The present invention relates generally to vibration systems and methods for driving objects into the earth and, more specifically, to vibration systems that use counter-rotating eccentric members to generate linear vibratory amplitude via centrifugal force.
Counter-rotating sets of eccentric members are often used in so-called pile-driving equipment to generate vibratory forces for driving objects into the ground, typically elongate members such as H-beams, sheet piles, caissons, and the like, often collectively referred to as “piles.” The eccentric members used in such equipment may be of any type or shape of rotating element or assembly in which the weighting of the member offsets the center of gravity of the member radially from its axis of rotation. The product of the mass of the eccentric weight of the member times the perpendicular distance of its offset from the rotational axis is referred to as “eccentric moment.”
Such an eccentrically weighted member generates centrifugal force as its offset center of gravity rotates about its axis which thereby produces vibration. As is well-known in the art, when two such eccentrically weighted members of equal eccentric moment are constrained to rotate in synchronism in opposite directions and at equal speed, the opposing centrifugal forces generated by the counter-rotating members will cancel each other in a transverse direction but will be additive, positively or negatively, in a longitudinal direction. The resulting output generates a linear vibration in such longitudinal direction, but essentially no vibration in the transverse direction, and is the basic operating principle of vibratory pile drivers, also known as “vibrodrivers.” Such synchronous opposing rotation is typically accomplished by rotatably connecting the eccentric members via gears, chains, electro-hydraulic control or a similar means. As is also well known in the art, when two pair of eccentric members are arrayed so that the longitudinal axes of the eccentric pairs are aligned and both pairs of eccentric members are constrained to rotate “in-phase” at the same speed and with the identical angular position of the centers of gravity of the eccentric members, the additive longitudinal forces generated by the eccentric members produce a linear sinusoidal vibration. Conversely, when the pairs of eccentric members are rotated “out-of-phase” at an identical speed but with the angular position of their respective centers of gravity offset from one another by 180°, both the longitudinal and transverse force components of each set of eccentric members cancel each other, so that no linear vibration is produced. This is the basic operating principle of vibratory pile drivers.
Such resonance-free vibratory pile driving equipment may employ eccentric members arranged in pairs or alternatively may group eccentric members in sets of a greater number of counter rotating eccentric members, e.g., a set of three eccentric members comprised of one large eccentric member and two smaller eccentric members each having an eccentric moment that is one half that of the larger member. This arrangement is essentially the equivalent of a pair of counter-rotating eccentric members of equal masses.
Known vibratory pile driver constructions include a support frame adapted to be suspended from a crane or a like support and a vibratory assembly mounted to the support frame via elastomeric or similar springs to isolate vibrations from the crane. The vibratory assembly comprises one or more sets of eccentric members for generating linear vibrational forces to drive a pile into the earth and a clamping assembly for selectively clamping and releasing the piles and for transmitting the vibrational forces to said piles while clamped. One or more hydraulic or electric motors are provided for driving rotation of the eccentric members at sufficient speeds, e.g. 1500-2500 rpm, to produce high force, large amplitude vibrations in the vibratory pile driver for driving the piles into the earth.
At start-up, the motor increases the rotational speed of the eccentric members from a standstill to the working speed of the vibratory pile driver. Likewise, when the vibratory pile driver is shut down, the speed of the eccentric members is reduced to a stop. A common problem experienced with known vibratory pile drivers arises during these start-up and shut-down periods. As the speed of the vibratory pile driver increases or decreases through a frequency equal to its natural frequency (i.e., its resonant frequency), potentially destructive vibrations of extreme amplitude can occur that can cause damage to the vibratory pile driver, the pile, the crane and/or possibly adjacent structures such as buildings or the like. Although operators attempt to bring the vibratory pile drivers up to speed and to shut them down as quickly as possible to minimize the amount of damaging vibration that occurs, this practice does not eliminate the risk.
The conventional means for addressing the above-described problems are known vibratory pile driver design variations commonly referred to as variable moment (VM) or resonance free (RF) designs. Both of these designs employ a “phase shifting” arrangement to allow the vibratory pile driver to accelerate to, or decelerate from, operating speed while generating no vibration. By selective phase shifting, vibration output is initiated after the eccentric members have reached operating speed, thus eliminating any period of vibrating at resonant frequencies. An example of a variable moment (VM) vibratory pile driver is described in U.S. Pat. No. 6,604,583, and an example of a resonance free (RF) vibratory pile driver is described in U.S. Pat. No. 7,168,890.
Both variable moment (VM) and resonance free (RF) vibratory pile drivers include a vibratory assembly which comprises at least two sets of multiple eccentric members arranged so that their longitudinal output force components align, producing a uniaxial vibratory force. The eccentric member sets may be arranged concentrically, as represented in U.S. Pat. No. 5,177,386, or horizontally, as represented in U.S. Pat. No. 7,168,890, but are most commonly arranged vertically, as represented in U.S. Pat. No. 6,604,583, i.e., with a top row of eccentric members positioned directly above a bottom row of eccentric members. Typically, the top row and bottom row of eccentric members are each driven by independent hydraulic motors, although any number of motors may be used depending on the size of the vibratory pile driver and other design criteria of the unit. The top and bottom eccentric members are connected and synchronized by the aforementioned phase shifting arrangement, which is capable of adjusting the relative angular relationship of the top and bottom eccentric members from 0°, or “in phase” with each other, to 180°, or “out of phase” with each other. Depending upon the type of phase shifting arrangement utilized, the top set of eccentric members and the bottom set of eccentric members may rotate in the same direction or in opposite directions. Many types of phase shifting arrangements are known and used in these vibratory pile drivers, and include bevel gear sets, harmonic gear sets, planetary gear sets, swinging spur gear sets, helical splines, helical cams, differential motor displacement, hydraulic rotary actuators and the like. In the forgoing types of phase shifting devices, some are self limiting to produce only a maximum of 180° relative movement, while others require additional limiting mechanisms (e.g., stops or a stop mechanism) to limit the phase shift to 180°.
In the case of a variable moment (VM) vibratory pile driver, the phase shifting device has the ability to adjust infinitely the phase relationship of the top eccentric members to the bottom eccentric members between 0° and 180° and to hold the relationship setting while the vibratory pile driver is running. Thus, the overall effective eccentric moment of the machine is infinitely adjustable between a zero value and a maximum value.
In the known types of resonance free (RF) vibratory pile drivers, the phase shifting mechanism is only capable of setting the phase relationship of the top eccentric members and the bottom eccentric members at two positions, i.e. 0° in phase and 180° out of phase. Consequently, the overall effective eccentric moment of the machine is either a zero value or a maximum value.
Both the variable moment (VM) and the resonance free (RF) types of vibratory pile drivers solve the low speed resonance problems described above. On one hand, the additional ability of variable moment (VM) vibratory pile drivers to permit infinite eccentric moment adjustment would seem to be an advantage. On the other hand, however, this infinitely adjustable feature is seldom used since maximum eccentric moment will almost always drive piles faster than a lesser moment. Further, all the known applicable phase shifting arrangements used in variable moment (VM) pile drivers are extremely expensive and fairly complicated. This adverse effect on the overall cost of a variable moment (VM) vibratory pile drivers essentially means that they cannot be justified except in extremely high risk areas or very sensitive job sites. It is also well known that these infinitely variable phase shifters are often unreliable, due to the vibrating environment and the relative small space into which they must fit.
The resonance free (RF) type of vibratory pile driver tends to be less complex, with resultant lower cost. However, the known phase shifting arrangements which produce the resonance free (RF) type of functionality have little or no control of the shifting speed and rely on mechanical stops to limit the maximum phase shift angular displacement. Due to the heavy masses being phase shifted, and the violent, high velocity impacts of the stop mechanism, these phase shifting arrangements are also unreliable.
The present invention seeks to address the disadvantages and problems of known phase shifting arrangements in vibratory pile drivers. Basically, the present invention provides an apparatus for driving an object into the ground and for removing an object from the ground by imparting to the object vibration generated via rotation of eccentric members, comprising a housing, a first set of eccentric members mounted in the housing for synchronized rotation in opposing directions relative to one another, and a second set of eccentric members mounted in the housing for synchronized rotation in opposing directions relative to one another, with the first and second sets of eccentric members being disposed relative to one another (e.g., vertically or horizontally with respect to one another) to generate vibrational force in the housing in a common longitudinal direction.
The apparatus further includes a phase shifting arrangement connecting the first and second sets of eccentric members for controlling coordinated rotation thereof. More specifically, the phase shifting arrangement comprises a limiting device arranged between the first and second sets of eccentric members to be shiftable between a first condition wherein the first and second sets of eccentric members are constrained to rotate out of phase with one another to negate generation of vibration in the housing and a second condition wherein the first and second sets of eccentric members are constrained to rotate in phase with one another to generate vibration in the housing. According to the present invention, each of a first motor and a second motor is independently connected with the limiting device for driving rotation thereof. A control arrangement is provided for selectively driving the limiting device predominantly by the first motor for shifting the limiting device into the first condition thereof for maintaining the first and second sets of eccentric members in the first non-vibrating condition or for selectively driving the limiting device predominantly by the second motor for shifting the limiting device into the second condition for generating vibration in the housing.
In a preferred embodiment of the invention, the first set of eccentric members may comprise a first pair of eccentric members, and likewise the second set of eccentric members may comprise a second pair of eccentric members. The limiting device preferably comprises first and second drive components which are shiftable relative to one another between the first and second conditions. The first motor is preferably a hydraulic motor connected with the first drive component of the limiting device for driving rotation thereof, and similarly the second motor is preferably a hydraulic motor connected with the second drive component of the limiting device for driving rotation thereof.
In a preferred embodiment, the phase shifting arrangement further comprises a first hydraulic circuit connecting the first and second motors in hydraulic series for delivering a first source of pressurized hydraulic driving fluid to the first and second motors in sequence. The control arrangement preferably comprises a second hydraulic circuit including a second source of pressurized hydraulic driving fluid. The second hydraulic circuit is connected to the first hydraulic circuit and the control arrangement further comprises a control device for selectively adding supplementary hydraulic fluid to and withdrawing hydraulic fluid from the first hydraulic circuit to selectively shift the limiting device between the first and second conditions thereof. Preferably, the first condition of the limiting device is utilized for maintaining the first and second sets of eccentric members in the first non-vibrating condition during start-up acceleration and shut-down deceleration thereof and the second condition of the limiting device is utilized to generate vibration in the housing when the first and second sets of eccentric members are rotating at an operating speed. The control device may comprise a solenoid valve movable between a position wherein the second source of pressurized hydraulic driving fluid delivers the hydraulic fluid to the first hydraulic circuit and a position for receiving hydraulic fluid from the first hydraulic circuit.
In a preferred embodiment, the first drive component of the limiting device may comprise a first pinion connected with the first set of eccentric members for driving rotation thereof and the second drive component of the limiting device may similarly comprise a second pinion connected with the second set of eccentric members for driving rotation thereof. The first and second pinions are mounted for relative rotation about a common axis and have respective stop surfaces arranged to shift between engagement in a first abutting relationship in the first condition and in a second abutting relationship in the second condition, thereby to limit relative rotation between the first and second conditions.
It is preferred that the first and second motors are equivalent and each motor is independently capable of driving the phase shifting arrangement. The eccentric members are preferably identical to one another. In a preferred embodiment, the first and second sets of eccentric members are arranged with one set vertically above and in alignment with the other set.
Referring now to the accompanying drawings,
With reference now to
A phase shifting arrangement, indicated overall at 24, connects the two pairs of eccentric members 20, 21, 22, 23 to control coordinated rotation of the members, and includes a limiting device in the form of a double pinion mechanism 26 comprised of two pinion gears 28, 29 mounted coaxially with one another and in meshing engagement respectively with the gears of eccentric members 20, 22. The pinions 28, 29 are independently rotatable except that each pinion 28, 29 includes a stop 28A, 29A, respectively, projecting axially toward each other for engagement whenever one pinion rotates substantially a full revolution in either direction relative to the other pinion, thereby to limit the amount of relative rotation of the pinions. The gear ratios of the eccentric members 20, 21, 22, 23 and the pinions 28, 29 and the respective centers of gravity of the eccentric members are arranged such that, when the pinions 28, 29 are rotated in respective clockwise directions into a first condition wherein their stops 28A, 29A abut, the two pairs of eccentric members are disposed out of phase with one another to negate generation of vibration in the housing, as depicted in
According to the present invention, the two hydraulic motors 30, 31 are driven from a hydraulic power unit, such as a pump 32, via a hydraulic circuit 34 in which the motors 30, 31 are arranged in series to receive pressurized hydraulic fluid in sequence first to the motor 30 and then to the motor 31. The hydraulic motors 30, 31 are of equal power displacement selected such that either motor is sufficiently powered to alone drive the overall pile driving apparatus, but because the motors 30, 31 are plumbed together in series, the motors only develop the torque of a single motor and only rotate at the same speed as a single motor. As will be understood, if the pinions 28, 29 did not include stops 28A, 29A, the motors 30, 31 would rotate at approximately the same speed, but with nothing to control their particular phase relationship. Also, as will be understood, the fluid pressure in the intermediate section 34A of the hydraulic circuit 34 between the exhaust port A of motor 30, and the intake port A of motor 31, will be about half that applied at the intake B to pump 30.
According to a unique feature of the current invention, a second hydraulic circuit 36 supplied with pressurized hydraulic fluid from an independent pump or other hydraulic power unit 38 is connected in fluid communication with the intermediate section 34A of the hydraulic circuit 34 between the two motors 30, 31. The hydraulic circuit 36 is controlled via a solenoid valve 40 to operate to selectively add or subtract small amounts of hydraulic fluid flow to or from the intermediate section 34A of the hydraulic circuit 34. When vibration is desired in the apparatus, the solenoid valve 40 is deenergized to move into the position shown in
When it is desired to prevent vibration in the apparatus, the solenoid valve 40 is energized to move into the position shown in
The rate of fluid flow into and from the hydraulic circuit 34 via the circuit 36 is regulated via two pressure compensated flow control valves and ball checks, indicated overall at 42, regardless of the pressure prevailing in the two circuits. The amount and rate of flow must be accurately controlled to prevent the motors 30, 31 from driving the pinions 28, 29 too rapidly between the positions of
Although the above description of operation for the current invention relates to a vibratory pile driver apparatus in which sets of eccentric members are vertically arrayed, the principles of the present invention apply equally well to apparatus having horizontally arrayed eccentric members and to apparatus having concentrically arranged eccentric members. Fundamentally, it is merely important that the sets of eccentric members be disposed relative to one another to be capable of generating vibrational force in the housing in a common uniaxial direction when the eccentric members are rotated in phase with each other. Persons skilled in the art will also recognize and understand that embodiments with a greater number of pairs of eccentric members or with more than two eccentric members in each set are equally possible. Likewise, a greater number of hydraulic motors may be utilized, and may be differently arranged, e.g., at the same side of the apparatus.
For example,
As will be understood, each of the embodiments of the present invention thus far described is of the resonance free (RF) type of vibratory pile driving apparatus. The present invention however is not limited to such resonance free (RF) embodiments.
As will thus be understood, the vibratory pile driving apparatus of the present invention advantageously provides a simplified design, as compared to known prior art apparatus, which is rugged, reliable and inexpensive as well as being adapted to function in differing embodiments as a resonance free (RF) type of pile driving apparatus and as a variable moment (VM) type of pile driving apparatus with selectively fixed intermediate positions.
Those persons skilled in the art will thus recognize and understand that the invention is susceptible of broader utility and application. Many embodiments and adaptations of the present invention other than those herein described, as well as many variations, modifications and equivalent arrangements, will be apparent from or reasonably suggested by the present invention and the foregoing description thereof, without departing from the substance or scope of the present invention. Accordingly, it is to be understood that the foregoing disclosure is only illustrative and exemplary of the present invention and is made merely for purposes of providing a full and enabling disclosure of the invention. The foregoing disclosure is not intended or to be construed to limit the present invention or otherwise to exclude any such other embodiments, adaptations, variations, modifications and equivalent arrangements, the present invention being limited only by the claims appended hereto and the equivalents thereof.
The present application is entitled to the benefit of, and claims priority from, U.S. Provisional Patent Application Ser. No. 61/280,535, filed Nov. 6, 2009, and entitled “Series Motor Resonance-Free System,” the entirety of which is incorporated herein by reference.
Number | Date | Country | |
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61280535 | Nov 2009 | US |