The invention pertains to a latch mechanism adapted for use in a sash window assembly. More specifically, the invention pertains to a latch mechanism having at least one sidewall which extends down from the top of the top rail of the window sash along a portion of the external surface of a corresponding one of the front facing and the back facing of the top rail.
Tiltable window assemblies have previously incorporated tilt latches at the end of the window sash opposite the pivot bar of the tilt mechanism. The previous latch mechanisms have generally provided additional mechanical support for maintaining the window sash in a non-tilted position, so as to be oriented in a plane which enables a direction of travel of the window sash within the window frame.
Prior tilt latches have included a bolt, which travels within a latch housing, and which selectively engages the side jamb of the window frame. The bolts generally have an angled surface at the end of the bolt and on the side of the bolt, that engages the side jamb. When the angled surface of the bolt engages the side jamb as the window sash moves from a tilted position to a non-tilted position, the angled surface of the bolt causes the bolt to at least momentarily deflect inward until it clears the obstructing portion of the side jamb.
The other side of the end of the bolt that engages the side jamb as the window sash moves from a non-tilted position to a tilted position, is generally perpendicular to the direction of tilting movement. The generally perpendicular side of the bolt, when it engages the obstructing portion of the side jamb does not deflect the bolt, but engages the side jamb and resists movement toward a tilted position. Generally the sash is rotationally locked in a non-tilted position within the window frame until the end of the bolt of the tilt latch, which is generally biased toward engagement, is manually retracted and released from the side jamb. An early example of such a tilt latch is described in Menns, U.S. Pat. No. 1,862,757.
Window can be subjected to extreme weather conditions, where the required response to the extreme weather conditions are often dictated by building codes. Trends in building codes have increasingly required that the window assemblies be able to survive increasingly extreme weather conditions. One such example includes high winds or large pressure differentials between indoor and outdoor pressures, which can be associated with tornadoes and/or hurricanes. Windows may also be expected to survive an impact from one or more types of flying debris. Examples of different types of materials used to simulate flying debris includes two-by-four pieces of wood and ball bearings to simulate small rocks and/or hail.
Historically, accepted wisdom suggested that one should open the window slightly during a tornado or a hurricane, so as to provide an air path via which the air pressure on the interior side of the window can more easily be equated to the air pressure on the external side of the window. However, more recently, the generally accepted wisdom has changed to suggest, that one should maintain the window in a closed position. This is because storms, which have high winds, like hurricanes, are often accompanied by rain. By opening the window during such a storm, one may be subjecting the interior of the building to potential water damage, where any pressure equalizing effects are now viewed as having only a marginal effect. Additionally, opening the window slightly may affect the structural integrity of the window by disengaging elements, which would otherwise overlap and/or be locked together.
As the building code requirements become increasingly stringent, the building techniques and the components used in the construction of a window assembly need to keep pace or stay ahead of the stricter standards, in order to be able to sell into the markets covered by the building codes. Consequently, there is a need to develop building techniques and/or better components and incorporate them into the window assemblies, in order to enhance the integrity of the window, and allow it to withstand greater and greater harmful forces, as required by the building codes.
Many currently used window assemblies include plastic extruded jamb liners, which can deflect when under relatively high levels of stress. Similarly, the top and bottom rails, as well as the stiles of the window sash for many window assemblies are also made from extruded plastic components, which are then welded together at the joints. The plastic extruded top and bottom rails can similarly bow and/or deflect, when significant external forces are applied.
As the window sash bows and/or deflects, the ends of the top and bottom rails can be deflected away from the side jamb toward the center of the window assembly. This in turn can pull the attached tilt latch assemblies away from and out of engagement with the side jamb. As a result, the tilt latch assemblies may no longer prevent the tilt motion of the window sash. Additionally the tilt latch assemblies may no longer anchor the non-pivot point side of the window sash within the window frame. This then becomes a weak point in the window construction, and a likely point for failure, when extreme forces are applied.
Still further, the flexing of the window assemblies, as a result of and in addition to the high wind forces, can sometimes cause the mounted window hardware to shear away, thereby further affecting the continued integrity of the window assembly. Consequently, it would be beneficial to develop a tilt-latch, which resists becoming detached or torn away from the window sash, and which adds additional support to the window assembly when the window assembly is subjected to higher levels of stress.
A latch mechanism adapted for being coupled to a window sash, which travels within a window frame, is provided which includes a main housing having a sidewall including one or more sidewall sections. The sidewall including one or more sidewall sections extends around at least a portion of the housing and defines an interior space and includes an opening in said sidewall at one end of said housing. The sidewall further defines a channel within the interior space of the main housing, which has an end that coincides with said opening. At least one of the sidewall sections which is substantially parallel to the direction of travel of the bolt is adapted to extend down from the top of the top rail of the window sash along at least a portion of the external surface of a corresponding one of the front facing and the back facing of the top rail.
The latch mechanism further includes a bolt, which is substantially located within said housing and travels along said channel. The bolt has a first end which is adapted for extending through the opening of said housing and extending into the side jamb of the window frame. The latch mechanism still further includes a tension device coupled to the bolt and the main housing for biasing the bolt toward a position where the bolt extends at least partially through the opening.
In at least one embodiment of the invention, at least a second one of the sidewall sections of the main housing, which is substantially parallel to the direction of travel of the bolt, extends down from the top of the top rail of the window sash along the external surface of at least a portion of the other one of the front facing and the back facing of the top rail.
In at least a further embodiment, the interlock element extends down further from the top of the top rail of the window sash along at least a portion of the external surface of one of the front facing and the back facing of the top rail a distance away from the one of the front facing and the back facing. The distance between the interlock element and the one of the front facing and the back facing provides for a space, therebetween, within which at least a part of the sash interlock associated with the bottom rail of the top sash will occupy, when the interlock element of the latch mechanism is engaged with the sash interlock.
In a still further embodiment, the interlock element extends from the at least one sidewall section initially in an upward direction before further extending in a downward direction a distance away from the one of the front facing and the back facing.
In yet a still further embodiment, one or more of the latch mechanisms are incorporated as part of a window assembly including a top sash and a bottom sash.
A further aspect of the present invention, a sash interlock is provided, which is adapted to be coupled to a bottom rail of a top sash of a window assembly including a top sash and a bottom sash. The sash interlock is further adapted to engage an interlock element of a latch mechanism coupled to the top rail of the bottom sash. The sash interlock includes a substantially vertically extending ridge, which is adapted to selectively engage the latch mechanism by entering the space formed between the interlock element of the latch mechanism and the corresponding one of the front facing and the back facing of the top rail of the bottom sash when the bottom sash moves within the window assembly towards a closed position.
Numerous other advantages and features of the present invention will become readily apparent from the following detailed description of the invention and the embodiments thereof, from the claims and from the accompanying drawings.
While the present invention is susceptible of embodiment in many different forms, there are shown in the drawings and will be described herein in detail specific embodiments thereof with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the invention to the specific embodiments illustrated.
Referring now to the drawings in greater detail, there is illustrated in
The window sashes 12, 14 are coupled to their corresponding window sash balance shoes via a pivot bar, which is attached to the bottom of the window sashes 12, 14. The pivot bar allows the window sash 12, 14 to pivot between a vertical and a horizontal position as shown in
In the illustrated embodiment, each window sash includes a top rail 22, a bottom rail 24, and a pair of side stiles 26. In at least the illustrated embodiment, a pair of latch mechanisms are coupled to the top rail of at least the bottom sash.
The tilt latch mechanism 20 further includes a bolt 42 (
The first end 44 of the bolt 42 has an angled surface 48 on the side of the bolt 42 which, when extended, contacts the side jamb 16, when the window sash 14 moves from a tilted position to a non-tilted position. In the embodiment illustrated in
The angled surface 48, when it contacts the side jamb 16 will bias the end 44 of the bolt 42 into the main housing 28, against a force exerted by a tension device 50 (
The manual release of the tilt latch mechanism 20 is facilitated by a finger contact 56 of the bolt 42, which extends through an opening 58 in the top surface 30 of the main housing 28. By engaging the finger contact 56, a user can bias the bolt 42 in a direction which is counter to the force applied by the tension device 50. The bolt further includes a tab 60 (
In the illustrated embodiment, the latch mechanism 20 is coupled to the top rail 22 of the sash 14 via one or more fasteners 64 (
The latch mechanism, further includes at least a portion of at least one of the sidewall sections 32 and 36, which is substantially parallel to the direction of travel of the bolt 42, that is adapted to extend down from the top 76 of the top rail 22 of the window sash along at least a portion of the external surface of a corresponding one of the front facing 74 and the back facing 80 of the top rail 22. In the embodiment illustrated in
The portion of the at least one of the sidewall section, which extends down from the top 76 of the top rail 22 of the window sash 14 provides additional lateral support, in maintaining a connection between the tilt latch mechanism 20 and the window sash 14. Additionally, the extended sidewall section helps to maintain the integrity of the overall structure. This allows greater forces in the form of positive and negative wind pressure 86 to be applied to the window sash without disengaging the tilt latch mechanism 20 from the window sash 14.
In the embodiment illustrated in
The dashed lines in
Similar to the tilt latch mechanism 100, the sash interlock 112 can be coupled to the bottom rail of the top sash via one or more fasteners, such as a screw, extending through corresponding mounting holes 114 in the sash interlock 112. Alternatively other forms of fasteners could similarly be used without departing from the teachings of the present invention.
Highlighting on at least one further difference in the alternative embodiment,
From the foregoing, it will be observed that numerous variations and modifications may be effected without departing from the spirit and scope of the invention. It is to be understood that no limitation with respect to the specific apparatus illustrated herein is intended or should be inferred. It is, of course, intended to cover by the appended claims all such modifications as fall within the scope of the claims.