Patent Application
20230295969
Various aspects of this disclosure relate to fenestration products, such as windows. In some specific examples, the disclosure relates to structures for mounting windows, to a frame.
Fenestration units such as hung windows include sashes mounted to a frame. Double-hung windows include two sashes mounted in the frame, each of which is operable for sliding movement (e.g., up and down) between open and closed positions independently of one another. The two sashes are stacked, and typically meet and overlap by a small amount in the middle of the window. Single-hung windows have one fixed or non-operable sash, and one operable or movable sash. The sliding sashes in hung windows may be supported by spring balance systems to counterbalance the weight of the sash. The operable sashes may also be configured to tilt or pivot with respect to the frame, typically inwardly, about a rotational axis at a bottom portion of the sash (e.g., for cleaning).
There remains a need for improved fenestration units. In particular, there is a need for improved structures for attaching sashes to the frames. Such structures that enhance the functionality of the window would be particularly advantageous.
Various aspects of the disclosure relate to a sash carrier, or other barrier or panel carrier, that can be used to slidably mount the barrier or panel to a fenestration unit such as a window. An exemplary sash carrier comprises a body configured for sliding movement on a frame member of the fenestration unit, a sash mount, and one or more balance springs. The body may include a first side to face the frame, and a second side opposite the first side. The sash mount is configured to mount the sash to the second side of the body. The balance springs are on the first side of the body.
In some examples, the sash mount includes a pivot mount to enable the sash to rotate between a tilt closed position and a tilt open position with respect to the body.
Some examples include a brake on the first side of the body. The brake is operable between a release position enabling sliding movement of the sash carrier on the frame member, and a brake position inhibiting sliding movement of the sash carrier on the frame member. In some examples the brake may be operable by the sash mounted to the sash mount. For example, the brake may be configured to be in the release position when the sash is in the tilt closed position, and in the brake position when the sash is in the tilt open position. Embodiments of the brake may include an engagement portion, a biasing member and an actuator portion. The engagement portion may be movable between a retracted position with respect to the body when the brake is in the release position and an extended position with respect to the body when the brake is in the brake position. The biasing member may bias the engagement portion to the retracted position when the sash is in the tilt closed position. The actuator portion may be configured to be actuated by the sash and to move the engagement portion to the extended position when sash is in the tilt open position.
In some examples the body is an elongated extrusion including a component mounting slot on the first side. The component mounting slot may, for example, include a T-shaped opening. The sash carrier may include one or more brake mounting members such as a pin extending from a base, where the base is slid into the mounting slot and secured to the body at a desired position. The sash carrier may include one or more balance spring mounting members such as a pin extending from a base, where the base is slid into the mounting slot and secured to the body at a desired position. The sash carrier may include an end cap. The end cap may include one or more mounting members configured to be secured to the mounting slot.
In some examples the body comprises an elongated extrusion. The extrusion may include a base wall defining the first and second sides of the body, a first side wall extending from the base wall toward the first side and a second side wall extending from the base wall toward the first side. Examples of the extrusion may also include a first lip extending from the first side wall, and a second lip extending from the second side wall The first and second side walls and first and second lips may be configured to engage the frame member and to enable the body to slide in the frame member. The extrusion includes a component mounting slot in some examples.
Examples also include fenestration units such as a window. The window may comprise a frame including first and second opposite side frame members, and at least two sash carriers such as those described above. Each of the sash carriers is mounted for sliding movement to one of the first and second side frame members. A panel such as a window is mounted to the at least two sash carriers.
Examples include a fenestration unit that comprises a frame including a first jamb and a second jamb, a sash including a first side and second side, and first and second sash carriers. Each sash carrier couples one of the first side or the second side of the sash to one of the first jamb or the second jamb of the frame. The first and second sash carriers may include (1) a body comprising a first side coupled for sliding movement on one of the first jamb or the second jamb, wherein the sash carriers facilitate the sliding movement of the sash between a sliding closed position and a sliding open position on the frame, and a second side opposite the first side, (2) a sash mount coupling one of the first side or the second side of the sash to the second side of the body, wherein the sash carriers facilitate rotating movement of the sash between a tilt closed position and a tilt open position with respect to the frame, (3) one or more balance springs coupled to the body, and (4) a brake coupled to the body and operable by the sash between a release position facilitating the sliding movement when the sash is in the tilt closed position and a brake position inhibiting the sliding movement when the sash is in the tilt open position.
Examples include a sash carrier for a fenestration unit. The sash carrier may comprise an elongated body, for example an extrusion, including (1) a first side configured for sliding movement between a sash closed position and a sash open position on a fenestration unit frame and a second side opposite the first side, (2) a sash mount to mount a sash to the second side of the body, and (3) one or more seal members on the body to provide a weather-resistant seal between the body and the fenestration unit frame.
While multiple inventive examples are specifically disclosed, various modifications and combinations of features from those examples will become apparent to those skilled in the art from the following detailed description. Accordingly, the disclosed examples are meant to be regarded as illustrative in nature and not restrictive. For example, although described below as a sash carrier for carrying a window, the sash carrier can be configured to carry other barriers or panels such as screens and sliding door panels (e.g., with the sash carriers configured and mounted to provide horizonal sliding motion of the door panels).
While the disclosure is amenable to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and are described in detail below. The disclosure, however, is not limited to the particular embodiments described. On the contrary, the disclosure is intended to cover all modifications, equivalents, and alternatives falling within the scope of the disclosure as defined by the appended claims.
Sash carriers according to the inventive examples may be adapted for fenestration units including a variety of window and door styles (collectively referred to as “fenestration units”) including one or more sashes, such as for example window panels, that slide between open and closed positions. Examples include hung windows, such as single-hung and double-hung windows. The sash carriers offer important functionality and advantages. In particular, they provide effective and weather-resistant seals, and smooth sliding motion for window opening and closing. The sash carriers may be efficiently manufactured and assembled.
For example, they provide a sliding bearing for sashes in window frames. Sealing materials such as felt strips at the interface between the sash carrier and a window frame jamb provide smooth and low-friction sliding action. The felt or other material bearings may also function as seals with a long leak path. Primary and at least substantial portions of the seal system are thereby pressure energized. The sashes are guided in grooves in the jambs, and dimensions can be controlled. Installation variations may have insubstantial effect on the operation of the sashes. For example, the seal surfaces are generally parallel to the wall in which sash carriers are used, so hourglass or reverse hourglass installation may not substantially affect engagement of the sealing surfaces.
The sash carrier provides functionality to mount as many constant force balance structures such as springs as needed for a given application. The balance mounts provide for operation of the balances with low friction, and enable low hysteresis from the balances. Space for additional balances enables balance selection for a wide range of cycle endurances.
Embodiments include a brake that may be self-energized to prevent upward motion, while allowing downward motion when the sash is tilted. The brakes are disengaged by the sash when the sash closed.
The top of the sash carrier includes features for locking the sash in place, and for unlocking the sash to permit tilting (e.g., for washing and sash removal). A seal may be positioned on the top end of the sash carrier to block vertical air flow past the back side of the sash carrier.
An exemplary fenestration unit in the form of a double-hung window 8 including sash carriers 10A and 10B in accordance with some examples may be described with reference to
Sashes 14A and 14B each include a frame 30 supporting a barrier or panel member such as a glass pane 32. As shown, each frame 30 includes a bottom member 34, a top member 36, a first side member 38, and a second side member 40. The bottom member 34 is a structural frame component that generally defines a bottom portion of the frame 30, while the top member 36 is a structural component that generally defines a top portion of the frame. The bottom member 34 and top member 36 each generally extend laterally between the first and second side members 38 and 40, as shown. The first and second side members 38 and 40 are structural components that extend vertically between the bottom member 34 and top member 36. In various examples, the top member 36 is supported by each of the first and second side members 38 and 40. The first side member 38 generally defines a first side portion of the frame 30, while the second side member 40 is situated opposite the first side member and generally defines a second side portion of the frame 30.
As described in greater detail below, the first side member 38 of sash 14A is mounted to the sash carrier 10A. The second side member 40 of sash 14A is similarly mounted to a sash carrier (not visible in
Seal members 57a and 57b are located on the outer surfaces of the first and second side wall portions 54 and 56, respectively. The seal members 57a and 57b, which may, for example, include felt and/or polymer members, may extend all, substantially all or portions of the length of the side wall portions 54 and 56 of the body 50, and function as bearings and provide sliding seals between the side wall portions and the inside walls of the first jamb 20 defining the channel 41 in which the sash carrier 10A is slidably engaged. Seal members 57a and 57b facilitate smooth, low-friction sliding motion of the sash carrier 10 on the first jamb 20. The exterior seal members 57b may provide weather-resistant (e.g., water-blocking) seals and the interior seal members 57a may provide resistance to air leaks, with long and narrow leak paths. In the case of the exterior seal member 57b, the design ensures that the air pressure on the exterior portion of the seal and the air pressure in the space behind the sash carrier are substantially equalized, thus eliminating the tendency for water to be pushed across that barrier. Water that is stopped at this barrier may drain inconsequentially to the exterior. The interior seal members 57a may be pressure energized, facilitating increased loading on the seal interface with increasing exterior pressure, and resisting air ingress behind the seal. The seal members 57a and 57b may enhance the adaptability of the window 8 to installation variations. The seal surfaces are generally parallel to the wall of the building structure in which the window 8 is installed, so hourglass/reverse hourglass installation (e.g., caused by improper shimming during installation and “bowing” or “reverse bowing” of the window frame) may have no or insubstantial effects on the engagement of the sealing surfaces. In embodiments, for example, the seal members 57a and 57b may accommodate certain degrees of bowing or deflection of the window frame 12 caused by installation, such as for example 0.020 inches, 0.050 inches, 0.100 inches or 0.150 inches lateral deflection of the jambs 20 or 22, while still providing an effective sliding and weather-resistant seal (e.g., with less than 15%, less than 10%, or less than 5% reduction in the seal capability). Conventional or otherwise known ASTM or other test standards may be used to assess performance parameters of these types.
A first mounting structure, shown for example as a first mount track 80, is located on the jamb-facing side of the base wall portion 52. In the illustrated embodiments the first mount track 80 includes structural members defining a generally T-shaped channel. As described in greater detail below, the mounting structure such as first mount track 80 may be used to mount one or more components, including for example components of one or both of the spring mechanism 74 or the brake mechanism 76, to the body 50. Other embodiments include other structures for mounting components such as the spring mechanism 74 and/or brake mechanism 76 to the body 50.
Second and third mounting structures, shown for example as a second mount track 82 and a third mount track 84, are located on the sash-facing side of the base wall portion 52. In the illustrated embodiments, the second mount track 82 and third mount track 84 include structural members defining generally T-shaped channels. Sealing members, such as for example weather strip members 88 and 90, are mounted to mount tracks 82 and 84, respectively. In the illustrated embodiments, the weather strip members 88 and 90 have mounting bases with shapes complementary to the T-shaped channels of the mount tracks 82 and 84, and may be slid into the mount tracks from one of the ends of the mount tracks. Other embodiments may include alternative or additional structures for mounting components such as weather strip members 88 and 90 to the body 50. In the illustrated embodiments, the weather strip member 88 provides a seal between the base wall portion 52 of the body 50 and the first side member 38 of the frame 30 of sash 14A. Weather strip member 90 provides a sliding seal between the body 50 and the first jamb 20 of the window frame 12. Other embodiments include more or fewer weather strip and/or seal members.
Sash mount structure 78 of the sash carrier 10A may be described with reference to
The latch 102 is an arm-shaped member having an end portion pivotally mounted to the second end portion 72 of the sash carrier 10A. The latch 102 extends from the body 50 of the sash carrier 10A in the sash-facing direction, and includes a pin 110 extending from its bottom surface in the illustrated embodiments. As described in greater detail below, the latch 102 is pivotally movable and operable between sash engaging and sash release positions. When in the sash 14A is in the tilt closed position and the latch 102 is in the sash engaging position, the latch 102 engages the sash to retain the sash in the tilt closed position. When the latch 102 is in the sash release position, the latch is disengaged from the sash 14A, enabling the sash to be rotated out of the planes defined by the sash carrier 10A and window frame 12 to the tilt open position.
The illustrated embodiments sash 14A also include a latch receiver 116 on the sash. The latch receiver 116 is configured to be releasably engaged by the latch 102 on the sash carrier 10A (e.g., as a shown in
Spring mechanism 74 and other components on the second end portion 72 of the sash carrier 10A may be described with reference to
An end cap 140 on the second end portion 72 of the sash carrier 10A may be described with reference to
A seal member 144 is mounted to the end cap 140. The seal member 144, which may for example be resilient polymer foam, provides a sliding and weather-resistant seal between the sash carrier 10A and the first jamb 20. As shown, the end cap 140 and seal member 144 include an opening such as slot 146 through which the tape 124 of the spring mechanism 74 extends.
Brake mechanism 76 may be described with reference to
Biasing portion 152 biases the engagement portion 150 to its retracted position. In the illustrated embodiments the biasing portion 152 includes an arm 170 having a first end portion 172 and a second end portion 174, and a biasing member such as spring 176. The first end portion 172 of the arm 170 is mounted to the base wall portion 52 of the body 50 for movement (e.g., rotational movement), for example by a pin 173. The second end portion 174 of the arm 170 is coupled to the second end portion 160 of the arm 156 of the engagement portion 150 by a hinge 177. Spring 176 is mounted to and extends between the first end portion 172 of the arm 170 and the first end portion 158 of the arm 156.
Actuator portion 154 includes a trigger 180 coupled to the arm 156 of the engagement portion 150 by lever 182. The trigger 180 is configured to be engaged by the actuator arm 114 extending from the bearing pin 112 on the sash 14A (
In the illustrated embodiments, the engagement portion 150, biasing portion 152 and actuator portion 154 of the brake mechanism 76, including hinge 177, are elements of a one-piece polymer member. Pins 164 and 173 extend from and are parts of mount members also including a bases 165 and 174 in the illustrated embodiments, and the pins extend from the bases. The bases 165 and 174 may be configured to mate and engage with the first mount track 80. For example, bases 165 and 174 may be slid into the first mount track 80 from an opening on an end of the body 50, located at desired positions on the body, and secured to be body by an attachment structure and/or process such as heat staking or adhesive.
When the sash 14A is in its tilt closed position, the actuator arm 114 on the bearing pin 112 is located at a position that enables the biasing portion 152 to bias the engagement portion 150 to the retracted position, enabling the sash carrier 10A and the sash 14A to slide between the sliding open and sliding closed positions. When the latch 102 is moved to its release position and the sash 14A is tilted to its tilt open position, the actuator arm 114 on the bearing pin 112 rotates as the sash tilts, engages the trigger 180, and causes the actuator portion 154 to drive the engagement portion 150 to its extended position against the bias force provided by the biasing portion 152. The first end portion 158 of the arm 156 extends beyond the wall portion 56 of the body 50 to engage a portion of the first jamb 20 of the window frame 12 when the engagement portion 150 is in this extended position. The brake mechanism 76 is thereby actuated to the brake position, and the sash carrier 10A and sash 14A mounted thereto are inhibited from movement when the sash is in its tilt open position.
Various modifications and additions can be made to the exemplary embodiments described herein without departing from the spirit and scope of this disclosure. For example, while the embodiments described above refer to particular features, the scope of this disclosure also includes embodiments having different combinations of features and embodiments that do not include all of the described features. Accordingly, the scope of this disclosure is intended to embrace all such alternatives, modifications, and variations as fall within the scope of the claims, together with all equivalents thereof.
| Number | Date | Country | |
|---|---|---|---|
| 63269580 | Mar 2022 | US |
