This relates to overhead garage doors, in particular, a system and method for carrying an overhead garage door between a closed position and an open position.
Conventional garage doors may be formed of a single panel, or as a sectional garage door, may be formed of two or more jointed panels.
Standard garage door sizes commonly used in the garage door industry may be characterized as single, double or commercial. A double garage door may, for example, have a measurement of 16 feet wide by 7 feet high, and have a mass of up to 225 pounds. Commercial garage doors may measure up to 32 feet in width and up to 24 feet in height.
A number of techniques exist to move a garage door between a closed position and an open position. For example, a single panel garage door may tilt between a closed position and an open position using jamb-type hardware to swing up and overhead with a hinge on each side. Alternatively, a sectional garage door may have rollers that follow along a track and may be actuated by a hinge on each side of the garage door. The sectional garage door may move between a closed position and an open position overhead along a track, and the jointed panels articulate as the door moves between a closed and open position.
Mechanisms used to operate movement of a sectional garage door between a closed position and an open position may also be spring-loaded. For example, in a torsion spring lift mechanism, a torsion spring is attached to cable drums that are above each end of the garage door. The cable drums turn as the torsion spring unwinds, pulling up cables that are affixed to the bottom of each end of the garage door. As the cables wrap around the cable drums, the garage door lifts and the panels roll along an arcuate track from a vertical section to an overhead horizontal section. As the garage door rises and the torsion spring unwinds, the weight of the door is transferred to the horizontal section of the track.
An extension spring lift mechanism acts as a counterbalance to the mass of a sectional garage door. In a closed position, the spring is extended to its longest length, and when moved into a vertical position, a cable runs via a pulley system between the spring and the bottom of the garage door to lift the garage door as the spring contracts. As the garage door rises, the panels of the garage door roll along an arcuate track from a vertical section to an overhead horizontal section.
Such traditional garage door openers have a number of moving parts, including springs, cables, and pulleys, that are vulnerable to break down from normal operating wear. A commercial underground parking garage may require thousands of cycles of closing and opening of a garage door per year. The strain on such traditional systems may cause hundreds of breakdowns, causing downtime, and tens of thousands of dollars in repairs a year to keep operational.
Accordingly, there is a need for a way to move a garage door between a closed position and an open position with a longer lifespan, less downtime, and reduced operating and repair costs.
According to an aspect, there is provided a carrier system for carrying a garage door between a defined closed position in which the garage door is generally vertical and blocks entry of a vehicle into a garage through an opening, and a defined open position in which the garage door is generally horizontal and allows entry of the vehicle into the garage through the opening, the carrier system comprising: a track for guiding the garage door by rolling engagement with the track; a lever rotatable about a pivot, the lever having an in-lever arm at a first side of the pivot and an out-lever arm at a second, opposing, side of the pivot, the out-lever arm extending from the pivot to a load end, the load end rotatably connected to the garage door; and a counterweight connected to the in-lever arm to provide in-force at the in-lever arm, translated as out-force at the load end of the out-lever arm, as the lever rotates about the pivot, to carry the garage door between the defined closed position and the defined open position.
According to another aspect, there is provided a method of carrying a garage door between a defined closed position in which the garage door is generally vertical and blocks entry of a vehicle into a garage, and a defined open position in which the garage door is generally horizontal and allows entry of the vehicle into the garage, comprising: rotating a lever about a pivot, the lever having an in-lever arm at a first side of the pivot, an out-lever arm at a second, opposing, side of the pivot and rotatably connected to the garage door at a load end, and a counterweight connected to the in-lever arm, wherein the counterweight provides in-force at the in-lever arm, translated as out-force at the load end of the out-lever arm, as the lever rotates about the pivot, to carry the garage door between the defined closed position to the defined open position.
Other features will become apparent from the drawings in conjunction with the following description.
In the figures which illustrate example embodiments,
Like reference numerals in the description refer to like elements in the drawings.
The closed state of garage door carrier system 100 and garage door carrier 10, as seen in
The open state of garage door carrier system 100 and garage door carrier 10, as seen in
As shown in
Garage door carrier 10 includes a top horizontal track 30 and an arcuate track 32 curving from a vertical section at ground level to a horizontal section adjacent top horizontal track 30. Top horizontal track 30 and arcuate track 32 guide garage door carrier 10 between the closed state with garage door 20 in the closed position (for example, as shown in
Garage door carrier 10 includes a lever arm 12 that rotates about a pivot 14. An out-lever arm of lever arm 12 extends forward from pivot 14 to a load end at hinge 16. Lever arm 12 is rotatably connected by a hinge 16 to garage door 20 at an end. An in-lever arm of lever arm 12 extends rearwardly from pivot 14 to counterweight 18. A counterweight 18 is connected to lever arm 12, for example, at an end opposite hinge 16.
Rotation of lever arm 12 about pivot 14 rotates garage door carrier 10 between the closed state with garage door 20 in the closed position (for example, as shown in
Lever arm 12 may be formed from structural tubing, for example, a metal with a hollow tubular cross section. Lever arm 12 may be formed, for example, from steel square tubing that is rectangular in cross-section. In other embodiments, lever arm 12 may be formed of material that is circular, cylindrical, square or rectangular in cross-section.
As shown in
In some embodiments, the length L of lever arm 12 may be adjustable for different sized garage doors by nesting an adjustable internal tubing member within outer tubing member 13A in a similar manner as described above in extending length L of lever arm 12. The adjustable internal tubing member may be nested within outer tubing member 13A on the opposite side of pivot 14 from internal tubing member 13B. The adjustable internal tubing member may have holes that line up with holes in outer tubing member 13A, and adjustable internal tubing member may be affixed to outer tubing member 13A by use of a common fastener, for example, a nut and bolt received through aligned holes in the adjustable internal tubing member and outer tubing member 13A, as would be understood by a person skilled in the art, such that length L of lever arm 12 may be adjusted and set.
Lever arm 12 rotates about pivot 14. As shown in
Hinge 16 rotatably connects lever arm 12 to garage door 20.
Garage door hinge 22 articulates about an axis 21 and is affixed to mounting plate 19A and 19B on each side of the hinge, and supports garage door 20 as it articulates about axis 21.
Garage door 20 attaches to mounting plates 19A, 19B. In some embodiments, as shown in
In the embodiment shown in
Returning to
In some embodiments, counterweight 18 may be mounted to lever arm 12 at a distance from pivot 14 that is equal to the distance between pivot 14 and hinge 16 which connects lever arm 12 to garage door 20.
In some embodiments, counterweight 18 may extend from pivot 14 at a distance that is less than the distance from pivot 14 to the bottom extent of garage door carrier 10, or the ground.
The shape of the counterweight 18 may be dictated by a desired location of the centre of gravity of counterweight 18 in combination with the centre of gravity of the portion of lever arm 12 that is to the rear of pivot 14. As shown in
Counterweight 18 may be formed from a solid object, or structural tubing with a hollow cross-section or a u-shape in cross-section.
In some embodiments, counterweight 18 includes an accessible hollow cavity in which weights may be placed inside, and affixed with a pin and lock through a distal end of counterweight 18. In this way, the mass of counterweight 18 may be adjustable. In some embodiments, the mass of counterweight 18 may be a quarter of the mass of garage door 20. As such, the ratio of the mass of counterweight 18 to the mass of garage door 20 may be, for example, 1:4. For example, counterweight 18 may have a mass of 55 pounds, and garage door 20 may have a mass of 225 pounds.
In some embodiments, the ratio of the mass of counterweight 18 to the mass of garage door 20 may be varied to compensate for the distance from counterweight 18 to pivot 14, and the distance from hinge 16 (where lever arm 12 connects to garage door 20) to pivot 14. For example, due to the characteristics of a lever, increasing the distance between counterweight 18 and pivot 14 may allow for the mass of counterweight 18 to be reduced. Similarly, decreasing the distance between counterweight 18 and pivot 14 may lead to an increase in the mass of counterweight 18. The ratio of the mass of counterweight 18 to the mass of garage door 20 may also be dependent on the rotational force intended to be applied to lever arm 12 (in operation, as discussed below), as increasing the mass of counterweight 18 reduces the amount of rotational force required to rotate garage door carrier 10.
As shown in
Counterweight 18 is mounted to lever arm 12 at an angle θ so that as garage door carrier 10 carries garage door 20 between the closed position and the open position, the “cog” of counterweight 18 may rotate through angle θ that is equal to an obtuse travel angle (illustrated as angle β in
In some embodiments, angle θ may be greater than 90°, for example, between 90° and 180°. In some embodiments angle θ may be between 120° and 150°, for example, angle θ may be 130° as shown in
A mounting angle α is defined as the angle between a reference axis passing through the “cog” (the combined centre of gravity of counterweight 18 and the portion of lever arm 12 that is to the rear of pivot 14) and the axis of the length of lever arm 12 that extends from pivot 14 to the end of lever arm 12 to which hinge 16 is attached to rotatably connect to garage door 20.
In some embodiments, the out-lever arm of lever arm 12 is horizontal to the ground and is orthogonal to garage door 20 in the closed position, and the value in degrees of (180°−α) may be the angular rotation that in-lever arm of lever arm 12 continues past vertical before reaching the open state in which garage door 20 is in open position, as the lever arm 12 rotates between the closed state and the open state, discussed in further detail below. In the open position, the centre of gravity “cog” may be aligned with a vertical axis passing through pivot 14.
In some embodiments, mounting angle α may be greater than 90°, for example, between 90° and 180°. In some embodiments mounting angle α may be between 120° and 150°, in an embodiment, 140° as shown in
In some embodiments, angle α may equal angle θ, for example, if both angle α and angle θ are equal to 135°.
While lever arm 12 is illustrated in
Garage door 20 may be any conventional garage door. In one example, garage door 20 may be 16 feet in width and 7 feet in height, and weigh 225 pounds. Garage door 20 shown in
In some embodiments, garage door hinge 22 may form part of garage door 20, omitting the remainder of hinge mechanism 17, and hinge 16 may connect directly to garage door 20.
In some embodiments, as shown in
In other embodiments, one or more hinge mechanisms 23 may be installed at other points along the length of garage door 20.
A top roller 34, a middle roller 36 and a bottom roller 38 are connected to garage door 20 and are in rolling engagement with top horizontal track 30 and arcuate track 32. In the embodiment illustrated in
As seen in
In some embodiments, garage door carrier 10 may be supported by a frame bracket, the components including a front vertical frame (not shown), a rear vertical frame 40, a lower horizontal frame 42, central vertical frame 44, a central horizontal frame 46, and an upper horizontal frame 48.
The components of the frame bracket may be formed, for example, from 1 inch by 3 inch square steel tubing. A portion of central vertical frame 44 in an embodiment can be seen in
The components of the frame bracket may be formed in pairs. When formed in pairs, components of the frame bracket may have lateral reinforcements joining the pairs, for example, as shown with rear vertical frame 40 in
Rear vertical frame 40 may attach to the rear extent of lower horizontal frame 42 and upper horizontal frame 48. Central vertical frame 44 may provide a support for pivot pin 15C of pivot 14, and be formed of two pieces of square steel tubing, one on each side of lever arm 12 and flange bearings 15A, 15B. One or both pieces of central vertical frame 44 may attach to lower horizontal frame 42 and upper horizontal frame 48 at approximately midway the length of lower horizontal frame 42 and upper horizontal frame 48, respectively. Central horizontal frame 46 may attach to central vertical frame 44 and rear vertical frame 40. Front vertical frame may attach to the front extent of lower horizontal frame 42 and upper horizontal frame 48.
In some embodiments, the length of components of the frame bracket may be adjustable, in a similar manner to adjustable lever arm 12, as described above.
The components of the frame bracket may stabilize parts of garage door carrier 10, including pivot 14, as lever arm 12 moves between the closed state and the open state.
Sections of top horizontal track 30 and arcuate track 32 may be supported by various components of the frame bracket. For example, top horizontal track 30 may be affixed to a 2 inch by 4 inch angle bracket by a track bolt, which is in turn affixed to upper horizontal frame 48, in some embodiments via a 2 inch by 7 inch piece of wood.
Any of the components of the frame bracket may be reinforced by attachment to a building or structure. For example, lower horizontal frame 42 may be affixed to the ground, for example, anchored into the ground or a floor of a garage in which garage door carrier 10 is installed. Lower horizontal frame 42 may be anchored into concrete or fastened to an anchor, as would be understood by a person skilled in the art. Any of front vertical frame (not shown), rear vertical frame 40, upper horizontal frame 48, central vertical frame 44, and central horizontal frame 46 may be anchored to a garage ceiling. Any of front vertical frame (not shown), rear vertical frame 40, lower horizontal frame 42, upper horizontal frame 48, central vertical frame 44, and central horizontal frame 46 may be anchored to an adjacent wall or support structure, for example, screwed into a wall, anchored to a wall or in a wall stud, as would understood by a person skilled in the art. These attachments to a structure or ground may be fastened by a support angle or bracket, formed of, for example, steel, as would be known by a person skilled in the art.
The components of garage door carrier 10, in particular, the components that move during operation, may be enclosed within a cage or screen (not shown), to limit access to the components, for example, by pedestrians in the garage and may increase the safety of the system by reducing the possibility of items being caught within moving parts.
Garage door carrier 10, as bounded by the frame bracket, may require a footprint that has several (e.g., between 6 and 12, in an embodiment, 7) inches of sideroom. The headroom above garage door 20, namely the minimum distance from the top of garage door 20 to the ceiling of the garage in which it is installed, that is required for garage door carrier 10 to operate may also be several (e.g., between 6 and 12, in an embodiment, 7) inches.
Garage door carrier 10′ is generally identical in structure and components to garage door carrier 10, in mirror image such that the structure is reversed, as shown in
As shown in
As shown in
In other embodiments, one or more angled stops 54 may be installed at other points along the length of bottom strut 50.
Similarly to bottom strut 50, as shown in
In some embodiments, garage door carrier system 100 may comprise only a single garage door carrier 10 or multiple garage door carriers. One or more garage door carriers may be located to one or more sides of the opening, as shown in
Garage door carrier system 100 and garage door 20 may be installed in conjunction with a lock, as would be known to a person skilled in the art, for example, by using an electronic deadbolt to engage with garage door 20 or one of top horizontal track 30 or arcuate track 32 to inhibit movement of garage door 20 when in the closed position.
In use, garage door carrier system 100 and garage door carrier 10 move between the closed state and the open state, moving garage door 20 between the closed position as shown in
As shown in
As moment M is applied, lever arm 12 rotates about a generally horizontal axis formed by pivot 14 that is normal or generally orthogonal to the axis of the length of lever arm 12. As garage door carrier 10 rotates, lever arm 12 and counterweight 18 rotate in a vertical plane, generally parallel to the plane or planes in which top roller 34, middle roller 36 and bottom roller 38 travel as garage door 20 rotates between the closed position and the open position, and generally normal to the opening.
The mass of counterweight 18 applies an in-force gravitational force to the in-lever arm of lever arm 12, which extends rearwardly from pivot 14 to counterweight 18. This translates to an out-force at the load end of the out-lever arm of lever arm 12, which extends from pivot 14 to the load end at hinge 16.
The out-force at the load end may assist in applying force to garage door 20 as lever arm 12 rotates about the pivot, to carry garage door 20 between the defined closed position and the defined open position.
As shown in
The angular rotation of the axis of lever arm 12 between the closed state and the open state is shown as obtuse angle β in
As the garage door carrier system 100 moves from the closed state to the open state, the “cog” travels along a circular path urging carrier system 100 into a steady state at the open state.
As shown in
Garage door carrier system 100 is primarily intended for commercial use, for example, with large underground parking doors. Garage door carrier system 100 eliminates cables, chains and springs used in a standard garage door opener (for e.g., torsion spring components). With fewer moving parts, garage door carrier system 100 may have fewer stress points than traditional garage door openers, which may result in a greater number of open and close cycles before requiring maintenance or repair, leading to less maintenance and downtime and reduced repair and maintenance costs. The reduced moving parts may also result in less skill required to install garage door carrier system 100, and once installed, garage door carrier system 100 may be less likely to go out of balance or out of alignment.
Garage door carrier system 100 may also reduce the noise level of opening and closing garage door 20.
It will be appreciated that the above disclosed garage door carrier system 100 may also be used in conjunction with a traditional garage door opener that is used to move garage door 20 between the closed position and the open position.
The above described embodiments are intended to be illustrative only and in no way limiting. The described embodiments are susceptible to many modifications of form, arrangement of parts, details and order of operation. The invention is intended to encompass all such modification within its scope, as defined by the claims.
Number | Name | Date | Kind |
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2293462 | Haynes | Aug 1942 | A |
2575201 | Tillotson | Nov 1951 | A |
2585110 | Gramlich | Feb 1952 | A |
2759226 | McKee | Aug 1956 | A |
3208108 | Doring | Sep 1965 | A |
3348336 | Hashagen | Oct 1967 | A |
3608242 | Braun | Sep 1971 | A |
3631628 | Bahnsen | Jan 1972 | A |
3839827 | Dickinson | Oct 1974 | A |
4443972 | Dolhaine | Apr 1984 | A |
5384975 | Yuran | Jan 1995 | A |
9273507 | Petrat | Mar 2016 | B2 |
9677314 | Houser | Jun 2017 | B2 |
Number | Date | Country |
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694448 | Aug 1940 | DE |
Entry |
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Translation_of_DE694448.pdf. |
Number | Date | Country | |
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20190162001 A1 | May 2019 | US |