The present invention relates generally to door assemblies in general, and, more particularly, to a door having a glass insert and a method for assembling the same.
A commonplace substitution for the traditional wooden doors in residential and commercial buildings is a door made from steel or fiberglass. One type of synthetic door is formed with resin sheets reinforced with fiber glass (in the art referred to as door skins) attached to opposite sides of rails and stiles forming a rectangular frame, with the resulting cavity between the door skins filled with a polymer foam material. Doors so constructed can include wood graining on the outer surfaces of the skins, and also raised paneling formed (molded) in the skins, which gives these doors the appearance of natural wood fabricated products.
Molded skins for making such doors are typically formed using mixtures having by weight 12% to 15% polyester resin, 5% to 15% polystyrene, 40% to 50% calcium carbonate and 15% to 25% chopped fiberglass. Such mixtures are deposited in a compression molding machine and subjected to pressures from 600 to 1,500 psi and elevated temperatures for a cure cycle of from 60 to 200 seconds to form rigid skins. The mixture described is one of those known as a “sheet molding compound” (SMC).
The door skins formed from SMC processes for doors can have thicknesses of from about 0.13 mm (0.05 inches) to about 52 mm (0.20 inches), depending on the door application in which they are used.
As previously noted such skins are affixed to opposite sides of a rectangular frame and the core (cavity) enclosed by the frame and skins is filled with polymer foam to complete the door. A rigid urethane foam having a density of 0.8 pounds per cubic foot to 3.5 pounds per cubic foot is suitable for the core of such doors.
Previously, these doors may have had glass inserts (glazing or lights) that covered less than 30% of the door's exterior surface. Currently the marketplace demands doors with larger glass inserts, which can comprise more than 60% of the door's exterior surface. Due to building codes, these large glass inserts must be double glazed (double pane) and in some cases made of safety glass. While known doors with glass inserts have proven to be acceptable for various applications, such doors are nevertheless susceptible to improvements that may enhance their performance and lower cost. With this in mind, a need exists to develop improved doors with glass inserts that advance the art.
The present invention provides an improved door having a large central glass insert and a method for assembling the same. Alternatively, the invention is an improved building component having a lite, such as a door, a side lite, or a transom lite.
According to a first aspect of the present invention, there is provided an improved door having a large central glass insert. The door includes a first door skin having a first planar portion formed with a first opening for receiving a glass insert, the first opening being defined by a first flange extending inward from the first planar portion and a lip portion extending from where the first flange meets the first planar portion and substantially parallel to the first planar portion to contact a first major surface of the glass insert. The door further includes a second door skin opposite to the first door skin to form a cavity therebetween and having a second planar portion formed with a second opening for receiving the glass insert, the second opening defined by a second flange extending into the cavity from the second planar portion to engage the first flange. The door further includes a glazing rim member having a leg portion disposed on a surface of the second flange with and a lip portion extending substantially parallel to the second planar portion of the second door skin and having at least one flexible sealant fin extending from the lip portion to apply a contact pressure to a second major surface of the glass insert, and a core material disposed in the cavity between the first and second door skins.
According to a second aspect of the present invention, there is provided a door having an improved structure. The door includes first and second door skins operatively secured to form a cavity therebetween filled with a foam material. Each of the first and second door skins has a substantially planar plate portion formed with an opening therethrough for receiving a glass insert, each opening defined by a flange portion formed integrally with the planar plate portion and extending substantially inwardly therefrom toward the opposite door skin. The second door skin has a lip portion formed integrally with the planar plate portion of the second door skin and extending from the flange portion substantially along the planar plate portion. The flange portion of the first door skin has a thickness allowing substantially no deflection thereof due to the expansion pressure of the expanding foam material within the cavity. The flange portion of the second door skin has a thickness allowing some deflection thereof due to the expansion pressure of the expanding foam material within the cavity. Distal ends of the flange portions of the first and second door skins engaging each other in an overlapping relationship to form an interlocking lap joint and define the cavity between the first and second door skins. The door further includes a glazing rim member including a lip portion disposed opposite the lip portion of the second door skin and a leg portion supported by the flange portion of the first door skin.
According to a third aspect of the present invention, a building component having an improved structure is provided. The building component includes a first building component skin having a first planar portion formed with a first opening for receiving a glass insert, the first opening being defined by a first flange extending inward from the first planar portion and a lip portion extending from where the first flange meets the first planar portion and substantially parallel to the first planar portion to contact a first major surface of the glass insert. The building component further includes a second building component skin opposite to the first building component skin to form a cavity therebetween and having a second planar portion formed with a second opening for receiving the glass insert, the second opening defined by a second flange extending into the cavity from the second planar portion to engage the first flange. The building component further includes a glazing rim member having a leg portion disposed on a surface of the second flange with and a lip portion extending substantially parallel to the second planar portion of the second building component skin and having at least one flexible sealant fin extending from the lip portion to apply a contact pressure to a second major surface of the glass insert. The building component further includes a core material disposed in the cavity between the first and second building component skins.
According to a fourth aspect of the invention, a method is provided. The method includes providing a first door skin having a substantially planar plate portion integrally formed with a flange portion extending substantially normally therefrom so as to define an opening through the first door skin, providing a second door skin having a substantially planar plate portion integrally formed with a flange portion extending substantially normally therefrom so as to define an opening through the second door skin and a lip portion formed integrally with the planar plate portion of the second door skin and extending from the flange portion substantially along the planar plate portion, holding the first and second door skins together by engaging distal ends of the flange portions of the first and second door skins in an overlapping relationship to form a lap joint and to define a cavity between the first and second door skins, inserting a core material into the cavity, inserting a glass insert through the opening in the second door skin so that the glass insert engages the lip portion of the first door skin, providing a glazing rim member including a lip portion and a leg portion, mounting the glazing rim member to the second door skin so that the lip portion of the glazing rim member is disposed opposite the lip portion of the first door skin and a distal end of the leg portion is snap-locked between the flange portion of the second door skin and the distal end of the flange portion of the first door skin.
Other objects and advantages of the invention will become apparent from a study of the following specification when viewed in light of the accompanying drawings, wherein:
The preferred embodiment of the present invention will now be described with the reference to accompanying drawings.
Preferably, the first and second door skins 10 and 20 are molded from an appropriate polymer material and have a thickness of about 1 to 4 mm. The material of the door skins 10 and 20 of the present invention can be sheet molding compound (SMC) reinforced with fiber glass, wood fiber, steel or wood. Preferably, the door skins 10 and 20 are molded and can be made from such materials as fiberglass reinforced plastics, pressed board, vinyl esters, polystyrenes or other moldable materials. An outer surface of the door skins 10 or 20 can be smooth without wood grain or can have a simulated wood grain. The depth of the wood grain is about 0.05 to 0.2 mm. An inner surface of the door skins may have a relatively rough surface to increase the surface area for the adhesive when the door is assembled. This results in stronger bonds between the door skins, the foam material, the rails and the stiles.
As best shown in
As best shown in
The first door skin 10, as illustrated in
Furthermore, the flange portion 14 of the first door skin 10 includes a distal end 27 with a first notch 26. The first notch 26 has a geometry configured to mate with a distal end 16 of the flange portion 24 of the second door skin 20 (as shown in
As mentioned above, the first door skin 10 includes the plurality of positioning tabs 50 shown in
The second door skin 20, as illustrated in
Furthermore, as best shown in
As best shown in
Although a small spacing is shown in
Referring back to
As shown in
The glazing rim member 36 further includes a skirt portion 46 extending from the lip portion 40 and formed integrally therewith so as to form a pilot cavity 45 between the skirt portion 46 and a pilot edge 41 of the leg portion 38 of the glazing rim member 36. The pilot cavity 45 is provided for receiving the guide rim 15 of the second door skin 20 therein. As best shown in
The lip portion sealant fins 48, the midsection sealant fin 49, and the skirt portion sealant fin 47 allow the glazing rim member 36 to be interference fitted to the second door skin 20, the glass insert 6, and the glazing rim locking tabs 52. Each of the sealant fins 48, 49, and 47 is flexible so as to apply a contact force to the glass insert 6 and the second door skin 20 when assembled with the first and second door skins 10 and 20 and the glass insert 6. Since each of these sealant fins 47, 48, and 49 is pressed against a corresponding surface of the glass insert 6 or the second door skin 20, the friction that results from the contact pressure maintains the glazing rim member 36 in engagement with the insert 6. Accordingly, a tight seal is provided between an area on the glass insert 6 where the lip portion sealant fins 48 contact the glass insert 6 and the guide wall 19 of the second door skin 20.
Additionally, the sealant fins 48, 49, and 47 provide resistance to movement of the glass insert 6 within the opening in the door 2. As a result, the door 2 assembled from the first and second door skins 10 and 20, the glass insert 6, and the glazing rim member 36 is maintained in a stable state without shifting or movement of the components.
According to the preferred embodiment of the present invention, the glazing rim member 36 is coextruded from appropriate polymer materials as a single-piece part, which may then be cut to length and mitred to provide the individual glazing rim frame members 36 with the sealant fins 47, 48, and 49 formed from a flexible polyvinyl chloride and the remaining portions formed from a rigid polyvinyl chloride.
The lip portion 40, the skirt portion 46, and the leg portion 38 of the glazing rim member 36 may be made of a rigid extrusion material and the flexible sealant fins 47, 48, and 49 may be made of a flexible extrusion material.
For example, the glazing rim member 36 may be made of polyvinyl chloride (PVC). More specifically, the glazing rim member 36 may be coextruded from PVC such that the lip portion 40, the skirt portion 46, and the leg portion 38 of the glazing rim member 36 are made of a rigid PVC while the sealant fins 47, 48, and 49 are made of a flexible PVC (e.g., PVC 74±4 Shore A Durometer).
In an assembled position, illustrated in
Furthermore, in the assembled position, due to the resilient nature of the material forming the flexible sealant fin 47 of the skirt portion 46, the glazing rim member 36 tightly engages the outer wall 19 of the guide rim 15 of the second door skin 20. Due to the intimate contact between the flexible sealant fin 47 and wall 19, the skirt portion 46 functions as a window seal element. Also, because the material used to form the sealant fins 47, 48, and 49 of the glazing rim member 36 is resilient, the glazing rim member 36 may readily be removed in the event the glass insert 6 should become broken. Thus the glass insert 6 may be replaced without the necessity of replacing the door 2. Furthermore, because the glazing rim member 36 is formed of a resilient material, it forms a tight seal with the glass insert 6. Preferably, door skin 20 is the interior door skin and door skin 10 is the exterior or outside door skin.
As further illustrated in
The glass insert positioning tab 53 is disposed along the flange portion 14 of the first door skin 10 above the glazing rim locking tab 52. The glass insert positioning tab 53 maintains the glass insert in a predetermined position with respect to the opening in the door 2.
As best shown in
The glass insert 6 may be a preassembled two-pane unit or cassette that can be installed readily in the opening during assembly of the door 2. Additionally, due to the strength of assembly of the door 2, laminate glass may be used as the glass insert 6 and the possibility of glass breakage is minimized. The glass insert 6 may be impact resistant.
The procedure of assembling the door 2 with the glass insert 6 according to the preferred embodiment of the present invention will now be described.
First, the first and second door skins 10 and 20 are formed preferably by a compression molding process from any appropriate polymer material, such as fiber glass reinforced SMC. The openings 11, 21 are preferably molded into the door skins 10, 20 in order to reduce material cost and minimize manufacturing costs.
Then, the first and second door skins 10 and 20, the top and bottom rails 7, and the left and right stiles 8 are aligned and attached to each other with adhesive. In this position, the first notch 26 of the flange portion 14 of the first door skin 10 engages the distal end 16 of the flange portion 24 of the second door skin 20 to form a joint and define the cavity 34 (as shown in
Next, the cavity 34 between the first and second door skins 10 and 20 is tilled with the expandable foam material 35 which expands within the cavity 34 and may force together the flanges 14 and 24 of the first and second door skins 10 and 20, respectively. The expandable foam may be a polyurethane foam or other foamable material that adds weight to the door 2 and also provides sound and thermal insulation properties.
Preferably, the step of filling the cavity 34 with the foam material 35 is performed while the semi-assembled door 2 is held in an appropriate press (not shown). The semi-assembled door 2 is placed into the press to hold the skins 10, 20 into engagement with the stiles and rails. The press platens may be heated to enhance curing of the adhesive bonding the stiles and rails to the door skins. The press platens have sufficient strength to prevent deflection of the planar plate portions 12, 22 of the door skins 10, 20 during the foaming operation.
The door 2 is then removed from the press. Thereafter, a sealant 100 may be applied to the lip portion 28 of the first door skin 10 in groove 102, as best shown in
Subsequently, the glazing rim member 36 is mounted to the flange portion 24 of the second door skin 20 so that the leg portion 38 of the glazing rim member 36 is angled downward and moved in contact with the outer peripheral surface 18 of the flange portion 24 of the second door skin 20. As noted above, the glazing rim member 36 is properly oriented relative to the first door skin 10 by the guide rim 15 of the second door skin 20 engaging the pilot edge 41 and the skirt portion flexible sealant fin 47 of the glazing rim member 36.
As the glazing rim member 36 is forced into position, the flexible sealant fins 47, 48 and 49 apply a flexible resistance until the pilot edge 41 is moved passed the inner wall 17 of the guide rim 15. At this time, the pilot edge 41 is pushed down along the inner wall 17 such that the guide rim 15 is disposed within the pilot cavity 45. In this position, the glazing rim member 36 is interference fitted to the second door skin 20 and the glass insert 6. Accordingly, the force provided by the flexible sealant fins 47, 48, and 49 push the surface 41 of the glazing rim member 36 into the wall 17 to prevent the glazing rim member 33 from coming out of engagement and prevents the glazing rim member 36 from moving. Also in this position, the flexible sealant fins 47, 48, and 49 may be slightly deformed due to the interference fitting.
Additionally, the glazing rim member 36 is snap-locked into position such that the distal end 39 of the leg portion 38 is secured in the second notch 23 formed between the outer peripheral surface 18 of the flange portion 24, the distal end 27 of the flange portion 14, and the glazing rim member locking tab 52. Also in this position, the lip portion 40 of the glazing rim member 36 is placed against the glass insert 6 laid in the opening of the door 2 on the side opposite to the lip portion 28 of the first door skin 10. This procedure is repeated for each of the glazing rim frame members 36. Thus, the glass insert 6 is locked in place.
We prefer that the door 2 be removed from the press and stored in inventory, so that the appropriate glazing unit 6 may be installed as ordered by consumers.
While we prefer that the flange portion 14 provide a dam, it should be recognized that the expansion of foam 35 could be sufficient to force flange portion 24 upwardly into secure contact of flange portion 14 to further enhance the seal provided by the flange portions. In other words, the flange 24 may be deflected by the expansion force of foam 35.
Also, while we prefer that the core be foam 35, the core could be a wood composite, wood, wood, wood substrate, or foam cement.
The foregoing description of the preferred embodiment of the present invention has been presented for the purpose of illustration in accordance with the provisions of the patent statutes. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiment disclosed hereinabove was chosen in order to best illustrate the principles of the present invention and its practical application to thereby enable those of ordinary skill in the art to best utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated, as long as the principles described herein are followed. Thus, changes can be made in the above-described invention without departing from the intent and scope thereof. It is also intended that the scope of the present invention be defined by the claims appended thereto.
Number | Date | Country | |
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Parent | 11714281 | Mar 2007 | US |
Child | 12786872 | US |