This invention relates to an improved frame assembly for windows.
A common style of window construction has a first framed pane of glass (the sash) mounted within a larger frame (herein referred to for convenience as the master frame) in such a way that the sash is slidable between open and closed positions within the master frame. Typically, adjacent horizontal members of the sash frame and master frame are provided with slidably engaging tongue-and-groove style projections and recesses to define and support the sliding movement of the sash within the master frame. By adjusting the dimensions of the sash frame and master frame, this construction can also be used to provide doors, such as sliding patio doors.
A known technique for constructing frame assemblies for windows or doors is to extrude sections of aluminum or vinyl having a desired cross-sectional profile for the various vertical and horizontal members of the frames. The extrusions are then cut to length, and then assembled to form a separate master frame and sash frame. An example of known extrusion profiles for constructing window frames can be seen in U.S. Pat. No. 4,621,478 (Phillips et al.).
Another frame construction for a sliding window is disclosed in U.S. patent application Ser. No. 09/735,498, having Publication No. US 2002/0124494 (Zen). This frame construction has a two-piece master frame, between which a sash frame is sandwiched. The sash comprises two injection molded halves which are secured together with fasteners. The assembled sash is positioned between two halves of the master frame, each of which are also separate, injection molded elements, secured together with fasteners.
The construction techniques described above can be relatively time-consuming and costly. Also, if the assembly is improperly performed, problems with the function or appearance of the product may result. Accordingly, it may be advantageous to provide a frame assembly for a window or door wherein the master frame and sash frame are each integrally molded, one-piece structures.
The present invention provides a frame assembly for a sliding window or patio door, in which the frame assembly includes an integrally moulded unitary master frame having upper and lower horizontal members, and opposed first and second vertical jamb members extending between the horizontal members. An integrally moulded unitary sash frame is slidably mounted within the master frame.
In one embodiment, the frame assembly includes a mullion integrally moulded with the master frame, the mullion extending contiguously from, and vertically between, the upper and lower horizontal members, at a position between the first and second vertical jamb members. The master frame and the sash frame have inter-engaging channels and projections for supporting the sash frame within the master frame. The projections and channels are integrally moulded with the respective sash frame and master frame. More particularly, the upper and lower horizontal members of the master frame are provided with vertically projecting tongues, and the upper and lower horizontal members of the sash frame are provided with grooves shaped to receive the tongues in sliding engagement.
The present invention also provides an injection moulded frame assembly for a sliding window or door that is reversible. The frame assembly has a master frame and sash frame slidably supported within the master frame. At least the master frame can be installed in either one of a first position or a second position that is generally inverted (rotated 180 degrees in a vertical place) relative to the first position. In another embodiment, both the master frame and sash frame are inverted to provide the first and second positions. An interlacing configuration can be provided on two opposite horizontal or vertical frame elements to provide a gap between the sash frame and master frame for installation and removal of the sash frame within the master frame. Duplicate attachment elements can be provided for attaching gliders or other space-taking support elements for selectively filling the gap along one of the opposing frame elements.
In another aspect of the invention, a frame assembly for a window or patio door is provided with a weather buffering chamber across one or more flow paths between interior and exterior sides of the frame assembly and through which water or air may try to penetrate from the exterior to the interior side of the assembly. The weather buffering chamber can have an exterior seal with a first pressure gradient, and an interior seal with a second pressure gradient, the first and second pressure gradients being portions of the total pressure gradient across the two sides or faces of the assembly. The weather buffering chamber can be independently drained relative to any drains for water that may penetrate to the interior face of the assembly.
In another aspect of the invention, a sealed valve element is provided for draining water that may have penetrated to the interior face of the assembly. The sealed valve element can inhibit the suction of air from the exterior face to the interior face of the assembly.
In another aspect, the present invention provides a frame assembly for a window or door that has integrally moulded attachment elements for attaching gliders, locks, handles, seal elements including weatherstripping, in press fit or snap fit arrangements. A break-away panel can be provided to seal off duplicate attachment elements that may be provided for a reversible frame assembly.
In another aspect, the present invention provides a frame assembly for a window having a sash that slides vertically within a master frame. The master frame is substantially of unitary, one-piece construction that can advantageously be manufactured by an injection moulding process. The sash frame can also be of unitary, one-piece construction, and can also be manufactured by injection moulding. The master frame can be provided with liner support structures along the jambs to receive jamb liners in shamp fit. The liner support structures can advantageously be integrally moulded with the master frame.
For a better understanding of the present invention and to show more clearly how it would be carried into effect, reference will now be made by way of example, to the accompanying drawings that show a preferred embodiment of the present invention, and in which:
a is an enlarged view of a portion of the frame assembly shown in
b is an enlarged view of another portion of the frame assembly shown in
a is an enlarged portion of the frame assembly shown in
a, 9b, and 9c are vertical section views of the frame assembly of
a is an enlarged view of the check rail shown in
b shows an alternate embodiment of the check rail of
a is a front exterior view of a modified, reversible assembly in accordance with another embodiment of the present invention;
b is a front exterior view of the frame assembly of
a, 16b, and 16c are perspective views of alternate embodiments of gliders provided in the sash frame of
a is an enlarged end view of a carrier strip portion shown in
b is a perspective view of a lower portion of the sash frame shown in
c is a front sectional view of the portion of the sash shown in
a is an enlarged view of a portion of the frame assembly shown in
b is an enlarged view of another portion of the frame assembly shown in
c is a sectional view of the assembly of
a is an enlarged portion of the frame assembly shown in
b is a sectional view of a portion of the frame assembly shown in
c is a perspective view of sectioned portion of the portion of the frame assembly shown in
a, 25b, and 25c are vertical section views of the frame assembly of
a, 26b, 27a, 27b, 28a, and 28b are horizontal section views of the frame assembly shown in
a is a perspective view of the sectioned portion of the frame assembly shown in
a is an enlarged view of a portion of
A frame assembly for a window or door according to the present invention is shown generally at 110 in
The master frame 112 is generally rectangular, having upper and lower horizontal members 116 and 118, respectively. Vertical side members 120a and 122a extend between the upper and lower horizontal members 116 and 118, at either side of the master frame 112. The upper and lower horizontal members of the master frame 112 are commonly referred to as the header 116 and sill 118, respectively.
Aspects of the present invention generally provide a frame assembly having a slidable sash mounted in a master frame. Embodiments of the invention can provide horizontally or vertically slidable sash frames within respective master frames. For the purposes of illustration, in the embodiment illustrated in
The sash frame 114 is slidable within the master frame 112 between fully open and fully closed positions. In the fully open position, the vertical member 136 of the sash frame 114 is generally positioned behind the mullion 124, and the check rail 138 generally abuts (or nearly abuts) the fixed side jamb 122. In the fully closed position (
In the frame assembly 110, glazing 130 can be set directly into the fixed side 128 of the master frame 112. A screen element 129 can be provided in the vent side 126 of the master frame 112. Details of how the glazing 130 and screen element 129 may be mounted in the frame assembly 110 are provided hereinafter.
The frame assembly 110 has an exterior face 121 which would typically be exposed to the elements, and an interior face 123 opposite the exterior face 121. The glazing 130 and screen element 129 are positioned towards the exterior face 121 of the frame assembly 110, and the sash frame 114 is mounted interiorly of the glazing 130 and screen 129.
The master frame 112 of the frame assembly 110 is of one-piece, integrally moulded construction, devoid of any seams or joint lines between contiguous vertical and horizontal members 116, 118, 120, 122, and 124. In the embodiment illustrated, the members of the master frame 112 are advantageously provided with geometrical configurations which can facilitate manufacturing the master frame by a moulding process, such as, for example, but not limited to, injection moulding. More particularly, the geometrical configurations of the vertical and horizontal members of the master frame 112 have, in cross-section, a generally uniform wall thickness, and an orientation which permits ejection of the master frame 112 from a mould. The master frame 112 can be constructed of a suitable plastic material.
Referring to
Front views of the exterior face 121 of the frame assembly 110 can be seen in
As best seen in
As best seen in
Referring to
The groove 142 of the lower horizontal member 134 of the sash frame 114 is disposed between interior and exterior sidewall portions 154 and 156 of the lower horizontal member 134 of the sash frame 114. The sidewall portions 154 and 156 extend downward past the nub 152 and weather-stripping 148, respectively, to support the sash 114 above the sill 118 in a lateral direction.
A glider 157, comprising a glider housing 158 and gliding element 160, is provided within the groove 142 at either end of the lower horizontal member 134 (see also
Referring to
As seen in
As well, the integrally moulded glazing support features can include an attachment recess 166 provided opposite the glazing support surface 164 and directed towards the exterior face 121 of the frame assembly 110. The attachment recess 166 is shaped to receive a length of glass stop 168, which bears against an exterior surface of the glazing 131. Further details of the glazing support features 161 are described hereinafter.
In the first portion 118a of the sill 118, screen-mounting details 170a can also be provided. In the embodiment illustrated, the screen mounting details 170a include a screen support step 170, providing in a generally vertical plane an abutment surface 171 against which the frame 174 of a screen 129 can be positioned. The screen mounting details 17a further include horizontal support surfaces 172 provided adjacent the vertical face 171, to support the screen 129 vertically.
Referring again to
The upper horizontal member 132 of the sash frame 114 is provided with a channel or groove 186 which is directed upwardly and extends between generally vertical interior and exterior sidewall portions 188, 190, respectively, of the upper horizontal member 132. The interior sidewall portion 188 extends upwardly beyond the nub 152 of the tongue 180, and the exterior sidewall portion 190 extends upwardly beyond the strip mount 146 and the weather-stripping 148. Accordingly, the sidewalls 188, 190 of the groove straddle the horizontally outermost elements 152, 148, respectively, of the tongue 180, thereby providing lateral support for the sash frame 114.
Furthermore, the upper horizontal member 132 of the sash frame 114 can be advantageously provided with glazing support features 161 to support glazing 131 set within the sash frame 114. This includes the backstop surface 162, planar support surface 164, attachment recess 166, and glass stop 168, similar to those provided for the lower horizontal member 134.
Referring to
Towards the exterior face 121 of the frame assembly 110, the sill second portion 118b of the sill 118 is provided with integrally moulded glazing support features 161. The support features 161 again include the back stop surface 162, planar support surface 164, and attachment recess 166 for receiving a length of glass stop 168.
The second portion 116b of the header 116 includes the tongue 180, projecting downwardly from the header 116. The strip mount 146 and the weather-stripping 148 are generally not required along the header second portion 116b, and can be replaced by a second nub 152, extending towards the exterior face 121. The opposed nubs 152 are positioned between the interior and exterior sidewall portions 188 and 190 of the upper horizontal member 132 of the sash frame 114, providing lateral support for the sash frame 114.
Above the sidewall portions 188 and 190 of the horizontal member 132, and extending outwardly from the tongue 180, are interior and exterior shoulders 196, 198, respectively. The shoulders 196, 198 prevent the sash frame 114 from being lifted up, thereby ensuring that the groove 142 of the lower horizontal member 134 of the sash frame 114 remains properly engaged with the tongue 140 of the sill 118. Further details concerning lift-up of the sash frame 114 will be provided hereinafter.
Adjacent the exterior shoulder 198 and towards the exterior face 121, the header second portion 116b is provided with glazing support details 161 for supporting the fixed glazing 130. The glazing support details 161 again comprise the backstop surface 162, planar support surface 164, and the attachment recess 166 for receiving a length of glass stop 168.
Referring again to
To provide the vertical clearance 200, in the illustrated embodiment of the frame assembly 110 the profile of the header 116 of the master frame 112 has a sash frame interlacing configuration 202 along at least a portion of the length of the header 116. The sash frame interlacing configuration 202 has a longitudinal extent along the length of the header 116 that is at least as long as the length of the upper horizontal member of the sash frame 114. The sash frame interlacing configuration 202 comprises channels and projections in the header 116 that match with corresponding projections and channels in the upper horizontal member 132 of the sash frame 114 to laterally support the sash frame 114 slidably within the master frame 112, while also providing the vertical clearance 200 for lift-out of the sash frame 114.
In the embodiment illustrated, the sash frame interlacing configuration 202 of the header 116, includes the tongue 180 having downwardly projecting exterior and interior sidewalls 181, 183, respectively, which are spaced sufficiently narrowly apart to fit within the sidewalls 188, 190 of the groove 186. No shoulders or other surfaces extend outward from the tongue sidewalls 181, 183 to interfere with lift-up of the upper edges of the groove sidewalls 188, 190. Furthermore, the extent to which the tongue 180 projects vertically from the header 116 is sufficiently short to fit substantially within the hollow depth of the groove 186.
The sash frame interlacing configuration 202 need not be provided along the entire length of the header 116, but may advantageously be provided along only a portion thereof. In the embodiment illustrated, the sash frame interlacing configuration 202 is provided along only a portion of the header 116 that extends a length which is just slightly longer than the length of the upper horizontal member 132 of the sash frame 114. The portion of the header 116 along which the sash frame interlacing configuration 202 (and hence, vertical clearance 200) is provided defines a lift position 204 (see
To extend the sash frame interlacing configuration 202 behind the mullion 124, a recess or cavity 205 can be provided in the header 116 between the mullion 124 and the tongue 180 (
Between the second end 203b of the sash frame interlacing configuration 202 and the fixed side jamb 122 of the master frame 112, the header 116 is generally provided with the header profile 116b (as best seen in
Between the first end 203a of the sash frame interlacing configuration 202 and the vent side jamb 120 of the master frame 112, integrally moulded interior and exterior shoulders 206, 208 can be provided (as best seen in
In use, to install the sash frame 114 in the master frame 112, the sash frame 114 is positioned adjacent the interior surface 123 of the frame assembly 110, and the upper horizontal member 132 of the sash frame 114 is aligned with the lift position 204, between the ends 203a and 203b of the interlacing configuration 202. The lower horizontal member 134 of the sash frame 114 is tilted away from the master frame 112, and the groove 186 can then be aligned with the tongue 180 of the header 116 (
The sash frame 114 can then be lifted up, so that the vertical clearance 200 is occupied by the various elements of the tongue 180 and groove 186, and the lower horizontal member 134 of the sash frame 114 may then be swung over the tongue 140 of the sill 118, so that the groove 142 of the lower horizontal member 134 is aligned with the tongue 140 (
The sash frame 114 may then be lowered, until the glider 157 engages the runner 144 of the tongue 140 (
Removal of the sash frame 114 from the master frame 112 is substantially the reverse operation. It will be understood that, to initiate the procedure, the sash frame 114 must first be aligned with the lift position 204, between the ends 203a and 203b of the interlacing configuration 202.
Additional members of the master frame 112 and sash frame 114 will now be described. Referring to
Between the tongue 210 and the exterior face 121 of the frame assembly 110, the vent side jam 120 may advantageously be provided with screen support details 169. In the embodiment illustrated, a step is positioned along the profile 120, providing a vertical surface 216 against which the frame 174 of a screen element 129 can bear. Furthermore, an aperture 218 is provided adjacent the step, for receiving a plunger or clip for retaining the screen 129 in the master frame 112.
Opposite the groove 212, the vertical member 136 of the sash frame 114 may be advantageously provided with integrally moulded glazing support features 161, for supporting the sash glazing 131. In the embodiment illustrated, the glazing support details 161 comprise the back stop surface 162, planar support surface 164, and the attachment recess 166 for receiving a length of glass stop 168.
The cross-sectional profiles of the mullion 124 and check rail 138 can best be seen in
Also adjacent the front face 121 of the frame assembly 110, but directed towards the fixed side 128 of the master frame 112, the mullion 124 may be provided with integrally moulded glazing support features 161 for supporting the fixed glazing 130. The glazing support features 161 comprise the back stop surface 162, planar support surface 164, and the attachment recess 166 for receiving a length of glass stop 168 (not illustrated).
The mullion 124 further comprises an engagement flange 226. The engagement flange 226 extends from the mullion 124 opposite the back stop surface 162, and parallel to the direction along which the sash frame 114 can slide within the master frame 112.
A reinforcement recess 228 may optionally be provided in the mullion 124, for receiving metal reinforcement bars 229 or the like, which may be desired to limit the maximum deflection of the mullion 124. In the embodiment illustrated, a reinforcement recess 228 is provided in the mullion 124, opposite the attachment recess 166.
The cross-sectional profile of the check rail 138 of the sash frame 114 can also best be seen in
A return bracket 234 extends from the seal surface 230 so as to engage the engagement flange 226 of the mullion 124. In particular, in the embodiment illustrated, the return bracket 234 has an offset portion 236 which extends from the seal surface 230 in a direction towards the exterior face 121 of the frame assembly 110, and at a position spaced slightly away from the terminal vertical edge 227 of the engagement flange 226 when the sash frame 114 is in the closed position. A catch portion 238 extends from the offset portion 236 in a direction towards the mullion 124, and, for the embodiment illustrated, in generally parallel alignment with the engagement flange 226.
Accordingly, when the sash 114 is in the closed position, the return bracket 234 provides a mechanical coupling between the check rail 138 and the mullion 124 in a direction perpendicular to the sliding operation of the sash frame 114. Forces such as, for example, wind loads that may tend to push the sash frame 114 laterally towards the interior face 123 of the assembly 110 are counteracted by the overlap of the catch portion 238 of the check rail 138 and the engagement flange 226 of the mullion 124. The overlap can increase the lateral stability of the sash frame 114 within the master frame 112, and can ensure that the weather-stripping provided in the check rail 138 remains satisfactorily engaged with the engagement flange 226 of the mullion 124.
To facilitate the integral injection moulding of the return bracket 234 of the check rail 138 when moulding the sash frame 114, the offest and catch portions 236, 238 of the return bracket 234 may advantageously be provided in a staggered arrangement. Such an arrangement can facilitate moulding by reducing the requirements for additional slides in the die, and can improve the flow characteristics of the plastic when filling the mould by reducing the overall die cavity volume.
The portion of the check rail 138 facing the opposite vertical member 136 of the sash frame 114 may be provided with integrally moulded glazing support details 161 for supporting the sash glazing 131. The glazing support details 161 comprise the backstop surface 162, planar support surface 164, and the attachment recess 166 for receiving a length of glass stop 168.
As best seen in
As best seen in
The cross-sectional profile of the fixed side jam 122 of the master frame 112 can be best seen in
In accordance with the present invention, the frame assembly 110 may also be provided in a modified form, referred to as a reversible frame assembly 110′. The reversible frame assembly 110′ is similar to the frame assembly 110, but is configured to be selectably installed in either a slide-right or slide-left configuration for opening the window, as best seen in
The reversible frame assembly 110′ has a modified master frame 112′ and a modified sash frame 114′. The modified master frame 112 has a modified sill 118′ which is substantially a mirror image of the header 116. In particular, the sill 118′ is provided with the same interlacing configuration 202 as provided in the header 116, thereby defining a second lift position 204′ along the adjacent horizontal elements 118′ and 134′ of the master frame 112′ and sash frame 114′, respectively.
Details of the modified sill 118′ and horizontal member 134′ of the modified frame 110′ can best be seen in
Referring again to
To account for the vertical clearance 200′ provided by the interlacing configuration 202′ of the modified lower horizontal member 134′, a modified glider 157′ is provided within the groove 140′ of the horizontal member 134′ to operably support the sash frame 114′ above the sill 118′ of the master frame 112′. The modified glider 157′ includes the glider housing 158 and a modified glider element 160′. The modified glider element 160′ has a greater vertical height than the glider element 160, to compensate for the increased depth of the groove 142′ provided in the lower horizontal member 135′, as compared to the groove 142 provided in the lower horizontal member 134 (FIG. 5). When installed, the glider 157′ engages the runner 144 of the tongue 140′, and thereby supports the sash frame 114′ above the sill 118′.
When the reversible frame 110′ is installed as shown in
Referring now to
Furthermore, the glazing support features 161 include elongate recesses 166 extending generally parallel to and adjacent to the planar surfaces 164. The recesses 166 are shaped to receive a length of glass stop 168 (
Once the length of glass stop 168 has been inserted, the glazing is securely fixed in the master frame 112 or sash frame 114 by being squeezed between the backstop surface 162 of the respective frame, and an opposed contact surface 248 provided on the length of glass stop 168. Furthermore, the glazing is constrained from moving in a direction parallel to the glazing by the setting blocks 242. It is again noted that according to the present invention, the backstop surface 162, planar support surface 164, recesses 166, setting block housing 240, and the recesses 246, can be advantageously integrally moulded with the respective frame elements 112 and 114.
An alternate embodiment of a frame assembly 310 according to the present invention can be seen in
Referring to
The members of the master frame 312 are shaped and sized to facilitate manufacturing the master frame 312 by a moulding process, such as, for example, injection moulding. The master frame 312 can be constructed of a suitable plastic material, such as polypropylene or a recycled plastics material.
The sash 314 is similarly of one piece, integrally moulded construction, having contiguous horizontal and vertical members 332, 334, 336, and 338. The sash 314 can be constructed of the same material as the master frame 312.
In the embodiment illustrated, the frame assembly 310 is reversible, similar to the frame assembly 110′. In other words, the frame assembly 310 can provide a sliding window or door with the fixed side 328 on either the left or the right side when looking at the exterior face 321. In the embodiment illustrated, the fixed side 328 is on the right side of the frame assembly 310 when viewed from the exterior.
Referring to
As best seen in
Details of the carrier strips 502 and their attachment to the tongues 340, 380, 440 will be described by way of example with respect to the strip 502 mounted to the tongue 340 and referring to
The carrier strip 502 is adapted to support weatherstripping 348 that extends along the length of the carrier strip 502, providing a seal between the tongue 340 and the lower horizontal member 334 (Shown in
To install the carrier strip 502 onto the tongue 340, the support legs 506 can be pressed over the tabs 510 so that the clips 508 are spread apart and then snap back into place as the clips 508 are pressed past the tabs 510. The carrier strip can be constructed of a durable plastic material and can be manufactured by an extrusion process. The carrier strips 502 can be provided with rubber-like fins 514 extending downward from the ends of the support legs 506. The fins 514 can provide a seal between the tongue 340 and the strips 502, and can be coextruded with the strips 502. The seal provided by the fins 514 can inhibit penetration of weather elements underneath the carrier strips 502, so working their way from the exterior face 321 of the assembly 310 to the interior face 323
In use, the orthogonal portion 504a of the facing surface 504 of the strip 502 attached to the tongue 340 provides the runner 344 against which the roller/glider 357 of the sash 314 can bear (
Referring again to
Any water that does make its way past the skirt 522 and exterior weatherstripping 348 is channeled to remain on the exterior side of the sash glazing 331, within the groove 386. In particular, the upper horizontal member 332 of the sash 314 has a protruding dam 526 that extends along the inside lower surface of the groove 386, and forms a drainage channel 527 between the dam 526 and the exterior sidewall 383 of the tongue 380. The channel 527 is positioned laterally between the exterior weatherstripping 348 and the position of the glazing 331. Water that does pass the weatherstripping 348 into the groove 386 is conveyed along the channel 527 to the vertical members 336 and 338 of the sash 314, where it is again channeled along the exterior side of the glazing 331. The water is then directed onto the inclined portion 504b of the carrier strip 502 on the tongue 340, and drains towards the exterior facing surfaces of the sill 318. The water may temporarily rest on top of the exterior weatherstripping 348b, but generally eventually works it sway through the piles of the weatherstripping and drains down the exterior sloped portion of the sill 318. Between the tongue 340 and the exterior edge of the sill 318, an attachment recess 520′ can be provided, to receive the skirt 522 when the frame assembly 310 is in the inverted position, for reversing the vent and fixed sides 326, 328, respectively.
The inventors have found that in some cases, water that penetrates the exterior weatherstripping 348 along the tongue 380 could migrate, by capillary action, across the facing surface 504 of the carrier strip 502. Such water could thereby cross from the exterior side to the interior side of the glazing, and pose a risk of water intrusion. To eliminate such water migration, the carrier strip 502 is provided with a drip groove 528 positioned laterally between the exterior weather stripping 348 and the drainage channel 526. Any water traveling across the surface 504 beads up and falls down upon encountering the groove 528, landing in the channel 527. The drip groove 528 can also be seen in
Referring now to
The portions 530a and 530b are laterally adjacent each other, as best seen in
As best seen in
The glazing support details 361 of the frame assembly 310 will now be described referring to
Referring now to
As best seen in
Between the second end 403b of the lift position 404 and the fixed side jamb 322 of the master frame 312, the header 316 is generally provided with the second header portion profile 316b. The second portion 316b includes the exterior shoulder 398 above the exterior sidewall 390 of the groove 386 of the upper horizontal member 332 (see
Referring now to
As best seen in
Referring now to
Referring now to
The inventors have observed that one pathway along which air and water can be drawn through the frame assembly is between the mullion 324 and the sash checkrail 338. This pathway can be seen at arrows 448 in
The first strip of weatherstripping 552a extends along the height of the mullion 324, adjacent an edge of the mullion 324 near the vent side 326 of the frame assembly 310. The second strip of weatherstripping 552b extends generally parallel to the first strip, but is positioned nearer to the fixed side 328 of the frame assembly 310. In the embodiment illustrated, the strips of weatherstripping 552a and 552b can be press-fit into corresponding attachment slots 554a and 554b that extend along the height of the mullion 324. The slots 554a and 554b can be integrally moulded with the master frame 312. The space between the weatherstripping 552a and 552b, and between the mullion 324 and the checkrail 338 generally defines the weather buffering chamber 550.
The first strip of weatherstripping 552a has its upstream side (relative to the flow path 448) exposed directly to the exterior elements. The downstream side of the first strip 552a is exposed to the weather buffering chamber 550. The strip 552a acts as an exterior seal, serving as an initial wind and rain barrier, through which some penetration of wind or water can be tolerated. The first strip (exterior seal) 552a can be constructed of, for example, but not limited to, densely packed synthetic pile.
Any wind or rain that penetrates the external seal 552a ends up in the weather buffering chamber 550. The invading wind can elevate the air pressure in the chamber 550, so that the pressure is higher than interior conditions but lower than the exterior conditions. To manage the invading water, the chamber 550 can be provided with an exterior drain 555a for draining the invading water from the chamber 550 to the exterior 321 of the frame assembly 310. Further details of the exterior drain 555a are provided hereinafter.
The upstream side (relative to the flow path 448) of the second strip of weatherstripping 552b is not exposed directly to the exterior elements, but rather, is exposed to the weather buffering chamber 550. The downstream side of the second strip 552b is generally exposed to the interior 323 of the frame assembly 310. The second strip 552b acts as an “interior” seal. It is generally undesirable to have significant amounts of wind or water penetrate the interior seal.
In use, the weather buffering chamber 550 reduces the air pressure and amount of water to which the interior seal 552b is exposed. This reduces the amount of air and water that ultimately penetrates from the exterior 321 to the interior 323 of the frame assembly 310. The inventors have found that in one aspect the buffering chamber divides the total pressure gradient across the assembly 310 into a first, exterior gradient across the exterior seal 552a, and a second, interior gradient across the interior seal 552b. By having two separate, discrete pressure gradients across each of the exterior and interior seals 552a, 552b, each of which is lower than the total pressure gradient across the frame assembly 310, the forces tending to draw air and water across these seals are reduced.
The inventors have observed that tuning or balancing the pressure gradients across the seals 552a, 552b can further enhance the overall wind and water resistance of the frame assembly 310. Having a very high pressure drop across one of the seals 552a, 552b relative to the other can reduce the effectiveness of the weather buffering chamber 550.
Referring now to
In the embodiment illustrated, the mullion 324 has a generally hollow mullion cavity 556, which can serve as an air reservoir for supplying air to the chamber 550. The slots 554a, 554b for the seals 552a, 552b can be provided on opposite sides of the mullion cavity 556, so that the cavity 556 is in fluid communication with the chamber 550.
The mullion 324 can have a cover plate 558 that generally covers the cavity 556 and separates the mullion cavity 556 from the weather buffering chamber 550. The cover plate 558 can be assembled by means of a snap fit or press fit between the walls of the cavity 556.
To provide fluid communication between the cavity (or reservoir) 556 and the chamber 550 for venting the chamber 550, the cover plate 558 can have ventilation apertures 560 in the form of notches 561 along one edge. Alternatively, the notches 561 can be positioned along the walls of the mullion 324 adjacent the cover 558, to provide a gap between the mullion 324 and the cover 558. The cover 558 can also have cut-outs 562 at the upper and lower ends of the cover 558. The cut-out 562 at the upper end of the cover 558 can serve as an additional ventilation aperture 560. The cut-out 562 at the lower end of the cover 558 adjacent the sill 318 (see
The mullion cavity 556 can be in fluid communication with the exterior atmosphere by means of external apertures 564 provided in the sidewalls of the mullion 324, on the opposite side of the cover 558 as the chamber 550. In the embodiment illustrated, the external apertures 564 are integrally moulded in the mullion 324 at a position behind the lugs 422 for retaining the window screen 329 (
Details concerning the drainage of any water that may penetrate the exterior and interior seals 552a, 552b will now be described with reference to
The separate drains 555a and 555b can cooperate with, and enhance the function of, the weather buffering chamber 550. For example, the exterior drain 555a and interior drain 555b each drain water between environments having distinct pressure differentials between them. The pressure differential across the drains can be a significant factor in keeping water from penetrating to the interior face 323, since, particularly under high load conditions, the suction effect can draw water in through the drain, rather than discharging water to the exterior.
In the embodiment illustrated, the exterior drain 555a drains water from the weather buffering chamber 550 to the exterior face 321 of the frame assembly 310. The pressure differential across the chamber 550 and the exterior face 321 (and hence across the exterior drain 555a) is generally equal to the exterior pressure gradient across the exterior seal 552a, which is less than the total pressure gradient between the exterior and interior faces 321, 323. The interior drain 555b, however, drains water from the interior face 323 to the exterior face 321 of the frame assembly 310. The pressure differential across the interior drain is therefore equal to the total or maximum air pressure across the exterior and interior faces of the frame assembly 310, which will generally be equal to the sum of the pressure differentials across the exterior seal 552a and the interior seal 552b.
The exterior drain 555a discharges water from the chamber 550 directly to the exterior along the flow path 553a. The reduced pressure differeintial across the exterior drain 555a (i.e. from inlet end to outlet end of the drain 555a) permits direct discharge to the exterior face 321 without significant suction problems than inhibit drainage. The interior drain 555b discharges water from the interior to the exterior via a valve element 557 which is placed between upstream and downstream portions of the flow path 553b. The valve element is movable between an open position 557a, in which the interior and exterior environments are in fluid communication, and a closed position 557b, in which fluid communication through the interior drain 555b is sealed off.
In the embodiment illustrated, to provide the exterior and interior drains 555a and 555b, the inventors have made clever use of the recess 405 that is located in the sill 318. The recess 405 in the sill 318 is the same as the recess 405 in the header 316, and is provided in the sill 318 so that the frame assembly 310 can be inverted to reverse the relative positions of the vent and fixed sides 326 and 328.
The recess 405 in the sill 318 is generally covered by a diverter cap 570 (
The exterior and interior dust plug supports 578a, 578b (and dust plugs 580a, 580b) are spaced apart so that they are generally aligned with the exterior and interior seals 552a and 552b extending along the mullion 324. The supports 578a, 578b and dust plugs 580a, 580b generally fill the width of the recess 405, and form a continuous seal with exterior and interior seals 552a and 552b, respectively. The dust plugs 580a and 580b engage the underside of the sash 314. The supports 578a, 578b resiliently urge the dust plugs upwards into contact with the sash 314.
The space between the exterior and interior supports 578a, 578b and dust plugs 580a, 580b and around the narrow web 576 provides an opening 581, forming part of the exterior drain 555a and through which the flow path 553a extends. The diverter cap 570 further has a seal plate portion 582 (
The diverter cap 570 can be secured in the recess 405 in the sill 318 by means of dual sided adhesive sealant tape 584 provided between the underside of the seal plate portion 582 of the diverter cap 570 and the upper periphery of the primary recess 536 and positioned towards the interior side 323 of the interior dust plug 580b. The interior portion 572 of the diverter cap 570 is supported by a leg 585 extending downward from the exterior dust plug support 578a and generally abutting the first end 542 of the primary recess 536.
As best seen in
Most of the water that makes its way into the buffering chamber 550 will generally be drained through the exterior drain 555a. Accordingly, the pressure differential across the interior seal 502a will generally draw only air to the interior face 323 of the frame assembly 310, rather than water and air. However, under high loads, some water may work its way to the downstream side of the interior seal 502a. Although this may be undesirable, such water penetration is acceptable provided it is contained along the sill 318. Typical rating standards generally require that interior water be contained to the extent that it can eventually drain back to the exterior side 321 of the frame assembly 310. Wind loads are typically cyclical, so that periods of high load and highly increased water penetration are punctuated by periods of lower loads in which little or no water penetrates, and any contained water can drain. Tests to determine window ratings initiate these fluctuations by cycling applied loads between higher and lower pressure ratings.
One method for containing water that penetrates to the interior of a window is to provide the frame with a vertical barrier along the inside of the sill 318, forming a well in which a volume of water can collect or build-up during the higher-load periods. To achieve high ratings, however, such barriers must be of significant size so that a well of sufficient volume is created. Large vertical barriers can increase the raw material cost of the window, and can be unsightly and reduce the proportion of viewing area of the window relative to the frame dimensions. Furthermore, having a substantial pool of water along the interior of a window can be undesirable.
In the present invention, the weather buffering chamber 550 greatly reduces the amount of water that penetrates the interior seal for a given load. Water that does penetrate the interior seal is drained by means of the interior drain 555b. The interior drain 555b comprises the secondary recess 538 in the sill 318, along with an intake channel 586 and an outlet channel 588. The intake channel 586 is provided along the upper surface of the seal plate portion 582 of the diverter cap 570, between upper portions of the vertical sidewalls of the recess 405 that extend along either side of the seal plate portion 582 (
The outlet channel 588, as best seen in
The valve element 557 can comprise a single sealed weep 590 (
Referring now to
The general construction of the window frame assembly 610 with its master frame 612 and sash frame 614 can be seen in
The master frame 612 has an upper horizontal member or header 616, a lower horizontal member or sill 618, and left and right jambs 620 and 622. The master frame 612 also has a mullion 624 that extends in a horizontal direction, parallel to and spaced between the header 616 and sill 618. As seen in
The master frame 612 is of one-piece, integrally moulded construction, devoid of any seams or joint lines between contiguous vertical and horizontal members 616, 618, 620, and 622, and the mullion 624. The members of the master frame 612 are shaped and sized to facilitate manufacturing the master frame 612 by a moulding process, such as, for example, injection moulding. The master frame 612 can be constructed of a suitable plastic material, such as polypropylene or a recycled plastics material.
Referring now also to
As seen in
Referring now also to
As best seen in
In the illustrated embodiment, the liner support features 750 further include a locking tab 758 extending perpendicular to the ribs 754, 756 (protruding laterally inwardly), towards the centerline of the assembly 610. The locking tab 758 need not be continuous along the length of the jamb 620, 622, and can be provided in segments of about, for example, but not limited to, 25 mm segments spaced every 200 mm along the length of the jamb. Providing the locking tab 758 in segmented form can facilitate injection moulding of the tabs 758 with the master frame 612, using slides in the injection moulding die to form the tabs 758.
The jamb liners 752 are, in the embodiment illustrated, elongate members provided along the jambs 620 and 622. The jamb liners 752 can be made of an extruded plastic material. The jamb liners 752 provide a jamb track 760 for slidably supporting the sash 614, as is described in greater detail hereinafter. The jamb liners can also be provided with attachment features for attaching the liners 752 to a respective jamb 620, 622 of the master frame 612.
In the embodiment illustrated, and with reference also to
The attachment features of each jamb liner 752 include a first groove 774 for engaging with the first engagement rib 754, and a second groove 776 for engaging with the second rib 756. The jamb liner 752 is further provided with a resilient claw 778 extending from a side member 766, adjacent the second groove 756. The claw 778 is inclined slightly relative to the base 764, and hence also relative to the first and second ribs 754, 756 when installed on the jambs 620, 622. The claw 778 is flexibly movable between a closed (or engaged) position and an opened (or disengaged) position, and is biased to the closed position (seen in
The jamb liners 752 can further be provided with flexible fins 779 adjacent the grooves 774 and 776. The flexible fins 779 can be adapted to bear against adjacent surfaces of the jamb 620, 622 to seal against passage of air and/or moisture between the jamb liners 752 and the jambs 620, 622.
Referring now also to
The method of supporting the sash frame 614 in the master frame 612 will now be described. Referring to
Furthermore, in the embodiment illustrated, the channel 762 of the track 760 is adapted to slidably support a shoe 786 that can be inserted into an open end of the track 760 prior to installing the jamb liner 752 to the jamb 620, 622 (see
To move the sash frame 614 up and down within the master frame 612, a person can apply a vertical force against the sash frame 614, causing the shoes 786 to slide within the tracks 760 of the jamb liners 752. To facilitate grasping the sash frame 614, the lower horizontal member 634 can be provided with an inwardly directed flange 802 to serve as a handle (
The frame assembly 610 is also provided with features to improve the strength and performance of the assembly 610, particularly when the sash frame 614 is in a completely closed (lowered) position. Referring again to
Furthermore, as best seen in
Referring now to
The barrier wall 808, the opposing surfaces of the inwardly protruding portion of the jamb 620, 622, and the jamb sidewall extending between the barrier wall 808 and inwardly protruding portion cooperate to define a pocket 812 at either end of the sill 618. As best seen in
The abutment surface 810 can, as in the illustrated embodiment, be stepped, having a lower surface 810a and a raised (plateau) surface 810b. This can provide dual seal surfaces (see
While preferred embodiments of the invention have been described herein in detail, it is to be understood that this description is by way of example only, and is not intended to be limiting.
This application claims the benefit under 35 USC 119(e) of U.S. Provisional Application No. 60/610,976, which was filed on Sep. 20, 2004, and the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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60610976 | Sep 2004 | US |