A variety of automotive lift systems have been made and used over the years in a variety of contexts. Some types of automotive lifts are installed in-ground while other types are installed above-ground. One type of above-ground automotive lift is known as a parallelogram lift in which the supporting platform, such as a pair of deck rails aligned with the vehicle's wheels, is raised on sets of legs that pivot in relation to the deck rails. By increasing the angular relation between the deck rails and the legs of the lift, the deck rails can be maintained relatively level while being raised to the desired height. This may eliminate the central post or scissor linkages that may exist in other types of lift systems, allowing service personnel unobstructed access to the underside of the vehicle.
Examples of automotive lifts are disclosed in U.S. Pat. No. 5,096,159, entitled “Automotive Lift System,” issued Mar. 17, 1992, the disclosure of which is incorporated by reference herein; U.S. Pat. No. 6,059,263, entitled “Automotive Alignment Lift,” issued May 9, 2000, the disclosure of which is incorporated by reference herein; U.S. Pat. No. 6,213,451, entitled “Lifting Apparatus,” issued Apr. 10, 2001, the disclosure of which is incorporated by reference herein; and International Pub. No. WO 2007/148960, entitled “Vehicle Elevator and Lift Therein,” published Dec. 27, 2007, the disclosure of which is incorporated by reference herein.
While a variety of automotive lift systems have been made and used, it is believed that no one prior to the inventors has made or used an invention as described herein.
While the specification concludes with claims which particularly point out and distinctly claim the invention, it is believed the present invention will be better understood from the following description of certain examples taken in conjunction with the accompanying drawings, in which like reference numerals identify the same elements and in which:
The drawings are not intended to be limiting in any way, and it is contemplated that various embodiments of the invention may be carried out in a variety of other ways, including those not necessarily depicted in the drawings. The accompanying drawings incorporated in and forming a part of the specification illustrate several aspects of the present invention, and together with the description serve to explain the principles of the invention; it being understood, however, that this invention is not limited to the precise arrangements shown.
The following description of certain examples of the invention should not be used to limit the scope of the present invention. Other examples, features, aspects, embodiments, and advantages of the invention will become apparent to those skilled in the art from the following description, which is by way of illustration, one of the best modes contemplated for carrying out the invention. As will be realized, the invention is capable of other different and obvious aspects, all without departing from the invention. Accordingly, the drawings and descriptions should be regarded as illustrative in nature and not restrictive.
Exemplary Lift Actuation System
The structure of lift (10) will hereinafter be described in relation to one runway deck (19) (identified as 19a in
As shown in
As shown in
Lifting legs (30) near the front and near the rear of runway deck (19) are thus both secured to the same pair of sliding bodies (50) in the present example. As described in greater detail below, sliding bodies (50) are engaged into channels (28) formed within deck rail (20), and are configured to slide along at least a portion of the length of deck rail (20). Each runway deck (19) thus has a corresponding pair of sliding bodies (50), with the sliding bodies (50) of each pair being coupled together by axles (51) at the front end of the sliding body (50) pair and by piston block (78) at the rear end of the sliding body pair. Axles (51, 154) are configured to allow the corresponding legs (30) to rotate relative to sliding bodies (50).
As noted above, and as shown in
It should also be understood that legs (30a, 30b) and their two associated sliding bodies (50) together form a unitary sliding assembly in the present example. In other words, legs (30a, 30b) and their two associated sliding bodies (50) slide unitarily relative to their associated runway deck (19), with legs (30a, 30b) pivoting relative to their two associated sliding bodies (50) during such sliding. While sliding bodies (50) are each formed as one continuous piece in the present example, other suitable configurations may be used. By way of example only, each sliding body (50) may be broken up into two or more components that are unitarily coupled together by a bar or other third component. Other ways in which a unitary sliding assembly may be configured, including alternative components, features, and arrangements, will be apparent to those of ordinary skill in the art in view of the teachings herein.
Each leg (30) is also tied to runway deck (19) by a pair of link arms (42). Each link arm (42) has an upper end pivotally secured to a corresponding link arm mount (43), as shown in
As shown in
The configuration of the present example causes runway decks (19) to rise vertically as lift (10) is raised. Optimal leverage may be obtained when link arm (42) is secured to its associated leg (30) at approximately the midpoint of the leg (30). Alternatively, link arm (42) may be secured to any other suitable position along the length of its corresponding leg (30). The length of link arm (42) may be approximately one half of the length of its corresponding leg (30). Alternatively, link arm (42) may have any other suitable length, and such length may bear any suitable relationship with the length of legs (30).
Thus, in the present example, runway deck (19) is raised by applying a force to sliding bodies (50) to force them rearwardly along channels (28) of deck rails (20), decreasing the angulation between link arms (42) and the upper portions of legs (30) and at the same time increasing the angular relation of legs (30) relative to deck rail (20) (and floor (4)). In the present example, this is accomplished by providing a hydraulic actuator comprising a hydraulic cylinder (70) mounted at a fixed position, concealed underneath floor (26) of runway deck (19), laterally between the respective paths of travel of sliding bodies (50). Hydraulic cylinder (70) of the present example comprises a conventional single-end, two stage, single-acting type of hydraulic cylinder. By way of example only, hydraulic cylinder (70) may be configured in accordance with the teachings of U.S. Pat. No. 3,269,275, entitled “Two Stage Hydraulic Cylinder,” issued Aug. 30, 1966, the disclosure of which is incorporated by reference herein. Alternatively, any other suitable type of hydraulic cylinder may be used.
A hydraulic mount (100) is rigidly welded to the underside of floor (26) of runway deck (19) in the present example, though any other suitable structures or techniques for securing hydraulic mount (100) relative to runway deck (19) may be used. Hydraulic mount (100) is coupled with hydraulic cylinder (70) via a clevis (102). Clevis (102) may thus provide some degree of rotational freedom for hydraulic cylinder (70) (e.g., about an axis defined by a pin, bolt, or other fastener coupling hydraulic cylinder (70) with clevis (102)). In some settings, a clevis (102) connection between hydraulic cylinder (70) and runway deck (19) may be preferable over a rigid connection. For instance, if runway deck (19) deflects under the load of vehicle (2), the degree of freedom for hydraulic cylinder (70) provided by clevis (102) may keep the load of vehicle (2) from being transferred to hydraulic cylinder (70). Similarly, clevis (102) may reduce premature wear of components of hydraulic cylinder (70) that might otherwise occur when side loads are exerted on hydraulic cylinder (70). It should be understood that a variety of other types of components and techniques may be used to secure hydraulic cylinder (70) relative to runway deck (19), in addition to or in lieu of hydraulic mount (100) and/or clevis (102). Such alternative components or techniques may or may not provide a degree of freedom for hydraulic cylinder (70).
Hydraulic cylinder (70) of the present example drives a piston shaft (72) which projects out of one end of cylinder (70). The free end of piston shaft (72) is affixed to the sliding bodies (50), at piston block (78) that is positioned between sliding bodies (50) near the top ends of supporting members (31) of rear leg (30b), as shown in
Referring back to
Exemplary Braking System
Lift (10) of the present example further includes an incremental braking mechanism, which selectively locks sliding bodies (50) into position within channels (28) at the desired elevation of runway decks (19). The braking mechanism allows runway decks (19) to be set to virtually any desired elevated position, and provides a means for preventing free-falling of runway decks (19) in the event of hydraulic system failure. In particular, the braking mechanism is configured to bear the load of a vehicle. In the present example, each lift assembly (10a, 10b) has just one braking mechanism, though it should be understood that any other suitable number of braking mechanisms may be used.
As shown in
The braking mechanism of the present example further comprises a pawl (120), which is configured to selectively engage slots (112) of brake ground (110) to provide selective braking. Pawl (120) is pivotally coupled with a carriage (122), which is secured to and extends rearwardly from block (156). A mounting plate (124) is also secured to carriage (122). Mounting plate (124) carries a pneumatic cylinder (126) which is configured to selectively extend and retract a pneumatic piston shaft (128). In particular, pneumatic cylinder (126) comprises a pull-type cylinder, such that piston shaft (128) is retracted into pneumatic cylinder (126) when a pressurized medium is communicated to pneumatic cylinder (126). In some other versions, pneumatic cylinder (126) is configured such that piston shaft (128) is drawn into pneumatic cylinder (126) when a vacuum is induced in pneumatic cylinder (126). In still other versions, a solenoid-type electromechanical actuator or hydraulic actuator is used instead of pneumatic cylinder (126). Alternatively, any other suitable type of actuator or similar device may be used.
Piston shaft (128) is coupled with pawl (120) by a bracket (130), which is welded to pawl (120) in the present example. A spring (132) resiliently couples bracket (130) with block (156), and is biased to urge pawl (120) (via bracket (130)) into engagement with slots (112). While a coil spring (132) is used in the present example, it should be understood that any other suitable type of resilient member or other type of structure for biasing pawl (120) may be used. A stop member (134) is secured to piston shaft (128), and is configured to restrict movement of bracket (130) along the length of piston shaft (128). When piston shaft (128) is retracted relative to pneumatic cylinder (126) (e.g., by communicating a pressurized medium to pneumatic cylinder (126)), stop member (134) pulls on bracket (130) to disengage pawl (120) from slot (112), overcoming the resilient bias provided by spring (132). When piston shaft (128) is thereafter extended relative to pneumatic cylinder (126) (e.g., by venting or providing positive pressure to pneumatic cylinder (126)), spring (132) pulls bracket (130) to engage slot (112). Pneumatic communication with pneumatic cylinder may be controlled by controller (210), which is described in greater detail below, or such control may be provided in any other suitable fashion.
It should be understood that during operation of lift (10), with the exception of brake ground (110), the braking mechanism of the present example slides unitarily with sliding bodies (50) and other members of the sliding assembly described above. Such unitary sliding is provided by the coupling of the braking mechanism with sliding bodies (50) via block (156), brackets (150, 154), and piston block (78), which is itself secured to sliding bodies (50). In other words, such unitary sliding is provided by the common coupling of the braking mechanism and sliding assembly with blocks (156, 78) in the present example. With brake ground (110) being fixedly secured to runway deck (19), the rest of the braking mechanism slides relative to brake ground (110) as the braking mechanism slides unitarily with the sliding assembly.
During operation of lift (10), the configuration of pawl (120) and slots (112) may provide substantially little (if any) resistance to the ascent of runway decks (19). In other words, pawl (120) may essentially “ratchet” across brake ground (110) during ascent of runway decks (19). Once the desired height has been reached with runway decks (19), such that the ascent is stopped, pawl (120) may engage a slot (112) of brake ground (110) (under the resilient urging of spring (132)) to substantially lock the vertical position of runway decks (19). To the extent that pawl (120) is positioned somewhere between slots (112) when ascent of runway decks (19) is stopped, the vertical position of runway decks (19) may be further manually or automatically adjusted to engage pawl (120) with one of the adjacent slots (112). Alternatively, controller (210) may be programmed to prevent runway decks (19) from being stopped at a vertical position where pawl (120) would be positioned between slots (112), such that controller (210) will automatically provide a vertical position of runway decks (19) where pawl (120) will be engaged with a slot (112). As yet another alternative, lift (10) may permit runway decks (19) to be raised to and stopped at a vertical position where pawl (120) is positioned between slots (112), with pawl (120) being engaged in a slot (112) only in the event that a runway deck (19) suddenly drops, such as in the case of sudden hydraulic failure. Still other suitable ways in which the braking system may be operated during ascent of runway decks (19) and/or after ascent of runway decks (19) has stopped will be apparent to those of ordinary skill in the art in view of the teachings herein.
When raised runway decks (19) are to be lowered, pneumatic cylinder (126) may be actuated to retract piston shaft (128) to thereby disengage pawl (120) from slot (112), overcoming the resilient bias provided by spring (132). In some versions, decks (19) are raised slightly just before their descent, to facilitate disengagement of pawl (120) from slot (112) by providing clearance. With pawl (120) disengaged from slot (112), runway decks (19) may be lowered as described elsewhere herein. Pawl (120) may remain disengaged from slots (112) during the descent of runway decks (19), due to operation of pneumatic cylinder (126). In some versions, controller (210) is programmed to automatically operate pneumatic cylinder (126) to disengage pawl (120) from slot (112) upon receiving a command from a user to lower runway decks (19). In some other versions, a separate user input is used to manually operate pneumatic cylinder (126) to disengage pawl (120) from slot (112) when descent of runway decks (19) is desired. Alternatively, the braking mechanism may be operated in any other suitable fashion during descent of runway decks (19).
It should be understood that the braking mechanism of the present example may permit hydraulic cylinder (70) to be removed without requiring external support for runway deck (19). This is because, in the present example, hydraulic cylinders (70) are not used to support the weight of runway decks (19) and a vehicle (2). Each hydraulic cylinder (70) is merely used to move sliding bodies (50) along channels (28); whereas the braking mechanism is used to support the weight of runway decks (19) and a vehicle (2) in the present example. Of course, hydraulic cylinder (70) and piston shaft (72) may hydraulically bear the weight of runway deck (19) and a vehicle (2) as deck (19) is being raised, before the braking mechanism is engaged. However, once the braking mechanism is engaged in the present example, the braking mechanism bears the weight of runway deck (19) and a vehicle (2). Of course, the braking mechanism may be varied, modified, substituted, and/or supplemented in a variety of ways. Alternatively, the braking mechanism may be omitted altogether, if desired.
Exemplary Hydraulic System and Deck Synchronization
As noted above and as shown in
In the present example, blocking valve (312) is coupled with hose (86), which is in turn coupled with cylinder (70) of lift section (10b). Blocking valve (314) is coupled with hose (82), which is in turn coupled with cylinder (70) of lift section (10a). Hydraulic system (300) of the present example also includes a hand pump port (340), which is configured to couple with a hand pump. In particular, a hand pump may be coupled with hydraulic system (300) via hand pump port (340) during a power outage or under other circumstances to help raise runway decks (19) enough to allow pawl (120) to be disengaged from brake ground (110), allowing decks (19) to then be lowered manually. Of course, a variety of other components or features may be used to provide manual raising of decks (19) to assist in disengaging a braking mechanism. Alternatively, such manual lifting components may be omitted if desired.
Hydraulic Lift (10) of the present example also includes position sensors (200) that are in communication with controller (210) and that are used to influence how controller (210) controls hydraulic system (300), to substantially synchronize lifting of runway decks (19) as described in greater detail below. Each position sensor (200) of the present example comprises a rotary potentiometer. In particular, and as shown in
In an exemplary operation, an operator presses a “raise” button (not shown) to indicate to controller (210) that hydraulic lift (10) should move from a lowered position to a raised position. In response, controller (210) provides electrical power to activate pump (328), opens proportional valves (316, 318), and opens blocking valves (312, 314). Pump (328) thus sends fluid to hoses (82, 86), and thus to hydraulic cylinders (70), through check valve (322), a tee intersection (319), proportional valves (316, 318), and blocking valves (312, 314). Tee passageway (319) enables flow to both hydraulic cylinders from a single pump (328). Blocking valves (312, 314) are fully open as lift (10) is rising.
The amount of fluid directed to each hydraulic cylinder (70) is regulated by controller (210) sending an amount of electrical power to proportional valves (316, 318) to selectively adjust the degree to which either proportional valve (316, 318) is open. For instance, if position sensors (200) indicate that runway deck (19a) is lower in height than runway deck (19b) during the ascent of runway decks (19a, 19b), controller (210) opens proportional valve (318) to a greater degree than the degree to which proportional valve (316) is opened, thus causing more flow to enter the cylinder (70) associated with runway deck (19a), thereby increasing the ascent speed of runway deck (19a) relative to the ascent speed of runway deck (19b). In addition or in the alternative, controller (210) may respond to the same height discrepancy by reducing the degree to which proportional valve (316) is open relative to the degree to which proportional valve (318) is opened, thus reducing the flow entering cylinder (70) associated with runway deck (19b) to thereby decrease the ascent speed of runway deck (19b) relative to the ascent speed of runway deck (19a). It should therefore be understood that controller (210) may actively adjust either or both proportional valves (316, 318) to correct discrepancies between the heights of decks (19a, 19b) as decks (19a, 19b) ascend from a lowered position to a raised position. In other words, controller (210) may be used to speed up the ascent of a “lagging” runway deck (19a) and/or slow down the ascent of a “leading” runway deck (19a, 19b). It should also be understood that the adjustable control of proportional valves (316, 318) may allow decks (19a, 19b) to be raised in a substantially synchronized, coordinated, and simultaneous fashion.
Once decks (19a, 19b) have been raised to a suitable height, the operator may release the “raise” button. It should therefore be understood that the operator must continue to depress the “raise” as decks (19a, 19b) are being raised in order for the ascent of decks (19a, 19b) to continue. Alternatively, controller (210) may be configured such that the operator need only tap the “raise” button or press it for a predetermined time period (e.g., three seconds, etc.) in order to for decks (19a, 19b) to move to a raised height. In some such versions, decks (19a, 19b) will ascend to a predetermined height in response to such temporary pressing of the “raise” button, and will continue such ascent to the predetermined height even after the “raise” button is released. In the present example, when no button is depressed by the operator (e.g., after decks (19a, 19b) have reached a desired height or as decks (19a, 19b) are at a lowered position, etc.), controller (210) does not provide electrical power to pump (328) or any of the valves (312, 314, 316, 318, 320). As noted above, valves (312, 314, 316, 318, 320) are each resiliently biased to assume a fully closed configuration. In addition, check valve (322) is configured to prevent reverse flow back to pump (328). Thus, runways (19a, 19b) are held at their current position when neither a “raise” button nor a “lower” button is being activated by an operator. While the present example refers to buttons as user inputs, it should be understood that any suitable type of user inputs may be provided.
In another phase of exemplary operation, an operator presses a “lower” button to indicate to controller (210) that hydraulic lift (10) should move from a raised position to a lowered position. In response, controller (210) provides electrical power to blocking valves (312, 314), to proportional valves (316, 318), and to main lowering blocking valve (320) to open them. Fluid flows from hydraulic cylinders (70) through blocking valves (312, 314), through proportional valves (316, 318), through tee passageway (319), through main lowering blocking valve (320), then through filter (326) to ultimately reach reservoir tank (330). Tee passageway (319) enables fluid from each hydraulic cylinder (70) to flow through a single main lowering blocking valve (320) before it reaches reservoir tank (330). Decks (19a, 19b) lower to the ground or floor (4) as fluid is drained from cylinders (70).
The amount of fluid directed from each hydraulic cylinder (70) during descent of lift (10) is regulated by controller (210) selectively sending electrical power to proportional valves (316, 318) to selectively adjust the degree to which either proportional valve (316, 318) is open. For instance, if position sensors (200) indicate that runway deck (19a) is lower in height than runway deck (19b) during the descent of runway decks (19a, 19b), controller (210) restricts proportional valve (318) to a greater degree than the degree to which proportional valve (316) is restricted, thus causing less flow from the cylinder (70) associated with runway deck (19a), thereby slowing the descent speed of runway deck (19a) relative to the descent speed of runway deck (19b). In addition or in the alternative, controller (210) may respond to the same height discrepancy by opening proportional valve (316) to a greater degree than the degree to which proportional valve (318) is opened, thus increasing the flow from cylinder (70) associated with runway deck (19b) to thereby increase the descent speed of runway deck (19b) relative to the descent speed of runway deck (19a). It should therefore be understood that controller (210) may actively adjust either or both proportional valves (316, 318) to correct discrepancies between the heights of decks (19a, 19b) as decks (19a, 19b) descent from a raised position to a lowered position. In other words, controller (210) may be used to speed up the descent of a “lagging” runway deck (19a) and/or slow down the descent of a “leading” runway deck (19a, 19b). It should also be understood that the adjustable control of proportional valves (316, 318) may allow decks (19a, 19b) to be lowered in a substantially synchronized, coordinated, and simultaneous fashion.
In the present example, the openings in proportional valves (316, 318) are also varied to keep the rate of descent more consistent and above a specified threshold throughout the lowering range of travel of decks (19a, 19b). In some versions, this keeps lift system (10) from increasing in speed and crashing down as it reaches the fully lowered position. Hydraulic system (300) may also include a velocity fuse that is between hoses (82, 86) and hydraulic cylinders (70) in case hoses (82, 86) are severed or some other leak occurs. The velocity fuses is configured to automatically close in response to the fluid flow exceeding a predetermined flow rate. In some versions, due to the above-described use of controller (210), performance of lift (10) may be relatively unaffected by leakage of hydraulic fluid. In particular, corrections that can be made by controller (210) may substantially compensate for performance discrepancies that might otherwise occur if there is fluid leakage with respect to one of the lift sections (10a, 10b).
Of course, the above description of hydraulic system (300) relates to just one of many available options. In some other versions, hydraulic system (300) includes two independently operable hydraulic pumps, each pump being associated with a corresponding lift section (10a, 10b). Other suitable variations of hydraulic system (300) will be apparent to those of ordinary skill in the art in view of the teachings herein.
In some versions, position sensors (200) are also used to ensure engagement between pawl (120) and a slot (112) of the braking mechanism at the end of the ascent of runway decks (19). For instance, controller (210) may be programmed with discrete vertical heights associated with engagement between pawl (120) and slot (112), and may automatically ensure that the ascent of runway decks (19) is stopped only at one of such discrete vertical heights, using position data communicated from position sensors (200). As one merely illustrative example of operation of lift (10), a user's ascent command may be associated with some other vertical height that is between two of the discrete vertical heights known to controller (210). That is, the user may release an ascent button when runway decks (19) are located at a vertical position where pawl (120) is positioned between slots (112). Using feedback from position sensors (200), controller (210) may detect that this vertical position is between two of the discrete vertical heights known to controller (210), and may automatically further adjust the vertical position of runway decks (19) (e.g., higher or lower) to reach one of the discrete vertical heights known to controller (210), to thereby ensure engagement of pawl (120) with a slot (112). Of course, such use of position sensors (200) and operation of controller (210) is merely optional.
Various components that may be incorporated into controller (210) (e.g., processor, circuit board, etc.) will be apparent to those of ordinary skill in the art in view of the teachings herein. Similarly, other ways in which runway decks (19a, 19b) may be synchronized will be apparent to those of ordinary skill in the art in view of the teachings herein. It should also be understood that some versions of lift (10) may simply lack such automated synchronization altogether. For instance, controller (210), position sensors (200) and/or proportional valves (316, 318) may be simply omitted, if desired.
Exemplary Installation and Operation
To install lift (10) of the present example, one lift assembly (10a) is secured to the service bay floor (4) in a vertical orientation by bolting or otherwise securing anchor plates (40) to the floor (4). The other lift assembly (10b) is located so as to be parallel and aligned front-to-rear with lift assembly (10a), and spaced therefrom according to the wheelbase length of the vehicles (2) to be serviced on lift (10), and is secured to service bay floor (4) in like fashion. The hydraulic system is installed, care being taken to ensure that hoses (82, 86) are secured away from the workspace beneath lift (10) and will not be crimped or pinched by any of the moving parts of lift (10). Runway decks (19) are set to the lowered position and any entrained air is bled from the hydraulic system. Alternatively, lift (10) may be installed in any other suitable fashion.
In operation, an automotive vehicle (2) is driven up to rear plates (24) and onto runway decks (19), to the position shown in
To lower runway decks (19), the brake mechanism is disengaged by disengaging pawl (120) from slot (112) as described above, allowing sliding bodies (50) to slide forwardly in channels (28) as hydraulic fluid is drained from cylinders (70). In particular, the hydraulic pressure is reduced in cylinders (70), to allow for a controlled lowering of runway decks (19). The weight of the vehicle (2) causes sliding bodies (50) to slide forwardly along deck rails (20) in synchronous relation as piston shafts (72) are displaced forwardly through and into cylinders (70) with hydraulic pressure being reduced, until lift (10) has reached the lowered position shown in
Optionally, a failsafe switch (not shown) may be activated when lift (10) is being lowered, to automatically stop the lowering process, for example at a height of approximately 18 inches or at any other suitable height. This may provide service personnel an additional opportunity to ensure that the area under lift (10) is clear before lift (10) is completely lowered to floor level. Of course, lift (10) may be operated in any other suitable fashion, whether during ascent of runway decks (19), during descent of runway decks (19), and/or at any other stage of operation.
Automotive lift (10) of the present example may be suitable for standard automotive vehicles. For commercial vehicles, a lift having a higher capacity may be required, in which case a third leg (30) or any other suitable number of legs (30) may be added to each lift section (10a, 10b). Such additional legs (30) may be coupled with sliding members (50) in a manner similar to that described above, without necessarily introducing any additional hydraulic cylinders (70). Alternatively, one or more additional hydraulic cylinders (70) may be provided, and may be incorporated into lift (10) in any suitable fashion. Still other ways in which various features, components, functionalities, and operability of lift (10) may be varied, modified, substituted, supplemented, added, or omitted will be apparent to those of ordinary skill in the art in view of the teachings herein.
Having shown and described various embodiments of the present invention, further adaptations of the methods and systems described herein may be accomplished by appropriate modifications by one of ordinary skill in the art without departing from the scope of the present invention. Several of such potential modifications have been mentioned, and others will be apparent to those skilled in the art. For instance, the examples, embodiments, geometrics, materials, dimensions, ratios, steps, and the like discussed above are illustrative and are not required. Accordingly, the scope of the present invention should be considered in terms of any claims that may be presented and is understood not to be limited to the details of structure and operation shown and described in the specification and drawings.
This application is a continuation of PCT App. No. PCT/US10/32647, entitled “Multi-Link Automotive Alignment Lift,” filed Apr. 28, 2010, which claims the benefit of U.S. Provisional Application No. 61/176,357, entitled “Multi-link Automotive Lift,” filed May 7, 2009, the disclosures of which are incorporated by reference herein.
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Number | Date | Country | |
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Parent | PCT/US2010/032647 | Apr 2010 | US |
Child | 13290270 | US |