The present invention relates generally to the field of windows. More particularly, the present invention relates to a snubber system for securing pivotable windows to a window frame when subjected to strong winds.
Hung windows are well known. Single hung windows have a window frame that comprises a fixed glass pane and a sash having a glass pane, the sash being vertically slidable within the window frame. Double hung windows have two sashes, each having a glass plane, which are vertically slidable within the window frame.
Also well known are pivotable hung windows. For these, fixtures at the bottom of a sash pivotally engage cooperating fixtures disposed in opposite vertical channels of the window frame. A releasable latch mechanism is disposed at the top part of the sash and allows a user to pivot the sash to the inside of the building in which the window is installed. These pivotable hung windows allow for easy cleaning of the exterior of the window pane from the inside of the building.
Additionally, hung windows usually include a lock mechanism for locking together the top and bottom windows in a closed position. In addition to providing security to the building, the lock mechanism provides additional structural strength to the window assembly. This added strength is desirable particularly in stormy weather where strong winds prevail. However, the additional structural strength is only present when the lock mechanism is engaged.
Hung window sashes made of materials such as PVC tend to bend under strong wind pressure, sometimes causing them to dislodge from the window frame. Additionally, the latch mechanisms of pivotable window sashes in general can fail in such weather conditions. Consequently, window sashes can abruptly open and cause damage to the window unit and to the building.
To address the problem of abruptly opening hung windows, several window brackets, or snubbers, for hung windows have been developed. One such type of bracket is disclosed in U.S. Pat. No. 6,363,659 to Wang. The bracket includes an L-shaped part (20) for securing to a vertical side of the window frame and a Z-shaped part (10) for securing to a corresponding vertical member of the window sash. The bracket L-shaped and Z-shaped parts are mounted hidden from sight on respective planes parallel to each other and perpendicular to the glass pane plane. The bracket parts are of cooperating shape such that when mounted and with the window closed, the brackets parts overlap and interlock to prevent pivoting of the window sash. This type of bracket can be adequate for windows framed in aluminum or wood where bending under pressure is not considerable, but inadequate for PVC window units. The bending of PVC in strong winds is such that the interlocking mechanism of the L-shaped bracket and the Z-shaped bracket can fail and the hung window pop open.
Additionally, the Wang bracket parts are not easy to install. Installation of the bracket parts requires that the window sash be pivoted in the open position. Further, the Z-shaped part requires that a worker have access to each side of sash. This can be impossible in cases where the window unit is installed close to an interior perpendicular wall of the building. In such cases, the window sash has to be removed from the window frame to install the part. Furthermore, the Z-shaped part includes parallel, spaced-apart, segments that are for abutting to parts of the window sash. These bracket features have to match the dimensions and the features of the window sash. As such, a given Wang bracket is not adapted to fit to window sashes of different dimensions.
Another type of bracket for providing impact resistant window units is disclosed in U.S. Patent Application Publication No. 2005/0155301A1 to Hapka et al., hereinafter referred to as Hapka. The Hapka bracket is fitted in the frame of the window unit, on the inside of the building. The bracket includes a movable bracket portion which can be in an extended or retracted position, overlapping the window sash in the extended position. When in the extended position, the movable bracket portion abuts the window sash thereby providing additional structural force to the window sash in strong wind conditions. When in the retracted position, the movable bracket portion allows a pivotable window sash to pivot for cleaning. However, the Hapka bracket requires significant work for retrofitting in existing windows.
Consequently, there is a need in the pivotable hung window art for an affordable bracket, or snubber, system that can be easily retrofitted to existing windows and that provides additional structural strength to window unit to sustain strong winds.
It is an object of the present invention to obviate or mitigate at least one disadvantage of previous window snubber systems.
In a first aspect, the present invention provides a snubber system for a window unit mountable to a building, the window unit having a frame with a frame member and a window sash with a sash member, the sash member being substantially parallel to the frame member and being proximate the frame member. The snubber system comprises a frame mount for mounting to the frame member. The snubber system further comprises a sash mount for mounting to the sash member, on a surface of the sash member facing an outside of the building, the frame mount and the sash mount having cooperating shapes for abutting against each other when the window sash is in a closed position and when pressure is applied to the window sash.
The frame mount can include a straight segment and a folded segment, the straight segment for securing to the frame member when the window unit is in a closed position.
The sash mount can include a straight segment and a folded segment, the straight segment for securing to the sash member when the window unit is in a closed position.
The frame mount can be mounted to the frame member on a mounting part of the frame member disposed outside the building.
The mounting part of the frame member can define a plane substantially perpendicular to a plane defined by a glass pane of the window sash.
The sash mount can be mounted to the sash member on a mounting surface of the sash member substantially parallel to a plane defined by a glass pane of the window sash.
The frame mount can define a hole, or aperture, for receiving a fastener for fastening the frame mount to the frame member and the sash mount can define a hole, or aperture, for receiving a fastener for fastening the sash mount to the sash member.
The frame mount and the sash mounts can include folded segments for abutting against each other.
The folded segments can include hook segments and the cooperating shapes can include interlocking shapes.
The snubber system can further comprise a snubber profile allowing a full amplitude of movement of the window sash.
In a further aspect, there is provided a pivotable sash window unit comprising a snubber frame mount for mounting to a frame of the window unit and a snubber sash mount for mounting to a sash of the window unit. The snubber sash mount is for mounting proximate the snubber frame mount, on a surface of the sash facing an outside of a building receiving the window unit. The snubber frame mount and the snubber sash mount have cooperating shapes for abutting against each other when the window is in a closed position and when pressure is applied to the sash.
In a further aspect of the invention, there is provided a snubber system for a window unit mountable to a building, the window unit having a frame with substantially vertical frame members and a window sash with substantially vertical sash members. The snubber system comprises a frame mount for mounting to one of the substantially vertical frame members and a sash mount for mounting to one of the substantially vertical sash members on a surface of the substantially vertical sash member facing an outside of the building. The frame mount and the sash mount have cooperating shapes for abutting against each other when the window unit is a closed position and when pressure is applied to the window sash.
Other aspects and features of the present invention will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments of the invention in conjunction with the accompanying figures.
Embodiments of the present invention will now be described, by way of example only, with reference to the attached Figures, wherein:
For the purpose of this document, a sash is a part of a window unit movable within the frame of the window unit, and the term window unit includes window-door units such as, for example, sliding patio doors.
Generally, the present invention provides a snubber system for securing window units subjected to strong winds. The snubber system includes two cooperating parts that can easily be retrofitted to most window units. The snubber system includes a frame mount secured to the window frame and a sash mount secured to a window sash of the window unit on a part of the sash facing the outside of the building receiving the window unit. The frame mount and sash mount abut each other when the window is in a closed position and when pressure is applied to the window sash.
In
As an example, the frame mount 28 is shown secured to the frame 24 in a plane substantially parallel to a frame plane 42, which is substantially perpendicular to a window plane 44. The sash mount 30 is shown secured to the sash member 22 in a plane substantially parallel to the window plane 44. The frame mount 28 can be mounted to an inner part 46 of the frame member 24 and the sash mount 30 can be mounted to an exterior part 48 of the sash member 22, the exterior part 48 facing an outside of the building in which the window is installed. The orthogonality of the planes to which the frame mount 28 and the sash mount 30 are secured, as shown in
As shown in
When the frame mount 28 and the sash mount are vertically aligned as shown in
Although the snubber system 12 is shown installed to a pivotable window sash 18, it can also be installed to horizontal, pivotable slider windows or to non-pivotable windows to provide additional structural strength to the windows. The snubber system 12 can also be installed on sliding window-door units (not shown).
In
The sash mount 28 and the frame mount 30 can be made of any suitable material such as, for example, stainless steel or impact resistant plastic. The frame member 24 and the sash member can also be made of any suitable material including, but not limited to, wood, aluminum and PVC.
Normal use of the window sash 18 dictates that the profile of the snubber system 12 allow the window sash 18 to be lifted without catching the frame of the fixed window 16. The snubber system 12 can be constructed such that its profile has this characteristic. The profile is characterized by frame mount length 54 and by sash mount length 56 shown in
The same conditions regarding the profile of the snubber system 12 installed on a single hung window unit 10 also apply to a double hung window unit 60.
The advantages of the snubber system of the present invention over the prior art are that, unlike snubber systems such as Wang's, the frame mount and the sash mount are installed to accessible parts of the window unit, not on hidden parts of the window frame and sash. Additionally, the snubber system of the present invention can easily be retrofitted to existing windows regardless of the thickness or profile of the sash member. The snubber system of the present invention is also advantageous over the system of Hapka in that the retrofitting of the snubber system of the present invention does not require any delicate removal of portions of the window frame.
Therefore, the present invention provides a snubber system for securing windows subjected to strong winds. The snubber system includes two easy-to-install cooperating parts that can be retrofitted to most existing window units. The snubber system includes a frame mount secured to the window frame and a sash mount secured to a sash of the window unit on a part of the sash facing the outside of the building receiving the window unit. The frame mount and sash mount abut when the window unit is in a closed position and when pressure is applied to the sash window.
The above-described embodiments of the present invention are intended to be examples only. Alterations, modifications and variations may be effected to the particular embodiments by those of skill in the art without departing from the scope of the invention, which is defined solely by the claims appended hereto.
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20050166496 | Farag | Aug 2005 | A1 |
Number | Date | Country | |
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20080005972 A1 | Jan 2008 | US |