Vehicle lift

Information

  • Patent Grant
  • 6182796
  • Patent Number
    6,182,796
  • Date Filed
    Friday, October 30, 1998
    27 years ago
  • Date Issued
    Tuesday, February 6, 2001
    24 years ago
Abstract
Apparatus for use in lifting a vehicle from a substantially flat surface. The apparatus includes a pair of levers, each having a first lever and a second lever pivotally joined together cris-crossing one another and operable in a scissor-like motion between a collapsed position and a lifted position. A lifting platform is operatively coupled to the levers for supporting a vehicle thereon. A lifting mechanism is operably coupled to the levers for operating them between the collapsed position and the lifted position and thereby raising and lowering the lifting platform. An extendable, one-way incrementally lockable safety strut is pivotally connected to the first lever at a point along its upper portion and the other end of the safety strut is pivotally connected to the second lever at a point along its lower portion.
Description




FIELD OF THE INVENTION




This invention relates generally to lift devices, and particularly, to a full-rise safety operated vehicle lift.




BACKGROUND OF THE INVENTION




Several different vehicle lifts exist in the market place. Generally, these are designed within the constraints set by the design requirements of the lift, e.g., lifting capacity, lifting height, type of vehicle lifted, lift structure configurations and costs of materials and individual components. Thus, conventional designs represent a compromise between these different features.




There is a particular need for a vehicle lift that preferably does not suffer from the constraints of the conventional designs and that has the versatility to service a variety of vehicles in a variety of environments. Further, a vehicle lift is needed which preferably collapses to minimize storage space and enables lifting of a vehicle at multiple lifted positions between a collapsed position and a full-rise height of about six feet. Still further, a vehicle lift is needed which preferably maximizes access to the under side of a lifted vehicle while providing anti-collapse safeguards whenever the lift is not in the collapsed position. Yet further, a vehicle lift is needed which preferably is readily portable from one location to another.




As disclosed hereinafter, the vehicle lift of the present invention does not suffer from the constraints of the conventional designs. Also, the vehicle lift of the present invention preferably fulfills one or more of the above needs for a vehicle lift and most preferably all such needs.




SUMMARY OF THE INVENTION




According to the present invention there is provided an apparatus for use in lifting a vehicle from a substantially flat surface. The apparatus includes a pair of levers which include a first lever and a second lever pivotally joined together cris-crossing one another and operable in a scissor-like motion between a collapsed position and a lifted position. Each lever has an upper portion terminating in a top end and a lower portion terminating in a bottom end so that the top end of each lever lies opposite the bottom end of the other when the levers are in the collapsed position. A lifting platform is operatively coupled to the top ends of the levers for supporting a vehicle thereon. A lifting mechanism is operably coupled to the pair of levers for operating the pair of levers between the collapsed position and the lifted position and thereby raising and lowering the lifting platform. An extendable, one-way incrementally lockable safety strut has two ends. One end of the safety strut is pivotally connected to the first lever at a point along its upper portion and the other end of the strut is pivotally connected to the second lever at a point along its lower portion.




Other features of the invention relate to the configuration and operation of the safety strut which, for example, although moving in tandem with the pair of levers is independent of the lifting mechanism.




Still other features of the invention concern the configuration and operation of two pair of levers, and corresponding components for using the same, which enhance unrestricted access to the underbody of a lifted vehicle while simultaneously fulfilling safety and lifting range considerations.




According to other features of the invention there are provided infinite vehicle frame or tire engagement positions which enable the apparatus to accommodate today's late (1990's) non-homogenous vehicles which have a multitude of frame and tire widths, a variety of wheelbase lengths, various ground clearances and various pick-up points.











DESCRIPTION OF THE DRAWINGS




Other features of the invention will become more readily apparent upon reference to the following description when taken in conjunction with the accompanying drawings, which drawings illustrate several embodiments of the invention.





FIG. 1

is a perspective rear view of a lift assembly, including two lift apparatus, in a fully lifted position.





FIG. 2

is a view similar to

FIG. 1

but with the lift assembly in between the fully lifted position and a collapsed position.





FIG. 3

is a view similar to

FIG. 1

but with the lift assembly in the collapsed position.





FIG. 4

is a partial side view of the lift assembly of

FIG. 1

, taken along line


4





4


of FIG.


1


.





FIG. 5

is a rear view of the lift assembly of

FIG. 1

, with swing arms but without lifting accessories.





FIG. 6

is a front view of the lift assembly of

FIG. 1

, with swing arms but without lifting accessories.





FIG. 7

is a top view of the lift assembly of

FIG. 3

, with swing arms but without lifting accessories.





FIG. 8

is a top view of the lift assembly of

FIG. 1

, with swing arms but without lifting accessories.





FIG. 9

is a top view of another embodiment of the lift assembly, in the collapsed position, with stationary tracks and swing arms but without lifting accessories.





FIG. 10

is a partial side view of the lift assembly of

FIG. 9

, in the fully lifted position (similar to that of FIG.


4


).





FIG. 11

is a top view of another embodiment of the lift assembly, in the collapsed position, with lifting tracks.





FIG. 12

is a partial side view of the lift assembly of

FIG. 11

, in the fully lifted position (similar to that of FIG.


4


).





FIG. 13

is an enlarged partial cutaway side view of a safety strut of each lift apparatus.





FIG. 14

is a perspective view of a portion of the lift assembly without lifting mechanisms and with its tow means in an exploded unassembled position.





FIG. 15

is a perspective view of the lift assembly of

FIG. 14

, with its tow means in an assembled position and the lift assembly operationally portable.





FIG. 16

is a side view of the lift assembly of

FIG. 15

, with lifting platforms and in the collapsed position.





FIG. 17

is a perspective exploded view of a lifting platform, swing arms and lifting accessories of the lift apparatus.





FIG. 18

is a schematic representation of a hydraulic system of the lift assembly.





FIG. 19

is a schematic representation of an alternative exemplary embodiment of the hydraulic system of the lift assembly.





FIG. 20

is a front view of a portable power unit of the lift assembly.





FIG. 21

is a side view of the power unit of FIG.


20


.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




Referring to

FIGS. 1-4

generally, for example, there is depicted a lift apparatus


10


for use in lifting a vehicle (not shown) from a substantially flat surface


12


. Generally, lift apparatus


10


includes a pair of levers


14


each having a first lever


16


and a second lever


18


pivotally joined together cris-crossing one another and operable in a scissor-like motion between a collapsed position (

FIG. 3

) and a lifted position (

FIGS. 1

,


2


and


4


). For example, levers


16


,


18


, may each include paired members


20


,


22


and


24


,


26


, respectively, which may be connected together by conventional fitted pins


28


(second pin not visible but similarly located) proximate their middle for pivotal movement but otherwise being fixed relative thereto. Each lever


16


,


18


, may also have an upper portion


30


,


32


, respectively, terminating in a top end


34


,


36


, respectively, and a lower portion


38


,


40


, respectively, terminating in a bottom end


42


,


44


, respectively, so that the top end of each lever lies opposite the bottom end of the other when levers


16


,


18


are in the collapsed position (FIG.


3


). Preferably, lever members


20


,


22


,


24


,


26


are constructed from 1 and ½ inch by 3 inch machine milled steel. Moreover, unless provided differently herein, all components are constructed of steel and are sealed to prevent corrosion.




A lifting platform


46


is operatively coupled to top ends


34


,


36


for supporting the vehicle thereon. For example, rear end


48


of lifting platform


46


can be connected by a conventional hinge


50


to top end


34


for pivotal movement but otherwise is fixed relative thereto. Differently, preferably front end


52


of lifting platform


46


can be connected to top end


36


by a pair of rollers


54


(see also

FIG. 6

) trapped on opposite sides in platform L-shape guide


56


. In this way, top end


36


moves pivotally and axially relative to lifting platform


46


and also prevents lifting platform


46


from twisting (torquing) away from pair of levers


16


,


18


.




Referring to

FIGS. 1 and 2

, for example, a lifting mechanism


58


is operably coupled to levers


16


,


18


for operating the pair of levers between the collapsed position and the lifted position and thereby raising and lowering lifting platform


46


. Lifting mechanism


58


could be any conventional hydraulic cylinder that may have a preferred lifting stroke of 26 inches and may preferably be direct drive cylinder using no cables, chains or mechanical lifting screws. For example, the lifting mechanism may include a conventional hydraulic cylinder but which cylinder has the following rod fed configuration. An aluminum piston head (not shown), having an outer diameter of about 3 inches, is within piston cylinder


63


and connected to piston rod


61


. Rod


61


has about a 2 inch outer diameter and about a ¾ inch inside diameter and is hollow in the center for conducting the hydraulic fluid to the piston chamber within the hydraulic cylinder. Rod


61


is fitted for sliding engagement within piston cylinder


63


, where the cylinder has an outer diameter of about 3 and ½ inches and an inner diameter of about 3 inches. These dimensions preferably combine to give a pressure area of about 6.627 square inches i each hydraulic cylinder. The rod and cylinder are both steel. The hydraulic fluid is preferably maintained at 50 to 130 degrees Fahrenheit. Further, hydraulic line


378


is connected to piston rod


61


, by conventional means, for supplying hydraulic fluid thereto.




Lifting mechanism


58


may be connected at piston rod end


60


to bottom end


44


by conventional means for pivotal movement but otherwise is fixed relative thereto. Piston cylinder end


62


may be connected to linkage levers


64


(

FIG. 2

) by conventional means for pivotal movement but otherwise being fixed relative thereto. Linkage levers


64


are connected to upper portion


30


by slots


66


(second slot not visible but similarly located) which capture pins


68


(second pin not visible but similarly located) connected to opposite sides of lever


16


. Linkage levers


64


are preferably not connected to lever


16


but are mounted for horizontal, vertical and rotational movement relative thereto.




Referring to

FIG. 2

, for example, linkage levers


64


also include wheels


70


mounted for rotational movement but otherwise being fixed relative thereto. Wheels


70


engage respective lever guides


72


and serve to direct the movement of linkage levers


64


when lift apparatus


10


is moved between the collapsed and lifted positions in the range of fully collapsed to about one-half lifted. Additionally, second wheels


74


may be mounted to lever members


24


,


26


respectively, for rotational movement but otherwise being fixed relative thereto. Second wheels


74


serve to limit and guide linkage levers


64


when lift apparatus


10


is moved between the collapsed and lifted positions, nearer the collapsed range of positions.




Referring to

FIGS. 1

,


4


and


13


, for example, an extendable, one-way incrementally lockable safety strut


76


has two ends


78


and


80


. Each end is pivotally connected by conventional means to its respective lever


16


,


18


. For example, strut end


78


is connected to lever


18


at a point along upper portion


32


and strut end


80


is connected to lever


16


at a point along lower portion


30


. Safety strut


76


may be a round steel tube


82


sized to receive a steel rack or rod


84


for fitted sliding engagement therein. Rack


84


has a number of slots


86


, and preferably 10 slots starting at 6 inches from end


80


and extending along its length. Slots


86


are contoured so as to enable one-way movement of a cam


88


when cam


88


engages rack


84


, i.e., during lifting movement of the lift apparatus as described hereinafter.




Referring to

FIGS. 4 and 13

, for example, cam


88


is connected to tube


82


by a nut and bolt combination


90


which are connectable with a pair of spaced plates


92


(second plate not visible but similarly located) connected to the outside of tube


82


. The cam can rotate up and down but otherwise is fixed relative to tube


82


. Cam


88


may engage rack


84


merely by gravity or by additional force supplied through a spring or other conventional means. If cam


88


engages portion


94


of slots


86


with a downward force, it will lock the rack


84


relative to tube


82


preventing contraction of the strut


76


and thereby levers


16


,


18


to which it is connected. To disengage cam


88


from rack


84


at any time, conventional air cylinder


96


connected to tube


82


may be linked to cam


88


by cable


98


attached to air cylinder rod


100


. When air cylinder rod


100


is retracted into air cylinder


96


, it tenses cable


98


and pulls cam


88


away from rack


84


, thereby enabling retraction of rack


84


into tube


82


. Air cylinder


96


preferable is a single point air release, single act type cylinder, such as that sold by Parker Hannifin Corporation under model number 1.06PTSRS01.5. Conventional air supply line


379


is connectable thereto for providing the desired pneumatic pressure.




Referring to

FIGS. 1-4

, an operational example of the lift apparatus follows. As lifting mechanism


58


is caused to operate from the collapsed position to the lifted position, piston cylinder end


62


is forced away from piston rod end


60


. This drives the linkage levers


64


and their respective wheels


70


along and out of the lever guides


72


. Near simultaneously, slots


66


in linkage levers


64


are forced into engagement with pins


68


. As soon as slots


66


stop against pins


68


, levers


16


,


18


are driven from the collapsed position and moved in any of various lifted positions. Also near simultaneously, as levers


16


,


18


are driven apart, safety strut


76


connected at opposite ends to each lever


16


,


18


respectively, is extended in length. As this occurs, cam


88


slides into slots


86


and thereby incrementally locks levers


16


,


18


from collapsing should lifting mechanism


58


or its hydraulic supply (discussed hereinafter) fail or should a user inadvertently lower the lift apparatus. During operation, it is further preferred that lift apparatus


10


move in a straight up and down direction with substantially no horizontal movement. It is also preferred that the lift assembly


210


be self lubricating at all scissor like pivot points, by conventional means.




To move lift apparatus


10


from a lifted position to the collapsed position, cam


88


must be disengaged from slot


86


and rack


84


. Rack


84


can then slide into tube


82


as the piston rod of lifting mechanism


58


is retracted into the piston cylinder. To further enhance the safety provided by safety strut


76


, it is preferably separate and distinct from lifting mechanism


58


. This also has the advantage of maximizing underbody vehicle access while still providing the desired safety features. Further, these features can also combine to enable a maximum lifted position height of more than six feet which is preferred for taller mechanics working under the vehicle.




Referring generally to

FIGS. 1-6

, for example, such safety features are particularly preferred when lift apparatus


10


further includes a lift assembly


200


. Lift assembly


200


includes a second lift apparatus


210


similar to lift apparatus


10


. Lift apparatus


210


includes a second pair of levers


214


which include a third lever


216


, a fourth lever


218


, a second lifting platform


246


, a second lifting mechanism


258


and a second safety strut


276


. These second components are identical to their correspondingly named first components in all respects except for the lifting platforms


46


,


246


which are mirror images of one another. Further, components in lift apparatus


210


corresponding to those of lift apparatus


10


are numbered similarly but increased by an increment of


200


. In lift assembly


200


, preferably pair of levers


14


is sychronistically joined with second pair of levers


214


in an opposing substantially parallel relationship such that they are joined together substantially only proximate flat surface


12


when each is in a position other than the collapsed position. This configuration can be desired because it, in combination with the safety features discussed for each lift apparatus


10


,


210


above, further enhances underbody vehicle access while still providing safe and reliable lifting features.




Various means may be employed to achieve the desired synchronicity. For example, a ground engaging member


300


may be connected between adjacent rear bottom ends


44


,


244


of pairs of levers


14


,


214


. In this regard, ground engaging member


300


preferably is a rigid steel tube connected by conventional means such as welding, forming integral or the like to the pairs of levers


14


,


214


and which also serves to resist torque differentials cause by the pairs of levers


14


,


214


during operation. Further, ground engaging member


300


may substantially fix adjacent rear bottom ends


44


,


244


to flat surface


12


merely by frictional engagement therewith to prevent linear movement of the ends relative to flat surface


12


when pairs of levers


14


,


214


are operated.




Still referring to

FIGS. 1-6

, an additional or alternative means to achieve the desired synchronicity may include a synchronization member


302


connected between adjacent front bottom ends


42


,


242


of each respective pair of levers and proximate flat surface


12


. Member


302


preferably is a length of steel connected by conventional means such as welding or other conventional bonding means to pairs of levers


14


,


214


and which also serves to resist torque differentials caused by pairs of levers


14


,


214


during operation. Further, each adjacent front bottom portion


38


,


238


may include a roller


304


which slidingly engages flat surface


12


when the pairs of levers


14


,


214


are moved between the collapsed position and the lifted position. As mentioned earlier, lift apparatus


10


preferably moves in a straight up and down direction with substantially no horizontal movement. For example, this may be achieved as ends


44


,


244


remain substantially fixed relative to flat surface


12


(except for rotational movement) by ground engaging member


300


but ends


42


,


242


roll towards and away from ends


44


,


244


when the pairs of levers


14


,


214


operate between lifted positions and the collapsed position.




Referring to

FIGS. 18 and 19

are depicted schematic representations of lifting mechanisms


58


,


258


, e.g., conventional hydraulic cylinders


305


and a hydraulic fluid supply system


306


. Cylinders


305


and system


306


may be linked by conventional hydraulic lines (only shown schematically), generally ¼ inch lines, and with conventional fittings except as noted hereinafter. System


306


or hydraulic cylinders


305


may include, for example, at least one conventional velocity fuse


308


, preferably configured as shown and set at 4 gallons per minute. Velocity fuses


308


for each hydraulic cylinder can prevent fatal collapse in the remote possibility that a hydraulic line ruptures. For example, a velocity fuse sold by Vonberg Valve, Inc. under model number 28001-503-4 may produce excellent results. Still further, system


306


may include, for example, a conventional pressure compensated flow control valve


310


, preferably configured as shown and set at 2.75 gallons per minute. Pressure compensated flow control valve


310


can prevent excessive lowering speeds. For example, a flow control valve sold by Monarch Hydraulics, Inc. under model number 017270 may produce excellent results. Further components of system


306


may include conventional operating switch


312


, conventional relief valve


314


(preferably set at 2450 psi) and conventional motor


316


(preferably a 2 HP, 230 VAC, 60 Hz) which operates conventional hydraulic pump


318


having at a capacity of pumping 1.77 gallons per minute and producing 2000 psi at 3435 rpm. A conventional 150 micron strainer


320


may be included in reservoir


322


and in communication with pump


318


, where reservoir


322


preferably has a 2.5 gallon capacity.





FIGS. 9-12

inclusive depict two alternative embodiments of the invention. For example, each include a pair of longitudinal tracks


324


(

FIGS. 9-10

) and


326


(

FIGS. 11-12

) in which each of the pair is locatable adjacent lifting platform


46


,


246


of each respective pair of levers


14


,


214


. In particular, the longitudinal tracks may each be a lifting track


328


(

FIGS. 11-12

) which is removably attached to lifting platforms


46


,


246


of each respective pair of levers. Lifting tracks


328


may be constructed of U-shaped bent diamond floor plate sections


330


where two sections are welded together for each track. At the ends of each track


328


, there may be provided a ramp


332


constructed of plate steel. Also, an L-shaped piece of angle iron


333


may be welded or bolted to one end to restrain the vehicle. Each ramp


332


may have a hinged connection


335


to the track, providing an automatic wheel stop


334


for the vehicle when the lift is raised. Each track


328


has three connection plates


336


welded to the top surface of the tracks. These connection plates extend beyond the outer edges of the tracks and have holes


337


provided for bolting the track to the top of lifting platforms


46


,


246


. Use of these tracks convert the standard frame engaging capability of the lift into a tire (wheel) engaging roll-on lift. Further, ramps


332


allow vehicles to enter from one end of the lift and drive off the other end, offering ease and speed to vehicle removal.




Alternatively, referring to

FIGS. 9-10

, longitudinal tracks


324


may each be a stationary track


338


which is positionable along side lifting platforms


46


,


246


of each respective pair of levers


14


,


214


and is disconnected therefrom. Stationary tracks


338


may be constructed of U-shaped bent diamond floor plate sections


340


where two sections are bolted together for each track. At the ends of each track is supplied a ramp


342


constructed of plate steel and bolted thereto. Also, an L-shaped piece of angle iron


333


may be welded or bolted to one end to restrain the vehicle. Preferably, all of the parts of the longitudinal tracks


324


are bolted connections, allowing quick assembly, disassembly and easy storage when not in use. The stationary tracks enable vehicles with low profile vehicle under-clearance to be positioned for use over lift assembly


200


. Further, ramps


342


may also allow vehicles to enter from one end of the lift and drive off the other end, offering ease and speed to vehicle removal.




Referring to

FIGS. 3

,


7


-


8


and


17


, for example, each lift apparatus


10


,


210


may further include at least a pair of swing arms


344


,


346


wherein each swing arm is removably joined to lifting platform


46


,


246


. In particular, for example, each lifting platform surface


102


,


202


has tapped holes


350


allowing the mounting of swing arms


344


,


346


, which can rotate. Swing arms


344


,


346


are made of steel plate, one end having a drilled hole to attach the swing arm to the platform with a threaded bolt


348


and the other end having two drilled holes


352


for placing height adapters or lifting pads (described hereinafter). Preferably, multiple swing arm


344


,


346


connection locations are offered on lifting platforms


46


,


246


to allow the user to alter the location of swing arms


344


,


346


and thus, accommodate a wider variety of vehicle frame pick-up locations. This is particularly advantageous for today's (late 1990's) non-homogenous vehicles which have a multitude of frame/tire widths, wheelbase lengths, various ground clearances and pick up points, as opposed to the early 1960's vehicles which were all similar with large wide frames. In addition, easy removal of swing arms


344


,


346


lowers the profile of lift apparatus


10


,


210


to accommodate more of today's (late 1990's) low profile vehicles.




Referring to

FIGS. 2 and 17

, for example, each lift apparatus


10


,


210


may further include at least a pair of lifting accessories, such as those from the group consisting of lifting pads


354


, height adapters


356


and rubber blocks


358


. Each of the pair of lifting accessories is preferably removably joined with the lifting platforms


46


,


246


so as to provide symmetry. In particular, the lifting accessories offer a variety of ways to engage the lifting points of a vehicle. For example, lifting pads


354


may be constructed of a small, e.g., 4″ by 5″, rectangular steel plate with a “rippled” top surface which offers an anti-slip surface for the pad to engage the vehicle frame. Normal to the plate's bottom surface extends a round pin


360


, which is fittingly inserted into holes


352


in the end of swing arm


344


,


346


or height adapter


356


when used. Height adapters


356


are stands-offs used in conjunction with lifting pads


354


to raise the surface of the lifting pad towards the frame contact point. Rubber blocks


358


can be used on lifting platforms


46


,


246


on swing arms


344


,


346


or on lifting pads


354


. These three devices further offer a wide combination of vehicle frame engagement possibilities.




Referring to

FIGS. 14-16

, lift assembly


200


may include a towing member


360


removably attachable with ground engaging member


300


in between the pairs of levers


14


,


214


. For example, towing member


360


includes a T-shaped bar


362


having an upwardly projecting pivot point


364


. Two wheels


366


are attached on either side of pivot point


364


by conventional means such as a pin and retainer


368


. Preferably, a tow support


370


is shaped to encompass ground engaging member


300


and be inserted between a pair of ears


372


which are connected to ground engaging member


300


by welding, forming integral or the like. A pin or bolt


374


can then be inserted into aligned holes of ears


372


and tow support


370


(

FIG. 14

) Towing member


360


can then be inserted under tow support


370


and rotated so as to raise grounding engaging member


300


and the rear end of lift assembly


200


off of flat surface


12


(FIG.


15


). This is preferably done when the lift is in the collapsed position. Once ground engaging member


300


is “levered” off of flat surface


12


, the rear end of lift assembly


200


is then supported by wheels or rollers


366


of towing member


360


, and the front end of lift assembly


200


is supported by the rollers


304


(FIG.


16


). Lift assembly


200


, now on four rollers, can be pulled by a single person to a desired location.




Referring to

FIGS. 20 and 21

, there is depicted a portable power unit


376


which supplies hydraulic pressurized fluid and is a conduit for providing pneumatic pressurized fluid, through removably connected hydraulic supply line


378


and removably connected pneumatic supply line (not shown) to the respective hydraulic cylinders of lifting mechanisms


58


,


258


and air cylinders of safety struts


76


,


276


(FIG.


1


). Power unit


376


may include motor


316


, hydraulic pump


318


and reservoir


322


(see also FIGS.


18


-


19


), all bolted to power unit dolly frame


380


. Frame


380


is constructed of welded 1 inch square structural steel tubing. The bottom of the frame has axles


382


and wheels


384


allowing easy portability of the unit, and a bent flat steel bar


386


, ensuring tilt prevention for the dolly's stationary upright position. Quick connect/disconnect fittings


388


are provided on all the hydraulic and pneumatic lines


378


coming from the power unit and joined to the respective hydraulic cylinders of lifting mechanisms


58


,


258


and air cylinders of safety struts


76


,


276


. This preferably enables power unit


376


to be quickly and easily disconnected from the lift assembly and relocated to another lifting area. For example, a power unit sold by Monarch Hydraulics, Inc. under model number M-4509-0104 may produce excellent results. The Monarch Hydraulics, Inc. power unit provides only a conduit for providing pneumatic power and any conventional pneumatic supply source or device can be used to supply this utility. Accordingly, the power unit preferably provides the required hydraulic pressure to hydraulic cylinders


305


and pneumatic pressure to air cylinders


76


,


276


, as required by the invention. Alternatively, these pressure utilities could be provided separately or by an independent source.




Excellent results are contemplated when the lift assembly


200


or lift apparatus


10


,


210


are those components, materials and dimensions corresponding to the vehicle lift commercially available and known as model USL-6000 sold by Mohawk Resources, Ltd. of Amsterdam, N.Y., the assignee of this application. In particular, for example, these are the following. Lift assembly


200


may weigh 1700 pounds and have a lift capacity of about 6000 pounds with lift speed of 45 seconds @208/230 VAC or 90 seconds @110 VAC. The motor


316


of power unit


376


may be a 208/230 VAC single phase, 60 Hz (three phase optional) or 110 VAC single phase, 60 Hz. Lift assembly


200


may have: an overall length of 98 and ½ inches; overall width of 45 and ⅜ inches; lift height at top of lifting platform of 5 feet, 11 and ¾ inches; lift height at top of swing arm of six feet and ½ inch; maximum lift height with swing adaptor of six feet, 4 and ½ inches; minimum lowered lifting platform height of 4 and ¾ inches; minimum lowered lifting platform height with swing arm of 5 and ½ inches; maximum swing arm reach (longitudinal) of 70 and ¼ inches; width between lifting platforms of 27 and ⅜ inches; and lifting platform width of 9 inches.




However, as various possible embodiments may be made in the above invention for use for different purposes and as various changes might be made in the embodiments above set forth, it is understood that all of the above matters here set forth or shown in the accompanying drawings are to be interpreted as illustrative and not in a limiting sense.



Claims
  • 1. A lift apparatus for use in lifting a vehicle from a substantially flat surface, comprising:a pair of levers including a first lever and a second lever pivotally joined together cris-crossing one another and operable in a scissor-like motion between a collapsed position and a lifted position, each lever having an upper portion terminating in a top end and a lower portion terminating in a bottom end so that the top end of each lever lies opposite the bottom end of the other when the levers are in the collapsed position; a lifting platform operatively coupled to the top ends of the levers for supporting a vehicle thereon; a lifting mechanism operably coupled to the pair of levers for operating the pair of levers between the collapsed position and the lifted position and thereby raising and lowering the lifting platform; and an extendable safety strut incrementally lockable against motion in one direction and sharing no structure with aid lifting mechanism, said safety strut having two ends, one of which is pivotally connected to the first lever at a point along its upper portion and the other end of which is pivotally connected to the second lever at a point along its lower portion.
  • 2. The lift apparatus of claim 1, wherein the safety strut includes a rack and cam mechanism which automatically incrementally locks the safety mechanism as the pair of levers are moved from the collapsed position to the lifted position and wherein the cam can be selectively disengaged from the rack to permit the pair of levers to be operated from the lifted position to the collapsed position.
  • 3. The lift apparatus of claim 1, further comprising a lift assembly, the lift assembly including-a second pair of levers which include a second lifting platform, a second lifting mechanism and a second safety strut, wherein each pair of levers is sychronistically joined with the other pair of levers in an opposing substantially parallel relationship and wherein the pairs of levers are joined together substantially only proximate the flat surface when each is in a position other than the collapsed position.
  • 4. The lift apparatus of claim 3, further comprising a ground engaging member connected between an adjacent rear bottom portion of each respective pair of levers and wherein the ground engaging member substantially fixes the adjacent rear bottom portions to prevent linear movement thereof relative to the flat surface when the pairs of levers are moved between the collapsed position and the lifted position.
  • 5. The lift apparatus of claim 4, further comprising a synchronization member connected between an adjacent front bottom portion of each respective pair of levers and proximate the flat surface wherein each the adjacent front bottom portions each include a roller which slidingly engages the flat surface when the pairs of levers are moved between the collapsed position and the lifted position.
  • 6. The lift apparatus of claim 4, further comprising a towing member removably attachable with the ground engaging member in between the pairs of levers by a tow support positioned between a pair of ears connected to the ground engaging member.
  • 7. The lift apparatus of claim 3, wherein each lifting mechanism includes a hydraulic cylinder and a hydraulic fluid supply system.
  • 8. The lift apparatus of claim 7, wherein each hydraulic cylinder includes at least one velocity fuse.
  • 9. The lift apparatus of claim 7, wherein the hydraulic fluid supply system includes a pressure compensated flow control valve.
  • 10. The lift apparatus of claim 3, further comprising a pair of longitudinal tracks in which each of the pair of longitudinal tracks is locatable adjacent the lifting platform of each respective pair of levers.
  • 11. The lift apparatus of claim 10, wherein the pair of longitudinal tracks each comprise a lifting track which is removably attached to the lifting platform of each respective pair of levers.
  • 12. The lift apparatus of claim 10, wherein the pair of longitudinal tracks each comprise a stationary track which is positionable along side the lifting platform of each respective pair of levers and is disconnected therefrom.
  • 13. The lift apparatus of claim 3, further comprising at least a pair of lifting accessories from the group consisting of lifting pads, height adapters and rubber blocks wherein each of the pair of lifting accessories is removably joined with the lifting platform of each respective pair of levers.
  • 14. The lift apparatus of claim 13, further comprising at least a pair of swing arms wherein each of the pair of swing arms is removably joined to the lifting platform of each respective pair of levers.
  • 15. The lift apparatus of claim 14, wherein each of the pair of lifting accessories is removably connected to one respective swing arm.
  • 16. The lift apparatus of claim 3, further comprising a portable power unit which supplies hydraulic and pneumatic pressurized fluid through removably connected supply lines to the lifting mechanisms and the safety locks.
  • 17. The lift apparatus of claim 16, wherein the removably connected supply lines include at least one quick disconnect fitting.
Parent Case Info

This Appln claims the benefit of U.S. Provisional No. 60/063,771 filed Oct. 31, 1997.

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Entry
“Porta Contact Frame Lift or Roll-On Lift—Installation and Service Manual—Autoquip.”
“6,000-LB. Portable Lift—Model P-6—Mohawk,” Mohawk Resource Ltd., Amsterdam, New York.
“6,000-LB. Portable Lift—Model P-6—No Post, Space-Saving, Portable Lift—Mohawk,” Mohawk Resources Ltd., Amsterdam, New York, 1994.
Provisional Applications (1)
Number Date Country
60/063771 Oct 1997 US