The present invention relates to a system and method for installing and securing glass having a security film.
Glass is typically the weak point many criminals exploit in order to gain entry into a building or home. Consequently, it is desirable to have a system and method which allows for increased security compared to the prior art.
The novel features believed characteristic of the invention are set forth in the appended claims. The invention itself, however, as well as a preferred mode of use, further objectives and advantages thereof, will be best understood by reference to the following detailed description of illustrative embodiments when read in conjunction with the accompanying drawings, wherein:
Several embodiments of Applicant's invention will now be described with reference to the drawings. Unless otherwise noted, like elements will be identified by identical numbers throughout all figures. The invention illustratively disclosed herein suitably may be practiced in the absence of any element which is not specifically disclosed herein.
As depicted in
The pane of glass 104 can comprise virtually any type of glass. The glass 104 can comprise tempered glass, annealed glass, laminated glass, heat treated glass, etc. The glass 104 offers the benefit of increased visibility compared to a solid door. However, as noted above, the glass 104 also offers a weak point in trying to gain access to a structure. No matter how strong the support 102, the hinge 101, or the lock, a traditional glass 104 can simply be broken to permit access to a structure. The traditional glass 104 offers little to no security, and a determined criminal need only throw a brick to circumvent a locked door.
The traditional squeeze frame door 100 has two outer frames 103 which sandwich an inner frame 111.
In
As noted, a security film 105 increases the security of traditional glass 104. The security film 105 aims to keep the shattered glass intact. This is contrasted with a traditional glass which has not been adhered to a security film 105 which will simply shatter and fall away when broken. Security is thereby increased because a glass adhered to a security film 105, in some embodiments, will, in some embodiments, withstand several blows whereas a traditional glass will often not withstand a single blow. However, if the perimeter of the glass 104 adhered to a security film 105 is not properly secured to the support 102, then the glass 104 will simply break at its weak connection point with the support 102, such as a door. Thus, while the glass 104 may remain intact along the security film 105, the entire glass pane 104 will break along the perimeter. This is due, in part, because many films do not extend the entire length of the window pane. Further, there is insufficient support attaching the window 104 to the support 102. The security bracket depicted in
The security bracket 106 depicted in
As depicted, the adhesive 107 couples the bracket 106 with the glass 104. In one embodiment, and as depicted, the adhesive 107 is sandwiched between the bracket 106 and the security film 105. As noted, in one embodiment the adhesive 107 comprises double-sided tape which adheres to both the bracket 106 and the security film 105.
In one embodiment, and as depicted, the adhesive is adhered to the glass coupler portion 108 of the bracket 106. In one embodiment the bracket 106 comprises three portions: a glass coupler 108, a support coupler 110, and a gap definer 109 which connects the glass coupler 108 to the support coupler 110. In one embodiment, the glass coupler 108 is substantially parallel to the support coupler 110. In one embodiment the glass coupler 108 and the support coupler 110 are substantially perpendicular to the gap definer 109.
The glass coupler portion 108 is the portion of the bracket 106 which adheres to the adhesive 107 and the security film 105 and/or the glass 104. In one embodiment the glass coupler portion 108 is parallel to the orientation of the glass 104 and the security film 105. The glass coupler portion 108 offers sufficient surface area to properly adhere and attach the security film 105. The size of the glass coupler portion 108 can vary with the size of the door, the size of the window, etc. In one embodiment with a conventional squeeze frame door, the glass coupler has a length of about ¾ of an inch. In one embodiment the dimensions of the adhesive 107 are sized so as to match the dimensions of the glass coupler 108. In one embodiment the glass coupler portion 108 comprises a length of between about ⅜ of an inch to about 1 inch.
Coupled to the glass coupler 108 is the gap definer 109. The gap definer 109 provides an off-set distance between the glass coupler 108 and the support coupler 110. The size of the gap definer 109 can be adjusted to accommodate various glass and film thicknesses. In one embodiment the gap definer 109 is sized as to allow the glass coupler 108 to be adjacent to the film 105 and have the support coupler 110 be adjacent to the door 102. In one embodiment the gap definer 109 comprises a length of about ¾ of an inch.
The support coupler 110 couples the bracket 106 to support 102. The support coupler 110 acts like the glass coupler 108 described above. In one embodiment the support coupler 110 adheres to the adhesive 107 which also adheres to the door 102. In one embodiment any paint, sealant or any other such layer above the support surface is removed prior to adhering with the adhesive 107. As an example, if the support 102 is metal, the door 102 is sanded to the metal. This increases the adhesion of the adhesive 107 with the support 102.
The dimensions of the support coupler 110 can vary depending upon the size of the glass, size of the support, etc. In one embodiment the support coupler 110 has a length of about 1 and ¼ of an inch. As with the glass coupler 108, in one embodiment the adhesive 107 has dimensions similar to that of the length of the support coupler 110.
By coupling the glass 104 and the security film 105 to the support 102 via a rigid bracket 106, the glass 104 and the security film 105 remain attached to the support 102 even after the glass 104 has shattered. As noted above, previously if the glass 104 were shattered, even if the shattered glass 104 remained adhered to the security film 105, the entire glass 104 would fall out as a single unit. Now, however, the bracket 106 keeps the glass 104 and security film 105 adhered to the support 102. If the glass 104 is shattered, it remains adhered to the security film 105 and both remain attached to the support. The system, in one embodiment, will withstand several direct collisions before failure occurs, if it occurs at all.
While
As can be seen, the brackets 106 extend along the outer perimeter of the glass 104 and the security film 105. In the embodiment depicted wherein the glass 104 comprises a rectangular shape, the bracket 106 comprises of two top brackets and two side brackets. Each bracket will be installed are previously discussed. In one embodiment each bracket 106 is independent and is not directly coupled to any other bracket 106. In other embodiments, however, one bracket 106 is directly coupled to at least one other bracket 106. As an example, though not depicted, in some embodiments the top bracket 106 is coupled to the side bracket on the left. The two brackets 106 can be coupled via any device or method known in the art. Connecting two or more brackets 106, in some embodiments, results in increased structural rigidity.
In one embodiment, two or more brackets 106 are integrally made as a single piece. In some embodiments, this increases the structural rigidity of the bracket.
While a rectangular glass has been shown, this is for illustrative purposes only. The method and system disclosed herein can be practiced on glass with virtually any shape including curved, rounded, polygonal, triangular, etc. The number, size, and shape of the brackets 106 will be adjusted accordingly to accommodate the various shapes.
While a system has been described, a method of utilizing the system will now be described in reference to one embodiment. First, the outer frame 103 is removed and the glass 104 is decoupled from any inner frame 111. Thereafter, a security film 105 is applied to the glass 104. In one embodiment the security film 105 is applied such that the film extends to the outer edges of the glass 104. The security film 105 is then allowed to cure on the glass 104. The curing time will depend on several factors including the type of the glass, the type of film 105, the temperature, humidity, etc. In one embodiment, the curing time is about 30 days. In other embodiments the curing time is less than 30 days.
After the security film 105 has cured, an adhesive 107 can now be applied. As noted, in one embodiment the adhesive 107 is applied to side of the glass 104 which has the security film 105. The adhesive 107 is applied along the perimeter of the glass 104. In one embodiment the adhesive is applied to the bracket first and then simultaneously adhered to the glass 104 and the support 102. This process is repeated for every side of the glass 104. For the glass 104 in
After adhesive 107 has been applied, the adhesive 107 is coupled to the glass coupler 108 of the bracket 106. The bracket 106 is applied slowly and a force is applied to the bracket 106 to ensure adherence to the adhesive 107. Note, adhesive 107 can also be applied to the bracket 106 and then adhered to the glass 104.
Next, adhesive 107 is applied to the support 102, such as a door. Like above, adhesive 107 can also be applied to the support coupler 110 of the bracket 106. Adhesive 107 is applied in a location such that the adhesive 107 will adhere to both the support 102 and the security film 105. As above, the bracket 106 is applied slowly, and a force is applied to ensure the adhesive adheres to both the support 102 and the support coupler 110.
After the glass 104 has been installed and coupled to the support 102, the outer frames 103 can be secured as previously discussed. In this manner, in some embodiments, the bracket 106 is hidden from view. The resulting support 102 is one in which the glass 104 is properly secured to both the security film 105 and the bracket 106, and the bracket 106 is properly secured to the support 102. In this manner, the glass 104 can withstand several blows which would otherwise shatter conventional glass 104. Further, because the glass 104 is secured to the support 102 via the bracket 106, the glass 104 can withstand more blows than conventional glass 104 which has been laminated with a security film 105 but not properly attached to the support 102.
As noted above, in some embodiments the time required to cure the security film 105 to the glass 104 is relatively long. If the system discussed herein was going to be installed in a traditional door, for example, then the security film 105 would first need to be installed. Then, after the curing time, the installation crew would need to head to the home or office once again to install the bracket 106. This is undesirable for a variety of reasons. First, it inconveniences the customer. Second, it requires a second trip and, consequently, it is less efficient, driving up costs.
In alternative embodiments, an installation truck, trailer, or van, carries one or more replacement panes of glass 104 that has already been adhered to a security film 105. Thus, the curing time is already complete. The installer need simply remove the old glass and replace it with the new glass 104, security film 105, and the bracket 106.
In still another embodiment, the installation truck, trailer, or van, carries on or more replacement doors. Many of the squeeze frame doors 100 are common in size and appearance. If a customer desires to install the security film 105 and security bracket 106, the entire door can be swapped out with a new door. Thereafter the new door can simply be painted or modified as desired by the customer.
The above methods of installing overcome the many disadvantages associated with the prolonged curing time. This decreases any burden on the customer and makes installation a single trip rather than multiple trips. Thus, what would normally have been a 30 day plus project can now be completed on a single day.
While the invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.
The following clauses are offered as further description of the disclosed invention.
This application is a continuation of application Ser. No. 15/343,285, filed Nov. 4, 2016, which claims priority to U.S. Provisional Application No. 62/251,260 filed Nov. 5, 2015, the entirety of both is hereby incorporated by reference.
Number | Date | Country | |
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62251260 | Nov 2015 | US |
Number | Date | Country | |
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Parent | 15343285 | Nov 2016 | US |
Child | 15911431 | US |