Applications have also been filed directed to a lift bridge, a lift arm assembly, leveling pads, and a safety mechanism, as described in the present specification.
The invention relates to a device for lifting and supporting an object i.e. a corner of an automobile; particularly to a two part jacking system including a power unit that can be used to place and elevate a jack stand. The inventor of the present invention is a pioneer of the two part jacking system holding numerous issued patents for a two part jacking system and related products and processes as described below.
Briefly, the two part jacking system consists of a power unit and a set of separate mechanical jack stands. Examples of the two part jacking system and power unit are described in detail in Re. 32,715 and U.S. Pat. No. 4,589,630. Some examples of the jack stands are described in detail in U.S. Pat. Nos. 4,553,772; 4,490,264; 5,110,089; 5,183,235 and 5,379,974. The stands are capable of being vertically extended and retracted from the garage floor or road surface and, when extended, can be locked in place at any desired position by a ratchet and pawl assembly. The power unit has a mobile chassis adapted to carry a plurality of the jack stands, and has a pair of lift arms adapted to mate with the outermost jack stand for placement and removal.
In use, the mobile power unit is operated entirely from its handle. It is maneuvered under a vehicle to place a jack stand in a desired location for lift and supporting the vehicle. The power unit is activated from the handle, and this jack stand is then vertically extended to the desired height, thus lift the vehicle on the stand. By operating the controls at the end of the handle, the operator can cause the power unit to disengage from the stand, and the stand will remain locked in its extended supporting position under the vehicle. In this manner, the vehicle is raised and supported on a separate mechanical stand without transferring the vehicle from a jack to a stand and without the operator placing any part of his body under the vehicle or having to touch the stand itself. After the stand is raised and locked in place to support the vehicle or other load in a lifted position, the power unit lift arms are lowered and the power unit is disengaged from the stand and pulled away, leaving the stand in position supporting the load. Another jack stand, carried within the chassis, is automatically transferred to the forward end the chassis for placement at another desired location of the vehicle or for use to lift and support another vehicle.
To lower the vehicle and remove the stand, the power unit is maneuvered to reengage with the stand. The engagement causes any existing jack stands carried within the chassis to be automatically transferred rearward within the chassis. By manually operating a control at the end of the handle, the user can cause the power unit to reengage with the stand, and to disengage the ratchet locking mechanism of the stand and lower the stand to its original position. The power unit remains engaged with the stand and can be pulled away from the vehicle with the stand carried within the chassis.
The original power units were adapted to carry one or two jack stands within the chassis for consumer use; and up to four jack stands within the chassis for commercial use. Additional jack stands could be purchased and arranged at various stations on the garage floor to reload the power unit, so that a single power unit could be utilized to efficiently place and actuate numerous jack stands. However, it was found that many commercial users would utilize all of their available jack stands, and the power unit was thereafter useless until another jack stand was available to be extracted and reused. It was determined that it would be highly desirable if the power unit could also function as a lift device when no jack stands were available, and when the power unit was separated from the source of jack stands.
It was also discovered that consumer projects usually required only two supports, and it was determined that it would be highly desirable to have a consumer system consisting of one jack stand and a power unit that could also be utilized as a lift and supporting device.
It was also discovered that commercial users routinely provide emergency field service, and the weight and extended chassis length (for carrying four jack stands) was somewhat unwieldy and difficult to be loaded, transported and maneuvered for such emergency field services. It was determined that it would be highly desirable to have a compact commercial power unit for shop use; and that could also efficiently be used as a stand alone lift and supporting device, as well as a power unit for use with a jack stand, for such field service.
The two part system efficiently and effectively eliminates the need to use a cumbersome hydraulic floor jack as a jack stand. However, some consumer and even professional users carelessly and hastily use the hydraulic jack as a supporting device until the project is completed. Hydraulic jacks have suffered from the disadvantage of hydraulic bleed, making performance in supporting a load over an extended period of time, unpredictable and hazardous for the user. It was determined that it would be highly desirable to provide a hydraulic lift device with a reliable mechanical mechanism for securing the lift arm so that it would support the load even upon hydraulic bleed or other failure of the hydraulic lift system.
In view of the foregoing problems and desirable features of a two part lift and supporting system, it is an object of the present invention to provide a power unit for use with a jack stand, that is readily convertible for use directly as a load-lifting jack.
It is another object to provide a power unit that is automatically adapted for use with a jack stand when engaged with a jack stand, and automatically adapted for use as a load-lifting jack when not engaged with a jack stand.
The foregoing objects are accomplished by a mobile jack stand power unit for use with a jack stand, that is convertible for use as a load-lifting jack. The power unit comprises a generally rectangular mobile chassis having a forward end and a rearward end, and having a lift means mounted on the chassis. The lift means includes a pushing means, and a pair of parallel lift arms having forward ends and rearward ends, with the forward ends adapted to be raised and lowered by the pushing means. The forward ends of the lift arms are adapted for use with the jack stand and are alternatively adapted for use with a lift bridge. A lift bridge is adapted to be positioned on the forward ends of the lift arms whereby the power unit is operable for use as a load-lifting jack. The bridge is further adapted to be displaced from the forward ends of the lift arms whereby the power unit is operable for use with the jack stand.
Another embodiment of the present invention features a mobile jack stand power unit for use with a jack stand that is automatically convertible for use as an automotive jack by the use of an automatic slide forward bridge. The power unit includes the chassis and lift means as above, and further that the lift bridge is mounted to slide within a track on the lift arms and adapted to be positioned on the forward ends of the lift arms, and alternatively positioned away from the forward ends of the lift arms. The tracks include a compression spring for automatically biasing the lift bridge toward a slide forward position on the forward ends of the lift arms when the jack stand is not loaded within the chassis, and so that the loading of a jack stand within the chassis compresses the spring and automatically repositions the bridge away from the forward ends of the lift arms.
The power unit of the present invention features leveling means on the forward ends of the lift arms. The power unit further features means for mechanically securing the rearward end of the lift arms from rearward movement within the chassis independent of force from the pushing means, whereby the forward ends of the lift arm are safely secured in position during operation of the jack.
While the novel features of the invention are set forth in the appended claims, the invention will be better understood along with other features thereof from the following detailed description taken in conjunction with the drawings, in which:
The Figures and the following specification may describe and define several distinctive inventions that are interrelated within a lifting and supporting system, and may be included in divisional patents (or pending applications) having distinctive sets of claims directed to the respective invention. Also, the power unit and jack stands are discussed and described in terms of an automotive jack system, but it should be understood that the system is not limited to automotive uses and can be utilized for lifting and supporting any type of load.
Power Unit Convertible into a Load-Lifting Jack
Referring first to
The power unit includes a generally rectangular mobile chassis 26 having a forward end 28 primarily for receiving, placing and retrieving the jack stand 22, and a rearward end 30 including a pair of wheels 32 for providing mobility and maneuverability for the chassis by a handle assembly 34. The jack stand 22 includes a base having a pair of engagement lugs 21 and enclosing means for releasing the telescopic ratcheting ram of the jack, and a lift collar 23 for lifting the ratcheting ram by the power unit. The forward end 28 of the chassis has a “U” shaped opening 29 adapted to slide over the base of the jack stand 22 and under the engagement lugs 21 to carry and control the jack stand. The chassis includes a jack actuation mechanism 37 for engagement with the lugs 21 of the jack stand, to control the lifting and lowering of the jack stand. The handle assembly is also used to control and pump a hydraulic actuator 36 at the rearward end of the chassis and to actuate the mechanisms 37, at the forward end of the chassis, to control the engagement, release and elevation of the jack stand, as fully described in the prior art patents enumerated in the BACKGROUND OF THE INVENTION. The handle assembly is also used to actuate a release of a locking safety device to be described later in detail. The chassis includes a left flange 38 and a right flange 40 extending generally vertically upward from the sides of the chassis for supporting a lift arm assembly 42.
The lift arm assembly (see also
The hydraulic actuator 36 has a rearward end 64 pivotally mounted to the rearward end of the chassis (see
The Lift Bridge
The lift bridge 24 is illustrated as a separate component in
A basic embodiment of the lift bridge 24 is a simple plate that is adapted to be positioned by hand by the user into the desired position on the forward ends of the lift arms 44. The forward ends 46 of the lift arms include members adapted to engage the bottom surface or sides of the bridge. A suitable member is shown (see
The lift bridge 24 is efficiently produced by a metallic casting incorporating the desired recesses and flanges, as well as any other desired features, i.e. a central aperture therein with suitable reinforcing boss, or strengthening ribs or gussets for added strength or for other specific applications. The basic bridge, positioned by the operator, is incorporated into efficient new products; however, it is particularly useful as an accessory for retrofitting the numerous power units currently in use with jack stands, to be convertible for use as load-lifting jacks.
During initial development and experimental use of the lift bridge, it was discovered that an unattached bridge was sometimes misplaced, and sometimes required extra time and effort to properly position and remove the bridge during alternate jack stand/lifting jack operations. Continued development resulted in a preferred embodiments in which the bridge is slidably retained within guide tracks extending along the upper surface of the lift arms, so that the lift bridge is integral with the power unit and can be readily positioned by hand into the forward position and alternatively into the displaced position while retained within the tracks of the lift arms. A more preferred embodiment further includes a forward biasing means (i.e. a suitable elastomeric member or a suitable compression spring) so that the lift bridge is automatically urged into a slide forward position on the lift arms whenever a jack stand is not engaged within the chassis; and further, so that the presence of a jack stand within the chassis will automatically push the lift bridge rearward (overcoming the forward bias of the spring) along the lift arm to a displaced position.
The Lift Arm Assembly-Automatic Slide Forward Bridge
Referring also to
Referring now to
Referring now to
The springs 100 are retained within the channels 90 (see also
The springs 100 are shown fully compressed within the channels in
The foregoing left lift am, right lift arm and lateral push bar are efficiently manufactured as a single integral casting to form the lift arm assembly 42. The guide track recessed channels 90 are also efficiently and reliably directly formed into the casting. This casting assures reliable precise alignment of the lift arms and push bar, and further assures high strength and durability of the assembly. The assembly can be completed with minimum machining of the apertures and interactive surfaces, for final assembly with the mating components.
Leveling Pads
It is highly desirable for the forward ends of the lift arms to maintain a uniform generally level platform (parallel with the chassis) throughout the lifting operation. This is important for proper engagement of the forward ends of the lift arms 44 with the lift collar 23 of the jack stand 22 for use as a power unit; and also for engagement of the lift arms with the bridge 24 for level contact with the object to be lifted, for use as a jack. Basic leveling means can be incorporated, i.e. a spherical (or circular) ball and socket engagement between the pairs of components that permits relative rotation with changes in the angle of the lift arms. Another example of a basic leveling means can include a pivotal member having a heavy weight extended downward that tends to remain plumb during changes in the angle of the lift arms.
Referring particularly to
In an initial concept, the leveling mechanism was designed with the forward portion of the lift arm in a level orientation, with the lever arm 110 extending downward at an angle corresponding to the angle of the connecting arms 52 (about 20 degrees). The mechanism was conceived to operate as a parallelogram having the length of the connecting rods 112 equal to the distance from the aperture 108 to the common axis 60 of the lift arm; and the distance from the common axis 60 to the connection point 114 on the connecting arms 52 to be equal to the length of the lever arm 110. However, in an initial embodiment, it was necessary to slightly modify the component relationships to empirically perfect the desired level platform. In the example of the embodiment, the length of the lift arm 44 is about 12 inches, the distance from the aperture 108 to the common axis 60 is about 5.50 inches, the length of the lever arm 110 is about 2 inches, the connecting point 114 is about 1.05 inches from the common axis 60, and the connecting rods are about 6.25 inches in length. Although the concept of the parallelogram is believed to have merit, the above relative lengths and connection points are suitable to produce the desired level platform on the lift arm, and can be proportioned for other embodiments having lift arms with a different length
This leveling mechanism was developed in conjunction with the power unit and bridge for use as a jack. However, it should be understood that this feature is adaptable to all conventional floor jacks and pivotal linkages.
Safe Jack Securing Mechanism
As discussed in the BACKGROUND OF THE INVENTION, a hydraulic jack is dependent upon a series of fluid valves and seals and carefully aligned piston and ram components. With time or excessive use, these seals tend to leak fluid and loose hydraulic pressure known as “hydraulic bleed” and the jack becomes unreliable and unsafe. In spite of excessive use and wear, some hydraulic jacks can function in the dynamic mode with repeated pumping to extend the ram, and can lift a load; however, without the repeated pumping of the actuator, the ram can not sustain a static load for an extended period of time, without a block or mechanical stand, and the jack fails to support the load.
Another feature of the present invention is a hydraulic floor jack that includes a mechanical securing mechanism that converts the jack into a safe mechanical jack stand. This mechanism was developed in conjunction with the power unit and bridge for use as a safe jack, and for a safe jack stand. However, it should be understood that this feature is adaptable to all conventional hydraulic floor jacks.
Referring now to
The rack bar is typically formed of steel plate or casting about 0.5 inches wide and extends the length of the slot. The bar does not require welding and is efficiently attached to the base of the chassis with conventional rivet fasteners 126. The teeth 122 are typically evenly spaced and can have a variety of suitable shapes, however the teeth are preferably inclined toward the forward end of the chassis. The dog is suitably formed from a steel plate or casting and the weight of the extended dog is naturally forced by gravity onto the toothed bar. The engagement of the dog with the toothed bar can be further ensured by a coaxial torsion spring (not shown) exerting downward pressure on the dog. The dog is thus adapted to be engaged with a corresponding tooth of the rack bar at all times (unless intentionally disengaged), to mechanically secure the rearward ends of the lift arms to the chassis independent of any force of the hydraulic cylinder on the lift arm.
It is readily seen in
The dog of the securing mechanism can be actuated to be engaged or disengaged by suitable latches, detent means, cables and linkage (not shown), directly by an operator. Preferably, the dog further includes a spring release linkage 124, shown in
Securing Mechanism Adapted to the Power Unit with Bridge
Referring to
The securing mechanism is automated by a pair of slip rings 128 that are coaxially mounded around the lateral push bar 50 having a pair of tension springs 130 attached to the upper portion 132 thereof, and interconnected to an upper peripheral portion 134 of the dogs. The normal position of the slip rings is such that the tension springs are slack and fully contracted with no tension thereon, and the dogs are engaged with the toothed rack bar as shown in FIG. 16. The foregoing normal position corresponds to the power unit not engaged with a jack stand 22, and the bridge 24 is in the automatic slide forward position on the forward ends of the lift arms (see FIG. 3), and the power unit is adapted for use as a jack and jack stand. The power unit can thus be operated as a jack and raised to a desired level and positioned as a jack stand, as previously discussed, with the dogs automatically ratcheted forward within the teeth of the bar, and securely locked against any rearward movement of the lift arms.
The slip rings 128 include a linkage mechanism comprising a control lever 135 extending from the lower periphery of the slip rings, and interconnected by a control bar 136. When a jack stand 22 (see
It may also be convenient to manually release the safety mechanism when the power unit is being lowered or repositioned without a load. A suitable manual release is provided with a linkage 138 attached to the control bar 136, and extending to a suitable lever at the top of the handle assembly 34 (not shown).
While specific embodiments and examples of the present invention have been illustrated and described herein, it is realized that modifications and changes will occur to those skilled in the art. It is therefore to be understood that the appended claims are intended to cover all such modifications and changes as fall within the spirit and scope of the invention.
Number | Name | Date | Kind |
---|---|---|---|
5181821 | King, Sr. | Jan 1993 | A |
6199826 | Nix | Mar 2001 | B1 |
6416039 | Pietrusynski | Jul 2002 | B1 |
6435477 | Brunnhoelzl | Aug 2002 | B2 |
Number | Date | Country | |
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20030218160 A1 | Nov 2003 | US |