The present invention relates to a window assembly with a primary sash and a secondary movable interior sash attached to the primary sash.
Prior to the concern over energy efficiency and cost savings in building maintenance, many buildings, both residential and commercial, were constructed with a window assembly with a primary-glazing pane. In order to decrease thermal losses through window openings and increase the desirability and livability of these older buildings, either interior or exterior storm windows that create a multiple pane window unit, are used.
Exterior storm windows are typically mounted on the exterior of the building to cover the primary glazing and shield it from the environment. Such arrangements have served to provide improved insulation, but are also subject to certain drawbacks.
The exterior storm windows are usually constructed of rigid, weather resistant materials, such as aluminum or other metals. In addition, the exterior storm windows can be difficult to install and can require expensive, professional installation due to things such as ground landscaping or the height at which the windows would have to be installed. In some commercial buildings the window elevations are so extreme that exterior storm windows are not available as a practical matter. With certain historic buildings and condominium dwellings, use of exterior storm windows is prohibited by law or restrictive covenant. Even when such storm windows can be easily installed, to apply them over casement or awning windows typically restricts or entirely eliminates the workability of those window assemblies.
U.S. Pat. No. 4,160,348 (Chapman et al.); U.S. Pat. No. 4,369,828 (Tatro); and U.S. Pat. No. 5,282,504 (Anderson et al.) disclose interior storm windows attached to the window frame at the interior of the building. Such storm windows have, for example, been held in place by magnetic strips or guide tracks secured to the window frame adjacent to the primary glazing pane. The interior storm windows can be employed at all building elevations and are substantially unnoticeable from the building exterior, thus overcoming many of the limitations on usage of the exterior storm windows. Further, because these storm windows are on the inside of the building, they do not need to be as weather resistant.
However, interior storm windows typically require careful, on-site measurement of each window and largely custom construction often requiring professional installation. The finish trim often needs to be cut and stained at the site and installed separately from the storm window. Further, the interior storm windows often interfere with window hardware, such as handles and cranks for casement or awning windows. This hardware must be removed and the window assemblies rendered inoperative if the interior storm window is to be installed. Likewise, since interior storm windows are fixedly mounted to the window frame, the window's mounting frame and panes restrict access to the primary glazing pane for cleaning and/or removal of the primary glazing pane. Similarly, in window openings of lesser depth, use of the interior storm windows can preclude use of a Venetian blind or shade between the primary glazing pane and the storm window pane. Such between window mountings of blinds would otherwise be desirable to decrease the accumulation of dust on the blinds.
The present invention is directed to a window assembly having a window frame and at least one primary sash mounted in the window frame. The primary sash has a plurality of sash members forming a primary sash perimeter and a first glazing panel mounted in the primary sash perimeter. At least one secondary sash is pivotally attached directly to the primary sash perimeter along an interior surface thereof so that the secondary sash is rotatably movable between a closed position and an open position relative to the primary sash. The secondary sash has a plurality of secondary sash members forming a secondary sash structure and a second glazing panel mounted in the secondary sash structure. An air chamber is located between the primary sash and the secondary sash. At least one accessory channel is located along at least one side of the secondary sash members. The secondary sash optionally includes an opening stop to prevent the secondary sash from opening beyond a preset limit.
When the secondary sash is in the closed position, the secondary sash and the primary sash preferably move as a unitary structure relative to the window frame. At least one of the sash members forming the secondary sash structure is preferably an extruded member. A hinge is optionally integrally formed in at least one of the sash members forming the secondary sash structure. The primary sash can be an in-swing door, a sliding door, an out-swing door, a double hung window, a casement window, an awning window, a fixed window, or the like.
A window accessory operating mechanism is preferably located in the accessory channel. At least one window accessory mounting post is preferably attached to one of the plurality of sash members forming the secondary sash structure and located in the closed air chamber. At least one drive opening preferably extends through at least one of the sash members forming the secondary sash structure between the accessory channel and the closed air chamber. A window accessory is preferably located in the air chamber and releasably attached to at least one of the sash members forming the secondary sash structure.
In one embodiment, a first drive coupler extends through a side sash member forming the secondary sash structure. The first drive coupler is releasably coupled with a second drive coupler on a window accessory located in the air chamber. A window accessory drive mechanism is located in the accessory channel mechanically coupled to the first drive coupler. The first drive coupler preferably slidingly engages with the second drive coupler.
In another embodiment, at least two window accessory mounting structures are located in the closed air chamber and attached to a top sash members forming the secondary sash structure. The mounting structures are separated by a fixed distance. The window accessory preferably has a shade mechanism housing with first and second slots separated by the fixed distance. The first slot extends generally parallel to an axis of the shade mechanism housing and the second slot extends generally perpendicular to the axis of the shade mechanism housing. In one embodiment, the first drive coupler extends through a side sash member forming the secondary sash structure. The first drive coupler is located to mechanically couple with a second drive coupler on the window accessory when the window accessory is attached to the first and second mounting structures. A window accessory drive mechanism is located in the accessory channel mechanically coupled to the first drive coupler. At least one of the first and second slots preferably has one or more detents to releasably engage with the mounting structures.
In one embodiment, a glazing flange is located between the first glazing panel and the plurality of sash members forming the primary sash. The glazing flange is preferably a unitary structure attached to the primary sash perimeter. In one embodiment, the glazing flange is pre-formed in the shape of the primary sash and the individual sash members are then attached to the pre-formed glazing flange, locking the glazing flange into place. The glazing flange is preferably a welded polymeric structure attached to the primary sash perimeter. In another embodiment, the glazing flange can be metal or wood. Exterior cladding is optionally attached along at least one edge to the glazing flange. The glazing flange preferably forms an interlocking relationship with the plurality of sash members. An adhesive is optionally used to attach the first glazing panel to the glazing flange.
In another embodiment, at least one attachment region is located on the plurality of sash members forming the secondary sash. The attachment region is positioned in the closed air chamber. A plurality of muntin bar clips form a snap-fit relationship with the attachment region to fixedly position a muntin bar assembly in the closed air chamber. A window shade operable from the accessory channel is optionally located in the closed air chamber with the muntin bar assembly.
The window assembly may further include one or more window accessories (e.g., a grid, a grille, a shade, a screen, a blind, a window fashion, etc.) and one or more window accessory operating mechanisms. The window accessory is placed in the air chamber, while the window accessory operating mechanism is placed in the recessed region of the secondary sash. The window accessory operating mechanism is adapted to operate the window accessory. The window assembly may include a lock mechanism for locking the second sash in the closed position. The grille may be held in place using clips that attach to the primary sash or the secondary sash. The clips may include a spring portion and an engagement portion.
a is a cross-sectional view of the window assembly of
b is a cross-sectional view of an alternative embodiment of the window assembly shown in
a is a top view of the sash shown in
a is a top view of the sash of
b is a front elevation view of a secondary sash and a sash retaining system in accordance with the present invention.
a is a cross-sectional view of the primary and secondary sashes of
a, 13b and 13c are perspective views of the primary and secondary sashes of
a and 14b are top and bottom perspective views 15 respectively of a muntin bar clip in accordance with the present invention.
c and 14d are bottom perspective and side views respectively of the muntin bar clip attached to a frame of a secondary sash in accordance with the present invention.
a, 15b, 15c and 15d are views of a muntin bar connector and a muntin bar assembled using the connector in accordance with the present invention.
a is a perspective view of the mechanism
b illustrates the secondary sash 11 of
Referring now to
The window frame 16 can be constructed of wood, vinyl, aluminum, or a variety of other materials. In the illustrated embodiment, the window frame 16 includes four peripheral frame members, 16a, 16b, 16c, and 16d, joined and secured together to form a rectangular shape corresponding to the size and shape of the rough opening 17. The inner perimeter of the rough opening is slightly larger than the perimeter of the window frame 16 of the window assembly 1000, so that the window assembly 1000 can be received in the rough opening during installation. The methods of mounting the window frame 16 to the rough opening are well known in the window industry. The window frame 16 defines a window opening 18. In the illustrated embodiment, the window opening 18 has a rectangular shape. Although the window assembly 1000 in the illustrated embodiment is rectangular, it is understood that the present invention is not limited by the shape of the window assembly.
The window assembly 1000 also includes a first or primary sash 12 attached to the window frame 16 and received in the window opening 18 defined by the window frame 16. In the illustrated embodiment, the primary sash 12 is operated in the same or a similar manner as a conventional casement window with a vertical edge of the primary sash 12 hinged to the jamb of the window frame 16 allowing the opposite vertical edge of the primary sash 12 to swing outwardly from the window frame 16.
The primary sash 12 may be made from a durable material, such as for example wood, vinyl, aluminum or variety of other materials. The methods of making window sashes are well known in the window manufacturing industry.
In the illustrated embodiment, sash operator 20 for opening and closing the primary sash 12 is a crank that actuates a linkage for pushing/pulling the primary sash 12 open and pulling/pushing it shut. The window assembly 1000 may include a decorative wood trim or frame stop 22 mounted to the window frame 16 along the inner perimeter of the window frame 16. Further, a screen 26 can optionally be included in the window assembly 1000.
Referring to
The cord 1246 is anchored at a first end in keyhole opening 1214. The cord 1246 then wraps around the center member 1243 of the spring slider 1241 and is restrained from sliding off the center member 1243 by one of the ears 1244. The cord 1246 then extends back to the corner lock 1200 and threads into the one end of the ‘L’ shaped opening 1213 passing under the overhanging lip 1247 and out the other end. The cord 1246 extends toward and is removably secured at a second end 1249 to a window anchor 1248 mounted to the primary sash 12 or window frame.
When the secondary sash 1100 is closed with respect to the primary sash or window frame, as shown in
The restraining device 1240 provides a restraining mechanism to keep the secondary sash 1100 from opening too far. The resilient member 1245 both causes the cord 1246 to be recaptured within the member 1103 upon closing of the frame 1100 and encourages the closing of the frame 1100 with little or no effort on the part of the user opening the secondary sash 1100. Once opened, the second end 1249 of the cord 1246 may be disengaged from the window anchor 1248 so that the secondary sash 1100 may be opened further and/or removed from the primary sash or window frame.
In another embodiment shown in
a illustrates an alternate mechanism 71 for limiting movement of the secondary sash 1100 between the open position and the closed position. The mechanism 71 includes an arms 68 operatively connecting the primary sash 12 and the secondary sash 1100. The arm 68 includes a first section 70 and a second section 72 pivotally connected together at point 74.
A lock mechanism 13 for locking the secondary sash 1100 to the primary sash 12 is included in the window assembly 1000. Suitable lock mechanisms are well known in the art as is shown in U.S. Pat. Nos. 4,059,298; 4,095,829; and/or 4,429,910, which are hereby incorporated by reference. In the preferred embodiment, the locking mechanism 13 is shown in detail in the U.S. Patent application entitled Moveable Light Latch (attorney docket no. 301233), filed herewith.
The primary difference between
Breather channel 34 extends along the inner perimeter of the primary sash 12. During winter conditions, the breather channel 34 carries low humidity outside air to air chamber 62. In one embodiment, the seal 76 includes a serrated edge that interfaces with the interior pane 30 to provide a path for the low humidity air in the breather channel 34 to flow into the air chamber 62. As will be discussed in connection with
Referring to
When the secondary sash 1100 is in the closed position, the extrusions 52 are oriented toward the primary glazing panes 30. Seal 76 is preferably included in the window assembly 1000 to seal the secondary sash 1100 to the primary sash 12. The seal 76 generally extends along the inner perimeter of the first sash 12. The seal 76 can be made of a rigid material, such as for example metal or plastic, or a flexible material such as for example foam, soft plastic, an elastomeric material, such as rubber, or similar materials.
The secondary sash 1100 defines a secondary glazing opening 40. In the illustrated embodiment, a secondary glazing pane 42 is received in a retention groove 44 formed in the secondary sash 1100 to cover the secondary glazing opening 40. The groove 44 extends along the inner perimeter of the secondary sash 1100. Glazing materials 46 (such as for example, butyl mastic) and 48 (such as for example, urethane adhesive) are applied around the perimeter of the secondary glazing pane 42 to hold the secondary glazing pane 42 into the retention groove 44 of the secondary sash 1100.
In the illustrated embodiment, a decorative cover 57 is glued to a surface of extrusion guide flange 52b along the perimeter of the peripheral portion 50. The decorative cover 57 can be a coating, such as paint, stain or varnish, or an applique, such as a wood or plastic veneer. The decorative cover 57 can be attached to the extrusion guide flange 52b by an adhesive, fasteners, and/or a mechanical interlock, such as a snap-fit relationship.
Referring particularly to
The primary glazing panes 30 and the secondary-glazing pane 42 create an air chamber 62 substantially closed to the interior 29 of the building structure. The seal 76 may cooperate with a gasket 35, held in a gasket receiving slot 35a of the extrusion 52 to substantially seal off the air chamber 62 from external spaces. As will be discussed below in connection with
The primary sash 12 includes a recessed region 66 formed in at least a portion of the primary sash 12 along the inner perimeter. An accessory channel 67 is located along at least a portion of the outer perimeter of the secondary sash 1100. As used herein, “accessory channel” refers to a space or cavity located in one or more secondary sash members that is adapted to receive and contain at least a portion of a window accessory. The present accessory channels 67 are preferably located between the air chamber 62 and the region 66 on the primary sash 12, without interfering with the operation of the secondary sash 1100. Access to the accessory channel 67 is typically through the perimeter edge of the secondary sash 1100, but may be from any side. As will be discussed below, the secondary sash members 1101, 1102, 1103, 1104 optionally include openings along the edge opposite the air chamber 62 to provide access to the accessory channels 67.
The accessory channel 67 can be used for receiving one or more window accessory operating mechanisms, such as for example the shade operator disclosed in commonly assigned U.S. Patent applications entitled Shade Drive System (attorney docket no. 306547), filed herewith. The details of the operating mechanisms will be discussed below. In the illustrated embodiment, the accessory region 67 has generally a “U” shape.
In the illustrated embodiment, the peripheral portion 50 and the extrusion portion 52 is substantially covered by the region 66 on the primary sash 12 when the secondary sash 1100 is in the closed position. The extrusion 52 may also include a clip region 58 for connection of a muntin bars system to the secondary sash 1100, such as those discussed in connection with
Secondary pane 42 is placed into glazing channel 52a between extrusion extension 54 and extrusion guide flange 52b. The glazing panel 42 is held in place with glazing material 46, 48. The extrusion guide flange 52b also substantially covers the gap between the primary sash 12 and the secondary sash 1100 when the secondary sash 1100 is closed.
The secondary sash 1100 of
Referring to
Referring to
The corner locks 1200 function to both secure the two sash members 1101, 1104 together and to properly align the sash members, so that the two sash members 1101, 1104 are properly aligned along their 45° miters so as to form a true 900 angle when the sash members 1101, 1102, 1103, 1104 are secured to each other. The joint angles do not necessarily have to be 90°. The joint angles could be 105 °, 70 °, 150°, etc. with corresponding miter angles of one-half of the joint angle. The secondary sash 1100 does not necessarily have to be rectangular and does not necessarily have to be made of four sash members 1101, 1102, 1103, 1104. The shape of the secondary sash 1100 generally corresponds to the shape of the primary sash 12.
Referring to
Referring now to
Referring now to
b shows the hinge mechanism 79 without the secondary sash 1100 for clarity. First section 82 is pivotally coupled to a first block 90. First block 90 is stationary and resides in a recess 86 extending along the inner periphery of the primary sash 12. Second section 81 is pivotally coupled to a second block 88 residing in and slidable along recess 86. When the secondary sash 1100 is in a closed position, the second block 88 is longitudinally displaced from the first block 90. The secondary sash 1100 overlays the recess 86, blocking the hinge mechanism 79 from view. When the secondary sash 1100 is moved into an open position, second block 88 slides proximally toward first block 90 within recess 86. Blocks 88 and 90 are sized so that second block 88 contacts stationary first block 90 when the secondary sash 1100 forms a 90° angle with respect to the primary sash 12. Contact between block 88 and 90 prevents further opening of the secondary sash 1100.
The hinge mechanism 79 thus functions as a stop to prevent over-travel of the secondary sash 1100, which condition can sometimes cause damage to the secondary sash 1100 or window accessories. In other embodiments, the blocks 88 and 90 are sized to permit maximum travel of the secondary sash 1100 to an angle of 45°, 60° or 130° with respect to the primary sash 12. Chamber 62 between the primary glazing panes 30 and secondary glazing pane 42 is thus accessible when the secondary sash 1100 is in an open position, allowing easy cleaning of the primary and secondary glazing panes 30, 42 and access to the window accessory 45 (see
a and 14b are top and bottom perspective views respectively of a muntin bar clip 1400 of the present invention. The clip 1400 includes head 1410 and tail 1402. The head is formed of connector portion 1413, first finger 1411, second finger 1412 and spring region 1414. The first and second fingers oppose the spring region to provide a clamping force that is used to engage a portion of the window frame.
The tail 1402 includes an elongated portion ending in a distal tip 1408 and a connector region 1406 for connection of the tail to the head 1410. Intermediate the distal tip and the connector region is a bend 1407 that provides a spring force to hold the clip in place when placed in opening 1451 of muntin bar 1450.
Referring now to
a-15d are various views of a muntin bar connector 1500 and crossed muntin bars assembled using the connector. Connector 1500 includes body portion 1502 and fingers 1504. The connector is sized to fit in opening 1451 of a the muntin bar 1450. The opening 1451, in one embodiment, runs the entire length of the muntin bar 1450. Fingers 1450 can be formed to be resilient and to provide a spring force at the inner surface of opening 1451 to hold the connector in place. In
To releasably attach the shade mechanism housing 1701 to the member 1103, slot 1106a on the shade mechanism housing 1701 is slidingly engaged with the mounting post 1106. The depth of the slot 1106a is sufficient so that the drive coupler 1108a engages with the drive opening 1108 on the first frame side 1101. The shade mechanism housing 1701 is then rotated in a direction 1703 until the mounting post 1107 slidingly engages with the slot 1107a. The mounting posts 1106, 1107 provide lateral constraint while the plates 1106b, 1107b support the weight of the shade mechanism housing 1701. In the illustrated embodiment, the drive opening 1108 is tubular structure with a hexagonal inner profile and the drive coupler 1108a is a hexagonal shaft, although a variety of other shapes can be used.
In one embodiment, the slots 1106a, 1107a are formed with a base portion 1106c, 1107c that is sized to engage with the plates 1106b, 1107b and the mounting posts 1106, 1107, respectively. Overhangs 1106d, 1107d are formed to securely hold the shade mechanism housing 1701 to the posts 1106 and 1107. First and second detent portions 1705a and 1705b are optionally located in the slot 1107 to releasably engage with the mounting post 1107. For example, the first and second detents 1705a, 1705b are be formed by placement of spring structures (such as a resilient materials or springs) on one or both sides of the channel.
a is a perspective view of the shade mechanism housing 1701 of
In the illustrated embodiment, the drive system 1704 includes timing pulley assembly 1120, drive belt 1112 and idler pulley assembly 1140. The drive system 1704 is substantially contained in the accessory channel 67 formed in the secondary sash member 1101 (see
As discussed above, the secondary sash 1100 can be used with any style window or door, including double hung windows, awning windows, fixed windows, hinged doors, sliding doors, and the like.
Secondary sashes 1100 are attached to each of the primary sashes 2002, 2004 at the interior side 29. The secondary sashes 1100 are substantially the same as discussed above, including being hinged to open toward the interior side 29.
In the embodiment of
The present glazing flange 2018 is preferably assembled into a perimeter frame with welded corners. The corners of the polymeric glazing flange 2018 can be joined using thermal or ultrasonic welding, solvent bonding, adhesives and a variety of other techniques. The individual sash members 2008 are then assembled around the perimeter frame formed by the glazing flange 2018 to create the primary sashes 2002, 2004.
The present glazing flange 2018 provide a number of benefits over conventional wood glazing surfaces. Once the glazing flange 2018 is welded to form a perimeter frame, it serves as a structural member that increases the strength of the sashes 2002, 2004. Less wood is required for the sash members 2008. The interface between the glazing panel 2010 and the glazing flange 2018 is formed by materials that resist decay. The glazing flange 2018 also provide an excellent surface 2042 for engagement with cladding 2032.
Cladding 2032 is optionally attached to the glazing flange 2018 as illustrated in
All patents, patent applications, documents and publications referenced in this document are incorporated by reference herein as if set out in their entirety.
With regard to the foregoing description, it is to be understood that changes may be made in the details, without departing from the scope of the present invention. It is intended that the specification and depicted aspects be considered exemplary only, with a true scope and spirit of the invention being indicated by the broad meaning of the following claims.
The present invention claims the benefit of U.S. Provisional application No. 60/643,064 entitled WINDOW ASSEMBLY WITH MOVABLE INTERIOR SASH filed on Jan. 11, 2005 which is incorporated herein by reference. Provisional application Nos. 60/642,813 entitled WINDOW COVERING DRIVE SYSTEM; 60/642,812 entitled WINDOW COVERING LEVELING MECHANISM AND METHOD; and 60/642,811 entitled MOVABLE LIGHT LATCH, all filed on Jan. 11, 2005, are incorporated herein by reference.
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