, door, or other violent breach, are typically noisy events. Therefore, it is known to provide a microphone or other sound detection for glassbreak monitoring.
[0003] However, it would further be advantageous to be able to secure the glassbreak microphone against sabotage attempts, and/or to give a visual indication that an
attempt to sabotage the microphone has taken place. Certain national and industrial standards in the field require at least such sabotage detection means.
[0004] Therefore, in order to achieve this and other objectives, provided by the present invention is a method and apparatus for securing a microphone against damage, and for indicating that at least an attempt to damage or sabotage the microphone has occurred.
[0005] Provided by the present invention is a protective grommet for a microphone, the grommet having an enclosure with an internal cavity. The internal cavity is dimensioned to receive an input end of the microphone therein. A membrane, particularly a mesh, and more particularly a wire mesh, and more particularly a stainless steel wire mesh, is embedded into the enclosure spanning the cavity across the input end of the microphone. The stainless steel wire mesh may have an epoxy or other coating.
[0006] According to a method of the present invention, a grommet as described is fit over the input end of the microphone .
[0007] These and other features, advantages and benefits will be made apparent through the following descriptions and accompanying figures, where like reference numerals refer to the same features across the various drawings.
[0008] Fig. 1 illustrates in perspective view a protective microphone grommet according to an exemplary embodiment of the present invention;
[0009] Fig. 2 illustrates a plan view of the protective microphone grommet according to an exemplary embodiment of the present invention;
[0010] Fig. 3 illustrates a longitudinal cross-sectional view of the protective microphone grommet according to an exemplary embodiment of the present invention, taken along section line 3-3 of Fig. 2;
[0011] Fig. 4 illustrates an interface ridge formed at the first end of the microphone grommet according to an exemplary embodiment of the present invention, which area is circled in a phantom line ellipse in Fig. 3; and
[0012] Fig. 5 illustrates a glassbreak detector according to another aspect of the present invention in cross- sectional view.
[0013] Referring now to Fig. 1, shown is a protective microphone grommet, generally 10, according to an exemplary embodiment of the present invention. The grommet 10 has an enclosure 12 that is generally circular right cylindrical in shape, though other enclosure shapes are acceptable. At a first end 14 of the grommet 10, a projection 16 forms in its interior at least part of an acoustic cavity 18 to aid the performance of the microphone. A mesh material 20 can be seen at the bottom of the acoustic cavity 18. These features can be seen also in the plan view of Fig. 2.
[0014] Referring now to Fig. 3, a longitudinal cross- section is shown. The grommet 10 has an internal cavity 22. A first internal cavity wall 24 has a diameter 26. First internal cavity wall 24 is dimensioned to receive an input end of a microphone. Those skilled in the art will appreciate that various shapes and sizes are equally applicable, and are determined according to the shape of the microphone to be protected. In the exemplary embodiment only, the shape of the microphone to be protected, and particularly the input end thereof, is generally that of a right circular cylinder. The internal cavity 22 of the exemplary grommet 10 is therefore similarly shaped. The internal cavity 22 may have a second
internal cavity wall 28 having a diameter 30. Diameter 30 is greater than diameter 26 and may provide additional relief from the surface of the microphone.
[0015] A membrane, for example a mesh 20, has .a diameter 32, and a thickness 34. Diameter 32 is larger than the diameter 26 of the first internal cavity wall 24. Mesh 20 is embedded into the enclosure 12, particularly in an internal wall, for example first internal cavity wall 24. The mesh 20 spans the internal cavity 22 adjacent the first end 14 of the grommet 10, and closes off the internal cavity 22 across the input end of the microphone. The mesh 20 may be formed of a variety of materials, including, but not limited to, a gauze mesh and a stainless steel wire mesh. In the exemplary embodiment, the mesh 20 is a stainless steel wire mesh. More particularly, the stainless steel mesh is formed of type 304 stainless steel wire, having a wire diameter of about .009"; a mesh opening of about .011", a wire mesh density of about 50 per inch; a PSW-type weave, with a mesh open area of approximately 30%.
[0016] Two considerations are primarily contemplated when choosing a material for the membrane. First is the minimization of any effects on the acoustic response of the microphone. The membrane should be, as near as
practicable, acoustically transparent. An additional consideration in selecting the material for the membrane is its visual contrast with the input end of the microphone. Visual contrast may include differences in color, texture, reflectivity, or other characteristic detectable by sight. The input end of a microphone is generally covered with a black felt or similar dark material. It is desirable that the membrane has a contrasting color with that of the input end of the microphone. For example, a gauze mesh having a generally white color is acceptable. Similarly, a stainless steel mesh, left unfinished, will also present a light and contrasting color as compared with the input end of the microphone. Particularly with the stainless steel mesh, a coating, including but not limited to an epoxy or anodizing, having a white, light, or other contrasting color, may be applied to enhance the color contrast with the input end of the microphone.
[0017] The enclosure 12 may be formed of a plastic material, more particularly, a neoprene, including but not limited to Royalene 521. It additionally preferred that the material is non-conductive. One method of manufacture contemplated is a molding process, whereby the mesh 20 is held at the parting line of a two-piece mold. The mold
cavity would define the features of the enclosure 12. In this way, the mesh 20 would be located and embedded into the enclosure 12 during the molding process.
[0018] Referring now to Fig. 4, shown is the first end of the grommet 10 is greater detail. Particularly, a ridge 36 is formed which encircles the acoustic cavity 18. Ridge 36 has a diameter 38, a width 40, and a height 42. An outer perimeter of the ridge 36 may be radiused, as shown. Particularly, this ridge 36 is formed to facilitate an interface between the grommet 10 and the outer enclosure of a glassbreak detector, and more particularly with a acoustic cavity of the outer enclosure.
[0019] Referring now to Fig. 5, according to another aspect of the present invention shown in cross-section is a glassbreak detector, generally 100, including a microphone protective grommet 10. Glassbreak detector 100 includes an outer enclosure outer 102. An enclosure acoustic cavity 104 leads to an opening 106, though which sound passes into acoustic cavity 18 of the grommet 10. A microphone 108 is positioned within the internal cavity 22. The outer acoustic cavity 104 and the acoustic cavity 18 of the grommet 10 cooperate to enhance the function of the microphone 108.
[0020] As arranged, any attempts to physically sabotage the microphone at its input end via the acoustic cavity 18 would necessarily break the membrane. Therefore, the sabotage attempt would be detectable by visual examination of the assembled microphone and grommet 10. Moreover, any sabotage attempt would have to overcome the material properties of the membrane. A resilient membrane material, on the order of a wire mesh 20 or greater, would provide some measure of protection against the sabotage attempt. Moreover, the visible presence of the membrane may act as a deterrent to a knowledgeable saboteur, who would recognize that there would be evidence of the attempt, and the attempt would not go undetectable.
[0021] The present invention has been described herein with reference to certain exemplary and/or preferred embodiments. Certain modifications will be apparent to those skilled in the art, without departing from the scope of the invention. The embodiments described are offered merely as illustrative, and not limiting, on the scope of the present invention, which is defined with reference to the appended claims.