The present disclosure relates generally to a threshold system with an insulated thermal break device for a door threshold in a building structure, in particular for a garage door, and related methods of installation.
One of the first steps in building a residential or commercial structure is constructing a foundation. When it comes to residential or commercial structures, they are often built on a concrete slab foundation because of the ease of construction. However, in colder climates, a non-insulated concrete slab foundation results in cold floors and higher heating costs as heat is lost from an interior of a building to an exterior of a building. As concrete has a relatively high thermal conductance, concrete slab foundations lose energy primarily due to heat conducted outward and through the perimeter of the concrete slab foundation.
Typically, garages with heated floors are often built with hydronic radiant tubing that is often difficult to effectively insulate according to building regulations, thereby contributing to heat loss. In addition, a concrete floor within a garage door opening provides a conductive route for facilitating transfer of heat from the interior of a building to the outside.
Conventional insulation mechanisms are ineffective in especially harsh climates. For example, insulated garage doors alone can help reduce heat loss from an interior of a building. However, even then, the concrete floor extending through the garage door opening remains a conductive route for heat transfer. As a result, there remain increased energy costs associated with heating and unnecessary heat loss during colder seasons.
Thus, there is still a need for an insulated door threshold system capable of being installed that addresses the aforementioned problems of heat loss due to the movement of heat from the interior to the exterior of a building.
The present disclosure is an insulated garage door threshold for use in a garage of a building or a home. The device provides a thermal break to prevent movement of heat from an interior to an exterior of a building. More specifically, the device can provide a thermal break between heated garage floors and an exterior in colder climates.
An embodiment of the present disclosure includes a garage door threshold system. The garage door threshold system includes a thermal break device and an insulation member. The thermal break device includes an elongated sill member and an elongated base member. The elongated sill member includes a leading end, a trailing end opposite the leading end along a longitudinal direction, opposed side ends spaced apart along a transverse direction that is perpendicular to the longitudinal direction, a bottom surface, and an upper surface opposite the bottom surface. The elongated base member extends from the elongated sill member in a vertical direction that is perpendicular to the longitudinal direction and the transverse direction. The elongated base member further includes an inner surface and an outer surface opposite the inner surface. The insulation member is configured to be positioned adjacent to at least one of the bottom surface of the elongated sill member and the inner surface of the elongated base member, such that, the thermal break device and the insulation member are configured to provide a thermal break between an interior of a building structure and an exterior of a building structure when installed at a door opening.
Another embodiment of the disclosure is a thermal break device for a door opening of a building structure and configured to provide a thermal break between an interior of the building structure and an exterior of the building structure. The thermal break device includes an elongated sill member and an elongated base member. The elongated sill member includes a leading end, a trailing end opposite the leading end along a longitudinal direction, opposed side ends spaced apart along a transverse direction that is perpendicular to the longitudinal direction, a bottom surface, and an upper surface opposite the bottom surface. The elongated base member extends from the elongated sill member in a vertical direction that is perpendicular to the longitudinal direction and the transverse direction. The elongated base member further includes an inner surface, an outer surface spaced apart the inner surface along the longitudinal direction, and a lower terminal end spaced apart from the upper surface of the elongated sill member along the vertical direction. The bottom surface of the elongated sill member and the elongated base member form a receiving pocket sized to receive insulation therein.
Another embodiment of the disclosure is a method including installing insulation material in an opening in concrete aligned with a door opening. The method further includes placing a thermal break device into the opening so that an elongated sill of the thermal break device is aligned with an exterior surface near or adjacent to the door opening. The method further includes securing the thermal break device in place in the opening and pouring concrete into the opening to secure the thermal break device in alignment with the door opening.
Another embodiment of the disclosure is a method of installing a threshold system for insulating a door opening. The method includes cutting a thermal break device to a length of the door opening. The method further includes installing insulation material in an opening in concrete aligned with the door opening. The method further includes securing a thermal break device to a board adjacent a second insulation material so that an elongated sill of the thermal break device is aligned with an exterior surface adjacent the door opening. The method further includes pouring concrete into the opening to fix the thermal break device in alignment with the door opening.
The foregoing summary, as well as the following detailed description of exemplary embodiments of the present application, are better understood when read in conjunction with the appended drawings. For the purposes of illustrating the present application, there is shown in the drawings, exemplary embodiments of the disclosure. It should be understood, however, that the application is not limited to the precise arrangements and instrumentalities shown. In the drawings:
Referring to
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In addition, the door threshold system 10 is better equipped to comply with state, regional, and national building codes specific to buildings with heated floors used in cold weather climates. For example, builders and contractors in different geographic regions must follow specific guidelines and building codes regarding insulation and energy savings that are aligned with model codes such as the International Energy Conservation Code (“IECC”). Other standards that govern construction of building structures include the International Building Code (“IBC”), International Existing Building Code (“IEBC”), International Plumbing Code (“IPC”), International Mechanical Code (“IMC”) and the International Residential Code (“IRC”). As a result, building codes require that any construction be compliant with energy code requirements based on, for example, the IECC. Therefore, builders and contractors must meet or exceed an identified insulation R-value in order to comply with building codes. The door threshold system is intended to help ensure that builders and contractors meet and/or exceed energy requirements required by building codes in each jurisdiction. In many cases, especially, where radiant heating is installed in the foundation or slabs, during construction, a contractor may leave openings in the foundations proximate the door opening 5 (
Referring to
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It should be appreciated that the slope and the sealing member discussed above generally serve to restrict unwanted air and water leaks into an interior of a building. That is, the slope facilitates proper drainage of moisture and water associated with adverse weather or the melting of snow. Any runoff or debris moves in an exterior direction from the trailing end 114 to the leading end 112. As set forth in the present disclosure, the term drainage typically refers to movement of water. However, it is to be appreciated that drainage may refer to movement of any fluid, including any debris that may be entrapped within the fluid.
Continuing with
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The elongated sill member 110 and elongated base member 130 are designed to engage the driveway surface and slab but also provide an insulative “pocket” 195 to receive the insulation member 200. In other words, the bottom surface 122 of the elongated sill member 110 and the elongated base member 130 form receiving pocket 195 sized to receive the insulation member 200 therein. As shown, the elongated sill member 110 and elongated base member 130 form a generally L-shaped body. As shown in
The thermal break device 100 can be formed from a super high density polyethylene plastic or any composite material suitable for its intended purpose. It is to be understood that the elongated sill member 110 and elongated base member 130 of the thermal break device 100 are preferably fabricated of a high-density plastic or composite material that withstands ultraviolet light and is sufficiently strong enough to withstand heavy loads associated with a moving vehicle. Specifically, after the thermal break device is installed, vehicles will regularly travel on the thermal break device as they enter and exit a garage door opening of a building. As such, the thermal break device is designed to support heavy loads associated with vehicles traveling over the thermal break device on a daily basis over a long period of time.
It is to be appreciated that the elongated sill member 110 and elongated base member 130 of the thermal break device 100 can be made from various types of thermoplastics including, but not limited to, various acrylic monomers or polymers, acrylonitrile butadiene styrene (ABS), polybenzimidazole (PBI), polycarbonate, polyethersulfone (PES), polyoxymethylene (POM), polyether ether ketone (PEEK), polyetherimide (PEI), polyethylene, polypropylene, PVC, Teflon, high density poly ethylene (HDPE), or a blend of several plastics. Notably, HDPE has increased sustainability and is recyclable.
It is to be understood that thermal break device is fabricated from a material that advantageously has significant mechanical and thermal properties. For example, the thermal break device can be made from an HDPE material. The HDPE material provides increased tensile strength, scratch resistance, UV-resistance and chemical resistance. Additionally, HDPE can be easily imprinted with designs, and it is easier to clean. The HDPE material allows for the thermal break device to be easily formed with a particular color or pattern based on user preference that can withstand degradation from sunlight and mechanical damage (e.g., scratches, cracks, etc.) that might otherwise impact more conventional materials. Alternatively, it should be appreciated that the thermal break device can also be constructed of metal, aluminum, thermosetting polymers, rubber and combinations thereof.
As further discussed below, the thermal break device 100 is sized to accommodate a wide variety of garage door threshold openings. Although the thermal break device 100 is shown as having a unitary construction, it is to be appreciated that the thermal break device can be of modular construction. That is, the thermal break device can be formed with a plurality of adjacent thermal break device segments 100A-F (not shown) to adapt to the specific dimensions of an installation site. In accordance with an aspect, thermal break device segments 100A-F are configured to be coupled together end-to-end. In accordance with another aspect, the thermal break device segments may be fabricated off-site in certain designated dimensions, such as one-foot increments. Thereafter, the thermal break device can easily be cut on site with standard carpentry tools to accommodate the specific dimensions of the door opening.
As shown in
The insulation member 200 can be any high density insulation material suitable for supporting the weight of a vehicle once the thermal break device 100 is installed. In one example, the insulation member may be spray foam insulation, such as a closed-cell spray foam insulation. Closed-cell spray foam insulation refers to spray foam that is composed of cells that are completely encapsulated and tightly pressed together. Advantageously, the closed-cell structure of closed-cell insulation material reduces the absorption and migration of moisture from adjacent areas to ensure that, for example, water is not absorbed from concrete as it is being poured during installation of the thermal break device. Due partially to its extremely high density, closed-cell spray foam insulation has one of the highest R-values of any insulation material available in the industry. The R-value identifies how effective a particular insulation material is at preventing the flow of heat into and out of a building. The higher the R-value, the greater the insulation performance.
The R-value of insulation material typically will vary based on the type, thickness and density of the insulation material. As discussed throughout the present disclosure, insulation materials with higher R-values are especially advantageous and required by building codes in colder climates where residential and commercial buildings often suffer from energy inefficiency due to heat loss. For example, in the present disclosure, when properly installed, the closed-cell spray foam insulation can have an R-value of around 6.5-7 per inch.
It is to be appreciated that most residential and commercial buildings are built according to standardized building practices, e.g., uniform building codes. For example, buildings that contain metal, concrete and a combination of concrete and metal require a certain level of insulation due to the relatively high thermal conductance of metal and concrete. Further to this, state energy and building codes regarding insulation and energy savings are often guided by model codes such as the IECC and others referenced above. These requirements often consist of specific R-value requirements for insulation in building construction based on the geographic region. As a result, it is to be understood that the R-value for the insulation member 200 can be adjustable for the door threshold system so long as the insulation member 200 meets or can be adapted to meet the configuration of the present disclosure and any applicable construction regulations.
As discussed above, building code regulations often vary by climate zone. For example, building code regulations in New Hampshire's State Building Code Review Board (See https://www.nh.gov/safety/boardsandcommissions/bldgcode/) are governed by climate zones 5 and 6 and require that insulation for residential and commercial buildings correspond to a specific R-value. In accordance with an aspect, the R-value of the door threshold system 10 is preferably between about 12 and about 17. In one example, the R-value of the door threshold system 10 is 13.
As shown in
The second insulation member 220 can be a rigid foam strip or a rigid foam material including, but not limited to polyisocyanurates polyurethanes, extruded polystyrene, expanded polystyrene, tannic foams, phenolic foams, biophenolics foams, and combinations thereof.
Referring now to
In the present disclosure, the at least one fastener 245 is configured to secure the thermal break device 100 to the form board 240. Specifically, fastener 245 secures the elongated base member 130 to form board 240. Although the form board 240 is shown adjacent the outer surface 134 of the elongated base member 130, it is to be understood that the fastener 245 can secure the thermal break device 100 to a wood board (not shown) placed in the concrete foundation 284 near a door opening. In that scenario, the fastener 245 can extend through thermal break device 100 and into the wood board in the concrete foundation. It is to be appreciated that any type of fastener suitable for its intended purpose of securing the thermal break device 100 to form board 240 can be used.
It is appreciated that secondary fasteners may also be used to further secure the thermal break device 100 in position. For example, in accordance with another aspect, the door threshold system 10 can further include a pair of secondary fasteners (not shown) to secure the elongated base member 130 directly to the concrete foundation 284. The secondary fasteners can be any type of fasteners such as metal screws, self-threading screws, bolts, rivets, etc. with or without washers for additional support.
Referring now to
In operation, an installer or builder may initially determine the required length for the garage door threshold system by measuring the length of the door opening. The thermal break device is then cut to a desired length based on the length of the door opening. Thereafter, insulation material such as closed-cell spray foam insulation is installed into the concrete opening leaving a gap of approximately 2 inches to accommodate the elongated sill of the thermal break device. Subsequently, the thermal break device 100 is positioned in the opening so it is in contact with the slab 284 and/or floor 185. The thermal break device 100 can be fixedly attached to insulation material at a desired height or position. Additionally, fasteners are used to secure the thermal break device to a form board adjacent an outer surface of the elongated base member. The form board also serves as a retaining wall to ensure that concrete is properly poured. It is to be understood that the thermal break device can optionally be further secured to the foundation 284 and/or floor 185. Thereafter, the concrete (i.e., cast-in-place concrete) is poured into the gap between the foundation and the elongated sill member. As a result, the plurality of studs extending from the bottom surface of the elongated sill member are embedded into the concrete floor once cured. That is, the plurality of studs facilitates securing the thermal break device in place once the concrete floor is cured. The form board can then be subsequently removed. It is to be understood that the thermal break device is configured for use with the construction of new residential, commercial, or industrial buildings. For example, the thermal break device could be used with any building that suffers from heat loss through slab openings including, but not limited to, residential, commercial, industrial, municipal or any other mixed-use building.
Embodiments of the present disclosure will now be further described with respect to exemplary methods that utilize the garage door threshold system and the thermal break device described herein. For example, the garage door threshold system may be used in a particular method for insulating a door opening. One of the first steps in building a residential or commercial structure is pouring a foundation, e.g., a concrete slab foundation. As the concrete slab for the intended building structure is poured, the slab may include other devices to enhance strength, such as reinforcement bars. It is to be understood that wire mesh and/or additional steel reinforcing bars may be implanted in the concrete slab for additional structural integrity. As part of this process, a driveway surface is formed such that it is aligned with the door opening, such as a garage door opening of the building structure. When the driveway surface and concrete slab are formed, there is a break, i.e., opening, between the driveway surface and the concrete slab for positioning the thermal break device therein.
Specifically, the method includes installing insulation material in an opening in concrete aligned with the door opening. The method also includes placing a thermal break device into the opening so that an elongated sill of the thermal break device is aligned with an exterior surface near or adjacent to the door opening. The method also includes securing the thermal break device in place in the opening. The method further includes pouring concrete into the opening to secure the thermal break device in alignment with the door opening.
The method may further include, after securing the thermal break device in place in the opening, securing the thermal break device to a foundation in the opening. The thermal break device is secured to a form board adjacent a second insulation material via a plurality of fasteners. The method may further include, before placing a thermal break device into the opening, cutting the thermal break device to correspond to a measured length of the door opening. The method may further include, wherein pouring concrete into the opening causes a plurality of studs extending from a bottom surface of the elongated sill to be embedded into the concrete.
Another general example may include a method of installing a threshold system for insulating a door opening. The method includes cutting a thermal break device to a length of the door opening. The method further includes installing insulation material in an opening in concrete aligned with the door opening. The method further includes securing the thermal break device to a form board adjacent a second insulation material so that an elongated sill of the thermal break device is aligned with an exterior surface adjacent the door opening. The method may further include pouring concrete into the opening to fix the thermal break device in alignment with the door opening.
Implementations may include one of the following features or steps. The method may include, wherein pouring concrete into the opening causes a plurality of studs extending from a bottom surface of the elongated sill to be embedded into the cast-in-place concrete.
While the exemplary embodiments discussed above illustrate the thermal break device 100 as installed within a garage door threshold opening, it is to be understood that the thermal break device can also be installed in a doorway opening to provide a thermal break. It is to be understood that the thermal break device as described throughout the present disclosure can be used for insulating thresholds of door openings of any size and in any structure. For example, the thermal break device may also be used on trailers, sheds, delivery trucks, industrial doors, animal enclosures, metal buildings, campers, boats, ice shanties, or any other structure having an opening where insulation may be necessary.
Referring now to
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Wherever possible, the same or like reference numbers are used throughout the drawings to refer to the same or like features. It should be noted that the drawings are in simplified schematic form and are not drawn to precise scale. Certain terminology is used in the description is for convenience only and is not limiting. Directional terms such as top, bottom, left, right, above, below and diagonal, are used with respect to the accompanying drawings. The words “inwardly” and “outwardly” refer to directions toward and away from, respectively, the geometric center of the identified element and designated parts thereof. Such directional terms used in conjunction with the following description of the drawings should not be construed to limit the scope of the present disclosure in any manner not explicitly set forth. Additionally, the term “a,” as used in the specification, means “at least one.” The terminology includes the words above specifically mentioned, derivatives thereof, and words of similar import.
“Substantially” as used herein shall mean considerable in extent, largely but not wholly that which is specified, or an appropriate variation therefrom as is acceptable within the field of art. “Exemplary” as used herein shall mean serving as an example.
Furthermore, the described features, advantages and characteristics of exemplary embodiments may be combined in any suitable manner in one or more embodiments. One skilled in the art will recognize, in light of the description herein, that the exemplary embodiments can be practiced without one or more of the specific features or advantages of a particular embodiment. In other instances, additional features and advantages may be recognized in certain embodiments that may not be present in all embodiments of the present disclosure.
While the disclosure is described herein, using a limited number of embodiments, these specific embodiments are not intended to limit the scope of the disclosure as otherwise described and claimed herein. The precise arrangement of various elements and order of the steps of articles and methods described herein are not to be considered limiting. As such, the method can be implemented in any order as desired.
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