The present disclosure relates to a crane, and more particularly to a fast crane and an operation method for the same.
In general, cranes are one of the most heavily used instruments in construction base sites. There are more than 125,000 cranes operating in the construction industry in United States. Because so many construction activities rely on cranes for moving structural and nonstructural components, the efficiency of the crane operation can influence the entire project progress. However it is always challenging to maintain efficiency of crane operations and the safety of the site. This is especially true in high-rise construction where cranes play a particularly critical role in the overall construction schedule. The challenge for crane operation is the trade-off between the speed/efficiency and the safety.
Cranes are often in charge of the tasks in the critical path of construction schedule. The speed of crane erections can significantly influence the overall project progress. A fast crane operation may result in large sway of the hanging object and causes the safety concerns in the high-speed operation. Accordingly, novice operators usually slow down the crane motions to reduce the sway to ensure the safety of the operation. Although this seems reasonable, the accumulation of hundreds or even thousands slower erection cycles may influence the overall project productivity significantly. Experienced crane operators usually develop the skill and intuition of the crane control for increasing the efficiency and safety of the crane operation. They often vary the speed of the rotation to control the overall vibration in the erection cycle.
There is a prior velocity control method for preventing oscillations in crane, as disclosed in U.S. Pat. No. 5,550,733 (called Case A hereafter), issued on Aug. 27, 1996. Case A applies a closed circuit during the carrying for feeding back the oscillations of the object so as to quickly damping them. The tower crane is a large-scale machine operated at outdoor construction environment. The closed circuit is a close-loop control system which is suitable for use of a small scale machine, but it is difficult to use with the tower crane motor for controlling the suggested precise moving to and fro. Accordingly, an open-loop control system is more suitable for use of the tower crane.
First Referring to
Referring to
where θ1, θ2 are the rotation angles of double pendulum, {umlaut over (θ)}1, {umlaut over (θ)}2 the angular acceleration, P1, P2 the external forces acting on mass m1, m2. There is almost no control mechanism for the fast crane in the prior art. The acceleration input by the moving motor of the crane should be controlled.
Therefore, how to solve the problems of the oscillation of the steel cable for the crane are solved in the present invention. The inventors endeavor in the experiments, tests and researches to obtain a fast crane and an operation method for the same, which not only resolves the drawback of the oscillation of the hanging object, but also achieves the convenience that the moving time of the hanging object is shortened. Namely, the subject matters to be resolved in the present invention are how to overcome the problem that the sway angle is too large for the hanging object, and consequently the shortening of the moving time of the hanging object is feasible, how to overcome the problem that there is no acceleration between the first and the second accelerations, and how to overcome the problem that the time for the second accelerations is relative to the desired operation maximum speed. The present disclosure aims to develop a simple control method for the fast crane operations. The sway angle should be limited to maintain the controllability and safety. A fast crane based on the prior double pendulum equations will be established according to the embodiments of the present disclosure.
In an operation method for a fast crane having a cable with two segments hanging an object according to a piecewise acceleration schedule for moving the object to constrain the object to sway for a cycle of a pendulum period of the cable only and to sway within a maximum swaying angle during moving. The operation method includes calculating the pendulum period, moving the object, moving the object with a first constant speed and moving the object. The pendulum period of the cable is calculated. The object is moved with a first acceleration during a first stage time based on the pendulum period. The body is moved with a first constant speed during a second stage time. The object is moved with a second acceleration during a third stage time.
In an operation method for a crane having a cable hanging an object, the operation method includes calculating a pendulum period and moving the object. The pendulum period of the cable is calculated. The object is moved with an acceleration during an active time based on the pendulum period.
In a crane having a cable for hanging an object, the crane includes a first calculator and a second calculator. The first calculator calculates a pendulum period of the cable. The second calculator calculates an acceleration for moving the object during an active time based on the pendulum period.
The present disclosure may best be understood through the following descriptions with reference to the accompanying drawings, in which:
The present disclosure will be described with respect to particular embodiments and with reference to certain drawings, but the disclosure is not limited thereto but is only limited by the claims. The drawings described are only schematic and are non-limiting. In the drawings, the size of some of the elements may be exaggerated and not drawn on scale for illustrative purposes. The dimensions and the relative dimensions do not necessarily correspond to actual reductions to practice.
Referring to
The operation method further includes a step in which the body is moved with a second constant speed during a fourth stage time. The first stage time is a quarter of pendulum period T, i.e. T/4, the second stage time and the fourth stage time are one eighth of pendulum period T, i.e. T/8, the third stage time t2=(vmax−a1·T/2)/a2, where vmax a desired operation maximum speed, a1 is the first acceleration, T is the pendulum period, a2 is the second acceleration, and there is a relation function of
where g represents a gravity. The method further includes a step in which the object is accelerated with first acceleration a1 during a fifth stage time. The fifth stage time is a quarter of pendulum period T, i.e. T/4, and the piecewise acceleration stage is finished.
Subsequently, a constant speed stage is followed. The method further includes a step which the body is moved with a third constant speed during a rapidest moving stage time t3. The fifth stage time is followed by rapidest moving stage time t3. The third constant speed is the desired operation maximum speed. And the final stage is the piecewise deceleration stage. The method further includes a step in which the object is decelerated with a first deceleration −a1 during a sixth stage time. First deceleration −a1 has a first modulus, i.e. the absolute value, equal to that of first acceleration a1 and the sixth stage time is a quarter of the pendulum period, i.e. T/4. The method further includes a step in which the body is moved with a fourth constant speed during a seventh stage time.
The fourth constant speed is equal to the second constant speed and the seventh stage time is one eighth of pendulum period T, i.e. T/8. The method further includes a step in which the object is decelerated with a second deceleration −a2 during an eighth stage time. Second deceleration −a2 has a second modulus equal to that of second acceleration a2 and the eighth stage time t2 is equal to the third stage time t2. The method further includes a step in which the body is moved with a fifth constant speed during a ninth stage time. The fifth constant speed is equal to the first constant speed and the ninth stage time is one eighth of pendulum period T, i.e. T/8. The method further includes a step in which the object is decelerated with first deceleration −a1 during a tenth stage time. The tenth stage time is a quarter of pendulum period T, i.e. T/4. Second acceleration a2 is calculated based on first acceleration a1. The formula for calculating a total distance d for this plan in the
The accelerations a1, a2 applied in sequence may be 4 m/s2, 6.3 m/s2, and 4 m/s2. The accelerations are in general agreement with a2=g·tan(√{square root over (2)}·tan−1(a1/g)), for the purpose that the sway angle is controlled in
Referring to
A table is the numerical experiment which counts the operation time required by the control methods of the prior crane and the present fast crane. The control method of the fast crane can shorten a considerable time of the operation time. The longer is the operation distance, the higher is the benefit ratio. The table is shown as follows:
Referring to
In some embodiments, the operation method for the crane having the cable hanging the object, the operation method includes calculating pendulum period T and moving the object. Pendulum period T of the cable is calculated. The object is moved with an acceleration, e.g. first acceleration a1, during an active time, e.g. the first stage time, based on pendulum period T. The active time, for example, third stage time t2, is calculated based on the acceleration.
In some embodiments, the crane has the cable for hanging the object. The crane includes a first calculator, for example, a software, and a second calculator. The first calculator calculates pendulum period T of the cable. The second calculator calculates an acceleration, for example, second acceleration a2, for moving the object during an active time, for example, third stage time t2, based on pendulum period T. The first calculator is the second calculator.
Referring to
There are further embodiments provided as follows.
In an operation method for a crane having a cable hanging an object, the operation method includes calculating a pendulum period, moving the object, moving the object with a first constant speed and moving the object. The pendulum period of the cable is calculated. The object is moved with a first acceleration during a first stage time based on the pendulum period. The body is moved with a first constant speed during a second stage time. The object is moved with a second acceleration during a third stage time.
In the method according to the above-mentioned embodiment, the method further includes a step of moving the object with a second constant speed during a fourth stage time.
In the method according to the above-mentioned embodiment 1 or 2, the first stage time is a quarter of the pendulum period, the second stage time and the fourth stage time are one eighth of the pendulum period, and the third stage time t2=((vmax−a1·T/2)/a2, where vmax is a desired operation maximum speed, a1 is the first acceleration, T is the pendulum period, a2 is the second acceleration, and there is a relation function of
where g represents a gravity.
In the method according to any one of the above-mentioned embodiments 1-3, the method further includes a step of accelerating the object with the first acceleration during a fifth stage time.
In the method according to any one of the above-mentioned embodiments 1-4, the fifth stage time is a quarter of the pendulum period.
In the method according to any one of the above-mentioned embodiments 1-5, the method further includes a step of moving the object with a third constant speed during a rapidest moving stage time. The fifth stage time is followed by the rapidest moving stage time.
In the method according to any one of the above-mentioned embodiments 1-6, the method further includes a step of decelerating the object with a first deceleration during a sixth stage time.
In the method according to any one of the above-mentioned embodiments 1-7, the first deceleration has a first modulus equal to that of the first acceleration, and the sixth stage time is a quarter of the pendulum period.
In the method according to any one of the above-mentioned embodiments 1-8, the method further includes a step of moving the object with a fourth constant speed during a seventh stage time.
In the method according to any one of the above-mentioned embodiments 1-9, the forth constant speed is equal to the second constant speed, and the seventh stage time is one eighth of the pendulum period.
In the method according to any one of the above-mentioned embodiments 1-10, the method further includes a step of decelerating the object with a second deceleration during an eighth stage time.
In the method according to any one of the above-mentioned embodiments 1-11, the second deceleration has a second modulus equal to that of the second acceleration, and the eighth stage time is equal to the third stage time.
In the method according to any one of the above-mentioned embodiments 1-12, the method further includes a step of moving the object with a fifth constant speed during a ninth stage time.
In the method according to above-mentioned embodiment 1-13, the fifth constant speed is equal to the first constant speed. The ninth stage time is one eighth of the pendulum period.
In the method according to the above-mentioned embodiment 1-14, the method further includes a step of decelerating the object with the first deceleration during a tenth stage time and the tenth stage time is a quarter of the pendulum period.
In the method according to any one of the above-mentioned embodiments 1-15, the second acceleration is calculated based on the first acceleration.
In an operation method for a crane having a cable hanging an object, the operation method includes calculating a pendulum period and moving the object. The pendulum period of the cable is calculated. The object is moved with an acceleration during an active time based on the pendulum period.
In the method according to the above-mentioned embodiment 17, the active time is calculated based on the acceleration.
In a crane having a cable for hanging an object, the crane includes a first calculator and a second calculator. The first calculator calculates a pendulum period of the cable. The second calculator calculates an acceleration for moving the object during an active time based on the pendulum period.
In the method according to the above-mentioned embodiment 19, the first calculator is the second calculator.
It is concluded the present disclosure can reach high speed operation with zero sway angles by using multiple accelerations and decelerations, so it can be confirmed that the first constant speed is really a zero acceleration between the first and the second accelerations, and really able to accomplish the purpose of using the desired operation maximum speed to calculate the time for the second accelerations.
While the disclosure has been described in terms of what are presently considered to be the most practical and exemplary embodiments, it is to be understood that the disclosure need not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims, which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures. Therefore, the above description and illustration should not be taken as limiting the scope of the present disclosure which is defined by the appended claims.
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