The present invention relates generally to stair-climbing wheeled vehicles, and more particularly to an electrically powered or power-assisted, spider-, cluster-, or wheel-over-wheeled stair-climbing vehicle, such as a hand truck, having microprocessor-controlled modes for facilitating the balancing and maneuvering of the vehicle.
Hand trucks, wheelchairs, and other wheeled vehicles (collectively, “vehicles”) are well known, but electrically-powered vehicles having the ability to climb stairs are a relatively recent innovation. Such vehicles are typically complex, expensive, and difficult to use.
There have been numerous attempts to create a stair-climbing vehicle based on a spider, or wheel-over-wheel, design. While tri-wheel spider assemblies are well-suited for stair climbing, they generally have substantial steering problems when used on flat ground. Since a pair of tri-wheel spider assemblies naturally has four wheels (two of each spider) in contact with the ground, it is much more difficult to turn the vehicle, and the turning radius is much larger than that of a conventional hand truck—which only has two wheels in contact with the ground.
There have been various approaches to addressing these and other issues. A simple approach involves inclusion of a manually-operable mechanism that mechanically locks the spiders in positions such that only two wheels (one of each spider assembly) touch the ground during rolling transport. For example, various chain and-sprocket mechanisms have been used to achieve two-wheel locking, but they significantly increase the cost and weight of the vehicle. The chains are also under extreme tension, and can pose a reliability or safety hazard in the event of failure.
Further, mechanical pin-based systems require the tri-wheel assembly to rotate to a precise angle, at which point a locking pin is inserted to lock the assembly at an angle that allows the unit to be manually tipped onto two wheels. The main problems with the mechanical pin method are strength and complexity.
Moreover, the tri-wheel assembly must be aligned exactly prior to pin insertion, which may be difficult to accomplish without extensive user effort. The pin may also be difficult to retract under load to transition to stair-climbing mode. As with the chain-and-sprocket approach, the components are also under considerable mechanical stress, and thus will be relatively heavy and pose a significant reliability and safety issue.
The foregoing designs may use a rigid locking system, which will not tolerate shocks and impacts well. For example, it would be relatively common for the hand truck to experience impacts when rolling over curbs and other bumps. The chains or pin lock could easily experience peak stresses many, such as 5 or more, times higher than the average static stress, but the parts must be designed to withstand this peak stress. This design requirement will increase weight and production costs. A complex and expensive approach, frequently employed in passenger-carrying wheelchairs, involves inclusion of motors, sensors, and feedback-based control to cause the wheelchair to actively balance itself, relative to a vertical reference plane, on two wheels (one of each spider assembly).
There are numerous stair climbing vehicle designs that utilize a multiple armed, wheel-supporting spider drive so as to place rotating wheel points located near the ends of the wheel's arms successively on wheel-supporting surfaces, such as a flight of stairs. Such spider wheels may be small, freely-rotating wheels fastened at the ends of spokes that rotate all together as a rigid assembly. For example, PCT Patent Publication No. WO8600587A1 describes a stair-climbing hand truck utilizing rotating spider wheels.
However, even the state of the art fails to address a critical safety issue likely to arise on stairwells with a shallower rise. During stairwell descent, the spider assembly rotates continuously in the down-stairs direction, placing each of the individual spider wheels successively on each lower stair riser in a controlled manner. The spider, though, may unintentionally reverse rotation direction during descent if the lower-leaning wheel of the assembly does not become properly pinned against the inside corner of the lower riser. In such a case, weight is not properly shifted to the lower leaning wheel, allowing the lower leaning wheel to roll forward rather than remain anchored as a pivot against the inside corner of the lower stair riser. This may result in the unit falling to the lower stair riser, thus interrupting a smooth and controlled descent and potentially causing damage.
The prior art attempts to address this problem associated with descent through altering the geometrical structure of the spider assembly, proposing the use of a four-wheeled spider assembly instead of a three-wheeled one, built with predetermined dimensions to suit a stairwell of typical height. Thus crafted, the pre-dimensioned four-wheel spider avoids the aforementioned problem on a typical stairwell since its central pivot locations lie forward of the pivot center of the lower leaning wheel. However, even a four-wheeled spider thus properly dimensioned will confront the aforementioned problem on a relatively shallow stairwell outside the bounds of its geometrical design, and will exacerbate the aforementioned problems of a non-round wheel, limited turning radius, and the like.
The present invention is and includes a wheeled vehicle including a rigid frame supporting a rotatable axle, and a pair of spider assemblies rotatably supported adjacent opposite ends of the axle. Each of the spider assemblies supports a plurality of rotatable wheels coupled to rotate in synchronicity.
The vehicle may further include an angular position sensor supported on the frame in position to measure an angular position of one of the spider assemblies relative to the frame. The vehicle further includes an electric motor and a power source supported on said frame and operatively connected to drive the pair of spider assemblies to rotate. The vehicle further includes a controller supported on the frame and operatively connected to the angular position sensor and the power source to cause the electric motor to apply varying rotational torque to the spider assemblies to cause them to maintain a selected angular position relative to the frame as a function of input received from the angular position sensor.
The vehicle may “fix”, lock, or maintain, subject to corrective variations, the spider assemblies at any of several different target angles relative to the frame. Thus, the vehicle includes a feedback system including an angular position sensor, a microprocessor based controller pre-configured with suitable instructions, and a main drive motor.
The spider assemblies may have angular ranges/regions of inherent instability when descending stairs. In certain embodiments, the controller stores instructions identifying a range of angular positions corresponding to such regions, as a function of the tri-wheel or other configuration of the spider assemblies, and the angular position sensor detects the position of the spider assemblies. In such embodiments, the controller may actively accelerate the spider-assemblies through the regions of instability, greatly reducing the risk of rolling off the edge of the stairs. This feature greatly increases the safety and ease of use of the product, and is particularly useful for tri-wheel spider assemblies to acceptably meet the expectations of non-professional users.
The vehicle may include a variable engagement clutch and brake system. This clutch can either lock the wheels to the same reference frame as the hand truck frame, or can allow them to spin freely. During ascent and descent modes, the clutch system may provide added driving traction to force the hand truck to climb the stairs, rather than roll off or bounce in place. The clutch also can act as a brake to lock the hand truck to the stairs, reducing the possibility that it would roll off if the user were to stop at some point during ascent or descent. In one embodiment, the clutch is electromagnetic and fully controlled by the controller; no user control is required.
The invention may further include using a friction clutch system to create a wheel that spins freely in one direction, while offering a configurable amount of slip torque resistance in the opposite direction of rotation. Further included may be a unidirectional slip clutch system for the wheels of a stair climbing hand truck to provide a forward driving and/or locking force. Moreover, the disclosure includes a slip clutch system with a low level of resistance opposing forward motion and a moderate level of resistance opposing reverse motion for the wheels of a stair climbing device. For example, in an embodiment a clutch device may allow a wheel to freely rotate in one direction while encountering a slip clutch resistance in the opposite direction of rotation.
Optionally, the vehicle is configured as a hand truck and further includes removable cargo baskets, and a dual-platform load-carrying system. The vehicle may further include wheel-guarding enclosures, and a telescoping, rotatable handle.
Thereby, the present invention is advantageous at least in that it addresses the shortcomings of the known art, as discussed above.
The present invention will now be described by way of example with reference to the following drawings, in which:
It is to be understood that the figures and descriptions provided herein may have been simplified to illustrate elements that are relevant for a clear understanding of the present disclosure, while eliminating, for the purpose of clarity, other elements found in typical wheeled-vehicle apparatuses, systems and methods. Those of ordinary skill in the art may recognize that other elements and/or steps may be desirable and/or necessary to implement the devices, systems, and methods described herein. However, because such elements and steps are well known in the art, and because they do not facilitate a better understanding of the present disclosure, a discussion of such elements and steps may not be provided herein. The present disclosure is deemed to inherently include all such elements and steps, and all variations and modifications to the disclosed elements and methods that would be known to those of ordinary skill in the pertinent art.
The present invention relates generally to stair-climbing wheeled vehicles, and more particularly to electrically-powered, and/or spider-driven, and/or stair-climbing wheeled vehicle having a microprocessor-controlled mode or modes for facilitating balancing and maneuvering of the vehicle. The present invention is applicable to hand trucks, luggage carriers, wheel chairs, baby carriages and/or other wheeled vehicles. A wheeled vehicle in accordance with the present invention includes sensors, an electric motor, and a controller for controlling the motor as a function of input received from the sensors to provide modes for facilitating balancing, including facilitating manual balancing, and maneuvering of the vehicle.
Unlike principally mechanical designs, the approach of the present invention includes principally electronic control. Further, the disclosed embodiments do not require any significant addition of components or production costs, and avoid end user complexity.
For illustrative purposes, the present invention is discussed in the context of an exemplary hand-truck vehicle, which is shown in
The vehicle 10 includes a microprocessor-based controller 60 configured to receive input from various sensors discussed throughout, and to control operation of the motor's driveshaft as a function of the input received, as shown in
The wheels of each spider assembly 20a, 20b may be operatively coupled to rotate in synchronicity, e.g., by gears 70 fixed to rotate with each wheel 28A, 28B, 28C and coupled by a double-sided timing belt 72, as shown in
The vehicle 10 may further include a variable-force actuator 80, such as an electromagnetic clutch, that provides a variable braking force to rotation of the wheels 28A, 28B, 28C about their respective axes. The variable-force actuator 80 is operatively coupled to the controller 60, which controls current supplied from the power source, and that thus controls the amount of braking force applied. See
As illustrated with particularity in
When engaged, the clutch 80 provides a variable torque between the rotating plate 68 fixed with respect to the wheels (rotatable relative to the axle 24) and the fixed plate 66 fixed to the frame. The clutch 80 locks the central pulley to the frame 22 with variable force. As the wheels and spider hubs 26 rotate around the locked central pulley, the wheels 28A, 28B, 28C are driven to rotate with relation to the frame 22, while they translate in a rotational arc based on the driving of the hubs 26 by the main axle 24. Thus, the wheels are caused to rotate with respect to the frame 22 while the spider assemblies 20a, 20b rotate around them, resulting in a net forward driving force that forces the vehicle 10 into abutting relationship with the base of the stairs, instead of allowing it to fall off or bounce in place. When the wheels of the spider assemblies contact the riser of the next stair, the vehicle can no longer be driven further into the stairs, and the clutch 80 slips to limit the torque on the pulley system.
In accordance with the present invention, the vehicle 10 may further include an angular position sensor 32 (see
The vehicle 10 may further include user-operable switches 56 mounted on the handle 34, as shown in
The controller 60 is programmed to control operation of the hand truck in the various modes. More specifically, controller 60 is configured to control current supplied to electric motor 30 from power source 50 as a function of input received from one or more of angular position sensor 32, velocity sensor 34, optical sensors 64, and switches 56, in accordance with microprocessor-executable instructions stored in the memory of microprocessor-based controller 60. See
Transport mode is used for transporting items, such as water jugs, pallets, cases, luggage, etc. over a substantially level flat or inclined but flat floor, etc. In this mode, the controller 60 causes the variable-force actuator (electromagnetic clutch) 80 to disengage, and thus permits the wheels 28A, 28B, 28C to rotate freely. The controller 60 receives data from the angular position sensor 32 and causes the motor to rotate the spider assemblies (hubs 26) to one of several (three for a tri-wheel spider assembly, spaced by approximately 120 degrees) predetermined angular positions relative to the frame, and to fix the spider assemblies in the selected angular position. The angular position is such that the vehicle rests with the frame 22 in a substantially upright position, with four wheels (two of each spider assembly) resting on the ground. Upon inclining frame 22 to traverse horizontal surfaces, the spider assembly hub 26 and frame 22 tilt as one fixed unit, the angle between the hubs 26 and the frame 22 being fixed, at which point only two wheels (one on each spider) are positioned to contact the floor during rolling transport of the hand truck. The controller 60 continues to receive angular position data from the angular position sensor 32 as feedback, and to control the motor 30 by varying current from the power source to the motor, to fix the hubs 26 in the selected angular position, e.g. to maintain the predetermined angular relationship between the spiders and the frame, regardless of the position or orientation of the frame/hand truck relative to the floor, or a vertical plane.
More specifically, the controller 60 uses the angular position sensor 32 to determine the current angle between the hubs 26 and the frame 22, and sets the target angle to the nearest of several acceptable points (one corresponding to each wheel of the tri-wheel assembly). The motor 30 is actively controlled through bi-directional pulse width modulation (PWM) to maintain the target angle. The controller uses a proportional integral derivative (PID) control loop to maintain a stable angular position of the spider assembly hubs. Gradual power ramping is used to prevent any sudden movements or jerking. Accordingly, the relative angular position of the hubs 26 and frame 22 is maintained substantially constant, the frame and hubs tilt as a unit, and the hubs are “fixed” relative to the frame. The unit's turning radius is thus greatly reduced, enabling the turning of tight corners. The locking mechanism may then be disengaged prior to ascent and descent, allowing for the free rotation of the spider wheel as depicted in
Thus, regardless of the hand truck's spatial orientation/inclination relative to a vertical plane, etc., the controller, angular position sensor, motor and power source cooperate to maintain a fixed angular position of the hubs 26 relative to the frame 22 in fixed mode.
It will be appreciated that an advantage in employing the controller for an at least substantially electronic control of the motor to maintain a somewhat resilient “fixed” relationship is the lack of a rigid mechanical restraint that mechanically couples the hubs and frame. According to the present invention, impacts and torque on the hubs thus mainly act on the motor's electromagnetic field, which is not a breakable mechanical component. The control system thus acts as an electronic shock absorber, and permits the tri-wheel assembly to move by several degrees during impacts, reducing the stress on the power train. In one embodiment, the controller is configured with a present current limit, such that if the hubs experience an exceptionally large impact exceeding a predefined threshold, the motor will hit its preset current limit, and the controller will permit the tri-wheel assembly to rotate to a next sequential predetermined angular position. Once the impact has passed, the controller will retarget a new fixed angle and immediately resume operation, having sustained no damage.
Thus, a feature of vehicles in accordance with the present invention is accomplished by fixing, e.g. locking or maintaining, the spider assemblies at a fixed angle relative to the frame through use of a feedback system utilizing a magnetic or other absolute angular position sensor, a controller, and the main drive motor. No pins, levers, or other mechanical locks are needed, which reduces the possibility of breakage.
By way of non-limiting example, in ascent mode, the leading wheels of the tri-wheel assembly are likely to impinge upon the riser of the step rather than roll onto the tread pull if the angle has changed significantly from when the user was standing on the ground. To correct the angle and place the two leading wheels on the stairs, controller 60 may rotate the spider assembly hubs 26 to an appropriate angular position for starting ascent, and may use feedback from the angular position sensors 32 to vary the current/torque applied to the motor 30 to fix the hubs in the appropriate positions relative to the frame 22. The appropriate angular positions position the leading wheels to ensure that they will not interfere with a next step during ascent. In contrast, in transport mode, the angular positions may be selected to reduce torque required to fix the hubs relative to the frame by keeping the points of ground contact relatively close to the center of mass (or expected center of mass) of the loaded hand truck, to reduce motor power consumption and to extend battery life. Accordingly, use use of the controller and electronic components avoid stress on, and possible failure of, mechanical components.
Further, in ascent mode, the controller 60 may cause the variable-force actuator to provide a moderate amount of braking force, e.g., 0-15 inch-pounds of torque or 0-4 pounds of driving force at the contact points of the wheels, to prevent free-spinning of the wheels, to effectively lock rotation of the wheels. This driving torque adds a horizontal component to the force exerted on the stairs, causing the hand truck to “hug” the riser of each stair. Without this force, the spider assembly would tend to exert only a sinusoidal force in the vertical direction, providing no motivation to ascend the stairs without the user's pulling of the unit against the riser of each next stair, and if the user did not pull consistently, the unit could skip a step, bounce in place, or fall down the stairs. Additionally, the controller 60 causes the motor to drive the spider assemblies to rotate in an ascent-appropriate direction. This locking of the wheels facilitates stability during climbing of stairs as the spiders rotate. The moderate amount of braking force also allows a limited amount of slipping during climbing to allow rotation of the wheels about their axes when a wheel abuts a tread/riser juncture of a staircase, and the associated spider continues to rotate. The controller 60 senses the speed of rotation of the spiders (as determined directly by the velocity sensor 34 or indirectly from data provided by the angular position sensor 32) and controls the motor to vary the spider rotation speed to maintain a substantially constant speed of ascent. In will be noted that the vehicle 10 may or may not attempt to balance itself, but rather may rely upon a person climbing the stairs to guide the hand truck and to provide stability as the hand truck climbs the stairs.
In one embodiment, the vehicle includes stair sensors 64, as best shown in
If an adjacent step is not detected, the vehicle may not drive the spider assemblies in an attempt to ascend, but will remain in ascent mode until cancelled by the end user. After the first step is detected by the sensors, the controller will cause the motor to drive the spider assemblies and the vehicle will climb as long as the ascent button is held or until ascent mode is otherwise canceled. If the user decides not to ascend the stairs, the vehicle may be returned to transport mode by briefly pressing the descent button or another appropriate one of the switches 56.
In descent mode, the controller 60 may cause the variable-force actuator 80 to disengage, and causes the motor 30 to drive the spider assemblies 20a, 20b to rotate in a descent-appropriate direction. In this mode, the controller 60 senses the angular position of the spider assemblies 20a, 20b relative to the frame 22, and causes the motor 30 to accelerate rotation of the spiders through each of three predefined zones of angular positions of the spiders relative to the frame. These zones correspond to zones of instability in which the center of gravity of the loaded hand truck tends to be positioned toward the upstairs side of the axis of rotation of a leading wheel on a lower stair tread. For example, each zone may span angular positions of a respective arm of the spider from a position −10 degrees from vertical to a position +5 degrees from vertical. Due to the weight distribution, the loaded hand truck has a greater tendency to roll along the tread and down the stairs in an unstable manner, than to descend the stairs in a controller manner by rotation of the spiders in these zones of instability. Accordingly, the rapid rotation of the spiders through these zones minimizes any related instability. This rotation has relatively little impact on descent speed, and a substantially constant descent speed is nevertheless maintained.
The controller 60 may be configured to provide alternating climb-down and climb-up oriented torque on the spider assemblies during stairwell descent responsive to the absolute rotation angle of the spider assemblies relative to the frame 22. This helps to ensure that the leading wheel remains pinned against the inside corner of a tread/riser interface, thus eliminating the possibility of unintended backward rotation, without imposing any restrictions on the geometry or dimensions of the spider assembly to suit any specific stairwell height. As a result, an advantage is gained that allows for any spider assembly configuration, including a three-wheeled configuration, to properly descend stairwells of any riser height.
The spider assembly 20a, 20b may be selectively driven either clockwise or counterclockwise by the motor 30. The controller 60 may be configured to vary motor power based on feedback from the velocity sensor 34 and the absolute angular position sensor 32 to regulate climbing and descent speeds. Since the loading torque on the spider assemblies may be sinusoidal, both climbing torque and descent braking alternate in a sinusoidal pattern such that the rotation speed may be maintained substantially constant even though the loading torque and motor power follow a counteracting sinusoidal pattern. Accordingly, in descent mode, the controller 60, angular position sensor 32, angular velocity sensor 34, motor 30 and power source 50 may cooperate to cause acceleration of rotation of the hubs 26 through zones of instability, as predefined and stored in the memory of the controller. This reduces the length of time that the leading wheel is ahead of the center of mass of the hand truck, and thus reduces the length of time that the hand truck remains in an unstable state.
By way of example, in transport mode, the target angle may be such that the center of mass is located approximately directly over the center of wheel contact when the frame is tilted for transport, such as approximately 20-45 deg off the vertical. In ascent mode, the target angle may change by about 5-15 degrees to ensure the leading wheels clear an adjacent stair.
While ascending or descending stairs, a user may wish to stop the vehicle so that the user may climb, descend or rest. The controller 60 is preferably configured such that if the ascent button is released while the vehicle is still ascending or descending stairs, the vehicle must stop and rest at a stable angle until the user is ready to either ascend or descend. Accordingly, the vehicle may be configured to enter a stop mode in this event.
In stop mode, the controller 60 causes the motor 30 to drive the spider assemblies 20a, 20b to continue to rotate to one of three predetermined angular positions, as determined by feedback provided by the angular position sensor 32. Although the hubs 26 can be stopped and electronically fixed (by the angular sensor/motor feedback loop) at any desired angle, it is particularly stable to stop rotation of the hubs in predetermined positions such that two wheels of the vehicle rest on a lower tread and another two wheels rest on the tread of the next higher step, and the hand truck is positioned in a substantially upright position. The predetermined positions are defined as positions at which the hand truck is expected to stand in a stable manner on stairs of a staircase.
It will be noted that even when ascent or descent has stopped and the spider assemblies have ceased to rotate, the vehicle could roll down the stairs if the user were not to provide adequate holding force. To eliminate such rolling, the controller may cause the variable-force actuator 80 to engage (and prevent free-spinning of the wheels 28A, 28B, 28C) to provide a significant amount of locking force that locks the wheels into position and prevents the hand truck from rolling off of the stair treads when a predetermined position is reached. This permits the hand truck to maintain its position, on a stair case, during either ascent or descent of stairs.
For example, to operate the unit on horizontal surfaces or stairwells, frame 22 may be inclined with respect to the horizontal at the aforementioned predetermined angle (as depicted in
To avoid this scenario, a forward torque .tau.sub.f may be applied by the geared motor in the case that .delta.<.lamda., i.e., when the center of 26 is not horizontally to the left of the center pivot point of 28A. Since 22 is kept at a constant level of inclination with respect to the horizontal, and angle sensor 32 measures the angle formed between 22 and 26, 22 effectively measures the orientation of 26 in relation to the horizontal by transitive property. 32 is thus able to verify when the condition .delta.<.Iamda. holds. As .tau.sub.f is applied, 26 rotates counterclockwise about the central point of 28A until .delta.>.Iamda. as depicted in
Higher stair risers may be encountered, as depicted in
One advantage of the foregoing embodiment allows for the geared motor 30 to allow for continued rotation of the spiderwheel assembly until a predetermined position is attained where at least two of the wheels 28A-C will abut a surface. In an unstable position such as that depicted in
Individual stages of the vehicle depicting ascent up stairs are referred to in the reverse sequence
The spiderwheel may also employ an optional locking mechanism, such as a latch, hand brake, mechanical clutch, or electronic brake, to disallow spiderwheel rotation in relation to frame 22 when the unit is resting on a horizontal surface with the two of the three wheels resting on the ground. For example, upon inclining frame 22 to traverse horizontal surfaces, the spider assembly and frame may tilt as one fixed unit, allowing only two of the wheels to contact the ground rather than four as depicted in
According to the foregoing exemplary embodiments, the invention may thus introduce a means to apply climb-down torque to ensure proper pinning of the lead wheel of a towing device against the inside corner of a lower riser, ensuring proper descent. The exemplary embodiments of the invention may further introduce a means of braking the spider wheel assembly by applying climb-up oriented torque using the means for applying torque, and may enable the locking of the spider wheel into predetermined orientations in relation to the frame during ascent and descent mid-stairwell. Further, such embodiments may enable the locking of the spider wheel in relation to the frame while traversing horizontal surfaces so as to reduce the number of ground contact, thus increasing mobility.
Additionally, it should be noted that in selected embodiments, such as in a baby carriage embodiment, an additional set of wheels may be attached to a support stand 40 that is mounted to frame 22 to pivot between an inoperative position, and an operative positions facilitating horizontal traversal as depicted in
In certain embodiments, the wheeled vehicle is configured as a hand truck 10 including a fixed or foldable base platform, a secondary foldable upper platform, and detachable cargo baskets, as best shown in
Referring now to
It will be appreciated that the dual platform configuration allows two loads to be carried without having to stack them on top of each other. This may prevent breakage of fragile loads, and may increase stability for difficult to stack loads.
Thus, in the exemplary embodiment of
Optionally, a wheeled vehicle 10 in accordance with the present invention may include a pair of enclosures 60a, 60b mounted on the frame 22, each in position to partially enclose a respective spider assembly 20a, 20b during their rotation, and to shield the spider assemblies from a cargo area defined adjacent the lower platform 27 and the frame 22, as best shown in
Optionally, the wheeled vehicle 10 may further include a telescoping, rotating one of the control handle 34 supported on the frame 22, as shown in
An advantageous feature of vehicles in accordance with certain embodiments of the present invention is the descent cycle variable-speed, angle-based braking. Spider assemblies have angular ranges/regions of inherent instability when descending stairs. In those regions, under certain conditions, a conventional spider assembly can roll off the edge of the stairs instead of synchronously rotating down them. In accordance with the present invention, an absolute angular position sensor detects the position of the spider assemblies and when within those regions, as determined by a preprogrammed controller, the controller actively accelerates the spider-assemblies through the regions of instability, greatly reducing the risk of rolling off the edge of the stairs. This feature greatly increases the safety and ease of use of the product, and is particularly useful for tri-wheel spider assemblies to acceptably meet the expectations of non-professional users.
Another particularly advantageous feature of vehicles in accordance with the present invention is the afore-discussed integrated variable engagement clutch and brake system. This clutch can either lock the wheels to the same reference frame as the hand truck frame, or can allow them to spin freely. During ascent and descent modes, the clutch system is essential for providing added driving traction to force the hand truck to climb the stairs, rather than roll off or bounce in place. The clutch also can act as a brake to lock the hand truck to the stairs, reducing the possibility that it would roll off if the user were to stop at some point during ascent or descent. The clutch 80 discussed above is electromagnetic and fully controlled by the controller; no user control is required.
In an additional embodiment of the clutch, illustrated in
In more detail, referring to the invention of
The shaft 308 does not rotate and is rigidly mounted to an external structure, which results in the outer races of roller clutch 307 and ball bearing 309 rotating around the stationary inner races and shaft. Cam driver 306 is coupled to the unidirectional bearing system and can likewise rotate freely in one direction around shaft 308. The cam driver 306 is a cloverleaf shaped structure that engages brake pad 304 and provides transfer of torque without overly restricting free motion in the axial direction. Brake pad 304 and magnet/spring assembly 305 are driven by cam driver 306 and create a friction drive against clutch plate 303, which is bonded to wheel rim 302 and tire 301. The device functions by allowing the assembly to spin freely in one direction relative to fixed shaft 308, while providing a constant friction torque resistance in the opposite direction.
In further detail, when the tire 301 and wheel rim 302 rotate in the direction shown by the arrow at the top of the figure, clutch plate 303, brake pad 304, and magnet/spring assembly 305 all also rotate in the same direction. Cam driver 306 is rotated around stationary shaft 308 in the direction permitted by roller bearing clutch 307. No back torque is applied to resist the motion, and the wheel freely rotates.
When the wheel rotates in the direction opposite of the arrow in
The wheel rim 302 and tire 301 may be sized appropriately for a stair climbing hand truck wheel. Magnet/spring assembly 305 can be manufactured to provide a wide range of slip friction by changing the strength of the magnets or spring constant of the springs. Increasing spring or magnet force will increase the torque level at which the friction plate assembly starts to slip, which can be used to provide additional locking and roll-back resistance to the wheel assembly. Too much force may result in added difficulty in maneuvering the unit in the backwards direction, so the clutch force must be optimized carefully for the application.
The construction details of the invention, as shown in
Thereby, when the triwheel assembly rotates, a vertical climbing force is generated to lift the stairclimber and load. More particularly, if the three wheels were completely free spinning on their respective axes, the stairclimber would be prone to bouncing up and down and could potentially fall off the edge of the stairs. Alternatively, if the three wheels axes were “hard” locked to the triwheel hubs, the stairclimber would walk up the stairs and generate a large amount of horizontal driving force in addition to vertical force. While this large amount of horizontal drive force would ensure the unit was always pressed against the stairs, it could also cause the unit to seize up, jam into the stairs, rip carpeted stairs, or skid the wheels as the unit tries to drive into the base of the stairs a greater distance per rotation than the average tread length.
Thus, an exemplary solution provided in this alternative clutch embodiment is to provide a one direction slip clutch that allows the unit to freely roll towards the user (towards the stairs), but that provides a resistance when the unit tries to roll away from the user or off the stairs. This fixed amount of resistance against backwards movement may easily be overcome if the user needs to roll the unit in the opposite direction of normal travel, but is preferably of adequate force to ensure that the stairclimber presses up against the root of the stairs instead of rolling off the edge thereof.
A slip clutch resistance level(s) that is easy to intentionally overcome when needed is preferred, but not required, in the disclosed embodiments. Otherwise, it is preferred that the resistance level(s) provides adequate driving force for stairclimbing with heavy loads.
The advantages of this exemplary alternative clutch include, without limitation, the ability to provide a forward driving force and backwards locking force for a stair climbing device. Compared to devices with freely spinning wheels, the friction locking system increases ease of use and user safety by preventing the stair climbing device from easily rolling off the edge of the stairs or failing to properly advance to the next step without being pulled by the user. The slip clutch action prevents jamming and allows the stair climbing device to be rolled backwards if adequate force is intentionally applied by the user. This aspect of the invention is also significantly simpler, more reliable, and more cost effective to manufacture than prior art designs which use secondary motors, chain drives, gear drives, or other mechanisms to actively control the level of wheel locking resistance.
Additional and alternative features of the invention may include removable cargo baskets, and a dual-platform load-carrying system. All spider assembly designs must prevent the load from hitting or entangling in the rotating wheel assemblies. In accordance with the present invention, the vehicle may include wheel guarding enclosures, and cargo baskets that fit between the two spider assemblies, ensuring proper clearance. These baskets can be used to carry groceries, laundry, or any other typical household items. The dual-platform system allows tall, thin loads to be carried on the lower platform with the upper platform folded out of the way, while wide loads can be carried on the upper platform only, ensuring that the load will clear the rotating wheel assemblies.
In other exemplary aspects, maneuvering of the hand truck on two wheels, rather than four, has been found to be advantageous to increase the maneuverability of the hand truck while being used on a substantially flat ground surface. As discussed above, previous designs have featured manually activated mechanical locking mechanisms, which typically use a locking pin or lever to fixedly lock each tri-wheel assembly to the hand truck's frame, to prevent its rotation. However, if the tri-wheel assembly is rigidly locked, a large bump, drop or other overload condition could bend or jam the locking mechanism. For motor-driven tri-wheel assemblies, if the user forgets that the tri-wheel assembly is locked and activates the motor, the motor could burn out or the gear train could be overloaded. Thus, such fixed mechanical locking mechanisms are prone to jamming, breakage, or motor stalling.
The discussion above includes a discussion of an electronically-controlled tri-wheel assembly locking mechanism that includes a controller, motor, angular position sensor, etc., and that provides an effective, low-cost solution to this problem, and that avoids mechanical failure in the event of an overload condition, by permitting movement, and subsequent relocking of the tri-wheel assembly. This system uses an angular position sensor to dynamically lock\the position of the tri-wheel assembly, so that the unit may be easily balanced on two wheels, while imposing torque limits electronically, as discussed above.
The main limitation of such an electronically-controlled system is the power consumption requirement, which may deplete the battery if used for a long enough period of time. Since it may be necessary in some situations to roll the hand truck along level ground for substantial amounts of time, a lower power alternative wheel angle locking system may be desired. Further, the electronic locking mechanism may be available only when the hand truck has adequate electrical charge remaining in the battery, and thus avoids consumption of a significant amount of the remnants of electric power when used for extended periods of operation.
Accordingly, further provided in an alternative embodiment is a mechanical tri-wheel retention assembly that avoids rigid tri-wheel locking and associated mechanical failure in the event of an overload condition, and that also avoids extensive power consumption. The mechanical tri-wheel retention assembly may not fixedly lock the tri-wheel assembly, and permits rotation and relocking of the tri-wheel assembly in the event of an overload condition. Unlike pin-type or level-type, or other manually-operated mechanical locks that fixedly lock the tri-wheel assembly to a frame, etc., the inventive mechanical tri-wheel locking assembly uses a tri-lobular roller cam mechanism to retain the tri-wheel at a desired angular position for normal two-wheeled operation, and further includes a spring-loaded roller that is configured to pop out of a locking mode in the event of an overload condition, permitting rotation of the tri-wheel assembly to a next predetermined angular position at which point the triwheel assembly will be retained, thus preventing damage to the unit and the locking mechanism.
The mechanical tri-wheel retention assembly may further include a solenoid actuator configured to automatically disengage the mechanical tri-wheel retention assembly. When used in combination with an electronically-controlled angular locking mechanism, this permits seamless transition to electronically-controlled locking mode. This eliminates the possibility of the unit stalling during an ascent attempt if the user forgot to disengage the wheel locks.
In this alternative embodiment, the mechanical tri-wheel retention assembly may use a spring-biased cam roller that rides along a cam having detents located at predefined angular positions of the tri-wheel assembly, one corresponding to each wheel. These angular positions are defined to correspond to preferred angular positions of the tri-wheel assemblies that are appropriate for two-wheeled transport and turning.
The cam is fixedly mounted to the main axle of the hand truck 10 for synchronous rotation therewith, as best shown in
An exemplary tri-lobular cam 1 is shown in
The cam roller 5 is biased into engagement with the cam surface 12 by spring 2. The cam roller 5 may be substantially cylindrical in shape, and thus tends to roll along cam surface 12. By way of example, the cam roller 5 may be constructed of steel or other suitable material.
Spring 2 is preferably constructed as a generally chevron-shaped resilient unitary body that is mounted to a housing 17 such that one end 18 of the body engages a central hub 16 of the cam 1, and the other end 19 abuts the roller 5. The ends of the spring are spread during manufacture to pretension the spring such that the tendency of the ends 19, 20 to resile spring-biases the roller 5 into engagement with the surface 12 of the cam 1.
Thus, spring 2 ensures that the cam roller 5 is forced tightly against the cam surface 12, such that it tends to seat in a detent at predefined angular positions, and thus to retain the interconnected tri-wheel assembly at the predefined angular position.
It will be noted, however, that in the event of an overload condition, the cam roller 5 can ride out of a detent on cam 1 and roll along the cam's outer surface 12, until the overload condition is abates, at which point the cam roller 5 will settle into the next detent. Thus, a mechanical angular retention assembly is provided that avoids breakage/damage in the event of an overload condition.
In an embodiment in which the mechanical angular retention assembly is employed in an electrically-powered hand truck having an electronically-controlled angular locking mechanism, the assembly may be further configured to disengage the mechanism angular retention assembly, e.g. to permit use instead of an electronically controlled angular locking mechanism. In such an embodiment, the assembly further includes a solenoid coil 3 operably connected to a housing 22, and a guide pin 8 riding in a track of the housing 22, as best shown in
When the unit is powered up and active electronic balancing is preferred, the locking mechanism is disengaged by the solenoid spring 4; such that is does not contribute to drag or inefficiency during operation.
In such an embodiment, when the hand truck 10 is powered on and use of the electronically controller angular locking mechanism is preferred, instead of the mechanical locking, the mechanical angular retention assembly is disengaged. Specifically, this is accomplished by a central control system (not shown) actuating the solenoid 3, which moves housing 22 to the left, as shown in
When a return to un-powered passive mechanical angular locking is desired, the solenoid 3 is de-energized), and solenoid spring 4 causes the housing to return to the position shown in
While the foregoing written description of the invention enables one of ordinary skill to make and use what is considered presently to be the best mode thereof, those of ordinary skill will understand and appreciate the existence of variations, combinations, and equivalents of the specific embodiment, method, and examples herein. The invention should therefore not be limited by the above described embodiment, method, and examples, but by all embodiments and methods within the scope and spirit of the invention.
This application claims the benefit of priority to U.S. Provisional Application No. 61/554,691, filed Nov. 2, 2011, the entire disclosure of which is hereby incorporated herein by reference.
Number | Date | Country | |
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61554691 | Nov 2011 | US |