JP6707801B2 - Unloader and unloader control method - Google Patents

Description

The present invention relates to an unloader including four drums and a grab bucket that conveys bulk goods, and a control method for the unloader, and more particularly to an unloader and a control method for the unloader that can move the grab bucket with high accuracy. ..

Various unloaders used when loading bulk cargo such as coal or iron ore from a bulk carrier have been proposed (see, for example, Patent Document 1).

Document 1 connects the ropes respectively unreeled from four drums to a grab bucket (hereinafter sometimes referred to as a bucket), and rotates the four drums in a mutually associated state to move the buckets up and down. , Proposes an unloader for traverse of trolley and opening and closing of bucket.

In the unloader described in Reference 1, for example, when four ropes of the same length are wound up at the same time, the bucket rises and the two drums on the sea side feed the rope, and at the same time, the rope of the same length is landed. When it is wound up with two drums, the trolley runs across to the land.

This unloader moves the bucket and the like by controlling the four drums in a mutually related state.For example, the bucket may be moved due to variations in the performance of the motors connected to the drums and the rope elongation. It may not behave as the crane operator does. That is, the accuracy of operations such as movement of the grab bucket becomes low. In such a case, there is a possibility that a malfunction occurs such that the bucket is unintentionally opened and the transported object leaks and falls.

If you try to perform two or more different operations at the same time, such as moving the bucket up and down and traversing the trolley, it will complicate the control of the number of rotations of the drum, and the effects of errors such as variations in the performance of the motors connected to the drum will increase. Was difficult.

International Publication No. 98/06657

The present invention has been made in view of the above problems, and an object of the present invention is to provide an unloader and a method of controlling the unloader that can move a grab bucket and the like with high accuracy.

The unloader of the present invention which achieves the above-mentioned object, four drums for respectively paying out and winding the rope, four motors respectively connected to the drums, and a calculation mechanism for determining the rotation speed of the motors, In an unloader including four inverters that respectively control the rotation speed of the motor based on the speed determined by this arithmetic mechanism, and a grab bucket suspended by the rope, the motor is connected to each of the inverters. When the inverter is winding the rope, the torque measuring unit that measures the torque generated in the motor connected to the inverter, and the motor connected to the inverter is winding the rope. Is, the larger the absolute value of the actual torque acquired by the torque measuring unit is, the more the rotation speed instructed to the motor from the calculation mechanism is decreased at a large rate, and the motor connected to the inverter causes the rope to be extended. During the operation, the control unit increases the rotation speed commanded by the calculation mechanism to the motor as the absolute value of the actual torque acquired by the torque measurement unit increases.

An unloader control method according to the present invention is provided with four drums that respectively reel out and wind a rope, four motors that are respectively connected to the drums, a calculation mechanism that determines a rotation speed of the motors, and a calculation mechanism. In the control method of the unloader including four inverters that respectively control the rotation speed of the motor based on the speed determined by, and a grab bucket that is suspended by the rope, the motor is connected to each of the inverters. have been, by measuring the torque generated in the motor connected to the inverter, is when the motor connected to the inverter is performing the winding of the rope is connected to the inverter the larger the absolute value of the measured actual torque of the motor to reduce the rotational speed of the motor at a large proportion, the inverter when the motor connected to the inverter is performing the feeding of the ropes are The larger the absolute value of the measured actual torque of the motor connected to the motor, the larger the rotational speed of the motor is controlled to increase.

According to the present invention, the larger the actual torque generated in the motor when the motor is winding the rope, the slower the rope winding speed is, and the actual torque is generated when the motor is unwinding the rope. The larger the value is, the faster the rope can be fed out, so that the rotational speed of each drum is automatically controlled in the direction in which the tension generated in each rope becomes uniform. Therefore, it is advantageous to prevent the grab bucket from being opened unintentionally or the grab bucket or the trolley to move due to variations in the rotation speed of the drum or elongation of the rope.

It is explanatory drawing which illustrates the unloader of this invention. It is explanatory drawing which illustrates the state where the rope of the unloader of FIG. 1 was wound. It is an explanatory view illustrating a circuit for controlling the rotation speed of the drum. It is explanatory drawing which illustrates the open/close state of a grab bucket. It is a graph which illustrates the speed command input by the controller. 3 is a graph illustrating the speed of a rope wound around or unwound on each drum. It is a graph which illustrates the speed change of the rope wound around the land side support drum. It is a graph which illustrates the speed change of the rope wound around the sea side support drum. It is a graph which illustrates the speed change of the rope wound around the land side opening/closing drum. It is a graph which illustrates the speed change of the rope wound by the sea side opening/closing drum. It is explanatory drawing which illustrates the structure of an inverter. It is explanatory drawing which illustrates each distance measured by an encoder.

Hereinafter, an unloader and a control method for the unloader of the present invention will be described based on the embodiment shown in the drawings. In the figure, the traveling direction of the unloader is indicated by an arrow y, the sea-land direction in which the boom of the unloader is extended (hereinafter sometimes referred to as a traverse direction) is indicated by an arrow x, and the vertical direction is indicated by an arrow z.

As illustrated in FIG. 1, an unloader 1 of the present invention includes a leg structure 2, a boom 3 and a girder 4 supported by an upper portion of the leg structure 2 and extending in the sea-land direction x, the boom 3 and The trolley 5 traverses along the girder 4 in the sea-land direction x, and a grab bucket (hereinafter sometimes referred to as a bucket) 6 arranged below the trolley 5.

A machine room 7 is arranged in the leg structure 2, and a drum D around which a rope R is wound is arranged in the machine room 7. The rope R fed from the drum D is connected to the bucket 6 via a sheave S and a trolley 5 which are respectively arranged at the tip of the boom 3 and the rear end of the girder 4. The leg structure 2 is provided with a hopper 9 for receiving the loose load conveyed by the bucket 6.

In the vicinity of the trolley 5, a driver's cab 8 that moves together with the trolley 5 in the transverse direction x is arranged. A controller for a crane operator to operate the unloader 1 is installed in the operator's cab 8.

As illustrated in FIG. 2, in the machine room 7, four drums D on which the ropes R are respectively wound are arranged. The four drums D include a land side support drum D1, a sea side support drum D2, a land side opening/closing drum D3, and a sea side opening/closing drum D4. In the figure, the trolley 5 is indicated by a broken line for the sake of explanation.

In this embodiment, the land-side support rope R1 fed out from the land-side support drum D1 passes through the first sheave S1 arranged at the land-side end of the girder 4 and the sheave S11 arranged at the trolley 5 and then the bucket. 6 is connected to the supporting portion 10. The sea-side support rope R2 fed out from the sea-side support drum D2 passes through the second sheave S2 arranged at the sea-side end of the boom 3 and the sheave S21 arranged at the trolley 5 to support the bucket 10 of the bucket 6. Is linked to.

The land side opening/closing rope R3 fed from the land side opening/closing drum D3 passes through the third sheave S3 arranged at the land side end of the girder 4 and the sheave S31 arranged at the trolley 5 to open/close the bucket 6. It is connected to 11. The sea side opening/closing rope R4 fed from the sea side opening/closing drum D4 passes through the fourth sheave S4 arranged at the sea side end of the boom 3 and the sheave S41 arranged at the trolley 5 to open/close the opening/closing section 11 of the bucket 6. Is linked to.

The arrangement position of the sheave S and the route around which the rope R is wound are not limited to the above. The number of sheaves S may be increased or decreased, or the arrangement position thereof may be changed.

As illustrated in FIG. 3, the four drums D1 to D4 are provided with motors M1 to M4, respectively. The four motors M are AC motors, and the inverters 12 that control the rotation speed of the motor M are connected to the four motors. The motor M is provided with a pulse generator PG for detecting the rotation speed, the rotation direction, and the like. Further, the drum D is provided with an encoder EC such as an absolute encoder that directly or indirectly detects the number of rotations, the rotation direction, and the like. The four inverters 12 are connected to one computing mechanism 13. The arithmetic mechanism 13 is composed of, for example, a PLC (Programmable Logic Controller). A controller 14 arranged in the cab 8 is connected to the arithmetic mechanism 13.

The crane operator in the cab 8 inputs the vertical movement speed Nh (m/min) of the bucket 6, the traverse speed Nt (m/min) of the trolley 5, and the opening/closing speed Nc (m/min) of the bucket 6 by the controller 14. Then, these speed commands are sent to the calculation mechanism 13. The controller 14 is composed of, for example, a tiltable lever or the like, and sends a predetermined speed command to the calculation mechanism 13 in accordance with the tilting direction and angle. The calculation mechanism 13 determines the speed V of the rope R wound around each drum D from the input vertical movement speed Nh, traverse speed Nt, and opening/closing speed Nc based on the following equations (1) to (4).
V1=Nh+Nt−Nc/2. ． ． (1)
V2=Nh-Nt-Nc/2. ． ． (2)
V3=Nh+Nt+Nc/2. ． ． (3)
V4=Nh-Nt+Nc/2. ． ． (4)

Here, V1 (m/min) is the speed at which the land side support rope R1 is wound around the land side support drum D1, and V2 (m/min) is the speed at which the sea side support rope R2 is wound around the sea side support drum D2. , V3 (m/min) is the speed at which the land side opening/closing rope R3 is wound around the land side opening/closing drum D3, and V4 (m/min) is the speed at which the sea side opening/closing rope R4 is wound around the sea side opening/closing drum D4. ing. The vertical moving speed Nh is positive when the bucket 6 moves upward, and the negative moving speed is negative. The transverse speed Nt is positive when the trolley 5 travels to the land side and negative when traveling to the sea side. As for the opening/closing speed Nc, the speed in the closing direction of the bucket 6 is positive and the speed in the opening direction is negative.

In the present specification, the opening/closing speed Nc of the bucket 6 is defined as a relative speed at which the opening/closing ropes R3 and R4 are wound or unwound with respect to the support ropes R1 and R2, as illustrated in FIG. is doing. Therefore, for example, when the ends of the opening/closing ropes R3 and R4 are directly connected to the opening/closing portion 11, the opening/closing speed Nc is a relative speed when the opening/closing portion 11 approaches and separates from the support portion 10. Becomes Further, for example, when a plurality of sheaves acting as moving pulleys are arranged on the support portion 10 and the opening/closing portion 11 and the opening/closing ropes R3 and R4 are wound around the sheaves, 1/N of the opening/closing speed Nc is determined according to the number of moving pulleys. The support portion 10 and the opening/closing portion 11 approach and separate at a speed of 2, 1/4 or the like.

In the formulas (1) to (4), the opening/closing speed Nc of the bucket 6 not including the moving pulley is assumed, but in the case of the bucket 6 including the moving pulley, the opening/closing speed Nc is 1 with respect to the moving speed of the rope R. Since it changes to /2 and 1/4, the coefficient of the opening/closing speed Nc is doubled or quadrupled accordingly.

The speeds V1 to V4 calculated by the calculation mechanism 13 and sent to the inverter 12 are actually converted to the rotation speed of the motor M by the calculation mechanism 13 and then sent to the corresponding inverters 12. The inverter 12 controls the rotation speed of the corresponding motor M independently based on this speed command.

For example, when a speed command to wind the bucket 6 at 50 m/min is sent from the controller 14 to the arithmetic mechanism 13, the vertical movement speed Nh is input to the arithmetic mechanism 13 as +50. When the traverse speed Nt and the opening/closing speed Nc are set to 0, the unloader 1 only winds the bucket 6.

The computing mechanism 13 substitutes Nh=+50 and Nt=Nc=0 into the mathematical expressions (1) to (4) to calculate V1=V2=V3=V4=+50. The four drums D wind up the corresponding ropes R at 50 m/min. Since the four ropes R are wound around the four drums D at the same speed, the bucket 6 moves up at a speed of 50 m/min.

When winding the bucket 6 down, Nh=−50 is substituted into the equations (1) to (4). Since V1=V2=V3=V4=−50, four ropes R are paid out from the four drums D at the same speed, and the bucket 6 descends.

When a speed command to traverse the trolley 5 to the land side at 100 m/min is sent from the controller 14 to the arithmetic mechanism 13, the transverse speed Nt is input to the arithmetic mechanism 13 as +100. When the vertical movement speed Nh and the opening/closing speed Nc are set to 0, the unloader 1 only traverses the trolley 5.

The arithmetic unit 13 substitutes Nt=+100 and Nh=Nc=0 into the mathematical expressions (1) to (4) to calculate V1=V3=+100 and V2=V4=-100. The corresponding ropes R1 and R3 are wound at 100 m/min on the land side support drum D1 and the land side opening/closing drum D3, and the corresponding ropes R2 and R4 are 100 m/min on the sea side support drum D2 and the sea side opening/closing drum D4. As it is extended, the trolley 5 traverses to the land side at a speed of 100 m/min.

When the trolley 5 is made to traverse to the sea side, Nt=-100 is substituted into the mathematical expressions (1) to (4). Since V1=V3=−100 and V2=V4=+100, the ropes R1 and R3 are fed from the land side drums D1 and D3, and the ropes R2 and R4 are wound up by the sea side drums D2 and D4. 5 crosses to the sea side.

When a speed command to close the bucket 6 at 10 m/min is sent from the controller 14 to the calculation mechanism 13, the opening/closing speed Nc is input as +10 to the calculation mechanism 13. When the vertical movement speed Nh and the traverse speed Nt are set to 0, the unloader 1 only opens and closes the bucket 6.

The computing mechanism 13 substitutes Nc=+10 and Nh=Nt=0 into the mathematical expressions (1) to (4) to calculate V1=V2=-5 and V3=V4=+5. The corresponding ropes R1 and R2 are fed at 5 m/min on the land side support drum D1 and the sea side support drum D2, and the corresponding ropes R3 and R4 are wound at 5 m/min on the land side opening/closing drum D3 and the sea side opening/closing drum D4. Taken. Since the support portion 10 of the bucket 6 and the opening/closing portion 11 approach each other at a speed of 10 m/min, the bucket 6 is closed accordingly.

When a speed command for hoisting the bucket 6 at 50 m/min and traversing the trolley 5 to the land side at 100 m/min is simultaneously sent from the controller 14 to the calculation mechanism 13, the calculation mechanism 13 has a vertical movement speed Nh= +50 and traverse speed Nt=+100 are input. When the opening/closing speed Nc=0, the unloader 1 rolls up the bucket 6 and causes the trolley 5 to traverse to the land side.

The computing mechanism 13 substitutes Nh=+50, Nt=+100, and Nc=0 into the formulas (1) to (4) to calculate V1=+150, V2=−50, V3=+150, V4=−50. .. The corresponding ropes R1 and 3 are wound at 150 m/min on the land-side support drum D1 and the land-side opening/closing drum D3, and the corresponding ropes R2 and 4 are at 50 m/min on the sea-side support drum D2 and the sea-side opening/closing drum D4. Be paid out.

When the bucket 6 is unwound at 80 m/min, the trolley 5 is traversed to the sea side at 100 m/min, and a speed command to open the bucket 6 at 20 m/min is simultaneously sent from the controller 14 to the calculation mechanism 13, The vertical movement speed Nh=-80, the traverse speed Nt=-100, and the opening/closing speed Nc=-20 are input to the calculation mechanism 13.

The calculation mechanism 13 calculates V1=-170, V2=+30, V3=-190, and V4=+10 based on the mathematical expressions (1) to (4). On the land side support drum D1, the land side support rope R1 is paid out at 170 m/min, on the sea side support drum D2, the sea side support rope R2 is wound up at 30 m/min, and on the land side open/close drum D3, the land side open/close rope R3. Is wound up at a speed of 190 m/min, and the sea-side opening/closing drum D4 winds up the sea-side opening/closing rope R4 at a speed of 10 m/min.

The winding and unwinding speed of the rope R wound around each drum D is uniquely determined according to a speed command from the controller 14 operated by the crane operator, and each motor M in each inverter 12 is determined according to this speed. Can be controlled independently. Since the rotation speeds of the motors M are controlled independently of each other without being influenced by the other motors M, the vertical movement of the bucket 6, the traverse of the trolley 5, and the opening and closing of the bucket 6 are performed at arbitrary speeds. It is possible to do it in parallel.

Since the motors M do not affect each other, even if there is a variation in performance of the motors M, if the motors M rotate at the rotation speed based on the speed command from the calculation mechanism 13, as a result, the bucket 6 moves. Etc. can be performed accurately.

The crane operator operates the controller 14 as shown in, for example, FIG. In the graph of FIG. 5, the vertical axis represents the speed (m/min) of each operation of the unloader 1, the horizontal axis represents the elapsed time (min), the vertical movement speed Nh is a solid line, the traverse speed Nt is a broken line, and the opening/closing speed Nc. Is indicated by a one-dot chain line.

First, the crane operator inputs into the controller 14 an operation of closing the bucket 6 that has been swung into the hold in the open state. The bucket 6 closes while accelerating according to the opening/closing speed Nc, and then decelerates to a closed state after reaching a constant speed. After that, the crane operator accelerates the bucket 6 accommodating the bulk load to the target height while ascending, and decelerates the bucket 6 as it approaches the target height. At this time, the rising speed of the bucket 6 is controlled according to the vertical movement speed Nh input from the controller 14.

Along with the deceleration of the vertical movement speed Nh, the crane operator then laterally traverses the trolley 5 toward the hopper 9 installed on the leg structure 2 and decelerates as it approaches the hopper 9. At this time, the traverse speed of the trolley 5 is controlled according to the traverse speed Nt input from the controller 14.

The crane operator then opens the bucket 6 and drops the bulk cargo in the bucket 6 into the hopper 9 as the traverse speed Nt is reduced. At this time, the opening speed of the bucket 6 is controlled according to the opening/closing speed Nc input from the controller 14.

After confirming that the bulk cargo in the bucket 6 has fallen into the hopper, the crane operator causes the trolley 5 to traverse to the sea side while the bucket 6 remains open. As the trolley 5 approaches directly above the hold, the bucket 6 is lowered to swing the open bucket 6 into the hold.

In response to the operation of the crane operator illustrated in FIG. 5, the speeds V1 to V4 of the rope R wound around each drum D are controlled as illustrated in FIG. 7 to 10 are graphs showing how the speeds V1 to V4 change.

In the graphs of FIGS. 6 to 10, the vertical axis represents the winding speed (m/min) of the rope R, and the horizontal axis represents the elapsed time (min). The speed V1 is shown by a solid line, the speed V2 is shown by a broken line, the speed V3 is shown by a one-dot chain line, and the speed V4 is shown by a two-dot chain line. The respective speeds V1 to V4 are calculated by the calculation mechanism 13 based on the above-mentioned mathematical expressions (1) to (4), and are determined by the speed command sent from the calculation mechanism 13 to the respective inverters 12.

As illustrated in FIGS. 5 to 10, since the speeds V1 to V4 are uniquely determined according to the input value from the controller 14, no matter what operation the crane operator performs, the intention of the crane operator As described above, the unloader 1 can be operated with high accuracy. It is advantageous to improve cargo handling efficiency.

The controller 14 may be installed outside the unloader 1 and the unloader 1 may be operated remotely. Alternatively, the unloader 1 may be automatically or semi-automatically operated by automatically inputting the speeds Nh, Nt, Nc to the arithmetic mechanism 13 based on a program created in advance.

As illustrated in FIG. 11, the inverter 12 measures the torque generated in the connected motor M, the torque measurement unit 15, and the frequency of electricity sent to the motor M according to the value acquired by the torque measurement unit 15. It may be configured to include a control unit 16 that adjusts. Although FIG. 11 shows one of the four inverters 12 installed in the unloader 1, the other inverters 12 have the same configuration. The signal transmission direction is indicated by a solid arrow, and the electric power supply direction to the motor M is indicated by a dashed arrow.

When the crane operator operates the controller 14, a speed command is sent from the controller 14 to the control unit 16 of each inverter 12 via the calculation mechanism 13. The control unit 16 adjusts the frequency and the like of the electricity supplied from the unloader 1 according to this speed command, and then supplies it to the motor M.

The torque measuring unit 15 of the inverter 12 sequentially measures the torque generated in the motor M (hereinafter sometimes referred to as actual torque) and sends the magnitude (absolute value) of the actual torque to the control unit 16. When the motor M is winding the rope R, the control unit 16 reduces the speed V instructed from the calculation mechanism 13 at a large rate as the actual torque value increases, and the speed decreases to this reduced speed. The control for supplying the corresponding electricity to the motor M is sequentially performed. Further, when the motor M is paying out the rope R, the control unit 16 increases the speed V commanded by the arithmetic mechanism 13 at a large rate as the value of the actual torque increases, and the electric power corresponding thereto is increased. Is sequentially supplied to the motor M. The rate of decreasing or increasing the rotation speed of the motor M with respect to the magnitude of the actual torque is preset in the control unit 16.

The amount (correction amount) for reducing or increasing the actual rotation speed of the motor M in response to the speed command sent from the calculation mechanism 13 to the control unit 16 can be determined based on the mathematical expression P=aT/100, for example. Here, P is a correction amount (%), a is a preset constant, and T is a ratio (%) of the absolute value of the actual torque to the rated torque of the motor M. That is, the correction amount P for decreasing or increasing the speed commanded by the calculation mechanism 13 to the control unit 16 increases in proportion to the absolute value of the actual torque.

A case where the constant a is set to 3, for example, will be described as an example. When the actual torque of the motor M measured by the torque measuring unit 15 at the time of winding the rope R is equal to the rated torque of the motor M (T=100%), the correction amount P is 3% from the above formula, The control unit 16 controls the motor M to a rotation speed that is reduced by 3% from the rotation speed of the motor M converted by the calculation mechanism 13. That is, when the rotation speed command is 100% (rated speed), the actual motor M rotates at 97% of the rated speed, and when the speed command is 50%, it rotates at 47% of the rated speed.

When the actual torque of the motor M is equal to the rated torque of the motor M (T=100%) when the rope R is paid out, the correction amount P is 3% from the above formula, so that the control unit 16 converts the calculation mechanism 13 into a value. The motor M is controlled to a rotation speed increased by 3% from the rotation speed of the motor M. That is, when the rotation speed command is 100% (rated speed), the actual motor M rotates at 103% of the rated speed, and when the speed command is 50%, it rotates at 53% of the rated speed.

When the actual torque of the motor M measured by the torque measuring unit 15 at the time of winding the rope R is 50% of the rated torque (T=50%), the control unit 16 controls the calculation of the motor M by the calculation mechanism 13. The motor M is rotated at a speed obtained by subtracting 1.5% from the rotation speed. That is, when the rotation speed command is 100% (rated speed), the actual motor M rotates at a rotation speed of 98.5% of the rated speed, and when the speed command is 50%, it is 48.5% of the rated speed. Rotate at the rotation speed. When the rope R is being extended, the actual motor M rotates at a rotation speed of 101.5% of the rated speed when the rotation speed command is 100% (rated speed), and the speed command is 50%. The rotation speed is 51.5% of the rated speed.

When the measured actual torque of the motor M is 200% (T=200%) with respect to the rated torque and the rope R is wound, the control unit 16 controls the rotation of the motor M converted by the calculation mechanism 13. The motor M is rotated at a speed reduced by 6.0% from the speed. That is, when the rotation speed command is 100% (rated speed), the actual motor M rotates at 94% of the rated speed, and when the speed command is 50%, it rotates at 44% of the rated speed. To do. When the rope R is being extended, the actual motor M rotates at a rotation speed of 106% of the rated speed when the rotation speed command is 100% (rated speed), and the rated speed is 50% when the rotation speed command is 50%. Rotate at a rotational speed of 56% of speed.

The value of the constant a is not limited to the above, and can be changed as appropriate according to the scale of the unloader 1 and the configuration of the device. The value of the constant a is set within a range of 1 or more and 20 or less, preferably within a range of 2 or more and 6 or less. A knob for changing the constant a may be installed in the controller 14 so that the crane operator can change the constant a at any time.

The correction amount P for increasing/decreasing the rotation speed of the motor M with respect to the magnitude of the actual torque measured by the torque measuring unit 15 is not limited to the above, and the larger the absolute value of the actual torque is, the more the rope R is wound. It suffices if the control unit 16 is set to a state in which the rotation speed is decreased at a large rate and the rotation speed is increased at a large rate at the time of feeding. For example, instead of the above-described mathematical expression for obtaining the correction amount P, a table in which the correction amount P is predetermined may be set according to the ratio of the actual torque to the rated torque of the motor M as illustrated in Table 1. The mathematical expression and the table for determining the rotation speed of the motor M can be stored in the control unit 16, for example.

Each inverter 12 independently performs torque measurement by the torque measurement unit 15 and control of the rotation speed of the motor M by the control unit 16. That is, when torque measurement and control of the rotation speed of the motor M are performed in the present invention, signals are not exchanged between the inverters 12 and between the inverters 12 and the arithmetic mechanism 13 in this regard.

For example, if the sea-side opening/closing rope R4 is loosened when the bucket 6 is wound up, the bucket 6 may unintentionally open. At this time, since the ropes R1 to R3 other than the sea side opening/closing rope R4 support the load of the bucket 6, the tension of the ropes R1 to R3 increases and the actual torque of the motor M corresponding to these ropes R1 to R3 is To increase. Since the motor M is winding the rope R, the larger the value of the actual torque, the more the rotation speed commanded by the arithmetic mechanism 13 to the motor M decreases. That is, the winding speed of the ropes R1 to R3 becomes slower, and the winding speed of the sea side opening/closing rope R4, which is relatively slack, becomes faster. Since the actual torque of the motor M corresponding to the ropes R1 to R3 becomes smaller as the slack of the sea side opening/closing rope R4 becomes smaller, the value of the correction amount P gradually becomes smaller and the winding speed of the ropes R1 to R3 becomes smaller. Is gradually getting faster. That is, since the rotation speeds of the motors M are controlled so that the loads applied to the four ropes R become uniform, it is advantageous to prevent the bucket 6 from unintentionally opening.

Even when the sea-side opening/closing rope R4 is slackened when the bucket 6 is unwound, the tensions of the ropes R1 to R3 similarly increase and the actual torque of the motor M corresponding to these increases. Since the motor M is paying out the rope R, the larger the value of the actual torque, the larger the rotational speed commanded to the motor M from the arithmetic mechanism. That is, the payout speed of the ropes R1 to R3 becomes faster, and the payout speed of the relatively slack sea-side opening/closing rope R4 becomes slower. Since the load applied to the four ropes R becomes uniform, it is possible to avoid the problem that the bucket 6 opens and the loose load falls.

Since the same control as above is performed when the trolley 5 traverses, it is possible to prevent the bucket 6 from unintentionally opening when the trolley 5 traverses. The four motors M are controlled independently of the inverters 12 connected to each other, but as a result, a uniform tension is always generated on the four ropes R. Therefore, even if the bucket 6 tilts and the load concentrates on one of the ropes R, the movement speed of each rope R is automatically controlled in the direction in which the tilt of the bucket 6 is eliminated. You can also

The control units 16 of the four inverters 12 are set so that the same correction amount P is determined for the same actual torque. That is, the four control units 16 store the same formula or the same table that determines the correction amount P.

The present invention is not limited to this. For example, the control unit 16 corresponding to the land-side opening/closing drum D3 and the sea-side opening/closing drum D4 has a configuration in which the correction amount P determined for the same actual torque is smaller. Good. For example, when the tension of the ropes R1 and R2 of the land-side or sea-side support drums D1 and D2 increases when the bucket 6 is wound up, the speed is reduced by 6% with respect to the speed command, and the land-side or sea-side opening/closing drums D3 and D4 When the tensions of the ropes R3 and R4 increase, the speed is reduced by 5% with respect to the speed command.

According to this control, the ropes R3 and R4 of the land-side or land-side opening/closing drums D3 and D4 are controlled in a direction in which the tension is slightly larger than that of the ropes R1 and R2. If the tensions of the ropes R3 and R4 are larger than those of the ropes R1 and R2, the bucket 6 becomes more difficult to open, which is advantageous for avoiding the problem that the bucket 6 is unintentionally opened and the bulk load falls.

The above control is a control for increasing or decreasing the value of the speed command input from the controller 14 and transmitted to the motor M according to the correction amount P. Therefore, when the controller 14 instructs opening/closing of the bucket 6. The bucket 6 is opened and closed according to the instruction. That is, the above control does not prevent the intended opening/closing operation of the bucket 6.

As illustrated in FIG. 12, the encoder EC installed on the drum D may be used to detect the position and opening of the bucket 6. Since the encoder EC can detect the rotation speed and the rotation direction of the drum D, the total length L of the rope R fed from each drum D can be obtained based on the measurement value of the encoder EC. The rope lengths L1 to L4 (m) obtained from each encoder EC are sent to the calculation mechanism 13. The calculation mechanism 13 calculates the position X of the trolley in the transverse direction, the height H of the bucket, and the opening amount C of the bucket 6 from the input rope lengths L1 to L4 based on the following equations (5) to (7).
X=(L1-L2)/2+Xk. ． ． (5)
H=(L1+L2)/2-Xk. ． ． (6)
dC=dL3-dL1. ． ． (7)

Here, L1 to L4 are the total length (m) of the ropes fed from the drums D1 to D4, Xk is the total length (m) of the boom 3 and the girder 4 in the sea-land direction x, and X is the land-side end of the boom and the girder. Section to the trolley 5 (m), H is the vertical distance from the trolley 5 to the bucket 6 (m), dC is the amount of change in the distance between the support portion 10 and the opening/closing portion 11 of the bucket 6 (m). , DL3 and dL1 indicate the amount of change (m) from the initial value of the total length of the land side opening/closing rope R3 and the land side supporting rope R1. In this embodiment, the horizontal distance X indicates the distance from the sea-side end of the drum D to the land-side end of the trolley 5, and the vertical distance H indicates the distance from the lower end surface of the trolley 5 to the upper end surface of the bucket 5. There is.

If L3 and L1 in the state where the bucket 6 is closed are preset as initial values, when the ropes of the same length are fed from the land side opening/closing drum D3 and the land side supporting drum D1, dL3−dL1=0 and the bucket 6 Is kept closed. Further, when the rope R fed from the land side opening/closing drum D3 is shorter than the land side supporting drum D1, the opening/closing section 11 moves toward the supporting section 10 of the bucket 6, so that the bucket 6 is closed. That is, when dC is 0 or less, the bucket 6 is moved in the closing direction or maintained in the closed state.

When the rope R fed from the land side opening/closing drum D3 is longer than the land side supporting drum D1, the opening/closing part 11 moves in a direction away from the supporting part 10 of the bucket 6, so that the bucket 6 opens. At this time, dL3−dL1 becomes larger than 0. Therefore, when C is larger than 0, the bucket 6 is opened.

Even if the controller 14 does not issue an instruction to open the bucket 6, if Cd becomes larger than 0, it is possible to determine that the bucket 6 has started to open and issue an alarm from the arithmetic mechanism 13. This allows the crane operator to quickly know that the bucket 6 is starting to open, and by performing an operation of closing the bucket 6, it is possible to prevent loose loads from falling from the opened bucket 6.

Not limited to the above, when the opening of the bucket 6 is detected, the arithmetic mechanism 13 controls the feeding speed of the opening/closing ropes R3 and R4 by, for example, reducing the speed by 3% with respect to the speed command from the controller 14. The bucket 6 may be automatically closed.

The use of the encoder EC can prevent the bucket 6 from being opened unintentionally, which is advantageous for avoiding the problem of loose loads falling from the bucket 6. Further, since the positions of the trolley 5 and the bucket 6 can be detected, it is advantageous to improve the operation accuracy when the unloader 1 is automatically operated or semi-automatically operated.

In addition to the configuration using the encoder EC, the configuration in which the actual torque of the motor M is measured by the torque measurement unit 15 described above and the rotation speed of the motor M is controlled by the control unit 16 according to this magnitude may be combined. .. Even if the rope R is stretched or the like, the opening of the bucket 6 can be detected from the actual torque of the motor M, which is advantageous for avoiding the unintended opening of the bucket 6.

In the embodiment illustrated in FIG. 12, the four drums D1 to D4 are installed at the land side end of the girder 4, but the present invention is not limited to this, and the girder 4 is displaced from the land side end to the sea side. It is also applicable when four drums D are arranged in the position. In this case, it is necessary to consider the distance from the drum D to the land side end of the girder 4 as a constant.

Further, the mathematical expressions (5) to (7) may be replaced with the following mathematical expressions (8) to (10).
X=(L3-L4)/2+Xk. ． ． (8)
H=(L3+L4)/2-Xk. ． ． (9)
dC=dL4-dL2. ． ． (10)

By the control based on the mathematical formulas (8) to (10), the same effect as the control based on the above mathematical formulas (5) to (7) can be obtained. Further, the accuracy may be verified by comparing the values X, H, and dC obtained from the equations (5) to (7) with the values obtained from the equations (8) to (10). That is, if the value obtained from the equations (5) to (7) is equal to the value obtained from the equations (8) to (10), the value is used as a highly accurate value. Since there is a possibility that elongation has occurred, it may be configured to issue an alarm or the like.

1 unloader 2 leg structure 3 boom 4 girder 5 trolley 6 grab bucket (bucket)
7 Machine room 8 Operator's cab 9 Hopper 10 Supporting part 11 Opening/closing part 12 Inverter 13 Computing mechanism 14 Controller 15 Torque measuring part 16 Control part D Drum D1 Land side supporting drum D2 Sea side supporting drum D3 Land side opening/closing drum D4 Sea side opening/closing drum R rope R1 land side support rope R2 sea side support rope R3 land side opening/closing rope R4 sea side opening/closing rope S sheave S1 first sheave S2 second sheave S3 third sheave S4 fourth sheave S11, S21, S31, S41 sheave M, M1 to M4 Motor PG Pulse generator EC Encoder Nh Vertical movement speed Nt Traverse speed Nc Opening/closing speed V1 to V4 Rope R winding speed X Trolley position H Bucket height dC Bucket opening amount

Claims (6)

Four drums for respectively paying out and winding the rope, four motors respectively connected to the drums, a calculation mechanism for determining the rotation speed of this motor, and the above-mentioned based on the speeds determined by this calculation mechanism. In an unloader including four inverters that respectively control the rotation speed of a motor, and a grab bucket suspended by the rope,
The motor is connected to each of the inverters ,
The inverter, the torque measuring unit for measuring a torque generated in the motor connected to the inverter, the torque measurement in the motor connected to the inverter is performing the winding of the rope When the absolute value of the actual torque acquired by the section is large, the rotation speed commanded to the motor from the arithmetic mechanism is decreased at a large rate, and when the motor connected to this inverter is paying out the rope. An unloader, comprising: a control unit that increases the rotation speed commanded by the arithmetic unit to the motor at a large rate as the absolute value of the actual torque acquired by the torque measurement unit increases. The drum is composed of a pair of opening and closing drums and a pair of support drums,
The control unit of the inverter corresponding to the open/close drum is set to have a smaller rate of decreasing or increasing the rotation speed instructed to the motor from the arithmetic mechanism than the control unit of the inverter corresponding to the support drum. The unloader according to claim 1, which is provided. The drum is composed of a pair of opening and closing drums and a pair of support drums,
The drum is provided with an encoder that directly or indirectly measures the amount of change in the length of the rope unrolled or wound up from the drum,
The grab is based on a comparison between the amount of change in the length of the rope unwound or wound from the support drum and the amount of change in the length of the rope unwound or wound from the open/close drum. The unloader according to claim 1, further comprising a function of determining an open/closed state of the bucket. Four drums for respectively paying out and winding the rope, four motors respectively connected to the drums, a calculation mechanism for determining the rotation speed of this motor, and the above-mentioned based on the speeds determined by this calculation mechanism. In a control method of an unloader comprising four inverters that respectively control the rotation speed of a motor and a grab bucket suspended by the rope,
The motor is connected to each of the inverters,
Measuring the torque generated in the motor connected to the inverter ,
When the motor connected to the inverter is winding the rope, the rotational speed of the motor increases as the absolute value of the actual torque measured by the motor connected to the inverter increases. When the motor connected to the inverter is feeding the rope, the absolute value of the measured actual torque of the motor connected to the inverter increases as the absolute value of the motor increases. A control method for an unloader, characterized by performing control for increasing the rotation speed at a large rate. The drum is composed of a pair of opening and closing drums and a pair of support drums,
The control method of an unloader according to claim 4, wherein the rotation speed of the motor corresponding to the opening/closing drum is decreased or increased at a rate smaller than the rotation speed of the motor corresponding to the support drum. The drum is composed of a pair of opening and closing drums and a pair of support drums,
An encoder that directly or indirectly measures the amount of change in the length of the rope that is unrolled or wound up from the drum is installed on the drum,
The open/closed state of the grab bucket based on a comparison between the amount of change in the length of the rope unrolled or wound from the support drum and the amount of change in the length of the rope unrolled or wound from the open/close drum. The unloader control method according to claim 4 or 5, wherein the determination is made.

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