JPH08295488A - Method and device for controlling floating crane - Google Patents

Abstract

PURPOSE: To keep a relative position in a vertical direction between an article suspended by a wire rope and a water bottom in a constant relation and to facilitate a lifting work and dredging work by a floating crane. CONSTITUTION: Based on a work condition data signal 53 for a work condition setter 39 and a tide data signal 52 from a tide data memory unit 38, a tide level deviation signal 54 is outputted to a controller 42 from a tide data correction computer 40. In which case, an electromagnetic proportional switching valve 32 is switched by means of excitation signals 56a and 56b outputted to solenoids 32a and 32b from the controller 42 to exert a working oil pressure on pilot ports 14a and 14b, and a direction switching valve 14 is switched. This constitution drives a winch drum 2 by a hydraulic motor 10 and unwinds or winds a wire rope 6 suspended from the boom 5 of a floating crane according to the change of a tide level.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floating crane control method and a floating crane control device.

[0002]

2. Description of the Related Art FIG. 4 shows an example of a floating crane. The floating crane is a floating ship 3 which is installed on a deck 1a of the floating ship 1 and has a winch drum 2 therein. And a boom 5 that is undulated with respect to the pedestal 1 having a base end pivotally supported by the revolving structure 3 and bearing sheaves 4a, 4b, 4c at the tip end, and a wire rope 6 extended from the winch drum 2. The sheave 4a at the tip of the boom 5,
The wire rope 6 hanging from the sheave 4b is wound around the sheave 8b and the boom 5b.
The wire rope 6 is wound around the sheave 4c at the tip end of the wire rope 6, and the tip end of the wire rope 6 is locked to the tip end of the boom 5.

FIG. 3 shows an example of a hydraulic circuit of a floating crane. This hydraulic circuit has a hydraulic motor 10 for driving the winch drum 2 via a speed reducer 9, a main hydraulic pump 11, and a pilot hydraulic pump 12. , Hydraulic oil tank 1
3, a directional control valve 14, and a remote control valve 15.

The main hydraulic pump 11 and the pilot hydraulic pump 12 are configured to be driven by the same engine 16.

The suction port of the main hydraulic pump 11 is connected to the downstream end of a pipe line 17 whose upstream end communicates with the hydraulic oil tank 13, and the discharge port of the main hydraulic pump 11 is connected to a check valve 18.
One end of a pipe line 19 having is connected.

At the suction port of the pilot hydraulic pump 12,
An upstream end is connected to a downstream end of a pipe 20 communicating with the hydraulic oil tank 13, and an outlet of the pilot hydraulic pump 12 is connected to one end of a pipe 21.

Further, the relief valve 2 is provided in a portion of the pipeline 19 on the downstream side of the portion where the check valve 18 is provided.
2 is connected to the upstream end of a pipe line 23 having a downstream end communicating with the hydraulic oil tank 13, and a relief valve 24 is provided at an intermediate portion of the pipe line 21 and the downstream end is the hydraulic oil. The upstream end of the pipe 25 communicating with the tank 13 is connected.

The direction switching valve (pilot pressure switching type 3-position 4-port switching valve) 14 is one pilot port 1
When fluid pressure is applied to 4a, the spool moves so that one of the switching ports communicates with the inlet port and the other of the switching ports communicates with the outlet port, and the fluid pressure is applied to the other pilot port 14b. When applied, the spool moves so that the other switching port communicates with the inlet port and one switching port communicates with the outlet port, and further,
When the fluid pressure is not applied to either of the pilot ports 14a and 14b, the spool holds the neutral position so that the ports do not communicate with each other.

The other end of the pipe 19 is connected to the inlet port of the direction switching valve 14, and the outlet port of the direction switching valve 14 has a downstream end communicating with the hydraulic oil tank 13. The upstream end of is connected.

At one switching port of the directional control valve 14,
The other end of the pipe line 27, one end of which communicates with one of the oil supply and drain ports of the hydraulic motor 10, is connected, and the directional control valve 1
The other switching port of 4 has one end of the hydraulic motor 1 described above.
The other end of the conduit 28 that communicates with the other 0 oil supply / drainage port is connected.

The remote control valve (manual switching type 3-position 4-port switching valve) 15 is a revolving unit 3 (see FIG. 4).
When the operation lever 15a installed inside the cockpit of the vehicle is tilted in one direction by manual operation, one of the switching ports communicates with the inlet port, and the operation lever 15a is tilted in the other direction by manual operation. In this case, the other switching port communicates with the inlet port, and when the operating lever 15a is in the neutral state, both switching ports communicate with the outlet port.

The other end of the pipe 21 is connected to the inlet port of the remote control valve 15, and the outlet port of the remote control valve 15 has a pipe 29 whose downstream end communicates with the hydraulic oil tank 13. The upstream end of is connected.

One end of the remote control valve 15 is connected to the other end of the pipe 30 whose one end communicates with one pilot port 14a of the directional control valve 14, and the other end of the remote control valve 15 is connected. The other end of the conduit 31 whose one end communicates with the other pilot port 14b of the directional switching valve 14 is connected to the other switching port.

In the floating crane having the above structure,
When the driver tilts the operation lever 15a in one direction to bring the inlet port of the remote control valve 15 into communication with one of the switching ports, the fluid pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 is changed to the conduit 21, The spool is moved to the one pilot port 14a via the remote control valve 15 and the pipe 30, and the spool moves so that the inlet port of the direction switching valve 14 communicates with one switching port and the outlet port communicates with the other port. .

When the spool of the directional control valve 14 moves as described above, the hydraulic oil that the main hydraulic pump 11 sucks from the hydraulic oil tank 13 and discharges is the conduit 19 and the directional control valve 1.
4, the hydraulic oil is supplied to the hydraulic motor 10 from one of the oil supply / exhaust oil ports via the pipe line 27 and is discharged from the other oil supply / exhaust oil port of the hydraulic motor 10 to the pipe line 28, the direction switching valve 14, The oil is collected in the hydraulic oil tank 13 via the pipe line 26, whereby the hydraulic motor 10 rotates the winch drum 2 in the direction in which the wire rope 6 is paid out, and the hook block 7 descends.

When the driver tilts the operation lever 15a in the other direction so that the inlet port of the remote control valve 15 communicates with the other switching port, the fluid pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 is increased. Is applied to the other pilot port 14b via the pipe 21, the remote control valve 15 and the pipe 31, and the directional control valve 1
The spool moves such that the inlet port of No. 4 communicates with the other switching port and one port communicates with the outlet port.

When the spool of the directional control valve 14 moves as described above, the hydraulic oil that the main hydraulic pump 11 sucks from the hydraulic oil tank 13 and discharges is the pipe line 19 and the directional control valve 1.
4, the hydraulic oil supplied to the hydraulic motor 10 from one of the oil supply / exhaust ports via the pipe 28 and discharged from the other oil supply / exhaust port of the hydraulic motor 10 is supplied to the pipe 27, the direction switching valve 14, The oil is collected in the hydraulic oil tank 13 via the pipe line 26, whereby the hydraulic motor 10 rotates the winch drum 2 in the direction in which the wire rope 6 is wound up, and the hook block 7 rises.

As described above, in the floating crane shown in FIGS. 3 and 4, the operator tilts the operation lever 15a to move the hook block 7 up and down, and the structure lifted by the hook block 7 is lifted. It is designed to work.

The floating crane is also used for dredging work for excavating the water bottom by mounting a clamshell bucket (not shown) on the wire rope 6 instead of the hook block 7.

[0020]

However, when the pontoon 1 floating on the water is affected by waves, the floating crane oscillates vertically in a cycle of several seconds to several tens of seconds.

When the floating crane is swinging up and down under the influence of the waves in this way and the rocking work of the structure is attempted, the structure locked by the hook block 7 is moved to the bottom of the water. It becomes difficult to accurately position it in a predetermined place such as a pier or a quay.

Further, since the pontoon 1 floating on the water is affected by the tide, the vertical position of the floating crane with respect to the water bottom and the quay changes in a cycle of about one day.

For this reason, when the descent amount of the clamshell bucket is set to a constant value and the automatic dredging work for excavating the water bottom is performed so that the raising and lowering operations and the opening and closing operations of the clamshell bucket are automatically performed. , Irrespective of whether or not the pontoon 1 is affected by waves, the watchman measures the water depth with a sounding instrument every predetermined time and adjusts the descent amount of the clamshell bucket based on the water depth, or
A watchman measures the amount of elevation of the pontoon 1 with respect to the reference member installed on the quay with a surveying instrument at predetermined time intervals, and adjusts the amount of descent of the clamshell bucket based on the amount of elevation.

The present invention has been made in view of the above situation, and an object of the present invention is to make it possible to easily carry out lifting work and dredging work by a floating crane regardless of the change in tide.

[0025]

In order to achieve the above object, in the control method for a floating crane according to the present invention, when a work is carried out by suspending an article on a wire rope suspended from a boom of the floating crane, The change in tide level at the working position of the crane is grasped in advance, and the wire rope that suspends the article is unrolled or wound so that the relative position in the vertical direction between the water bottom and the article is kept constant based on the tide level change. take.

In addition to the wire rope unwinding or winding operation based on the above-mentioned tide level change, the acceleration acting on the boom due to the floating crane swinging up and down is detected, and the acceleration in the vertical direction of the boom is detected from the acceleration. The amount of displacement is obtained, and the wire rope that suspends the article is unrolled or wound up so that the relative position between the water bottom and the article in the vertical direction is kept constant based on the amount of displacement and the tide level change.

In order to control the floating crane based only on the tide change described above, the winch drum having the wire suspended from the boom of the floating crane and having the article suspended at the tip is driven. A hydraulic motor, a directional switching valve of a pilot pressure switching system for switching the direction of operating hydraulic pressure applied to the hydraulic motor, an electromagnetic proportional switching valve for switching the direction of pilot hydraulic pressure applied to the directional switching valve, and tidal data. Output as a tidal data signal, a work condition setting device that outputs work condition data as a work condition data signal, and a work condition data signal output from the work condition setting device and a tidal data storage device The deviation between the standard tide level and the current tide level at the working position of the floating crane based on the tidal data signal And a tidal data correction calculator that outputs a tidal deviation signal, a tilt angle detector that outputs a speed signal according to the tilt angle of the operating lever, and a speed signal and tidal data correction that are output from the tilt angle detector. It is preferable to use a control device provided with a controller that outputs an excitation signal to the solenoid of the electromagnetic proportional switching valve based on each of the tidal level deviation signals output from the computing unit.

In order to control the floating crane on the basis of the change in tide level and the acceleration acting on the boom, a winch in which an article is suspended at the tip and a wire rope hanging from the boom of the floating crane is wound. A hydraulic motor for driving the drum, a directional switching valve of a pilot pressure switching system for switching the direction of operating hydraulic pressure applied to the hydraulic motor, and an electromagnetic proportional switching valve for switching the direction of pilot hydraulic pressure applied to the directional switching valve. , A tidal data storage device that outputs tidal data as a tidal data signal, a working condition setting device that outputs working condition data as a working condition data signal, and a working condition data signal and tidal data storage that is output from the working condition setting device Based on the tide data signal output from the vessel, the standard tide level and Tidal data correction calculator that calculates the deviation from the tide level of the point and outputs a tide deviation signal, an acceleration detector that detects the vertical acceleration acting on the boom of the floating crane, and an acceleration output from the acceleration detector. A displacement prediction calculator that converts a detection signal into a displacement prediction signal, a tilt angle detector that outputs a speed signal corresponding to the tilt angle of the operating lever, and a speed signal output from the tilt angle detector,
A controller provided with a controller that outputs an excitation signal to the solenoid of the solenoid proportional switching valve based on the tidal level deviation signal output from the tidal data correction calculator and the displacement prediction signal output from the displacement prediction calculator Is desirable.

[0029]

In the control method for the floating crane of the present invention, based on the tide level change of the working position of the floating crane that is grasped in advance,
The wire rope hung from the boom of the floating crane is paid out or wound up so that the vertical relative position between the article suspended by the wire rope and the bottom of the water is kept constant.

Further, in the control method of the floating crane in which the wire rope is paid out or wound up based on the change in tide level and the acceleration acting on the boom, the vertical displacement of the boom is obtained from the acceleration acting on the boom, and the displacement is calculated. Based on the amount and the tide level change, the wire rope hung from the boom of the floating crane is paid out or wound up, and the vertical position of the article suspended on the wire rope and the bottom of the water is kept constant. So that

In the control device for a floating crane according to the present invention, a tide level deviation signal is output from the tide data correction calculator to the controller based on the work condition data signal of the work condition setting device and the tide data signal of the tide data storage device. Then, the electromagnetic proportional switching valve is switched by the excitation signal output from the controller to the solenoid, and the wire rope hung from the boom of the floating crane is unwound or wound up so that the wire rope is hung on the wire rope. Keep the relative vertical position between the existing article and the bottom of the water constant.

In addition, in the control device for the floating crane having the acceleration detector and the displacement prediction calculator, in addition to the above operation, the displacement prediction calculator outputs the displacement prediction signal based on the acceleration detection signal of the acceleration detector. Is output to the solenoid, the electromagnetic proportional switching valve is switched by the excitation signal output to the solenoid from the controller, and the wire rope hung from the boom of the floating crane is unreeled or wound up, thereby The vertical relative position between the suspended article and the bottom of the water is kept constant.

[0033]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a first embodiment of a control device for a floating crane according to the present invention. In the figure, the same parts as those in the hydraulic circuit of FIG. 3 represent the same parts.

In this embodiment, instead of the remote control valve 15 shown in FIG. 3, an electromagnetic proportional switching valve 32 is used as the switching means of the directional switching valve 14, and the tilt angle detector 3 is used.
3, rotation angle detector 34, acceleration detector 35, elevation angle detector 36, displacement prediction calculator 37, tidal data storage device 3
8, work condition setter 39, tidal data correction calculator 40,
A feeding length setting device 41 and a controller 42 are provided.

The main hydraulic pump 11 and the direction switching valve 1
4, the hydraulic oil supply / discharge system for the hydraulic motor 10 constituted by the conduits 19, 26, 27, 28 is the same as that shown in FIG.

Electromagnetic proportional switching valve (3 position 4 of electromagnetic switching system)
When one solenoid 32a is excited, the spool of the port switching valve 32 moves such that one switching port communicates with the inlet port and the other switching port communicates with the outlet port. When the solenoid 32b is excited, the spool moves so that the other switching port communicates with the inlet port and one switching port communicates with the outlet port, and neither of the solenoids 32a, 32b is excited. In the state, the spool holds the neutral position and the ports are not in communication with each other.

The inlet port of the electromagnetic proportional switching valve 32 is connected to the other end of the pipe line 43 whose one end communicates with the discharge port of the pilot hydraulic pump 12, and the outlet port of the electromagnetic proportional switching valve 32 is connected downstream. An upstream end of a pipe line 44 having an end communicating with the hydraulic oil tank 13 is connected.

One of the switching ports of the electromagnetic proportional switching valve 32 has one end which is one of the pilot ports 1 of the directional switching valve 14.
4a is connected to the other end of the conduit 45, and the other switching port of the electromagnetic proportional switching valve 32 is connected to the other end of the conduit 46 whose one end communicates with the other pilot port 14b of the directional switching valve 14. Are connected.

Further, an upstream end of a pipeline 25 having a relief valve 24 and having a downstream end communicating with the hydraulic oil tank 13 is connected to an intermediate portion of the pipeline 43.

The tilt angle detector 33 includes an operating lever 15a.
Is detected, and a velocity signal 47 having a value proportional to the tilt angle is output.

The rotation angle detector 34 is used for the winch drum 2
Is detected, and a rotation angle detection signal 48 corresponding to the rotation angle is output.

Acceleration detector 35 and elevation angle detector 3
6 are attached to predetermined positions of the boom 5, respectively.

The acceleration detector 35 is used for the ship 1 (see FIG. 4).
The vertical upward and downward accelerations acting on the boom 5 due to the rocking due to the waves are detected and an acceleration detection signal 49 is output.

The elevation angle detector 36 detects the elevation angle of the boom 5 and outputs the elevation angle detection signal 50.

The displacement prediction calculator 37 integrates the acceleration detection signal 49 output from the acceleration detector 35 for detecting the acceleration of the boom 5 in the direction perpendicular to the axis twice with respect to time, and the integrated value X ₀ Is output as a displacement prediction signal 51, which is a value X ₁ that is a value calculated by correction calculation based on the boom depression angle θ determined by the depression angle detection signal 50 output from the depression angle detector 36 (Equation 1 reference).

## EQU1 ## X ₀ .cos θ = X ₁ (1)

The tidal data memory 38 is configured to output the tidal data (the tidal level data for various conditions such as longitude and latitude, month and day, and time) preset as the tidal data signal 52. .

The work condition setting device 39 is provided with work condition data (latitude and longitude, month and day,
(Time data) is output as the work condition data signal 53.

The tide data correction calculator 40 has a clock mechanism, and based on the work condition data signal 53 output from the work condition setter 39, various conditions (longitude, latitude, month) of the work condition data signal 53. The tide data signal 52 corresponding to the date and time is read from the tide data storage unit 38, the deviation between the standard tide level and the current tide level is obtained, and this deviation is output as the tide level deviation signal 54.

The payout length setting device 41 sets the payout length setting signal 5 to the length of the wire rope 6 to be paid out from the winch drum 2 which is manually set.
It is configured to output as 5.

The controller 42 includes a speed signal 47 output from the tilt angle detector 33 and a rotation angle detector 3
4, a rotation angle detection signal 48, a displacement prediction signal 51 output from the displacement prediction calculator 37, a tide level deviation signal 54 output from the tidal data correction calculator 40, and a payout length setting device 41. An excitation signal 56a for exciting one solenoid 32a of the electromagnetic proportional switching valve 32 and an excitation signal 56b for exciting the other solenoid 32b of the electromagnetic proportional switching valve 32 are output based on the respective feed length setting signals 55.

The operation of this embodiment will be described below.

When performing lifting work or dredging work with the floating crane, the latitude and longitude of the place where the floating crane is located, the date, and the time are input and set in the working condition setter 39 as working condition data. Then, the work condition data signal 53 is output from the work condition setting device 39 to the tide data correction calculator 40.

Further, the length of the wire rope 6 to be paid out from the winch drum 2 at the time of work is input and set in the payout length setting device 41, and the payout length setting signal is sent from the payout length setting device 41 to the controller 42. 55 is output.

The tide data correction calculator 40 is provided with a work condition data signal 5 output from the work condition setter 39.
3, the tidal data signal 52 corresponding to various conditions (longitude and latitude, month, day, time) of the working condition data signal 53 is read from the tidal data storage 38, and the deviation between the standard tidal level and the current tidal level is calculated, This deviation is the tide deviation signal 5
4 and outputs to the controller 42.

If there is a deviation between the standard tide level and the current tide level when performing lifting work or dredging work, the tide level deviation signal 54 is output from the tide data correction computing unit 40 to the controller 42.

For example, assuming that the tide level at the present time is higher than the standard tide level in a state where the floating crane does not swing and the operation lever 15a is set to the neutral position, the controller 42 outputs the tide level deviation signal 54.
Is output to one solenoid 32a, and the spool moves so that one switching port communicates with the inlet port of the electromagnetic proportional switching valve 32.

Due to the movement of the spool, the fluid pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 becomes
3, the solenoid proportional switching valve 32, and a spool 45 which are provided to one pilot port 14a via the pipe 45 so that the inlet port of the directional switching valve 14 communicates with one switching port and the outlet port communicates with the other port. Moves.

When the spool of the directional control valve 14 moves as described above, the hydraulic oil sucked and discharged from the hydraulic oil tank 13 by the main hydraulic pump 11 becomes the conduit 19 and the directional control valve 1.
4, the hydraulic oil is supplied to the hydraulic motor 10 from one of the oil supply / exhaust oil ports via the pipe line 27 and is discharged from the other oil supply / exhaust oil port of the hydraulic motor 10 to the pipe line 28, the direction switching valve 14, The oil is collected in the hydraulic oil tank 13 through the pipe line 26, whereby the hydraulic motor 10 rotates the winch drum 2 in the direction of feeding the wire rope 6, and the hook block 7 moves to the boom 5 at the standard tide level and the current tide level. It falls by the deviation of.

At this time, the controller 42, based on the rotation angle detection signal 48 from the rotation angle detector 34 and the tide level deviation signal 54 from the tide data correction calculator 40, detects the current value of the excitation signal 56a to the solenoid 32a and Adjust the output time.

Further, in a state where the floating crane does not swing and the operation lever 15a is set to the neutral position,
Assuming that the current tide level is lower than the standard tide level, the controller 42 outputs an excitation signal 56b based on the tide level deviation signal 54 to the other solenoid 32b, and the other switching to the inlet port of the electromagnetic proportional switching valve 32. The spool moves so that the ports are in communication.

Due to this movement of the spool, the fluid pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 becomes
3, the solenoid proportional switching valve 32, and the spool which is provided to the other pilot port 14b via the pipe line 46 so that the inlet port of the directional switching valve 14 communicates with the other switching port and one port communicates with the outlet port. Moves.

When the spool of the directional control valve 14 moves as described above, the hydraulic oil that the main hydraulic pump 11 sucks from the hydraulic oil tank 13 and discharges is the conduit 19 and the directional control valve 1.
4, the hydraulic oil is supplied to the hydraulic motor 10 from the other oil supply / exhaust port via the pipe line 28 and is discharged from one of the oil supply / exhaust oil port of the hydraulic motor 10 to the pipe line 27, the direction switching valve 14, The oil is collected in the hydraulic oil tank 13 via the pipe line 26, whereby the hydraulic motor 10 rotates the winch drum 2 in the direction in which the wire rope 6 is wound, and the hook block 7 causes the boom 5 to reach the standard tide level and the current tide level. Rises by the amount of deviation from.

At this time, the controller 42, based on the rotation angle detection signal 48 from the rotation angle detector 34 and the tide level deviation signal 54 from the tide data correction calculator 40, detects the current value of the excitation signal 56a to the solenoid 32a and Adjust the output time.

Further, in a state where the floating crane does not swing and the operation lever 15a is set to the neutral position,
When the tide level at the present time is equal to the standard tide level, the tide level deviation signal 54 is not output from the tide data correction calculator 40.

Therefore, from the controller 42 to both the solenoids 32a and 32b, the excitation signal 56a,
Since 56b is not output and hydraulic oil does not flow into the hydraulic motor 10, the hook block 7 does not move up and down with respect to the boom 5.

As described above, in this embodiment, the tide data correction computing unit 40 obtains the work condition data signal 53 output from the work condition setting unit 39 and the tide data signal 52 read from the tide data storage unit 38. Tidal level deviation signal 54
Based on the above, the controller 42 operates the electromagnetic proportional switching valve 32, so that the vertical relative position of the hook block 7 with respect to a fixed object such as the water bottom or the quay can be kept constant regardless of the change in the tide level.

On the other hand, when the lifting or dredging work is performed, when the floating crane swings due to the influence of waves and the vertical acceleration is detected by the acceleration detector 35, the acceleration detector 35 A displacement prediction signal 51 based on the acceleration detection signal 49 and the elevation angle detection signal 50 from the elevation angle detector 36 is output from the displacement prediction calculator 37 to the controller 42.

For example, assuming that the acceleration detector 35 detects an upward acceleration in the vertical direction while the operating lever 15a is set to the neutral position, the excitation signal 56a for correcting the influence of the tide level described above. , 5
In addition to 6b, a displacement prediction signal 51 from the controller 42
Is output to one solenoid 32a, and the spool moves so that one switching port communicates with the inlet port of the electromagnetic proportional switching valve 32.

Due to this movement of the spool, the fluid pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 is applied to one pilot port 14a, and the inlet port of the direction switching valve 14 communicates with the one switching port and the outlet thereof. The spool moves so that the other port communicates with the port.

When the spool of the direction switching valve 14 moves as described above, the hydraulic oil discharged from the main hydraulic pump 11 is supplied to the hydraulic motor 10 from one of the oil supply / exhaust oil ports, which causes the hydraulic motor 10 to move to the wire rope. The winch drum 2 is rotated in the direction in which 6 is extended, and the hook block 7 is lowered by an amount that offsets the amount of upward displacement of the floating crane due to waves relative to the boom 5.

At this time, the controller 42 controls the length of the wire rope 6 fed from the winch drum 2 based on the rotation angle detection signal 48 from the rotation angle detector 34.

If the acceleration detector 35 detects downward acceleration in the vertical direction when the operating lever 15a is set to the neutral position, the excitation signal 56a for correcting the influence of the tide level described above. , 56b
In addition, the controller 42 outputs the excitation signal 56b based on the displacement prediction signal 51 to the other solenoid 32b, and the spool moves so that the other switching port communicates with the inlet port of the electromagnetic proportional switching valve 32.

Due to this movement of the spool, the hydraulic pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 is applied to the other pilot port 14a, and the inlet port of the direction switching valve 14 communicates with the other switching port and the outlet. The spool moves so that one port communicates with the other port.

When the spool of the direction switching valve 14 moves as described above, the hydraulic oil discharged from the main hydraulic pump 11 is supplied to the hydraulic motor 10 from one of the oil supply / exhaust oil ports, which causes the hydraulic motor 10 to move to the wire rope. The winch drum 2 is rotated in a direction in which the hook 6 is wound up, and the hook block 7 is raised by an amount that offsets the amount of downward displacement of the floating crane due to waves relative to the boom 5.

At this time, the controller 42 controls the length of the wire rope 6 fed from the winch drum 2 based on the rotation angle detection signal 48 from the rotation angle detector 34.

As described above, in this embodiment, based on the displacement prediction signal 51 obtained by the displacement prediction calculator 37 from the acceleration detection signal 49 of the acceleration detector 35 and the elevation / depression angle detection signal 50 of the elevation / depression angle detector 36. Since the controller 42 operates the electromagnetic proportional switching valve 32, the vertical relative position of the hook block 7 with respect to a fixed object such as the water bottom or the quay can be kept constant regardless of the presence or absence of waves.

Further, when the driver tilts the operating lever 15a in one direction when performing the lifting work or the dredging work, the speed signal 47 having a value proportional to the tilting angle of the operating lever 15a is displayed. It is output from the detector 33 to the controller 42.

When the velocity signal 47 is output, in addition to the excitation signals 56a and 56b for correcting the influence of the tide level and the signals 56a and 56b for correcting the influence of the wave described above, one of the signals from the controller 42 is output. The excitation signal 56a is output to the solenoid 32a of the
The spool moves so that one of the switching ports communicates with the inlet port of.

Due to this movement of the spool, the fluid pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 is applied to one pilot port 14a, and the inlet port of the directional switching valve 14 communicates with the one switching port and the outlet. The spool moves so that the other port communicates with the port.

When the spool of the directional control valve 14 moves as described above, the hydraulic oil discharged from the main hydraulic pump 11 is supplied to the hydraulic motor 10 from one of the oil supply / exhaust ports, which causes the hydraulic motor 10 to move to the wire rope. The winch drum 2 is rotated in the direction in which the hook 6 is extended, and the hook block 7 descends with respect to the boom 5 at a speed according to the tilt amount of the operation lever 15a.

At this time, the controller 42, based on the rotation angle detection signal 48 from the rotation angle detector 34 and the feeding length setting signal 55 from the feeding length setting device 41, sends the wire rope 6 fed from the winch drum 2.
Control the length of.

When the driver tilts the operation lever 15a to the other side, a speed signal 47 having a value proportional to the tilt angle of the operation lever 15a is output from the tilt angle detector 33 to the controller 42.

When the velocity signal 47 is output, in addition to the excitation signals 56a and 56b for correcting the influence of the tidal level and the signals 56a and 56b for correcting the influence of the wave described above, the controller 42 outputs the other signal. The excitation signal 56b is output to the solenoid 32b of the electromagnetic proportional switching valve 32.
The spool moves so that the other switching port communicates with the inlet port of.

Due to this movement of the spool, the hydraulic pressure of the hydraulic oil discharged from the pilot hydraulic pump 12 is applied to the other pilot port 14b, and the inlet port of the directional switching valve 14 communicates with the other switching port and the outlet. The spool moves so that one port communicates with the other port.

When the spool of the directional control valve 14 moves as described above, the hydraulic oil discharged by the main hydraulic pump 11 is supplied to the hydraulic motor 10 from the other oil supply / discharge port, which causes the hydraulic motor 10 to move to the wire rope. The winch drum 2 is rotated in the direction in which 6 is wound, and the hook block 7 is raised with respect to the boom 5 at a speed according to the tilt amount of the operation lever 15a.

At this time, the controller 42, based on the rotation angle detection signal 48 from the rotation angle detector 34 and the feeding length setting signal 55 from the feeding length setting device 41, sends the wire rope 6 fed from the winch drum 2.
Control the length of.

FIG. 2 shows a second embodiment of the control device for a floating crane according to the present invention. In the figure, the same symbols as those of the control device for the floating crane in FIG. 1 or the hydraulic circuit in FIG. 3 are attached. The parts represent the same thing.

In this embodiment, in the hydraulic circuit shown in FIG. 3, the electromagnetic proportional switching valve 32, the tilt angle detector 33, the rotation angle detector 34, and the like as in the embodiment shown in FIG.
Acceleration detector 35, elevation angle detector 36, displacement prediction calculator 37, tidal data storage 38, work condition setter 39,
Tide data correction calculator 40, feeding length setting device 41,
A controller 42 is added.

The main hydraulic pump 11 and the direction switching valve 1
4, the hydraulic oil supply / discharge system for the hydraulic motor 10 constituted by the pipelines 19, 26, 27, 28 is the same as that shown in FIG. 3, and the pilot hydraulic pump 12, the pipeline 21, The system for supplying and discharging hydraulic oil to the remote control valve 15 constituted by 25 and 29 is the same as that shown in FIG.

The remote control valve 15 has one switching port connected to the other end of a pipeline 58 having an opening / closing valve 57 and one end of which communicates with one pilot port 14a of the directional switching valve 14 described above. The other switching port of the remote control valve 15 is connected to the other end of a pipeline 60 having an opening / closing valve 59 and having one end communicating with the other pilot port 14b of the directional switching valve 14.

The inlet port of the electromagnetic proportional switching valve 32 communicates with the discharge port of the pilot hydraulic pump 12 via the conduit 43, whereby both the remote control valve 15 and the electromagnetic proportional switching valve 32 are connected. Further, the hydraulic oil discharged by the pilot hydraulic pump 12 is supplied.

One end of a conduit 62 having an opening / closing valve 61 is connected to one switching port of the electromagnetic proportional switching valve 32, and an opening / closing valve 63 is provided at the other switching port of the electromagnetic proportional switching valve 32. One end of the pipeline 64 is connected.

The other end of the conduit 62 is located at the pilot port 1 rather than the portion of the conduit 58 where the on-off valve 57 is provided.
4a, and the other end of the conduit 64 is
The conduit 60 is connected to a portion closer to the pilot port 14b than the portion where the on-off valve 59 is provided.

The operation of this embodiment will be described below.

When performing lifting work or dredging work with the floating crane, the vertical relative position of the hook block 7 with respect to a fixed object such as the bottom of the water or the quay is kept constant regardless of the change in tide level and the influence of waves. When performing control, the on-off valves 57 and 59 of the pipelines 58 and 60 are closed,
Further, the on-off valves 61, 63 of the pipelines 62, 64 are opened.

In this way, each on-off valve 57, 59, 61, 6
3 is set, the switching port of the remote control valve 15 and the pilot ports 14a, 14 of the direction switching valve 14 are set.
The communication with b is cut off, and the solenoid proportional switching valve 32
Switching port and the pilot ports 14a, 14b
And are in communication.

That is, when the operation lever 15a is tilted, only the speed signal 47 is output from the tilt angle detector 33, and the operating oil pressure is not applied from the remote control valve 15 to the pilot ports 14a and 14b, and the speed is reduced. Signal 47, rotation angle detection signal 48, acceleration detection signal 4
9, excitation signals 56a, 5 output from the controller 42 to the solenoids 32a, 32b based on the elevation angle detection signal 50, the displacement prediction signal 51, and the tidal level deviation signal 54.
By switching the electromagnetic proportional switching valve 32 by 6b, an operating hydraulic pressure is applied to the pilot ports 14a, 14b, and the vertical relative position of the hook block 7 with respect to a fixed object such as a water bottom or a quay is influenced by a change in tide level or waves. It is kept constant regardless of.

On the other hand, when performing the lifting work or the dredging work, if the control for keeping the relative position of the hook block 7 in the vertical direction relative to the fixed object such as the water bottom or the quay constant is not performed, the pipe 58, The on-off valves 57 and 59 of 60 are opened, and the on-off valves 61 and 63 of the pipelines 62 and 64 are closed.

In this way, each on-off valve 57, 59, 61, 6
3 is set, the switching port of the remote control valve 15 and the pilot ports 14a, 14 of the direction switching valve 14 are set.
While communicating with b, the communication between the switching port of the electromagnetic proportional switching valve 32 and the pilot ports 14a and 14b is cut off.

That is, even if the controller 42 outputs the excitation signals 56a and 56b to the solenoids 32a and 32b, the hydraulic oil is not supplied from the electromagnetic proportional switching valve 32 to the pilot ports 14a and 14b, and the operating lever Remote control valve 15 with tilting of 15a
By switching the pilot port 14
A hydraulic pressure is applied to a and 14b, and the hook block 7 moves up and down only by tilting the operation lever 15a.

Control for raising and lowering the hook block 7 only by tilting the operating lever 15a without keeping the vertical direction of the hook block 7 relative to the fixed object is performed by loading and unloading cargo with respect to other ships by a floating crane. Suitable for

The control method for the floating crane and the control device for the floating crane according to the present invention are not limited to the above-mentioned embodiments, and various modifications can be made without departing from the scope of the present invention. Is.

[0104]

As described above, according to the control method of the floating crane and the control device of the floating crane of the present invention, various excellent operational effects as described below can be obtained.

(1) In the control method for a floating crane according to claim 1 of the present invention, the wire rope hung from the boom of the floating crane is fed out based on the change in the tidal level of the working position of the floating crane that is grasped in advance. Alternatively, since it is wound up, the relative position in the vertical direction between the article suspended on the wire rope and the water bottom can be kept constant regardless of the change in the tide level.

(2) In the control method for a floating crane according to claim 2 of the present invention, the vertical displacement of the boom is determined from the acceleration acting on the boom, and the displacement and the work of the floating crane that is previously known. Since the wire rope suspended from the boom of the floating crane is paid out or wound up based on the change in the tide level of the position, the relative position in the vertical direction between the article suspended on the wire rope and the water bottom is determined by the change in the tide level and the wave Can be kept constant regardless of the effect of.

(3) In the control device for a floating crane according to claim 3 of the present invention, the electromagnetic proportional switching valve is switched by the excitation signal output by the controller based on the tidal level deviation signal from the tidal data correction calculator. The vertical position of the article suspended on the wire rope and the bottom of the water can be kept constant regardless of the change in the tide level, and the lifting work and dredging work by the floating crane can be easily performed.

(4) In the control device for a floating crane according to claim 4 of the present invention, the excitation output by the controller based on the tide level deviation signal from the tidal data correction calculator and the displacement prediction signal from the displacement prediction calculator. Since the electromagnetic proportional switching valve is switched by a signal, the vertical relative position between the article suspended on the wire rope and the bottom of the water can be kept constant regardless of the change in tide level and the influence of waves, and the floating crane can Lifting work and dredging work can be performed easily.

[Brief description of drawings]

FIG. 1 is a conceptual diagram showing a first embodiment of a control device for a floating crane according to the present invention.

FIG. 2 is a conceptual diagram showing a second embodiment of the control device for the floating crane of the present invention.

FIG. 3 is a conceptual diagram showing an example of a hydraulic circuit of a winch of a floating crane.

FIG. 4 is an overall view showing an example of a floating crane.

[Explanation of symbols]

 2 Winch drum 5 Boom 6 Wire rope 7 Hook block (article) 10 Hydraulic motor 14 Directional switching valve 15a Operation lever 32 Electromagnetic proportional switching valve 32a Solenoid 32b Solenoid 33 Tilt angle detector 35 Acceleration detector 37 Displacement prediction calculator 38 Tidal data Storage device 39 Working condition setting device 40 Tidal data correction calculator 42 Controller 47 Speed signal 49 Acceleration detection signal 51 Displacement prediction signal 52 Tidal data signal 53 Working condition data signal 54 Tidal level deviation signal 56a Excitation signal 56b Excitation signal

Claims (4)

[Claims] 1. When suspending an article on a wire rope suspended from a boom of a floating crane to perform work, the tidal level change of the working position of the floating crane is grasped in advance, and the water bottom is determined based on the tidal level change. A method for controlling a floating crane, which comprises paying out or winding up a wire rope that suspends an article so that a relative position in the vertical direction with the article is kept constant. 2. The floating crane swings up and down by grasping beforehand the change in the tide level of the working position of the floating crane when the work is suspended from the wire rope suspended from the boom of the floating crane. By detecting the acceleration acting on the boom, the vertical displacement of the boom is obtained from the acceleration, and the vertical relative position between the water bottom and the article is kept constant based on the displacement and the tide level change. A method for controlling a floating crane, which comprises feeding out or winding up a wire rope that suspends an article as described above. 3. A hydraulic motor for driving a winch drum having an end portion on which an article is suspended and a wire rope hanging from a boom of a floating crane is wound, and a direction of an operating hydraulic pressure applied to the hydraulic motor is switched. Pilot pressure switching type directional control valve, electromagnetic proportional switching valve that switches the direction of pilot hydraulic pressure applied to the directional control valve, tidal data memory that outputs tidal data as tidal data signal, and working condition data Based on the work condition setter that outputs as a condition data signal, the work condition data signal output from the work condition setter and the tidal data signal output from the tidal data storage device, the standard tide level at the working position of the floating crane and the current A tide data correction calculator that calculates the deviation from the tide and outputs a tide deviation signal,
Electromagnetic proportional switching based on a tilt angle detector that outputs a speed signal corresponding to the tilt angle of the operating lever, a speed signal output from the tilt angle detector, and a tide level deviation signal output from the tidal data correction calculator. A controller for a floating crane, comprising: a controller that outputs an excitation signal to a solenoid of a valve. 4. A hydraulic motor for driving a winch drum, on which a wire rope hanging from a boom of a floating crane is wound, and a direction of an operating hydraulic pressure applied to the hydraulic motor are switched. Pilot pressure switching type directional control valve, electromagnetic proportional switching valve that switches the direction of pilot hydraulic pressure applied to the directional control valve, tidal data memory that outputs tidal data as tidal data signal, and working condition data Based on the work condition setter that outputs as a condition data signal, the work condition data signal output from the work condition setter and the tidal data signal output from the tidal data storage device, the standard tide level at the working position of the floating crane and the current A tide data correction calculator that calculates the deviation from the tide and outputs a tide deviation signal,
An acceleration detector that detects vertical acceleration acting on the boom of a floating crane, a displacement prediction calculator that converts an acceleration detection signal output from the acceleration detector into a displacement prediction signal, and a tilt angle of the operating lever according to the tilt angle. A tilt angle detector that outputs a speed signal, a speed signal output from the tilt angle detector, a tide level deviation signal output from the tidal data correction calculator, and a displacement prediction signal output from the displacement prediction calculator And a controller that outputs an excitation signal to the solenoid of the solenoid proportional switching valve based on the above.