1. Field of the Invention
The subject invention generally pertains to a system and method for sealing doors and more specifically to an inflatable or fluid-filled seal for a door.
2. Description of Related Art
So-called horizontally sliding doors (which actually may slide or roll) usually include one or more door panels that are suspended by carriages that travel along an overhead track. To open and close the door, the carriages move the door panels in a generally horizontal direction in front of the doorway. The movement of the panels can be powered or manually operated. Depending on the width of the doorway and the space along either side of it, a sliding door can assume a variety of configurations.
For a relatively narrow doorway with adequate space alongside to receive an opening door panel, a single panel may be sufficient to cover the doorway. Wider doorways with limited side space may require a bi-parting sliding door. Bi-parting doors include at least two panels, each moving in opposite directions from either side of the doorway and meeting at the center of the doorway upon closing. For even wider doorways or those with even less side space, multi-panel sliding doors can be used. Multi-panel doors have a series of door panels that overlay each other at one side of the doorway when the door is open. When the door closes, each panel slides out from behind the others to cover the span of the doorway. Applying such an arrangement to both sides of the doorway provides a bi-parting door with multiple panels on each side.
Sliding doors are often used to provide access to cold-storage lockers, which are rooms that provide large-scale refrigerated storage for the food industry. Doorways into such a room are often rather wide to allow forklift trucks to move large quantities of products in and out of the room. When closing off a refrigerated room, sliding doors are often preferred over other types of doors because sliding panels are generally easy to make thick with insulation to reduce the cooling load on the room. Refrigerated rooms, however, may have other types of doors such as swinging doors, roll-up doors, bi-fold doors, and overhead-storing doors.
Regardless of the type of door applied to a cold-storage locker, ineffectively sealing the edges around the door panels can create cooling losses and promote frost buildup in certain areas of the door. A particularly narrow seal, for instance, may be unable to span relatively wide air gaps and may provide insufficient thermal insulation. Air gaps can allow warm outside air to enter the refrigerated room where the warm air can condense and freeze on inner surfaces of the door and the room. Even without air gaps, seals with insufficient thermal insulation may conduct heat from exterior surfaces to the interior of the refrigerated room. This lowers the temperature of those exterior surfaces and promotes condensation and frost buildup.
Consequently, a need exists for a more effective system and method for the sealing of cold-storage lockers, wherein the seal can span rather wide air gaps and inhibit the buildup of frost.
In some embodiments, a door includes an inflatable seal through which air is conveyed to help warm the seal.
In some embodiments, air is conveyed through a door seal regardless of whether the door is open or closed.
In some embodiments, a flexible hose connects a stationary blower to a movable seal.
In some embodiments, a blower that inflates the seal moves with the door panel.
In some embodiments, the air entering the seal is warmer than the air exiting the seal, whereby the air releases heat to the seal.
In some embodiments, an inflatable or fluid-fillable seal with novel and advantageous properties is disclosed.
Accordingly, the presently disclosed invention provides a sealing system and method according at least to the subject matter of the independent claims. Some of the embodiments of the invention are defined in the respective dependent claims. It will be apparent to those skilled in the art that the previously mentioned features and those explained below pertain to the invention not only in the given combinations, but in other combinations or individually.
In the illustrated example, panels 18 and 20 are suspended from panel carriers 26 that can roll, slide, or otherwise travel along an overhead track 28. Track 28 can lie horizontally or lie at an incline. For cold storage applications, panels 18 and 20 preferably comprise a thermal insulating foam core encased in a protective cover; however, other panel structures are well within the scope of the invention.
Door 10 could be manually operated, or a drive unit 30 can be used to open and close door 10. In some cases, drive unit 30 comprises a roller chain 32 supported between a motor-driven sprocket 34 and an idler sprocket 36. One fastener 38 connects a lower portion 40 of chain 32 to panel 18 (via one of the panel carriers 26), and a second fastener 42 connects an upper portion 44 of chain 32 to panel 20. So, the driven rotation of sprocket 34 determines whether panels 18 and 20 move toward each other to close door 10 or move apart to open the door.
To provide sealing along an upper edge 46 and two lateral edges 48 of doorway 12, sealing system 16 includes an inflatable seal 50 (e.g., a pliable tubular seal having any appropriate cross-sectional shape). In some cases, seal 50 comprises two inverted L-shaped sections connected to a common manifold tube 56. To fasten seal 50 to wall 14, a cord 52 or welting of seal 50 can be inserted into a wall-mounted extruded channel 54, as shown in
Seal 50 has a pliable tubular wall 58 that defines an elongate air passageway 60 that in some cases extends from an air inlet 62 to at least one air outlet 64. This allows a blower 66 to inflate seal 50 by forcing air through passageway 60. The forced air expands tube 50 to fill any gaps between wall 14 and panels 18 and 20. Since tube 50 is inflatable, it can expand to fill wide or irregular gaps, which makes tube 4 particularly useful in retrofitting doors whose existing drive or guidance system is unable to accurately and repeatably position the door panels. To make seal 50 more robust and tolerant of damage, blower 4 may be selected to have a rated discharge volume and pressure that is sufficient to inflate tube 50 even if its tubular wall 58 were punctured or torn, whereby seal 50 can continue functioning even though it may be damaged.
A continuous flow of air through passageway 60 prevents localized cooling of seal 50 by virtue of the fact that the moving air serves to conduct heat throughout the tube. In addition, in the current embodiment, the blower 66 is drawing relatively warmer air for area 24. The heat content of this forced warmer air also helps keep seal 50 relatively warm for the purpose of minimizing or eliminating frost accumulation on the seal. To further inhibit frost from accumulating on the exterior surface of tube 50, in some cases, the material of tubular wall 58 may have some porosity so that relatively warm air within tube 50 actually passes through the tube's wall. In other cases, however, tubular wall 4 is impervious to air.
Keeping seal 50 relatively warm not only inhibits frost from accumulating on seal 50 but also inhibits frost from building up in other areas of door 10. For instance, the doorway edges of many cold storage lockers are often lined with sheet metal cladding 68. Since sheet metal readily conducts heat, the cold storage locker cools cladding 68. This can cause frost to accumulate in area 70, as that area is exposed to the warmer air of area 24. With seal 50 being heated, however, the heat warms cladding 68, which prevents frost from collecting on area 70 of cladding 68.
Frost also tends to collect on an inside surface 72 of panel 18. When door 10 is closed, the colder air in area 22 cools surface 72. Then when the door opens, the relatively cold surface 72 becomes exposed to the warmer air in area 24. The warmer air then condenses on surface 72 and later freezes when the closing of door 10 places the now wet surface 72 back into colder area 22. To avoid this problem, the relatively warm seal 50 wipes the condensation off surface 72, since surface 72 slides across seal 50 whenever the door closes.
In some cases, portions of seal 50 can be lined with thermal insulation 55 (
To provide sealing along a lower edge 74 of panel 18 and between the leading and abutting edges of panels 18 and 20, sealing system 16 includes another inflatable seal 76. Seals 50 and 76 are similar in that seal 76 also includes a pliable tubular wall 78 that defines an elongate air passageway 80 extending from an air inlet 82 to at least one air outlet 84. Seal 76 comprises two L-shaped sections that two flexible tubes 86 connect to a common manifold tube 88. Flexible tubes 86 allow relative movement between manifold 88, which is stationary, and the portions of seal 76 that are attached to panels 18 and 20, which move between open and closed positions. To force the air through seal 76, blower 66 or a second blower 90 can be connected to manifold tube 88. As in the previous embodiment, the source of forced air for blower 66 may advantageously be from warmer area 24. When expanded by air, tube 76 fills gaps between a floor 92 and panels 18 and 20 and fills gaps between the abutting leading edges of panels 18 and 20 when door 10 is closed. A continuous flow of air through passageway 80 helps keep seal 76 relatively warm to inhibit frost from accumulating in the area of seal 76.
An extruded channel 94, similar to channel 54, can attach seal 76 to panel 18. In an alternate embodiment, however, an inflatable tube seal 96 can be created by attaching a flexible sheet of material 98 to a door panel 18′, as shown in
In another embodiment, shown in
Rather than relying solely on the heat from the surrounding air in area 24, seals 106 and 108 can be provided with a heater 113 that heats the air or fluid within the seals. Heaters 113 can be any suitable source of heat including, but not limited to, electrical resistance heat. Heaters 113 can be installed at various locations including, but not limited to, within the air passageway downstream of blower 110 (as shown in
In another embodiment, shown in
As fluid mover 118 forces fluid to circulate through the elongate passageway (interior) of seals 106′ and 108′, a heater 120 or a heater such as heater 113 heats the fluid. In this example, heater 120 is an elongate electrical resistive wire, such as conventional heat tape, that can be attached or laid loosely within the interior of seals 106′ and 108′. Cable 112, which powers fluid mover 118 and blower 110, can also power heaters 120 and 113.
Fluid mover 118 and blower 110 can be eliminated by installing an elongate wire heater, such as heater 120, within a pliable tubular seal similar to seals 106′ and 108′. The seals, however, would be urged to an expanded or inflated state by the seal's own wall stiffness or by hermetically sealing pressurized fluid within the tubular seal.
In cases where a blower is used, repeated starting and stopping of the blower can shorten its life, so the seals in such cases are preferably kept inflated regardless of whether the door is open or closed. Also, a continuous supply of air flowing through the seals helps prevent localized cooling of the seals and/or keeps the seals relatively warm. At the same time, it is considered to be within the scope of the invention to cycle the blower on and off with door activation. That is, the blower could be cycled off when the door moves away from the closed position—thereby minimizing wear on the seals by virtue of the fact that they will be deflated as the door panels move past. The blower could then be reactivated when the door is closed, allowing the seals to inflate and advantageously fill the gaps between the door panels and the surrounding walls or floor.
Although the invention is described with reference to a preferred embodiment, it should be appreciated by those skilled in the art that various modifications are well within the scope of the invention. It should be noted that the term, “door member” refers to any door-related structure including, but not limited to, floor 92; a threshold, a door frame, a lintel, wall 14; cladding 68; door panels 18 or 20; and door seals 50, 76, 96, 104, 106, or 108. The various described seal structures that move with the door panel can also be readily adapted and installed on the stationary or door member portion of the door, and vice versa. It should also be noted that the term “inflatable” when used in reference to a seal means that the seal can be inflated but is not necessarily inflated. For example, a flexible tubular seal may have sufficient rigidity to maintain an open elongate air passageway therethrough even though the air passageway is at a subatmospheric pressure. In such a case, the seal could still be inflated but is not. Instead, the air passageway is connected to the suction side of a blower, which draws air through the air passageway. Finally, while the novel and advantageous seals have been disclosed for use in association with a door, such seals could have broader application for sealing between two or more relatively movable members. In the disclosed embodiments herein, the door member represents one such relatively movable member, and the door panel represents the other. But the seal could potentially be used in a wide variety of other environments and for other purposes besides those disclosed. Therefore, the scope of the invention is to be determined by reference to the claims that follow.
Number | Name | Date | Kind |
---|---|---|---|
2420240 | Haggerty | May 1947 | A |
3303615 | O'Neal | Feb 1967 | A |
3341974 | Ganzinotti | Sep 1967 | A |
3359687 | Wallace | Dec 1967 | A |
3491825 | Matson et al. | Jan 1970 | A |
3518355 | Luce | Jun 1970 | A |
3714745 | O'Neal | Feb 1973 | A |
3745707 | Herr | Jul 1973 | A |
3809144 | Garufo | May 1974 | A |
3816867 | Shirzad et al. | Jun 1974 | A |
3840266 | Carlson | Oct 1974 | A |
3939614 | Frommelt et al. | Feb 1976 | A |
3984942 | Schroth | Oct 1976 | A |
3994103 | Ouellet | Nov 1976 | A |
4020607 | Bjervig | May 1977 | A |
4045925 | O'Neal | Sep 1977 | A |
4150509 | Knap | Apr 1979 | A |
4177353 | McCormack | Dec 1979 | A |
4238910 | O'Neal | Dec 1980 | A |
4262458 | O'Neal | Apr 1981 | A |
4293969 | Frommelt | Oct 1981 | A |
4322923 | O'Neal | Apr 1982 | A |
4371175 | Van Dyk, Jr. | Feb 1983 | A |
4372084 | Janke | Feb 1983 | A |
4579192 | Mueller | Apr 1986 | A |
4671029 | Bennett et al. | Jun 1987 | A |
4706413 | James | Nov 1987 | A |
4750299 | Frommelt et al. | Jun 1988 | A |
4813184 | Weimar | Mar 1989 | A |
4821468 | Moore | Apr 1989 | A |
5007211 | Ouellet | Apr 1991 | A |
5220696 | Dannenberg et al. | Jun 1993 | A |
5452550 | Vanesky et al. | Sep 1995 | A |
5553424 | Brockman et al. | Sep 1996 | A |
6098992 | Long et al. | Aug 2000 | A |
6922945 | Dron | Aug 2005 | B2 |
Number | Date | Country |
---|---|---|
600 117 | Dec 1977 | CH |
2220434 | Jan 1990 | GB |
Number | Date | Country | |
---|---|---|---|
20050060937 A1 | Mar 2005 | US |