This invention relates generally to movable barrier operators and more particularly to devices used to counter the weight of a movable barrier.
Movable barrier operators of various kinds are known in the art. Such movable barrier operators often work in conjunction with a corresponding movable barrier such as a single panel or segmented garage door, a rolling shutter, a pivoting, swinging, or sliding gate or arm barrier, and so forth. In particular, the movable barrier operator typically responds to user inputs (often as input via a remotely located user interface) to effect selective movement of a corresponding movable barrier (for example, to transition the movable barrier back and forth between a closed and an opened position).
A variety of mechanisms may serve to effect the movement of a movable barrier, including electric motors linked to the movable barrier through chain, belt, or screw driven mechanisms. Fluid-based operators that rely upon a rigid cylinder are also known in the art as a way to effect the movement of a movable barrier. These systems rely upon either hydraulic or pneumatic pressure to actuate a piston mechanically linked to the movable barrier. When hydraulic or pneumatic pressure increases in the rigid cylinder, the piston extends from the cylinder. Fluid-based operators have not gained popular success, however. Expense of the system components, labor intensive installation, specialized knowledge or tools required for installation, and the large amount of space required for such systems have prevented their popular adoption. Rigid piston and cylinder mechanisms are expensive to manufacture, requiring tight tolerances and specialized materials. Fluid-based operators also rely upon complicated mechanisms to translate the motion of a rigid cylinder into motion of the movable barrier. In many cases, these mechanisms require large amounts of space and are difficult to install and calibrate. Some of the known fluid-based movable barrier operators rely upon a second rigid cylinder to counterbalance the weight of the door. This configuration increases the costs associated with the fluid-based operator, because it requires duplication of expensive piston and cylinder components.
In conjunction with vertically lifted movable barriers, for example single panel or segmented garage doors and rolling shutters, counterbalance mechanisms are typically provided to reduce the effort required to lift the movable barrier. Counterbalance mechanisms that rely upon mechanical springs, such as torsion or extension springs, are known in the art, as are pneumatic mechanisms that rely upon a rigid piston and cylinder acting as an energy storage device.
An example prior art counterbalance mechanism will be described with reference to
A garage door opener 1050 lifts and lowers the garage door 1001 by pulling a carriage 1051 along a lift track 1052 using a chain, belt, or screw. The carriage 1051 is connected to the garage door 1001 through a linkage 1053. As the garage door is raised, the weight of the segments 1002, 1003, 1004, and 1005 becomes supported as they move from the vertical portion 1022 to the horizontal portion 1021 of the garage door track 1020. In this way, the force required to lift the garage door 1001 becomes less as more segments pass along the horizontal portion 1021 of the garage door track. The prior art torsion spring 1035 accommodates this decrease in the weight of the garage door 1000 because it exerts less force as it relaxes. The torsion spring 1035 must be sized appropriately so that the reduction in its force corresponds correctly to the position of the garage door. Any one of several sizes of torsion spring 1035 could be required, based on the width of the garage door 1001 and the relative weight of the garage door 1001. For example, different springs 1035 would be required for a two-car garage than for single car garages. Likewise, wood doors are substantially heavier than foam-cored metal doors and therefore require different springs 1035. Because this type of counterbalance mechanism is a commonly installed system, there is a need for counterbalance mechanisms that can be retrofitted on these types of existing movable barriers systems.
Counterbalance mechanisms that rely upon mechanical springs are known to have sudden failures that can be disturbing for people in the vicinity. If the spring is not adequately secured during installation, or if the spring loosens during ordinary operation, it may snap loose as the movable barrier is lowered. Further, mechanical springs typically have a relatively short lifespan. The mechanical springs known in the art and used to counterbalance the weight of movable barriers commonly fail after as few as 10,000 cycles. Particularly in industrial and commercial door installations, the limited lifespan of mechanical springs requires frequent replacement of the springs. Replacing these mechanical springs is a labor intensive procedure that requires disassembly of the entire jack-shaft assembly. The mechanical spring is coiled around the outside of the jackshaft, so the only way to replace the spring is to remove the jackshaft completely and slide the spring off the end of the shaft.
When used as counterbalance mechanisms, mechanical springs require careful selection to match the weight of the door. The characteristics of the spring, such as spring constant and/or the displacement the spring is capable of, must be selected according to the weight and size of the door. Because these characteristics are fixed in a mechanical spring, manufacturers must stock a variety of springs.
Pneumatic counterbalance mechanisms that rely upon a rigid piston and cylinder suffer from the high costs associated with fluid-based movable barrier operators. The system components are expensive to manufacture and install for many of the same reasons discussed above.
In light of these disadvantages of the known current counterbalance and movable barrier operator systems, there is a need for a counterbalance mechanism and movable barrier operator that is robust and capable of a longer lifespan, that may be easily installed on existing jackshaft mechanisms, that reduces risks during installation and the likelihood of failure during use, and that may be installed using commonly available tools and knowledge.
The above needs are at least partially met through air spring counterbalance approaches described in the following detailed description, particularly when studied in conjunction with the drawings, wherein:
Skilled artisans will appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions and/or relative positioning of some of the elements in the figures may be exaggerated relative to other elements to help to improve understanding of various embodiments of the present invention. Also, common but well-understood elements that are useful or necessary in a commercially feasible embodiment are often not depicted in order to facilitate a less obstructed view of these various embodiments of the present invention. It will also be understood that the terms and expressions used herein have the ordinary meaning as is accorded to such terms and expressions with respect to their corresponding respective areas of inquiry and study except where specific meanings have otherwise been set forth herein.
Generally speaking, pursuant to these various embodiments, an air spring is mechanically connected to support the weight of a movable barrier. For example, the air spring is configured to exert a linear force, which is converted through a mechanical coupling into a rotational force that counterbalances the weight of the movable barrier through a jackshaft. More specifically, a fluid-based spring counterbalance mechanism including an elastic flexible fluid-based spring disposed between two surfaces is used to support some or all of the weight of a movable barrier. A linkage mechanism comprising at least one rotatable shaft is configured to receive rotational motion from a jackshaft associated with the movable barrier. A translational mechanism coupled to the at least one rotating shaft and coupled to at least one of the two surfaces is configured to compress the flexible fluid-based spring between the two surfaces in response to rotation of the rotatable shaft. By compressing the fluid-based spring, the counterbalance mechanism provides a force that partially or fully supports the weight of the movable barrier.
So configured, a single type of fluid-based spring such as an air spring can be configured to work with a variety of barrier types because the fluid-based spring's counterbalance effect can be controlled by adjusting the pressure within the spring. Accordingly, a minimal number of types of fluid-based spring systems can be applied to a large number of barrier types such that the spring to barrier matching problem is largely reduced or eliminated. Moreover, typical fluid-based springs can be expected to have a longer expected lifetime than the 10,000 cycle lifetime expected of typical mechanical torsion springs. Additionally, fluid-based springs are less likely to fail in a sudden event, instead gradually losing the ability to maintain a pressure sufficient to counterbalance a barrier. Such a failure mode provides an opportunity to replace a fluid-based spring before total failure of the system. These and other benefits will become apparent through study of the following description and accompanying figures.
Turning to the figures, an example air spring counterbalance mechanism 100 for a movable barrier is shown in
In the illustrated example, the translational mechanism includes a cable 150 made of metallic wire rope or other suitably strong and flexible connecting material that is fixed at its first end 151 to the fixed plate 120. In other approaches, the cable 150 is fixed to the movable plate 130. The cable 150 passes through a hole 131 in the moveable plate 130 and over a pulley 160 having a groove 161 configured to support the cable 150. The pulley 160 rolls on a shaft 162 that is supported by flanges 132 that protrude from the bottom of the movable plate 130. In another approach, the flanges 132 supporting the pulley 160 protrude from the top of the movable surface 130, alongside the air spring 110. The second end 152 of the cable 150 is coupled to a drum 170. As the drum 170 rotates, it takes up the cable 150 and causes the movable plate 130 to compress the air spring 110 by reducing the distance between the fixed plate 120 and the movable plate 130. The combination of the two plates 120 and 130, along with the cable 150 and the drum 170, comprise a translational mechanism designed to compress the air spring 110.
In this example, the drum 170 is coupled through a planetary gear mechanism 171 to a rotatable shaft 180. The rotatable shaft 180 is supported by flanges 123 that protrude from the top surface of the fixed plate 120. The rotatable shaft 180 may include a keyway 181 or other indexing feature used to link the shaft 180 to other shafts, including the jackshaft 1130 described with respect to
With brief reference to the example of
With reference to
The use of the air spring 110 in this mechanism provides several benefits over a traditional coil spring. The force generated by the air spring 110 at a given displacement is capable of adjustment by increasing or reducing the air pressure within the air spring 110. A nozzle 116 allows air to be added or removed from the air spring 110 to adjust air spring's 110 internal air pressure. The nozzle 116 preferably incorporates a one-way valve or other mechanism to capture the air pressure added to the air spring 110. Because the air spring's 110 internal air pressure correlates to its output force, the air spring counterbalance mechanism 100 can be adjusted simply by adjusting the air spring's 110 air pressure to accommodate many different sizes and weights of movable barrier. Thus, a single air spring counterbalance mechanism 100 can serve to replace multiple mechanical springs. Instead of stocking an inventory of different torsion springs for different door-weights, a single air spring mechanism can be installed and then adjusted to accommodate a given movable barrier.
Another benefit of the air spring, as compared to traditional coil springs, is the reduced likelihood of a sudden failure in the counterbalance mechanism. Mechanical springs have a tendency to fail suddenly and with little warning. In contrast, air springs are most likely to fail gradually, typically through loss of pressure over time due to a gradual leak. This provides ample warning of the imminent failure. When complete failure occurs, the spring gradually goes limp rather than suddenly and uncontrollably releasing energy. In addition, air springs are known to have substantially longer cycling lifespans than the mechanical torsion springs commonly used in movable barrier counterbalance mechanisms.
The air spring 510 is mounted between a fixed plate 520 and a movable plate 530. The cables 550 are fixed at a first end 551 to the fixed upper surface and route through holes 531 in the movable plate 530. The cables pass over pulleys 560 and through a second set of holes 531 in the movable plate 530. The pulleys 560 rotate on shafts 562 that are supported by a housing 533 that extends from the bottom surface of the movable plate 530. The cables 550 then route through holes 524 in the fixed plate 520 and are mounted to a drum (570 shown in
Other approaches of the translational mechanism are possible, as would be envisioned by a person having ordinary skill in the art. These might include, but would not be limited to, various methods of fixing the cable 550 to the plates 520 and 530, the use of multiple drums 570 to take up the cable 550, and designs in which the pulleys 560 are eliminated by fixing the cables 550 to the movable surface 530.
Bottom side plates 633 extend vertically from the movable plate 630. Four guide rollers 634 are mounted on each of the bottom side plates 633. The guide rollers 634 are supported by shafts 635 that extend outwardly from the bottom side plates 633. The rollers 634 are mounted such that they bear against the vertical stabilizers 625. In this way, the rollers 634 and the vertical stabilizers 625 keep the movable plate 130 substantially parallel to the fixed plate 120.
As discussed with respect to
Turning to
The air spring counter balance 1100 is intended to replace other counterbalancing mechanisms such as the mechanical torsion spring (e.g., 1035 in
The design of the air spring counterbalance mechanism is advantageous over the mechanical torsion springs that are typically used as movable barrier counterbalance mechanisms. Because the air spring counterbalance mechanism can be installed at the end of the jackshaft, the jackshaft does not need to be disassembled and removed when the air spring counterbalance mechanism is installed or replaced. This reduces the time and labor required to install or replace the air spring counterbalance mechanism, which is a benefit to any owner of a movable barrier system. The reduction in time and labor is a particular benefit for owners of commercial and industrial movable barriers, which are subject to more frequent use and consequently more frequent replacement.
The relationship between displacement, force, and pressure within the Goodyear® 1S4-008 air spring is plotted in
The variable force exerted by an air spring is one advantage associated with various ones of the described designs. By adjusting the fluid pressure in the air spring, the air spring counterbalance can be adjusted to match the force needed to balance the weight of the movable barrier, which offers several benefits. Because the force exerted by the air spring counterbalance mechanism corresponds to the pressure of the air in the air spring, the counterbalance mechanism can be installed in a de-energized state and later pre-loaded by pressurizing the air spring, reducing the level of skill and training required to install the counterbalance device. In contrast, mechanical torsion springs must be pre-loaded before they are secured, or as part of the process of securing the spring. If the mechanical spring is improperly secured after pre-loading, the spring may snap loose suddenly and release its stored energy.
Further, as illustrated in
Additionally, by varying the pressure within the air spring, the air spring counterbalance can be used to move a garage door (e.g., 1101 depicted in
Operating circuitry is configured to control a position of a movable barrier by effecting adding pressurized fluid to the flexible fluid-based spring from the source of pressurized fluid coupled to the flexible fluid-based spring or by effecting removal of pressurized fluid from the spring via a release mechanism operably controlled by the operating circuitry. In the illustrated example, the operating circuitry includes control electronics 1330 that provide signals to the valve 1310 and the compressor 1320 to control the operation of those devices. The valve control wire 1331 provides a signal that indicates to the valve 1310 to go to the open state, or the exhaust state, or to a no-flow state. In the open state, air is added to the air spring 110, and the pressure in the air spring is consequentially increased. In the exhaust state, air flows from the air spring 110 through the exhaust port 1313 of the valve 1310, reducing the pressure in the air spring 110. Preferably, the exhaust port 1313 includes a constriction that limits the amount of air exiting the air spring 110 to a controlled rate. In the no-flow state, the air spring 110 is closed off and maintains whatever pressure is already in the air spring 110. In one approach, the signal transmitted via the wire 1333 is a digital electronic signal (e.g. 12V, −12V, or 0V). Alternative approaches could include analog electronic signals or any communication signal known in the art. In one alternative approach, the valve 1310 is replaced with a pressure regulator, such that the electronic signal sent over the wire 1331 commands the regulator to maintain a certain pressure within the air spring 110. The compressor control wire 1332 provides a signal that indicates to the compressor 1320 that the compressor should run. As with the signal sent to the valve 1310, a digital signal is preferred for control of the compressor 1320, but other signals could be used in alternative approaches. In still other approaches, the signal may indicate the desired pressure that the compressor 1320 should generate.
The control electronics 1330 also receive signals. A pressure gauge 1340 is mounted inline in the hose 1311 between the valve 1310 and the air spring counterbalance 100. The pressure gauge 1340 provides a signal via a pressure signal wire 1333, so that the control electronics 1330 knows what pressure exists within the air spring counterbalance 100. In other approaches, a wire 1337 connected to a strain gauge on the cable 150 might provide information about the force exerted by the air spring counterbalance. Similarly, a wire 1338 connected to a torque sensor mounted to the shaft 180 might indicate the output torque generated by the air spring counterbalance. The control electronics 1330 receive command signals, either through electro-magnetic radiation such as radio or light-based signals or through a wired connection 1334 to a command button. Door position sensors provide position information for the garage door 1101 to the control electronics 1330 via wires 1335 and 1336. The door position sensors may alternatively be proximity sensors or digital encoders, and additional wires may be added to the system to accommodate these different sensors. In alternative approaches, any of the signals received by the control electronics 1330 could be received via a wireless communications protocol.
The control electronics comprises a processor capable of receiving command signals and pressure signals. The processor is also capable of acting upon those signals based on predetermined logic and providing output signals to the valve and the compressor such that those devices modulate the pressure in the air spring and therefore operate the air spring to move a garage door (e.g., 1101 in
Each of the counterbalance mechanisms 1400 is connected to a low voltage control line 1492 and a compressed air line 1491. The low voltage control line 1492 may comprise wiring for digital or analog signals, or any wired communication known to a person having skill in the art. Wireless communications are also possible. Each counterbalance mechanism 1400 has a valve (e.g., 1310 depicted in
Each counterbalance mechanism 1400 has position sensors 1402 and 1403 capable of determining the position of the door. Position sensors 1402 and 1403 may include proximity sensors, light beams, encoders or any other sensors known to a person having ordinary skill in the art. In one approach, the low voltage control line 1492 transmits signals to the control unit 1490 from the sensors 1402 and 1403 located at the counterbalance mechanisms 1400. In another approach, the sensors 1402 and 1403 are configured to send signals to the control electronics for the corresponding counterbalance mechanism, which can control the movement of the barrier at least in part in response to the signals from the sensors 1402 and 1403. In another approach, the counterbalance mechanism 1400 may include an encoder or other sensor designed to determine the position of the drum 1404.
Optionally, as described in step 1560, the air spring is connected to a source of pressurized air. The pressurized air source may optionally be used at step 1570 to maintain the pressure in the air spring. This is accomplished by periodically adding a volume of air to the air spring, by using a pressure regulated valve to maintain a constant pressure in the air spring or by adding pressure or volume based on ambient temperature or the observed position of the door. The pressure source should be configured in step 1550, to the extent any of these mechanisms, or some other mechanism, is used to maintain the pressure in the air spring. These alternative approaches are implemented through hardware described with respect to
In addition to setting the fluid pressure to counterbalance the weight of the movable barrier, the fluid pressure may be controlled dynamically to operate the movable barrier. By controlling the fluid pressure in the air spring, the barrier may be raised or lowered. In this mode of operation, the air spring counterbalance serves as both a counter balance mechanism and as a movable barrier operator. This system offers many advantages because it replaces both the movable barrier operator (e.g., 1050 in
If the control electronics 1330 determines that the barrier is to be raised, the system proceeds to step 1620 and fluid is added to the air spring, by opening the valve 1310 discussed in
If the control electronics 1330 determines that the barrier is to be lowered, the system proceeds to step 1630 and fluid is released from the air spring by putting the valve in the exhaust state, as discussed with respect to
Those skilled in the art will recognize that a wide variety of modifications, alterations, and combinations can be made with respect to the above described embodiments without departing from the spirit and scope of the invention, and that such modifications, alterations, and combinations are to be viewed as being within the ambit of the inventive concept. This will also be understood to encompass various combinations and permutations of the various components that have been set forth in these teachings.
This application is a continuation of the previously filed U.S. patent application Ser. No. 14/079,716, filed on Nov. 13, 2013, to be issued as U.S. Pat. No. 8,813,429, which application is a divisional of the previously filed U.S. patent application Ser. No. 13/628,691, filed on Sep. 27, 2012, now issued as U.S. Pat. No. 8,590,209, both of which applications are incorporated by reference in their entirety as though fully rewritten herein.
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Number | Date | Country | |
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Parent | 13628691 | Sep 2012 | US |
Child | 14079716 | US |
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Parent | 14079716 | Nov 2013 | US |
Child | 14467081 | US |