JP2020138869A - Quay crane and method for controlling the same - Google Patents

Abstract

To provide a quay crane and a method of controlling a quay crane that can control a boom swing.SOLUTION: It is configured such that a displacement measuring mechanism 13 measures a displacement direction when the sea side end of a boom 2 is displaced from the initial position to the front side or the rear side in the traveling direction of a quay crane 1, and the relative speed of a land side traveling device 2b with respect to a sea side traveling device 2a is reduced when the sea side end of the boom is displaced to the rear side in the traveling direction, and the relative speed of the sea side traveling device 2a with respect to the land side traveling device 2b is reduced when the sea side end of a boom 4a is displaced forward in the traveling direction. When the relative speed is reduced, the sea side traveling device 2a and the land side traveling device 2b are controlled only in the deceleration direction and not in the acceleration direction.SELECTED DRAWING: Figure 6

Description

The present invention relates to a method for controlling a quay crane and a quay crane provided with a sea-side traveling device and a land-side traveling device and a boom and a girder extending in the transverse direction, which are opposed to each other at intervals in the transverse direction. It relates to a quay crane and a quay crane control method capable of suppressing boom runout.

Quay cranes are used as cargo handling equipment for handling containers and the like at ports and the like. The quay crane is a traveling device that is opposed to each other at intervals in the transverse direction (sometimes called the land and sea direction) that crosses the traveling direction along the quay at a right angle, a crane structure supported by the traveling device, and the crane structure. It is equipped with a boom and girder that are supported by the crane structure and extend in the transverse direction. The traveling device is composed of a sea-side traveling device arranged on the sea side and a land-side traveling device arranged on the land side.

The sea-side traveling device and the land-side traveling device are a traveling wheel, a motor that transmits power to the traveling wheel, an inverter that is connected to the motor and controls the rotation speed (rotation speed) of the motor, and this inverter. It has a controller that gives a command of the rotation speed to the motor via.

The controller is installed in the cab of the crane, for example, and gives a speed command to each inverter by the operation of the driver. The inverter supplies electricity to the motor whose frequency and voltage are adjusted based on this speed command. That is, the sea-side traveling device and the land-side traveling device are controlled independently.

When a typhoon approaches, anchor pins are inserted into the through holes formed in the traveling device and the quay in order to fix the quay crane to the quay. At this time, the sea side traveling device and the land side traveling device are independently controlled so that the alignment of the sea side traveling device and the through hole of the quay and the alignment of the land side traveling device and the through hole of the quay can be performed respectively. It is configured so that it can be done.

When loading and unloading a container with a quay crane, the driver runs the quay crane in the traveling direction to align the boom so that the center of the boom is aligned with the center of the container to be handled. When traveling the quay crane, the driver operates the controller so that the sea-side traveling device and the land-side traveling device travel at the same speed and in the same direction.

When stopping the quay crane, for example, the speed is gradually reduced to 2% with respect to 100% of the rated rotation speed of the motor, and then the braking device installed in the traveling device is operated to stop the traveling device. If the speed of the motor is reduced to 0% of the rated rotation speed, that is, 0 rpm, the quay crane may be pushed and moved by wind or the like. Therefore, conventionally, the brake is applied before the traveling device is completely stopped. Was there.

Since the quay crane has a boom that overhangs the sea side, the center of gravity of the quay crane is biased toward the sea side, and the load that the sea side traveling device should support compared to the land side traveling device (hereinafter, (Sometimes called a wheel load) increases. Since the wheel load of the sea side traveling device is heavier, even if a speed command is given from the controller so that the sea side traveling device and the land side traveling device travel at the same speed, the wheel load is relatively large on the sea side. The applicant found that the device would be delayed.

When the quay crane is driven, the land-side traveling device is advanced ahead of the sea-side traveling device, that is, the positions of the respective traveling devices are deviated in the traveling direction. Due to the deviation of the traveling direction between the sea-side traveling device and the land-side traveling device, a rotational moment about the vertical direction is generated in the crane structure, and the crane structure is distorted (deformed). Further, in the crane structure, a rotational moment in the opposite direction to the above is generated as a force in the direction of releasing this strain. This rotational moment causes vibration in the crane structure, and this vibration causes a problem that the sea side end of the boom swings in the traveling direction.

In addition, when the brake is applied to stop the traveling device, the sea-side traveling device and the land-side traveling device are in a state of being displaced in the traveling direction, so that the crane structure remains in a residual strain. The position of the traveling device is fixed. Due to the influence of this distortion, vibration is generated in the crane structure after braking, and this vibration causes a problem that the sea side end of the boom swings in the traveling direction.

The boom of the quay crane has a twin box structure in which two columnar members extending in the transverse direction are connected by a steel material extending in the traveling direction to form a frame-like structure, and one extending in the transverse direction. There is a monobox structure formed of columnar members. The boom of the monobox structure is lighter than the boom of the twin box structure, but the rigidity against the shaking in the traveling direction is relatively small, so that the sea side end of the boom is likely to swing.

When the sea-side end of the boom is swinging, it is not possible to align it with the container to be handled, so conventionally it was necessary to wait until the sea-side end of the boom subsided. This waiting time was required each time the quay crane was running and stopped.

The applicant has already proposed a vibration damping structure that suppresses the shaking of the boom of the quay crane (see, for example, Patent Document 1). Patent Document 1 proposes a configuration in which damping masses are installed at the sea side end of the boom and the land side end of the girder to suppress the shaking of the boom that occurs during an earthquake. Although this damping mass can dampen the boom sway that occurs when the quay crane is running and stopped, it is not possible to prevent the boom sway itself, so waiting time was still required.

Japanese Unexamined Patent Publication No. 2011-213455

The present invention has been made in view of the above problems, and an object of the present invention is to provide a quay crane and a quay crane control method capable of suppressing boom runout.

The quay crane of the present invention that achieves the above object includes a sea-side traveling device and a land-side traveling device that are opposed to each other at intervals in a transverse direction crossing the traveling direction, and the sea-side traveling device and the land-side traveling device. A crane structure supported by the traveling device and a boom and a displacement supported by the crane structure extending in the transverse direction are provided, and the sea-side traveling device and the land-side traveling device travel respectively. A quay having a wheel, a motor for transmitting power to the traveling wheel, an inverter connected to the motor to control the rotation speed of the motor, and a controller for giving a command of the rotation speed to the motor via the inverter. In the crane, a displacement measuring mechanism that measures the displacement direction when the sea side end of the boom is displaced from the initial position to the front side or the rear side in the traveling direction of the quay crane, and the displacement acquired by this displacement measuring mechanism. comprise a control mechanism for adjusting the rotational speed to be commanded to the motor from the controller based on the direction, before Symbol control mechanism, when the sea-side end portion of the boom to the rear side of the traveling direction is displaced When the relative speed of the land-side traveling device with respect to the sea-side traveling device is reduced and the sea-side end of the boom is displaced toward the front side in the traveling direction, the sea-side traveling device with respect to the land-side traveling device It is characterized by having a configuration for reducing the relative speed of the above, and having a configuration in which the sea-side traveling device and the land-side traveling device are controlled only in the deceleration direction and not in the acceleration direction when the relative speed is reduced. And.

The control method of the quay crane of the present invention comprises a sea-side traveling device and a land-side traveling device which are opposed to each other at intervals in a transverse direction crossing the traveling direction, and the sea-side traveling device and the land-side traveling device. A crane structure to be supported and a boom and a girder supported by the crane structure and extending in the transverse direction are provided, and the sea-side traveling device and the land-side traveling device are provided with a traveling wheel and a traveling device, respectively. Control of a quay crane having a motor that transmits power to the traveling wheels, an inverter that is connected to the motor and controls the rotational speed of the motor, and a controller that gives a command of the rotational speed to the motor via the inverter. in the method, the sea-side end of the boom by measuring the displacement direction when the displacement from the initial position to the front side or rear side in the traveling direction of the quay cranes, the previous SL said boom to said rear side in the traveling direction small allowed reducing the relative velocity of the land-side travel system for the sea-side traveling device when the sea-side end portion is displaced, the land when the sea side end part of the boom on the front side of the advancing direction is displaced have a reduced little is to configure the relative velocity of the sea-side traveling device for side traveling device, wherein in reducing the relative speed sea-side driving device and the landward traveling device is controlled only in the deceleration direction increasing It is characterized in that it is not controlled in the speed direction .

According to the present invention, the displacement direction of the boom is directly measured, and this displacement is eliminated to control the pair of traveling devices in the direction in which the boom returns to the initial position. Therefore, the crane structure is deformed into a boom. It is advantageous to suppress the occurrence of vibration.

The displacement measuring mechanism can consist of accelerometers installed on at least one of the boom or girder. The accelerometer can be configured to be installed either near the seaside end of the boom or near the land side end of the girder. According to this configuration, the acceleration sensor is installed at a position where the displacement is large in the boom and the girder, so that the measurement accuracy in the displacement direction can be improved.

The displacement measurement mechanism is composed of a measurement receiver installed on at least one of the boom or the girder and capable of acquiring position information, and a reference receiver installed on the crane structure and capable of acquiring position information, with respect to the reference receiver. The configuration can be configured to measure the displacement direction of the boom from the relative position of the measuring receiver.

Since a receiver such as a satellite positioning system or a transponder can be installed on the boom or the like and the displacement direction of the boom can be directly measured from the position information, it is advantageous to improve the measurement accuracy of the displacement direction.

The control mechanism reduces the rotation speed commanded by the controller to the motor of the sea-side traveling device or land-side traveling device located on the front side in the traveling direction by a larger rate as the displacement amount measured by the displacement measuring mechanism increases. Can be configured.

The larger the displacement amount of the boom, the stronger the control for eliminating this displacement works, which is advantageous for shortening the time until the boom stops swinging. Since the control is performed in a direction that reduces the rotation speed of the motor, it is possible to avoid a problem that the output exceeding the capacity of the motor is required in this control and the control effect cannot be obtained.

It is explanatory drawing which illustrates the quay crane of this invention. It is explanatory drawing which illustrates the quay crane of FIG. 1 in the cross section AA. It is explanatory drawing which enlarges and illustrates the vicinity of the traveling device of the quay crane of FIG. It is explanatory drawing which schematically exemplifies the control mechanism and the inverter of a quay crane. It is explanatory drawing which schematically exemplifies the plane of the quay crane in which the boom is in the initial position. It is explanatory drawing which illustrates the state which the boom is displaced to the rear side in the traveling direction. It is explanatory drawing which illustrates the state which the boom is displaced forward side in the traveling direction. It is a graph which illustrates the fluctuation of the rotation speed of a motor at the time of applying a brake.

Hereinafter, the quay crane and the control method of the quay crane of the present invention will be described based on the embodiment shown in the figure. In the figure, the traveling direction of the quay crane and the traveling device is indicated by an arrow y, the transverse direction which is the horizontal direction orthogonal to the traveling direction y is indicated by an arrow x, and the vertical direction is indicated by an arrow z.

As illustrated in FIGS. 1 to 3, the quay crane 1 of the present invention has a sea-side traveling device 2a and a land-side traveling device 2b that are opposed to each other at intervals in the transverse direction x, which is a horizontal direction orthogonal to the traveling direction y. (Hereinafter, collectively referred to as a traveling device 2), a crane structure 3 supported by the traveling device 2, a boom 4a supported by the crane structure 3 and extending in the transverse direction x, and a girder. It has 4b.

The crane structure 3 includes four leg members 3a extending in the vertical direction z, and a plurality of horizontal members 3b extending in the transverse direction x or the traveling direction y and connecting adjacent leg members 3a. ing. The boom 4a and the girder 4b are suspended from the lower surface of the horizontal member 3b extending in the traveling direction y and connecting the leg members 3a on the sea side and the horizontal member 3b connecting the leg members 3a on the land side. It is fixed at. The quay crane 1 includes a trolley 5 traversing along the boom 4a and the girder 4b, and the driver operates the quay crane 1 from the cab 6 attached to the trolley 5.

A traveling device 2 is installed at the lower end of the crane structure 3, and the traveling device 2 is arranged on the sea side in the traveling direction y and is arranged on the sea side, and two land side traveling devices 2a are arranged on the land side. It is composed of a side traveling device 2b. In this embodiment, two sea-side traveling devices 2a and two land-side traveling devices 2b are installed in the crane structure 3, but the present invention is not limited to this configuration. The quay crane 1 of the present invention may include a sea-side traveling device 2a and a land-side traveling device 2b arranged at intervals in the transverse direction x.

As illustrated in FIG. 3, each of the traveling devices 2 includes four traveling wheels 7 and one motor 8 that transmits power to the traveling wheels 7. Further, at least one traveling device 2 is provided with a braking device 9 for braking the traveling device 2.

The traveling wheel 7 is composed of, for example, an iron wheel that moves while rolling on a rail laid on the quay 10. At this time, the brake device 9 is composed of, for example, a rail clamp that sandwiches the rail and fixes the traveling device 2. Further, the traveling wheel 7 is composed of, for example, a rubber tire or the like that moves on the quay 10 without a track while rolling. At this time, the brake device 9 is composed of a disc brake or the like that stops the rotation of the tire.

The number of traveling wheels 7 and motors 8 is not limited to the above. The number of traveling wheels 7 can be appropriately changed according to the load to be supported by the traveling wheels 7, and the number of motors 8 can be appropriately changed according to the magnitude of the power to be transmitted to the traveling wheels 7. For example, eight traveling wheels 7 can be installed in one traveling device 2, and power can be transmitted to the traveling wheels 7 from four motors 8.

Further, each traveling device 2 includes an inverter 11. The inverter 11 controls the rotation speed (rotation speed) of the motor 8 based on a rotation speed command from a controller installed in the driver's cab 6.

As illustrated in FIG. 1, a displacement measuring mechanism 13 for measuring the displacement direction when the boom 4a swings and is displaced in the traveling direction y is installed on the sea side end surface of the sea side end portion of the boom 4a. The displacement measuring mechanism 13 can be configured by an acceleration sensor such as a uniaxial acceleration sensor. The displacement measuring mechanism 13 is not limited to the acceleration sensor, and may have a function of measuring at least the displacement direction of the boom 4a in the traveling direction y. The displacement measuring mechanism 13 can be configured by, for example, a displacement meter capable of measuring the amount of displacement in addition to the displacement direction of the boom 4a.

The position where the displacement measuring mechanism 13 is installed is not limited to the sea side end surface of the boom 4a, and may be near the sea side end surface. For example, the displacement measuring mechanism 13 can be installed on the upper surface, the lower surface, or the side surface of the boom 4a facing the sea side end portion in the traveling direction y. In the present specification, the vicinity of the sea side end of the boom 4a means a position within 20% from the sea side end of the boom 4a with respect to the total length of the boom 4a and the girder 4b in the transverse direction x.

As illustrated in FIG. 4, the inverter 11 includes a sea-side inverter 11a that controls the motor 8 installed in the sea-side traveling device 2a and a land-side inverter 11b that controls the motor 8 installed in the land-side traveling device 2b. It is composed of. The inverter 11 is installed in each traveling device 2. The controller 12 that gives a rotation speed command (speed command) to the motor 8 via the inverter 11 is installed in, for example, the cab 6. In FIG. 4, the electric wire for supplying electricity to the motor 8 is indicated by a solid arrow, and the signal line for transmitting a signal is indicated by a broken line arrow.

Not limited to the above configuration, the inverter 11 may be installed in the cab 6 together with the controller 12. When the crane 1 is remotely controlled, the controller 12 is installed in an operation room at a remote location.

A control mechanism 14 is installed between the inverter 11 and the controller 12. The control mechanism 14 has a function of adjusting the rotation speed commanded by the controller 12 to the motor 8 based on the displacement direction of the boom 4a acquired by the displacement measuring mechanism 13. That is, the speed command sent from the controller 12 to the motor 8 always passes through the control mechanism 14. The control mechanism 14 is installed in, for example, the driver's cab 6. The control mechanism 14 may be arranged in the vicinity of the inverter 11 of the traveling device 2.

A configuration in which all the motors 8 installed in the sea-side traveling device 2a are controlled by one sea-side inverter 11a, and all the motors 8 installed in the land-side traveling device 2b are controlled by one land-side inverter 11b. Alternatively, the inverter 11 may be installed for each motor 8.

When the driver operates the controller 12, a speed command is sent from the controller 12 to the inverter 11. This speed command defines the rotation speed of the motor 8, and the inverter 11 adjusts the frequency of electricity supplied from the quay crane 1 and supplies the motor 8 in response to the speed command. That is, the motor 8 rotates according to the rotation speed commanded by the controller 12.

In this embodiment, one controller 12 is connected to the two inverters 11a and 11b. A changeover switch for selecting the inverter 11 that sends a command for the rotation speed may be installed in the controller 12 so that only the sea-side traveling device 2a or the land-side traveling device 2b can be traveled to perform alignment. Further, the controller 12 may be connected to each of the two inverters 11.

As illustrated in FIG. 5, when the quay crane 1 is stopped, the boom 4a does not swing and is in a stopped state. The position of the boom 4a when it is not swinging is referred to as an initial position in this specification. When the driver operates the controller 12 with the start of cargo handling work from this state, the quay crane 1 starts traveling along the rail 10a laid on the quay 10.

As illustrated in FIGS. 6 and 7, when the quay crane 1 travels, the sea side traveling device 2a and the land side traveling device 2b may deviate in the traveling direction y, and accordingly, travel to the boom 4a and the girder 4b. A runout (displacement) in the direction y occurs. In FIGS. 6 and 7, the traveling direction (traveling direction) of the quay crane 1 is indicated by a white arrow for explanation. For the sake of explanation, the initial positions of the boom 4a and the girder 4b are shown by broken lines.

As illustrated in FIG. 6, since the quay crane 1 is provided with a boom 4a that protrudes greatly toward the sea side, the center of gravity is biased toward the sea side. Therefore, the wheel load of the sea-side traveling device 2a becomes relatively large, and a delay occurs even when the same speed command as that of the land-side traveling device 2b is received from the controller 12. The crane structure 3 is distorted due to the delay of the sea-side traveling device 2a, and the sea-side end of the boom 4a swings to the rear side in the traveling direction of the quay crane 1.

After that, a force in the opposite direction is generated in the crane structure 3 in order to release the strain, so that the sea side end of the boom 4a swings forward in the traveling direction of the quay crane 1 as illustrated in FIG. At this time, the land side traveling device 2b lags behind the sea side traveling device 2a.

The runout of the boom 4a in the traveling direction y varies depending on the size of the quay crane 1 and the rigidity of the crane structure 3, but for example, the period is about 0.5 to 15 sec, and the amplitude at the sea side end is ± 0.1 to 1. It will be about 1.0 m. Further, the boom 4a and the girder 4b rotate in a horizontal plane about a center point C near an intermediate position between the sea side traveling device 2a and the land side traveling device 2b.

In the situation illustrated in FIG. 6, the quay crane 1 of the present embodiment first measures the displacement direction of the sea side end portion of the boom 4a by the displacement measuring mechanism 13. This displacement direction is sent as a signal from the displacement measuring mechanism 13 to the control mechanism 14. The control mechanism 14 adjusts the rotation speed commanded by the controller 12 to the inverter 11 based on the displacement direction.

In the case illustrated in FIG. 6, since the boom 4a is displaced to the rear side in the traveling direction, the sea side traveling device 2a is delayed. Therefore, the control mechanism 14 controls to reduce the relative speed of the land-side traveling device 2b with respect to the sea-side traveling device 2a.

For example, when the controller 12 issues a speed command to the inverter 11 to travel at 100% of the rated speed, the control mechanism 14 has 100% of the rated speed for the inverter 11 of the seaside traveling device 2a. The speed command is transmitted as it is, and for example, a speed command of 80% of the rated speed is transmitted to the inverter 11 of the land side traveling device 2b. By this control, the delayed sea side traveling device 2a approaches the land side traveling device 2b, and the strain of the crane structure 3 can be reduced.

When the boom 4a is displaced forward in the traveling direction of the quay crane 1 as illustrated in FIG. 7, the control mechanism 14 reduces the command of the rotation speed of the seaside traveling device 2a by, for example, 20% of the rated speed. Control to make it. By this control, the delayed land-side traveling device 2b approaches the sea-side traveling device 2a, and the strain of the crane structure 3 can be reduced.

Since the control mechanism 14 can know the traveling direction of the quay crane 1 from the rotation speed command sent from the controller 12, the boom 4a moves forward or backward in the traveling direction based on the signal from the displacement measuring mechanism 13. It is possible to determine which of the two is displaced.

The displacement direction of the boom 4a is measured by the displacement measuring mechanism 13, and the control mechanism 14 adjusts the relative speed between the sea side traveling device 2a and the land side traveling device 2b based on the measurement, so that the boom 4a is shaken. Can be suppressed and the runout generated in the boom 4a can be stopped. The control mechanism 14 may control to reduce the deviation between the sea-side traveling device 2a and the land-side traveling device 2b in the traveling direction y. Therefore, the relative speed may be adjusted by controlling to increase the speed of the traveling device 2 on the delayed side.

That is, since the sea-side traveling device 2a deviates from the land-side traveling device 2b in the same direction as the displacement direction of the boom 4a, the control mechanism 14 may perform control to eliminate this displacement. Specifically, the speed of the traveling device 2 on the leading side is reduced, or the speed of the traveling device 2 on the lagging side is increased.

Compared to the case where the strain of the crane structure 3 is measured and the runout of the boom 4a is indirectly estimated from this measured value, in the present embodiment, the displacement measuring mechanism 13 directly measures the runout of the boom 4a. , It is possible to accurately suppress the occurrence of runout in the boom 4a.

By suppressing the runout of the boom 4a, there is almost no waiting time for waiting for the runout of the boom 4a to settle during cargo handling, which is advantageous for improving the cargo handling efficiency of the quay crane 1.

Even when the quay crane 1 is enlarged, the runout of the boom 4a can be suppressed. Even if the weight of the quay crane 1 is reduced and the rigidity of the crane structure 3 is reduced, the runout of the boom 4a can be suppressed. Therefore, even when the quay crane 1 is provided with a boom 4a having a monobox structure that is lightweight and has low rigidity, the runout of the boom 4a can be effectively suppressed.

The displacement measuring mechanism 13 can be configured to measure the displacement amount in addition to the displacement direction. In this case, the amount (correction amount) for reducing the rotation speed of the motor 8 may be changed according to the amount of displacement of the boom 4a from the initial position. When the displacement measuring mechanism 13 is composed of, for example, an acceleration sensor, the amount of displacement from the initial position can be calculated by integrating the values measured by the acceleration sensor.

The amount (correction amount) for reducing the actual rotation speed with respect to the speed command sent from the controller 12 to the motor 8 can be determined based on, for example, D = ad. Here, D is a correction amount (%), a is a preset constant, and d is a displacement amount (m). That is, the control mechanism 14 adjusts the rotation speed commanded by the controller 12 to the motor 8 in proportion to the displacement amount measured by the displacement measuring mechanism 13.

A case where the constant a is set to 10 will be described as an example. As illustrated in FIG. 6, when the displacement amount measured by the displacement measuring mechanism 13 is 0.1 m on the rear side in the traveling direction of the quay crane 1 (d = 0.1), the correction amount is corrected from the above equation. D is 1%. The control mechanism 14 rotates the motor 8 of the land-side traveling device 2b at a speed reduced by 1% from the rotation speed input by the driver to the controller 12. That is, when the rotation speed command is 100% (rated speed), the actual motor 8 rotates at a rotation speed of 99% of the rated speed, and when the speed command is 50%, it rotates at a rotation speed of 49% of the rated speed. To do.

When the displacement amount measured by the displacement measuring mechanism 13 is 1.0 m on the rear side in the traveling direction of the quay crane 1 (d = 1.0), the correction amount D is 10% from the above equation. The control mechanism 14 rotates the motor 8 of the land-side traveling device 2b at a rotation speed 10% less than the rotation speed input by the driver to the controller 12. That is, when the rotation speed command is 100% (rated speed), the actual motor 8 rotates at a rotation speed of 90% of the rated speed, and when the speed command is 50%, it rotates at a rotation speed of 40% of the rated speed. To do.

As illustrated in FIG. 7, when the displacement amount measured by the displacement measuring mechanism 13 is 1.0 m on the front side in the traveling direction of the quay crane 1 (d = -1.0), the correction amount is corrected from the above equation. D becomes -10%. The control mechanism 14 rotates the motor 8 of the sea-side traveling device 2a at a rotation speed that is 10% less than the rotation speed input by the driver to the controller 12. As described above, the control mechanism 14 reduces the speed of the sea-side traveling device 2a when the value of the correction amount D is negative, and reduces the speed of the land-side traveling device 2b when the value of the correction amount D is positive. When the traveling direction of the quay crane 1 is opposite to that in FIGS. 6 and 7, the control mechanism 14 reduces the speed of the land-side traveling device 2b when the value of the correction amount D is negative, and when it is positive, the speed is reduced to the sea. The speed of the side traveling device 2a is reduced.

The value of the constant a is not limited to the above, and can be appropriately changed according to the scale of the quay crane and the configuration of the equipment. The value of the constant a is set, for example, in the range of 1 or more and 100 or less, and preferably in the range of 2 or more and 10 or less. A knob for changing the constant a may be installed on the controller 12 so that the driver can change the constant a at any time. The larger the value of the constant a, the stronger the control for stopping the runout of the boom 4a, so that it becomes easier to stop the runout of the boom 4a. Since the amount of change in the speed of the traveling device 2 becomes smaller as the value of the constant a becomes smaller, it is advantageous to avoid a problem that an impact or the like is generated on the quay crane 1 due to the speed change of the traveling device 2.

The control mechanism 14 may be configured to control the rotation speed of the motor 8 with a correction amount D predetermined for a speed command, for example. Specifically, for example, the absolute value of the correction amount D is set to 8% in advance, and when the boom 4a is displaced to the front side, the value of the correction amount D is set to + 8% regardless of this displacement amount. That is, control is performed by setting the value of the correction amount D to + 8% or −8% according to the displacement direction.

When the boom 4a is displaced to the rear side as illustrated in FIG. 6, the motor 8 of the land-side traveling device 2b is rotated at a rotation speed 8% less than the rotation speed input by the driver to the controller 12. In this case, when the speed command from the controller 12 is 100% of the rated speed, the rotation speed of the motor 8 is 92% of the rated speed, and when the speed command is 50% of the rated speed, the rotation speed of the motor 8 is the rated speed. It becomes 42% of.

When the boom 4a is displaced to the front side as illustrated in FIG. 7, the value of the correction amount D is set to -8% regardless of the displacement amount, and the rotation speed of the motor 8 of the seaside traveling device 2a is reduced by 8%. ..

The correction amount D for reducing the rotation speed of the motor 8 with respect to the displacement direction and the displacement amount measured by the displacement measuring mechanism 13 is not limited to the above. For example, instead of the above-mentioned formula for obtaining the correction amount D, a table in which the correction amount D is predetermined is set according to the displacement amount in the traveling direction y of the sea side end portion of the boom 4a as illustrated in the following table. You may. The mathematical formulas and tables for determining the rotational speed of the motor 8 can be stored in, for example, the control mechanism 14.

The control by the displacement measuring mechanism 13 and the control mechanism 14 may be in a state of being constantly executed, but it is started when the quay crane 1 shifts from the stopped state to the running state, and shifts from the running state to the stopped state for a predetermined time. It is desirable to terminate after the lapse of time. As a result, the control for suppressing the runout of the boom 4a is started at the moment when the swing of the boom 4a occurs, and it becomes easy to maintain the state in which the boom 4a hardly swings. Further, it is possible to prevent the quay crane 1 from unexpectedly moving in the traveling direction y due to the control being executed during the cargo handling work.

The displacement measurement mechanism 13 may measure the displacement direction and displacement amount of the boom 4a, and the control mechanism 14 may adjust the speed at predetermined time intervals, but it is better to continuously perform the measurement without the time interval. desirable. By sequentially adjusting the rotation speed of the motor 8, it is possible to suppress the runout of the boom 4a before it becomes large.

The quay crane 1 may bring the boom 4a into a nearly vertical upright state when it is inactive, and the quay crane 1 may travel while the boom 4a is in the upright state. At this time, the displacement measuring mechanism 13 and the control mechanism 14 may be used for control, but if there is almost no problem even if the boom 4a is swung, the control may not be performed.

The installation position of the displacement measuring mechanism 13 such as the acceleration sensor is not limited to the sea side end of the boom 4a, and may be any position as long as the displacement direction and the amount of displacement in the traveling direction y of the boom 4a can be measured. For example, the displacement measuring mechanism 13 can be installed at a position on the boom 4a near the leg member 3a on the sea side. In this case, the displacement amount measured by the displacement measurement mechanism 13 is smaller than the displacement amount at the sea side end of the boom 4a, but in order to shorten the wiring of the electric wire or the like that supplies electricity to the displacement measurement mechanism 13. It is advantageous.

The displacement measuring mechanism 13 may be installed at the land side end of the girder 4b. The displacement direction and the displacement amount are detected in the opposite directions to those when the boom 4a is installed. That is, as illustrated in FIG. 6, when the sea side end of the boom 4a is displaced to the rear side in the traveling direction of the quay crane 1, the land side end of the girder 4b is displaced to the front side in the traveling direction. When the displacement measuring mechanism 13 installed at the land side end of the girder 4b detects the displacement to the front side, the sea side traveling device 2a is delayed, so that the control mechanism 14 refers to the sea side traveling device 2a. Control is performed to reduce the relative speed of the land-side traveling device 2b. The displacement measuring mechanism 13 may be installed at a position on the girder 4b near the leg member 3b on the land side.

The displacement measuring mechanism 13 may be installed inside the columnar members constituting the boom 4a and the girder 4b. It is advantageous to avoid deterioration of the displacement measuring mechanism 13 due to wind and rain.

The displacement measuring mechanism 13 installed on the boom 4a or the like is not limited to one. For example, the displacement measuring mechanism 13 may be installed on each of the boom 4a and the girder 4b, or three or more displacement measuring mechanisms 13 may be installed. The state of the boom 4a and the girder 4b can be measured in more detail by installing a plurality of displacement measuring mechanisms 13 such as an acceleration sensor.

For example, as illustrated by the alternate long and short dash line in FIG. 6, the boom 4a may be in the traveling direction y, and the value measured by the displacement measuring mechanism 13 at the sea side end of the boom 4a may be larger than usual. When the control mechanism 14 controls to increase the deceleration rate of the traveling device 2 according to the amount of displacement measured by the displacement measuring mechanism 13, when the boom 4a is bent, the control for decelerating the traveling device 2 works strongly. There is a risk of passing.

Even in such a case, if the displacement measuring mechanism 13 is also installed in the girder 4b, the bending of the boom 4a can be detected from this measured value. It is advantageous for the control mechanism 14 to decelerate the traveling device 2 within an appropriate range.

In this case, for example, the average value of the displacement values obtained by the displacement measuring mechanism 13 installed on the boom 4a and the displacement measuring mechanism 13 installed on the girder 4b is calculated, and the control mechanism 14 travels based on this average value. The speed of the device 2 can be controlled.

If the value of the displacement measuring mechanism 13 installed on the boom 4a exceeds a predetermined range with respect to the value obtained by the displacement measuring mechanism 13 installed on the girder 4b, it is determined that the boom 4a is bent. , The control may be performed based only on the value obtained by the displacement measuring mechanism 13 installed in the girder 4b.

The displacement measuring mechanism 13 may use a satellite positioning system such as GPS. For example, the reference receiver can be installed in the vicinity of the two land-side traveling devices 2b, and the measurement receiver can be installed at the sea side end of the boom 4a. The displacement direction and displacement amount of the boom 4a can be calculated from the position coordinates of the measurement receiver with respect to the position coordinates of the two reference receivers.

Similarly, the displacement measuring mechanism 13 may utilize a transponder. The transponder is composed of, for example, a transmitter installed in a container terminal, a reference receiver installed in the vicinity of two land-side traveling devices 2b, and a measurement receiver installed in a boom 4a or the like. Can be done.

The position where the reference receiver and the measurement receiver are installed is not limited to the above. The measurement receiver is preferably installed at the sea side end of the boom 4a where the displacement is large, but it may be installed at another place of the boom 4a or at the girder 4b. Further, the reference receiver may be installed at a position where the position of the measurement receiver on the quay crane 1 can be known, and may be installed in, for example, two seaside traveling devices 2a, respectively. Two reference receivers may be installed on the crane structure 3 at intervals in the traveling direction y.

The displacement measuring mechanism 13 can be composed of a strain gauge installed at a joint portion between the horizontal member 3b and the girder 4b to which the girder 4b is fixed in a suspended state. The strain gauge can measure the displacement direction of the girder 4b or the like with respect to the horizontal member 3b.

When the quay crane 1 is stopped, the driver sends a speed command from the controller 12 to the inverter 11 to set the rotation speed of the motor 8 to 0% of the rated rotation speed, that is, 0 rpm. As illustrated in FIG. 8, the inverter 11 starts the control for maintaining this 0 rpm at t0 when the rotational speed of the motor 8 is gradually reduced to 0 rpm (control start point). For example, when the quay crane 1 is pushed in the traveling direction y by wind or the like, a force opposed to this external force is generated in the motor 8 to maintain the rotation speed of the motor 8 at 0 rpm. From the time when the rotation speed of the motor 8 becomes 0 rpm, for example, after a predetermined standby time T1 of about 2 to 10 sec elapses, the brake is applied by the brake device 9 installed in the traveling device 2 (brake operating point).

Even during the elapse of the standby time, the displacement measuring mechanism 13 measures the displacement direction and the amount of displacement of the boom 4a, and based on this, the control mechanism 14 sequentially performs control to adjust the rotation speed commanded by the motor 8. Therefore, even after the control by the inverter 11 to set the rotation speed of the motor 8 to 0 rpm is started, the sea side traveling device 2a and the land side traveling device 2b are displaced in the traveling direction y, and the crane structure 3 is If it is distorted, the boom 4a will be in a position swung from the initial position. For example, when a speed command for setting the rotation speed to 0 rpm is sent from the controller 12 to the inverter 11, the boom 4a may be displaced rearward as illustrated in FIG. 6 by the quay crane 1.

The control mechanism 14 controls to reduce the rotational speed of the motor 8 based on the displacement direction of the boom 4a. Since the controller 12 issues a speed command to the motor 8 to stop at a rotation speed of 0% of the rated rotation speed, the control mechanism 14 has a rotation speed that is reduced by, for example, 3% from the motor 8 of the land-side traveling device 2b. That is, the motor 8 is controlled to rotate at -3% of the rated rotation speed. That is, the motor 8 of the land-side traveling device 2b reverses and moves to the rear side approaching the sea-side traveling device 2a.

The control mechanism 14 stores the traveling direction of the quay crane 1 immediately before the speed command for setting the rotation speed to 0 rpm is sent to the inverter 11, and controls the moving direction of each traveling device 2 based on this traveling direction.

For example, the control mechanism 14 may be configured to control the sea-side traveling device 2a to travel the land-side traveling device 2b in the same direction as the displacement direction of the boom 4a. For example, when the boom 4a is swinging to the rear side in the traveling direction as illustrated in FIG. 6, the boom 4a is moved to the rear side by moving the land side traveling device 2b to the rear side while the sea side traveling device 2a is stopped. To return to the initial position. According to this configuration, the control mechanism 14 can execute the control for returning the boom 4a to the initial position without memorizing the traveling direction of the quay crane 1. Similarly, the sea side traveling device 2a may be controlled to move in the direction opposite to the displacement direction of the boom 4a while the land side traveling device 2b is stopped.

Since each traveling device 2 moves so that the boom 4a is in the initial position, the deviation of the traveling direction y of the traveling device 2 becomes small. That is, the residual strain of the crane structure 3 is released, and then the traveling device 2 is fixed by the brake device 9. Therefore, it is possible to prevent the crane structure 3 from vibrating after braking and the boom tip from swinging in the traveling direction y.

The timing of applying the brake is not limited to the elapse of the standby time T1. For example, the rotation speed of each motor 8 or the traveling speed of the traveling device 2 is monitored by a speedometer or the like, and when the rotation speed of all the motors 8 becomes 0 or the traveling speed of the traveling device 2 becomes 0 m / min. Occasionally, the brake device 9 may be activated. According to this configuration, the traveling device 2 can be fixed by the brake when the traveling direction y of the traveling device 2 is not deviated and each traveling device 2 is stopped. Therefore, the brake is applied after the strain of the crane structure 3 is completely released, which is advantageous for suppressing the vibration of the quay crane 1 after stopping.

According to the present invention, it is possible to prevent the crane structure from being distorted and vibrating when the crane 1 is running and stopped, so that the boom tip hardly swings during the standby time T1. Therefore, even during the standby time T1, the driver can align the container to be handled and the boom 4, and can proceed with preparations for starting the cargo handling work even before the brake is applied. This is advantageous for improving cargo handling efficiency because it eliminates the need for waiting time for the boom to subside.

Even in a quay crane that employs a boom with a monobox structure for weight reduction, the shaking of the boom tip can be significantly suppressed by applying the present invention. Further, even when the size of the boom of the quay crane is further increased due to the increase in size, the swing of the boom can be effectively suppressed by applying the present invention.

Anemometers may be installed on the boom 4a or girder 4b. The control mechanism 14 can be configured to correct the displacement direction and the displacement amount of the boom 4a based on the wind direction and the wind speed measured by the anemometer. The boom 4a may be displaced in the traveling direction y due to the influence of the wind. This displacement amount is calculated based on the measured value of the anemometer, and the displacement direction and the displacement amount of the boom 4a measured by the displacement measuring mechanism 13 are corrected. That is, since the influence of the wind can be removed, it is advantageous to accurately return the boom 4a to the initial position.

1 Crane 2 Traveling device 2a Sea side traveling device 2b Land side traveling device 3 Crane structure 3a Leg member 3b Horizontal member 4a Boom 4b Girder 5 Trolley 6 Driver's cab 7 Traveling wheel 8 Motor 9 Brake device 10 Quay 10a Rail 11 Inverter 12 Controller 13 Displacement measurement mechanism 14 Control mechanism

Claims (6)

A sea-side traveling device and a land-side traveling device that are opposed to each other at intervals in a transverse direction that crosses the traveling direction, a crane structure that is supported by the sea-side traveling device and the land-side traveling device, and this crane. It has a boom and girder that is supported by the structure and extends in the transverse direction.
The sea-side traveling device and the land-side traveling device are via a traveling wheel, a motor that transmits power to the traveling wheel, an inverter that is connected to the motor and controls the rotation speed of the motor, and the inverter. In a quay crane having a controller that gives a command of rotational speed to the motor.
Based on a displacement measuring mechanism that measures the displacement direction when the seaside end of the boom is displaced forward or backward in the traveling direction of the quay crane from the initial position, and the displacement direction acquired by this displacement measuring mechanism. It is equipped with a control mechanism that adjusts the rotation speed commanded by the controller to the motor.
Before SL control mechanism, the decrease of the relative speed of the land-side traveling device seaward end of the boom to the rear side of the traveling direction with respect to the sea-side traveling device when displaced, the front of the traveling direction The sea-side traveling device and the sea-side traveling device are provided when the relative speed of the sea-side traveling device is reduced with respect to the land-side traveling device when the sea-side end of the boom is displaced to the side. A quay crane characterized in that it has a configuration in which the land-side traveling device is controlled only in the deceleration direction and not in the acceleration direction . The quay crane according to claim 1, wherein the displacement measuring mechanism comprises an acceleration sensor installed on at least one of the boom or the girder. The quay crane according to claim 2, wherein the acceleration sensor is installed in at least one of the vicinity of the sea side end of the boom and the vicinity of the land side end of the girder. The displacement measuring mechanism is composed of a measurement receiver installed on at least one of the boom or the girder and capable of acquiring position information, and a reference receiver installed on the crane structure and capable of acquiring position information. The quay crane according to claim 1, further comprising a configuration in which the displacement direction of the boom is measured from a relative position of the measurement receiver with respect to the reference receiver. The displacement amount measured by the displacement measuring mechanism, in which the control mechanism measures the rotation speed commanded by the controller to the motor of the sea-side traveling device or the land-side traveling device located on the front side in the traveling direction. The quay crane according to any one of claims 1 to 4, which has a configuration in which the larger the value is, the larger the amount is reduced. A sea-side traveling device and a land-side traveling device that are opposed to each other at intervals in a transverse direction that crosses the traveling direction, a crane structure that is supported by the sea-side traveling device and the land-side traveling device, and this crane. It has a boom and girder that is supported by the structure and extends in the transverse direction.
The sea-side traveling device and the land-side traveling device are via a traveling wheel, a motor that transmits power to the traveling wheel, an inverter that is connected to the motor and controls the rotation speed of the motor, and the inverter. In a method of controlling a quay crane having a controller for giving a command of rotational speed to the motor.
By measuring the displacement direction when the sea-side end portion of the boom is displaced from the initial position to the front side or rear side in the traveling direction of the quay crane, the sea side edge of the boom to the rear side of the front Stories traveling direction part is less let decrease the relative speed of the land-side travel system for the sea-side traveling device when displaced, the land-side traveling device when the sea side end part of the boom on the front side of the advancing direction is displaced It has a configuration little is thereby reduced the relative velocity of the sea-side traveling device for, in the speed increasing direction the sea-side travel apparatus and the land-side traveling device is controlled only in the deceleration direction in reducing the relative velocity Is a method of controlling a quay crane, which is characterized by being uncontrolled.

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