This application claims priority to Chinese Patent Application No. 201110420520.4, filed Dec. 16, 2011, which is hereby incorporated by reference in its entirety.
The invention relates to industrial lift trucks and, in particular, pallet trucks for lifting and transporting pallets upon which goods may be placed.
Pallet trucks are often used to lift and maneuver pallets and goods supported thereon during warehousing and shipping. Pallet trucks have been developed to provide varying amounts of functionality to an operator and may be generally categorized as either manual or powered. Manual pallet trucks typically have a frame with forks connected thereto, a truck supported on a pair of rear wheels, and a hydraulic jack connected to the truck and the frame. The jack, which is typically a hydraulic bottle jack, is operated by pivotally pumping a steering handle of the pallet truck up and down which causes the hydraulic bottle jack to raise the frame and the forks thereof off of the ground. Once the pallet has been raised by pumping the handle, an operator may steer the pallet truck by turning the handle relative to the truck. The handle is connected to the hydraulic bottle jack and the pair of rear wheels such that turning the handle generates concurrent turning of the hydraulic bottle jack and the pair of rear wheels. With the pallet raised, the operator pushes or pulls on the handle with sufficient force to maneuver the pallet truck, the pallet, and the goods on the pallet to a desired location. As is apparent, maneuvering the pallet truck, the elevated pallet, and the goods thereon is even more difficult when the pallet truck is positioned on an inclined surface or within relatively tight confines, such as offloading pallets from a semi-truck trailer.
A powered pallet truck has a frame with forks connected thereto, a truck supported on a rear wheel, a hydraulic jack connected to the truck and the frame, and a drive mechanism connected to the rear wheel that assists the operator in maneuvering the pallet truck. Like the manual pallet truck, the powered pallet truck has a handle connected to the hydraulic jack and the rear wheel such that turning of the handle generates concurrent turning of the hydraulic jack and the drive wheel. However, the powered pallet truck has a drive mechanism, such as an electric motor, connected to the rear wheel that allows an operator to propel and brake the pallet truck by way of controls on the handle. This type of pallet truck may be referred to as a semi-powered pallet truck, as the operator still pivotally pumps the handle to activate the hydraulic jack and raise the frame and the forks thereof off the ground. An operator, such as an employee of a local delivery service, may make a large number of deliveries throughout a workday that each involve loading and unloading pallets and the goods thereon. Requiring the operator to manually pump the handle of the pallet truck each time they need to lift a pallet may be ergonomically difficult, particularly when the operator is attempting to move a pallet in limited working areas.
It is therefore desirable in some applications to provide a pallet truck having both a powered drive mechanism and a powered lift mechanism. Prior approaches for this type of pallet truck, which may be referred to as a fully-powered pallet truck, utilize a frame assembly comprising a large front frame having a pair of forks that moves up and down and a large rear frame to which the drive mechanism and lift mechanism are mounted that remains relatively stationary during up and down movement of the front frame. For many prior fully-powered pallet trucks, the drive mechanism comprises an electric drive motor for propelling the pallet truck and the lift mechanism comprises a hydraulic pump and a hydraulic cylinder for moving the front frame up and down relative to the rear frame. By mounting the electric motor, the hydraulic pump, and the hydraulic cylinder to the generally stationary rear frame, wear and tear on the wiring and hoses associated with these components is limited during up and down movement of the front frame and forks thereof. One problem with this type of pallet truck is that the rear frame needs to be relatively large to support the drive mechanism, the lift mechanism, and their associated wiring, hoses, fittings, and the like. Further, because the length of the forks of the pallet truck are generally fixed according to industry standards, providing a sufficiently large rear frame to support the drive mechanism, lift mechanism, and their associated components increases the overall length of the pallet truck and inhibits maneueverability of the pallet truck in tight operating spaces.
Another problem with prior fully-powered pallet trucks is that the configuration of the drive and lift mechanisms adds length to the rear frame and increases the overall length of the pallet truck. More specifically, the drive mechanism of the pallet truck comprises a drive motor mounted vertically or horizontally on the rear frame and the lift mechanism comprises one or more hydraulic cylinders mounted to the rear frame forward of the drive motor that are configured to raise and lower the front frame. Positioning the one or more hydraulic cylinders forward of the drive motor further increases the length of the rear frame which, in turn, increases the overall length of the pallet truck and further inhibits its maneuverability.
Yet another shortcoming with prior fully-powered pallet trucks is that a lower portion of the rear frame needs to be sufficiently strong to support the weight and loading applied by the drive and lift mechanisms. In addition, prior fully-powered pallet trucks have a two-bar linkage between upper portions of the front and rear frames to control relative movement therebetween. The rear frame therefore needs to be sufficiently strong at the lower portion thereof to support the weight and loading applied by the drive and lift mechanisms in addition to being sufficiently strong at the upper portion thereof to support the loading applied to the two bar linkage from the front frame, pallet, and goods on the pallet. This large, strong rear frame is expensive to manufacture, increases the weight of the pallet truck, and decreases the efficiency of the pallet truck due to the increased power necessary to propel the heavier pallet truck.
In accordance with one aspect of the invention, a powered pallet truck is provided having a frame assembly including a base support portion, a load lift portion having a pair of forks, and a central longitudinal axis extending in a fore-and-aft direction with the forks of the load lift portion extending forwardly on either side of the central longitudinal axis. The pallet truck has a drive wheel disposed below the base support portion, a drive motor mounted in the drive wheel, and an overall longitudinal length extending in the fore-and-aft direction from distal ends of the forks to the center of the drive wheel. The pallet truck further includes a lift mechanism operable for moving the load lift portion of the frame assembly up and down mounted to extend upwardly in general fore-and-aft alignment with the center of the drive wheel. Having the drive motor mounted in the drive wheel and the lift mechanism mounted in fore-and-aft alignment with the center of the drive wheel provides both a drive mechanism and a lift mechanism in a smaller envelope than previous fully-powered pallet trucks. Further, mounting the drive motor in the drive wheel provides a powered drive mechanism for the pallet truck without having the base support portion of the frame assembly be sufficiently large to accommodate the drive motor thereon.
The pallet truck further includes a pressurized fluid supply mechanism mounted to the load lift portion of the frame assembly forward of the lift mechanism along the central longitudinal axis which is configured to supply pressurized fluid to the lift mechanism through a fluid conduit. In contrast to prior fully-powered pallet trucks having a hydraulic pump mounted on a large stationary rear frame, the pressurized fluid supply mechanism of the subject pallet truck is mounted to the load lift portion of the frame which moves up and down relative to the base support portion of the frame assembly. While this approach runs counter to the approach taken in prior fully-powered pallet trucks, it increases utility of the load lift portion of the frame assembly by using the load lift portion to support the pressurized fluid supply mechanism. In one form, the pressurized fluid supply mechanism, one or more batteries, and a controller of the pallet truck are all mounted to the load lift portion of the frame assembly which provides a compact and lightweight configuration for the fluid supply and electrical systems of the pallet truck. Further, mounting the pressurized fluid supply mechanism to the load lift portion of the frame assembly forward of the lift mechanism provides a powered lift mechanism for the pallet truck without requiring that the base support portion of the frame assembly be sufficiently large to accommodate the pressurized fluid supply mechanism thereon. In this manner, the mounting of the drive motor, the lift mechanism, and the pressurized fluid supply mechanism keeps the overall longitudinal length of the pallet truck to a minimum, such as approximately 54 inches.
The load lift portion of the frame may have an upstanding housing portion configured to receive one or more batteries with the fluid supply mechanism mounted to the upstanding housing portion above the one or more batteries. In one form, the fluid supply mechanism includes a hydraulic pump and reservoir both mounted to the upstanding housing portion in a horizontal orientation above the batteries. With the drive motor mounted in the wheel and the one or more batteries are disposed upon a bottom wall of the housing portion, the drive motor, hydraulic pump, reservoir, and one or more batteries are configured to lower the center of gravity of the pallet truck and increase the stability thereof during use.
In a preferred form, the pressurized fluid supply mechanism includes a pump and the frame assembly includes a rearward power head to which the forks are connected and the pump is mounted. The power head has a longitudinal length and the forks have a standard length, with the power head being configured so that the mounting of the drive motor, lift mechanism, and the pump keeps the longitudinal length of the power head to a minimum. In one approach, the power head includes a steering seat to which a steering assembly is mounted, a drive wheel below the steering seat to which the drive motor is mounted, and a pump mount forward longitudinally of the steering mount. The rearward power head further includes a mounting portion to which the lift mechanism is mounted with the connection of the lift mechanism to the power head keeping the longitudinal length of the power head to a minimum. For example, the power head includes a lift mechanism seat to which the lift mechanism is mounted above the steering seat. By minimizing the longitudinal length of the power head, the pallet truck provides easier maneuverability in tight working areas for a given length of the forks.
In accordance with another form of the invention, a powered pallet truck is provided that includes a frame assembly having a base support portion and a load lift portion with a pair of forks extending forwardly of the base support portion in a longitudinal direction. The base support portion includes a steering seat and a lift cylinder device seat separate from the steering seat. The pallet truck includes a steering assembly rotatably coupled to the steering seat and a lift cylinder device operable to move the load lift portion up and down relative to the base support portion. The pallet truck has a pivot connection between an upper end portion of the lift cylinder device and the load lift portion that permits movement of the upper end portion relative to the load lift portion with up and down movement of the load lift portion and the forks thereof. Further, the pallet truck has a connection between a lower end portion of the lift cylinder device and the lift cylinder device seat of the base support portion configured so that the lower end portion and the lift cylinder device seat are fixed against longitudinal movement relative to each other.
The pallet truck further includes a fluid conduit between the lift cylinder device and a pressurized fluid supply mechanism mounted to the load lift portion. The fluid conduit is connected to the upper portion of the lift cylinder device adjacent the pivot connection between the upper portion of the lift cylinder device and the load lift portion of the frame assembly. This configuration limits movement of the fluid conduit during up and down movement of the load lift portion of the frame assembly and the associated pivoting of the upper portion of the lift cylinder device relative to the load lift portion. More specifically, by having separate steering and lift cylinder device seats, the lift cylinder device is not turned each time an operator turns the steering assembly to maneuver the pallet truck which keeps the lift cylinder from turning relative to the fluid conduit and imparting stresses thereto. Further, connecting the fluid conduit to the upper portion of the cylinder adjacent the pivot connection minimizes the change in vertical position of the fluid conduit as the load lift portion moves up and down. Still further, by fixing the lower end portion of the lift cylinder device against longitudinal movement relative to the lift cylinder device seat, horizontal movement of the lift cylinder relative to the pressurized fluid supply device mounted on the load lift portion is minimized during up and down movement of the load lift portion. In this manner, the stresses imparted to the fluid conduit and the connections between the fluid conduit and the lift cylinder and pressurized fluid supply device are reduced and prolongs the lifecycle of the lift cylinder device, fluid conduit, and pressurized fluid supply mechanism.
In one form, the upper end portion of the lift cylinder device includes a housing having a closed upper end and a lower end opening and the lower end portion of the lift cylinder device includes a piston which reciprocates into and out of the lower end opening of the housing during operation of the lift cylinder device. By utilizing a housing having a closed upper end, the fluid conduit can be connected to the closed upper end which minimizes the distance the fluid conduit needs to extend along the lift cylinder device to supply fluid to the lift cylinder device. As is apparent, the orientation of the lift cylinder device is inverted compared to the hydraulic cylinders of prior fully-powered pallet trucks and provides a powered lift mechanism without having the base support portion be sufficiently large to accommodate the housing and the fluid conduit connected thereto.
In another aspect of the present invention, a powered pallet truck is provided that includes a frame assembly having a base support portion and a load lift portion with a pair of forks. The pallet truck has a steering assembly rotatably coupled to the base support portion, a control head of the steering assembly for receiving manual inputs from an operator, and one or more cables operably connecting the control head to a controller mounted to the load lift portion of the frame assembly. The base support portion includes an arcuate window sized and configured to receive the one or more cables extending therethrough with the arcuate window permitting movement of the one or more cables within the window as the steering assembly is turned relative to the base support portion. The arcuate window permits the one or more cables to move with turning of the steering assembly without flexing or pinching of the one or more cables due to engagement with the base support portion. Further, the arcuate window provides a range of motion for the one or more cables for the full range of turning of the steering assembly, e.g., 180 degrees, without bending or wrapping the one or more cables around surfaces of the base support portion of the frame assembly.
The base support portion of the frame assembly may include a steering mounting portion disposed below the arcuate window to which the steering assembly is rotatably coupled, a lift mechanism mounting portion disposed above the arcuate window, and a lift mechanism connected to the lift mechanism mounting portion. The steering mounting portion and the lift mechanism mounting portion are disposed on opposite sides of the arcuate window such that the one or more cables can move within the arcuate window without being restricted by the steering assembly or the lift mechanism. Further, the vertically stacked configuration of the steering mounting portion, arcuate window, and lift mechanism mounting portion provides a powered pallet truck having a drive mechanism and a lift mechanism in a compact assembly.
In
More specifically, the pallet truck 10 has a central longitudinal axis 32 and an overall longitudinal length 34 extending along the longitudinal axis 32 between distal ends 36 of the forks 16, 18 and a center 38 of the drive wheel 26, as shown in
The pallet truck 10 further has a steering assembly 46 rotatably coupled to the yoke 40 and may be turned in direction 45 about a steering axis 45A. The yoke 40 has a steering seat 262 and a separate lift cylinder device seat 284 (see
In another aspect, as seen in
With reference to FIGS. 2 and 4-6A, the pallet truck 10 has a front housing 60 and a rear housing 62 that may be removed to illustrate operation of components of the pallet truck 10 as the forks 16, 18 are moved from the lowered position 50 to the raised position 52. The lift cylinder device 24 has a longitudinal axis 64 extending vertically when the forks 16, 18 are in the lowered position 50 and which angles forward as the forks 16, 18 reach the raised position 52 (see
The pressurized fluid supply mechanism 70 is operably coupled to the lift cylinder device 24 via the fluid conduit 72 extending between lift frame 15 and the lift cylinder device 24. In one form, the pressurized fluid supply mechanism 70 includes a hydraulic system assembly 74 having a hydraulic pump 76 (see
The pallet truck 10 has a link mechanism 53 pivotally connected to the yoke 40 and the lift frame 15 for controlling movement of the lift frame 15 along the arc of movement 120. In the illustrated embodiment, the link mechanism 53 includes a pair of arms 86A, 88A of bell cranks 86, 88 disposed on opposite sides of the yoke 40. The arms 86A, 88A are pivotally connected to the yoke 40 at pin joints 90 and are pivotally connected to the lift frame 15 as will be discussed in greater detail below. The lift mechanism 53 further includes the pivot joint 82 between the angle bracket 83 of the lift frame 15 and the lift cylinder device housing 80 which permits the lift cylinder device housing 80 to articulate relative to the lift frame 15 as the lift frame 15 raises and lowers. In this manner, the link mechanism 53 provides a pantograph-style elevation mechanism for the lift frame 15 and controls the movement thereof relative to the yoke 40. Further, the link mechanism 53 provides a movement of the lift frame 15 similar to a three-bar linkage due to the rigid connection between the piston 79 and the yoke 40, the pivot joint 82 between the lift device housing 80 and the angle bracket 83, and the pivot connections between the arms 86A, 88A and both the lift frame 15 and the yoke 40.
To raise the distal ends 36 of the forks 16, 18 simultaneously with lifting of the lift frame 15, a lift link assembly 84 (see
The bell cranks 86, 88 each include a trailing arm 98 connected by a hinge 100 to a lift bar 102. Each lift bar 102 is in turn connected to a load roller assembly 104 which is pivotally connected to the lift frame 15 by shafts 106. Therefore, activating lift cylinder device 24 and shifting the housing 80 upward causes the lift frame 15 and shaft 94 fixed thereto to lift upward which pivots the bell cranks 86, 88 and counter torque tube 92 about the shaft 94, which in turn shifts the lift bars 102 forward in direction 108 and pivots the load roller assemblies 104 about the shafts 106 in direction 110 and raises forks 16, 18, as may be seen in
With reference to
With reference to
To transmit the signals from the control head 156 to the controller 150, the wiring harness 44 extends from the control head 156, through arcuate window 42 of the yoke 40, and toward the lift frame 15, as shown in
With reference to
As shown in
Another advantage of the pallet truck 10 is that the steering assembly 46 includes a relatively long control arm 192 connected to a gear box housing 194 (see
With reference to
The pallet truck 10 has a transmission assembly 216 that transfers rotation of a driveshaft 220 of the drive motor 28 disposed within the drive wheel 26 into rotation of the drive wheel 26. More specifically, the drive motor 28 is mounted in the drive wheel 26 so that the drive wheel 26 extends about the drive motor 28, as shown in the cross-sectional view of
With continued reference to
With reference to
At the other end of the lift frame 15, the hydraulic system assembly 74 is secured to the upstanding housing 96. The upper portion of the lift cylinder device 24 is pivotally connected to the lift frame 15 at angle bracket 83 and rigidly connected at the lower portion of the lift cylinder device 24 to a lift cylinder device seat 262 (see
The hydraulic system assembly 74 may include the lift cylinder device 24, the hose 78, the pump 76, and a support 264 to which the pump 76 is mounted. The pump 76 includes a motor 142 for pumping fluid from a reservoir 276 toward the lift cylinder device 24 through hose 78. In contrast to prior manual or semi-powered pallet trucks, the hydraulic system assembly 74 is configured to operate the lift cylinder device 24 without pivotal pumping of the handle 164. In one form, the drive motor 28 and the pump motor 142 may both be permanent magnet direct current motors which provides efficient operation, extended battery capacity, and improved duty cycles for the pallet truck 10. The pump 76 also includes a valve 278 for controlling flow of the fluid and a solenoid 279 to control operation of the valve 278.
The gear box housing 194 is rotatably coupled to a steering seat 284 of the yoke 40 so that the transmission assembly 216, drive wheel 26, and drive motor 28 may be turned relative to the yoke 40 about the steering axis 45 (see
With reference to
It will be understood that various changes, modifications, alterations, and combinations in the details, materials, and arrangements of the parts and components that have been described and illustrated in order to explain the nature of the powered pallet truck as described herein may be made by those skilled in the art within the principle and scope of this disclosure.
Number | Date | Country | Kind |
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2011 1 0420520 | Dec 2011 | CN | national |
Number | Name | Date | Kind |
---|---|---|---|
2592091 | Weaver | Apr 1952 | A |
3043388 | Hansen | Jul 1962 | A |
3187917 | Miller | Jun 1965 | A |
3249170 | Quayle | May 1966 | A |
3295881 | Worthington | Jan 1967 | A |
3601423 | Goodacre | Aug 1971 | A |
3854748 | Goodacre | Dec 1974 | A |
4047698 | Ellis | Sep 1977 | A |
4065012 | Rocco | Dec 1977 | A |
4082195 | Wnek | Apr 1978 | A |
4096961 | Rocco | Jun 1978 | A |
4103795 | Miller | Aug 1978 | A |
4287959 | Inman | Sep 1981 | A |
4470578 | Arvidsson et al. | Sep 1984 | A |
4577463 | Kedem | Mar 1986 | A |
4615533 | Sewell | Oct 1986 | A |
4941794 | Hara et al. | Jul 1990 | A |
5113960 | Prinz | May 1992 | A |
5326217 | Simpson et al. | Jul 1994 | A |
5618154 | Irons et al. | Apr 1997 | A |
5752584 | Magoto et al. | May 1998 | A |
6027303 | Voegeli | Feb 2000 | A |
6125971 | Niebuhr et al. | Oct 2000 | A |
6260646 | Fernandez et al. | Jul 2001 | B1 |
D447612 | Niebuhr | Sep 2001 | S |
7040427 | Toomey | May 2006 | B2 |
D530878 | Ruppert et al. | Oct 2006 | S |
D583124 | Stark | Dec 2008 | S |
7744335 | Cleary | Jun 2010 | B1 |
8230976 | Baldini | Jul 2012 | B2 |
8246008 | De Jong et al. | Aug 2012 | B2 |
8306703 | Saleh | Nov 2012 | B1 |
8360443 | Ellington | Jan 2013 | B2 |
20050036880 | Magoto et al. | Feb 2005 | A1 |
20060181039 | Fridlington, Jr. | Aug 2006 | A1 |
20090260923 | Baldini | Oct 2009 | A1 |
Entry |
---|
Brochure for “PDS Power Drive Straddle Trucks” issued by Blue Giant®, Sep. 1, 2010 (2 pages). |
Website for Shanghai Noblelift Co. Ltd. Guangzhou Subsidiary “Semi-electric Pallet Truck Spt” http://gdnobliften.en.busytrade.com/products/info/1904267/Semi-electric-Pallet-Truck-Spt.html, accessed Jan. 13, 2012, (4 pages). |
Website for Starts for “Electric Vehicle—Electric Pallet Truck,” http://www.starstw.com/news/stars-electric-pallet-truck.html, accessed Jan. 13, 2012 (1 page). |
Website for Cherry's industrial Equipment for “SPT15-Semi Electric Pallet Truck” http://www.pallettruck.com/spt15.html, accessed Jan. 17, 2012 (1 page). |
Number | Date | Country | |
---|---|---|---|
20130153840 A1 | Jun 2013 | US |