Not Applicable.
The present invention relates to material handling vehicles, and more particularly to systems and methods for mast oscillation damping for material handling vehicles.
Material handling vehicles (MHV), such as lift trucks, forklift trucks, reach trucks, turret trucks, side loader trucks, counterbalanced lift trucks, pallet stacker trucks, orderpickers, transtackers, and man-up trucks, can be commonly found in warehouses, factories, shipping yards, and, generally, wherever pallets, large packages, or loads of goods can be required to be transported from place to place.
Often, MHVs can be high-lift vehicles that can be capable of manipulating loads at higher elevations. Undesirable oscillations may occur in the mast or other vertical weight-bearing portion of high-lift vehicles when operating at high elevations. For example, mast oscillations may be caused by accelerating or decelerating the body 102 and/or raising or lowering a load on a fork assembly when the MHV can be operating at higher elevations. These mast oscillations can increase the time required to pick a load from a rack or to place a load onto a rack as an operator of a manned MHV may have to wait until the oscillations cease or can be small enough as to enable accurate picking or placing of the load. Additionally, mast oscillations can, in some instances, increase wear on the MHV.
A previous solution for reducing mast oscillations utilizes the traction system to introduce counter impulse forces in the traction system to cancel mast oscillations. The traction motor accelerates or decelerates in forward or backward directions to cancel the mast oscillations. However, in such an approach, the perturbations imposed by the traction motor will cause the MHV to move fore and aft in conflict with a position hold algorithm. This can cause the MHV to move to a position away from where the operator intended the MHV to remain.
Another previous solution for reducing mast oscillations utilizes reach actuators of a moving-mast type reach MHV to move the entire vertical mast fore and aft to damp mast oscillations. However, such an approach can be not applicable for reach trucks that utilize a pantograph- or scissor-type reach mechanism instead of moving mast. Further, in a reach truck application setting, such a previous approach provides an inefficient control mechanism in that oscillations induced by a load or assembly situated at the top of a mast can be controlled by movements at the bottom of the mast.
Though suitable for some application settings, such previous solutions do not meet the needs of all application settings and/or users. For example, a desire may exist for an oscillation reduction mechanism that overcomes the aforementioned issues by, in certain embodiments, enabling its corresponding use with position hold algorithms and by enabling oscillation reduction with scissor-type reach trucks.
Pursuant to various embodiments disclosed herein, a material handling vehicle (MHV) and associated method can be provided for damping of mast oscillations of a mast of the MHV. In at least one embodiment, mast oscillations can be detected and/or anticipated and a countering force can be generated by one or more mechanisms of the MHV to damp the oscillations. In one approach, an elevated reach mechanism of the MHV can be actuated to damp the oscillations. In another approach, a traction system of the MHV can be activated to generate movement of the MHV to damp the mast oscillations.
In one aspect, the present invention provides a method for damping mast oscillations on a reach truck. The reach truck includes at least one traction wheel, a telescoping mast, a fork assembly moveably attached to the telescoping mast by a reach actuator, and one or more sensors arranged adjacent to a top of the telescoping mast and configured to measure oscillations adjacent to the top of the telescoping mast. The method includes determining if the reach truck is being commanded to travel, and upon determining that the reach truck is not being commanded to travel, acquiring data from the one or more sensors arranged adjacent to the top of the mast. The method further includes determining if the data acquired by the one or more sensors indicates an undesired mast oscillation occurring at the top of the telescoping mast, and upon determining that the undesired mast oscillation is occurring at the top of the mast, actuating the reach actuator in a desired direction thereby damping the undesired mast oscillation.
The foregoing and other aspects and advantages of the invention will appear from the following description. In the description, reference can be made to the accompanying drawings which form a part hereof, and in which there can be shown by way of illustration a preferred embodiment of the invention. Such embodiment does not necessarily represent the full scope of the invention, however, and reference can be made therefore to the claims and herein for interpreting the scope of the invention
The invention will be better understood and features, aspects and advantages other than those set forth above will become apparent when consideration can be given to the following detailed description thereof. Such detailed description makes reference to the following drawings.
Various embodiments of the present disclosure provide systems and methods for reducing oscillations in a mast of a material handling vehicle (MHV). These oscillations may be caused by manipulation of a load at high elevations or acceleration/deceleration of the MHV itself while a load can be at higher elevations. Generally, in various embodiments, mast oscillations can be detected and/or anticipated and can be reduced through operation of a reach mechanism, a traction control motor, or a combination thereof In certain embodiments, the mast oscillation reduction concept can be combined with a position hold feature to ensure integral operation so that the goals of each feature (e.g., oscillation reduction and position hold) can be realized. Implementation of oscillation reduction according to the embodiments disclosed herein provides solutions not previously realized or utilized for pantograph- or scissor-type reach trucks. Further, when combined with a position hold feature to form a smart position hold feature, the goals of each feature can be realized. Cycle time for MHVs may be reduced in that the oscillations can be reduced, thereby enabling an operator to pick or place a load quickly without the need to wait for mast oscillations to subside. Further, wear on the mast and other portions of the MHV may be decreased.
These and other benefits may become clear upon making a thorough review and study of the following detailed description. Referring now to the drawings, and in particular to
In other examples, as the entire MHV 100 begins to move or stop moving through acceleration or deceleration caused by the wheels 104, the load 204 will attempt to remain at its current velocity (e.g., stopped or moving). Thus, acceleration or deceleration of the entire MHV 100 will be countered by forces exerted by the load 204 on the top 301 of the mast 110, which forces can cause undesired oscillations 302 of the mast 110. For example, if the MHV 100 can be stopped with the load 204 stationary in a high-lift condition, as the MHV begins to accelerate forward, the inertia of the load 204 (e.g., stationary inertia) will exert a rearward force on the mast 110, possibly causing oscillations 302. Similarly, if the MHV 100 can be moving in a high-lift condition and subsequently begins to decelerate, the inertia (e.g., forward) will exert a forward force on the mast 110 as the MHV 100 decelerates, possibly causing oscillations 302.
The systems and methods described herein can enable the MHV 100 to actively detect and damp mast oscillations 302 in high-lift conditions. Oscillation detection may be achieved through a variety of detection mechanisms including, for example, using continuous and/or absolute velocity or relative velocity feedback from the mast 110 and/or the fork assembly 112. In other embodiments, for example, a mast accelerometer 304 may be placed on or within an inner telescoping member 306 of the mast 110 (which is, in certain embodiments, the highest telescoping member of the mast 110), as shown in
Mast oscillations 302 may be detected by detecting periodic accelerations or decelerations, for example, by the accelerometers 304 and/or 308. In some embodiments, the detected periodic accelerations may be checked against one or more instructed operations by an operator 202 to determine if the detected oscillations can be undesired mast oscillations 302. For example, if the operator can be not commanding the MHV 100 to move (i.e., the MHV 100 should be stationary), but oscillations can be detected, a processing device 708 (see
In another embodiment, the MHV 100 can distinguish undesired mast oscillations 302 from other intended movements. In one embodiment, the MHV 100 may assume that motion of the mast 110, the fork assembly 112, or the load 204 relative to the body 102 can be undesirable motion (e.g., a mast oscillation 302). In another embodiment, the MHV 100 may associate movement of the mast 110, the fork assembly 112, or the load 204 relative to the body 102 to be undesired mast oscillations 302 when the MHV 100 can be stationary, stopped, or when the MHV 100 can be not accelerating (e.g., at a steady pace). In another embodiment, the MHV 100 may consider movement of the mast 110, the fork assembly 112, or the load 204 (e.g., relative to the body 102) that can be unexpected to be undesired mast oscillations 302. For example, the MHV 100 may expect the mast 110 to deflect backwards to some extent when the MHV 100 begins accelerating forward. However, if and when the mast 110 deflects back forward during or after such forward acceleration, the MHV 100 may consider such a movement to be an undesired mast oscillation 302. In another embodiment, the MHV 100 may detect motion of the mast 110, the fork assembly 112, or the load 204 having a repeating periodicity or frequency, which may serve as an indication of a mast oscillation 302. The detected frequency or motion may be an expected oscillation frequency, for example, based on the extended height of the mast, the weight of the load 204, and/or the weight of other assembles, or the frequency of motion may be unexpected. Many other methods of determining the occurrence of undesired mast oscillations 302 may exist, as well, which can be contemplated by this disclosure.
In accordance with various embodiments disclosed herein, relative movement between the mast 110 and body 102 can be controlled through a control algorithm and various hardware elements effecting operation of the control algorithm. With continued reference to
Similarly, though in an opposite manner, as the mast 110 and the fork assembly 112 move rearward from a forward-flexed position during undesired mast oscillations 302, the reach actuator 118 can extend in an attempt to absorb and slow/stop the oscillations 302 of the mast 110. Similarly still, as the mast 110 and the fork assembly 112 move forward from a central position toward a forward-flexed position, the reach actuator 118 can retract while exerting a rearward force on the mast 110 away from the fork assembly 112 in an attempt to damp or stop the oscillations 302 of the mast 110. Moreover, as mast 110 and the fork assembly 112 move rearward from a central position toward a rearward-flexed position, the reach actuator 118 can extend while exerting a forward force on the mast 110 toward from the fork assembly 112 in an attempt to damp or stop the oscillations 302 of the mast 110. Any combination of the above described extensions and/or retractions or other variations can be implemented during various portions of the period of oscillation 302 of the mast 110.
Oscillation reduction or damping may require multiple half-periods (e.g., forward to backward or backward to forward) in order to cease the oscillation. This may be dependent upon many factors, including the amount of oscillation, the height of the fork assembly 112 and load 204, the distance S which the reach actuator 118 can be initially extended, the weight of the load 204, as well as many other factors.
In another embodiment, oscillation anticipation can be utilized. Oscillation anticipation can be used in addition to or in lieu of oscillation detection described above. In various approaches, a processing device 708 (
In various embodiments, once the mast oscillations 302 have ceased or can be at a low enough amplitude, the reach actuator 118 may return to a previously set distance S slowly so as to not induce additional mast oscillations 302. Alternatively, while oscillations can be being damped, the reach actuator 118 can be constantly adjusted so that when oscillations have ceased, the reach actuator 118 can be set to or close to the originally intended distance S.
Mast oscillation damping using the elevated reach actuator 118 enables a more direct manipulation of the space between the load 204 and the top 301 of the mast 110 to more effectively absorb and damp oscillations. Because the top 301 of the mast 110 and the load 204 can be where oscillations can be primarily generated, direct accelerations of the masses in the load 204 and the top 301 of the mast 110 using an elevated reach actuator 118 results in improved oscillation damping. The present oscillation damping concept can be unlike previous solutions that attempt to damp mast oscillations by my moving the entire mast 110 at its base. A notable difference between previous solutions and the present oscillation damping concept can be that, by moving the entire mast 110, previous solutions have utilized inverted pendulum control dynamics to create the control algorithm used to control the damping of mast oscillations. By moving the reach actuator 118 at the top of the mast 110, the present solution alternatively utilizes a more direct form of control dynamics (i.e., the force is being applied directly to the oscillating portion of the mast 110, opposed to being applied at the bottom of the mast 110 and being translated throughout the mast 110) to create the control algorithm used to damp mast oscillations. One skilled in the art will appreciate that the kinematic relationships between the various components (i.e. the mast 110, the reach actuator 118, and the fork assembly 112) and the dynamic forces needed to damp mast oscillations vary greatly between the two methods.
Furthermore, these previous solutions provide an attenuated relationship between the masses at the top 301 of the mast 110 (e.g., the load 204) and the reach actuator 118 or other control mechanism at the bottom of the mast 110. This can be akin to trying to hold a sledgehammer steady with the weight at top by grabbing the bottom end of the handle. Conversely, if applied to the same sledgehammer, the present mast oscillation damping concept would hold both the weight and the upper end of the sledgehammer handle steady by directly manipulating the acceleration of the heavy hammer head relative to the lighter handle.
The present mast oscillation damping concept can be more efficient in its use of power in that it takes less power and torque to steady a weight directly than remotely through an extended mast 110. Additionally, in previous solutions, when the entire mast is moved at the bottom of the mast, a direct force is applied to the body of the MHV, which can undesirably cause the MHV to move. Another potential benefit of mast oscillation damping using the elevated reach actuator 118 is that by applying the damping force at the top of the mast 110, there are no direct forces applied to the body 102 of the MHV 100, and so the MHV 100 is less likely to move.
In some embodiments, an MHV 100 includes a position hold feature implementing an algorithm to hold the position of the MHV 100 while the load 204 can be being manipulated and the operation is not commanding the MHV 100 to move (e.g., while manipulating a load on a rack). For example, when operating a reach truck, an operator 202 may request a reach or retract command from the reach actuator 118. This command will create an acceleration of the load 204 and the fork assembly 112, which can be manifested as a force on the MHV 100. Under certain circumstances, this force may be large enough to cause the MHV 100 to roll. The position hold feature works to generate an appropriate torque at the traction wheels 104 to restrict overall movement of the MHV 100 relative to the floor. In other circumstances, MHV 100 vehicle may be operating on an inclined surface. In such a case, the position hold algorithm would command a torque at the traction wheels 104 to prevent the MHV 100 from rolling on the inclined surface.
In certain embodiments, the functionality of the above described mast oscillation reduction concept can be combined with the functionality of a position hold algorithm to form a smart position hold algorithm. The smart position hold concept merges the position hold algorithm while simultaneously addressing the oscillations of the mast 110. In one approach, a smart position hold algorithm will use the traction system to hold the position of the MHV 100 within a predefined range 604 (see
In one embodiment, when the MHV 100 commands the reach actuator 118 to contract or extend (e.g., to accelerate or decelerate the load 204 and fork assembly 112 relative to the mast 110) to cancel mast oscillations 302, as described with respect to the above mast oscillation reduction concept, a reaction force may be generated and imposed on the MHV 100 as a whole. In anticipation of such a reaction force, the smart position hold algorithm may also generate a torque at the traction motor commensurate with the reaction force to prevent the MHV 100 from moving while the mast oscillations can be being damped. Without this combined smart position hold feature, while oscillation damping occurs through activation of the reach actuator 118, the MHV may move on its wheels. However, the combined smart position hold concept works to integrate the two features to both maintain relative location of the MHV 100 as a whole and to damp mast oscillations 302.
Turning now to
In accordance with the illustrated embodiment in
As described above, the MHV 100 may include a position hold feature. Accordingly, an additional embodiment of a smart position hold feature allows for both position hold functionality and traction-based mast oscillation damping. Turning to
According to an embodiment, the movement of the MHV 100 during traction-based mast oscillation damping can be confined to be within a range 604 from +C to −C. The range may be defined as an allowable distance which the center of the MHV 100 may be allowed to move away from the intended hold position Ao 602, or may be the limits of movement which the edges of the MHV 100 may be able to travel. The range 604 may be a preset range (e.g., 6 or 12 inches, or any other value as can be suitable in various application settings). Alternatively, the range 604 may be dynamically defined based on any number of factors, including elevation height of the mast 110 and/or load 204, weight of the load 204, speed of the MHV 100 prior to stopping, sensed distance to other obstructions, or any other pertinent factor. The range may be defined by an operator 202 or by another user, for example, to be smaller or wider to accommodate a configuration of a warehouse or other application setting. The range may be symmetrical or asymmetrical about the position A0 602 and may be dependent upon a given application setting or MHV 100 configuration. The range 602 may be dynamic and include various tiers of progressively larger ranges dependent upon various factors, for example, upon the amplitude of a sensed mast oscillation 302, the weight of a load 204, the height, or other factors.
In one embodiment of a smart position hold feature, after traction-based mast oscillation damping has eliminated or reduced mast oscillations to an acceptable amplitude, and/or while traction-based mast oscillation damping occurs, the MHV 100 may slowly (so as to avoid inducing additional mast oscillations) return to the intended hold position A0 602 and hold the MHV 100 at the intended hold position A0 602. Utilizing traction-based mast oscillation damping with a man-up truck MHV 100 may be useful in that an operator 202 positioned up near the load 204 will not feel or otherwise be affected by the movements of the MHV 100 by the traction motor as much as if they were positioned on or near the ground. Efficiency may be improved as an operator may not be required to wait for unwanted mast oscillations 302 to subside before handling goods. Further, as the operator 202 can be also elevated, reduction of unwanted mast oscillations 302 may add to the comfort and confidence of the elevated operator 202.
An MHV 100 implementing the smart hold feature according to various embodiments disclosed herein and including a traction-based mast oscillation damping feature can overcome the shortcomings of previous systems that otherwise have to choose between the conflicting goals of traction-based mast oscillation damping and position hold features. By allowing some movement within the range 604 during traction-based mast oscillation damping and by returning the MHV 100 to the intended hold position A0 602 at or upon cessation of oscillations, the benefits of both features can be realized.
In some embodiments, either or both types of mast oscillation damping may be utilized in combination with a smart position hold feature. For example, an MHV 100 configured with a reach actuator 118 may also implement traction-based mast oscillation damping either simultaneously with or as an alternative to oscillation damping with the elevated reach actuator 118. In some approaches, an operator 202 or another user may determine a preference for one or both oscillation damping technique, either ahead of time or dynamically as a particular situation requires. In other embodiments, the MHV 100 may utilize a combination of oscillation damping techniques. For example, if a reach actuator 118 can be fully or near-fully extended or fully retracted, oscillation damping may be achieved with traction-based oscillation damping, at least in one direction, instead of with the reach actuator 118. Alternatively, if a traction-based oscillation damping feature has moved the MHV 100 to the edges of the range 604 or senses an obstruction, the MHV 100 may rely more heavily on oscillation damping with the reach actuator 118. Further, if a position hold feature may be given priority over a traction-based mast oscillation damping feature so that the MHV 100 relies exclusively or more heavily on damping with the reach actuator 118. Many other factors can influence the choice between or a balance between a mixture of the two types of oscillation damping. As described, the smart position hold feature can operate with either or both types of the disclosed mast oscillation damping techniques. This may entail returning the MHV 100 to the intended hold position A0 602 or may entail anticipating additional forces exerted on the MHV 100 through use of oscillation damping with the reach actuator 118.
In various embodiments, it may be useful for the MHV 100 to determine the center of gravity (CG) of the MHV 100. The CG may also be determined with respect to one or all of the mast 110, the fork assembly 112, the operator platform 402, the operator cabin 404, and/or the load 204. In one embodiment, the CG may be estimated as can be described in U.S. Pat. No. 8,140,228 titled “System and Method for Dynamically Maintaining the Stability of a Material Handling Vehicle Having a Vertical Lift,” which is hereby incorporated herein by reference. In certain embodiments, a determined CG can be used to assign appropriate gains and/or filter settings to be used by a processing device 708 (see
Turning now to
The data collected from the mast accelerometer 304 and/or the fork accelerometer 308 can be monitored, and it can be determined if the collected data indicate an undesired mast oscillation at step 808. The detection of undesired mast oscillations at step 808 may comprise determining if a measured oscillation is above a predetermined threshold. Alternatively or additionally, the processes of detecting undesired mast oscillations, described above, may be implemented at step 808. If undesired mast oscillations are not detected at step 808, then the MHV 100 can be under normal operation 804. Conversely, if undesired mast oscillations are detected at step 808, the MHV 100 can be commanded to actuate the reach actuator 118 in a desired direction to damp or eliminate the detected mast oscillations at step 810. The damping or elimination of the mast oscillations via the reach actuator 118 at step 810 may be carried out in accordance with the above-described processes. As shown in
Additionally, in some instances, as described above, the traction-based mast oscillation damping may be used in conjunction with the reach actuator 118 mast oscillation damping. In these instances, if undesired mast oscillations are detected at step 808, the traction-based mast oscillation damping can simultaneously be implemented at step 812. As described above, the traction-based mast oscillation damping may cause the MHV 100 to move from the intended hold position A0 602. As such, after step 812, it can be determined if the MHV 100 has displaced from the intended hold position A0 602. If the MHV 100 is not at the intended hold position A0 602, the MHV 100 can be instructed to move to the intended hold position A0 602 at step 816. If the MHV 100 is at the intended hold position A0 602, the process can return to step 806. It should be appreciated that although the MHV 100 may move during the traction-based oscillation damping, this movement is not commanded, for example, by an operator. Rather, it can be an automatic movement integrated into a mast oscillation damping algorithm implemented by the processing device 708. It should further be appreciated that the position hold algorithm, described above, may be implemented simultaneously mast oscillation damping approach shown in
So configured, and in accordance with various embodiments, an MHV 100 reduces or damps mast oscillations, which can in turn improve operator productivity. For example, when the mast in a high-lift condition, an operator may be able to pick and/or place a load or pallet more efficiently due to reduced mast oscillations. Reduction of mast oscillations can also improve stability of the load on the forks and can improve cycle times for automated lift trucks. For example, an automated MHV, or an operator of a manned MHV, will be able to spear and/or engage a rack opening quicker when the mast is not oscillating or during reduced mast oscillations. Additionally, engaging a pallet situated in the racks at high elevations can occur quicker when the forks are not oscillating and remain stable. Combining one or both of the disclosed mast oscillation damping techniques (traction-based and/or reach mechanism-based) with a position hold feature into an improved smart position hold feature can ensure the utility of both features can be preserved.
Thus, while the invention has been described in connection with particular embodiments and examples, the invention can be not necessarily so limited, and that numerous other embodiments, examples, uses, modifications and departures from the embodiments, examples and uses can be intended to be encompassed by the claims attached hereto. The entire disclosure of each patent and publication cited herein can be incorporated by reference, as if each such patent or publication were individually incorporated by reference herein.
Various features and advantages of the invention can be set forth in the following claims.
The present application is based on, claims priority to, and incorporates herein by reference in its entirety, United States Provisional Patent Application No. 62/200,176, filed Aug. 3, 2015, and entitled “Oscillation Damping For A Material Handling Vehicle.”
Number | Date | Country | |
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62200176 | Aug 2015 | US |