Patent Grant
10894589
The present invention relates to a ship maneuvering system and a ship maneuvering method.
In the prior art, a ship maneuvering system that executes intermittent control during low-speed navigation of a ship is known.
For example, Japanese Patent Application Laid-Open No. 2016-216018 discloses a ship maneuvering system that executes intermittent control with one propulsion device during the low-speed navigation of the ship.
In recent years, a plurality of propulsion devices have been equipped on ships for complying with the speeding-up of ships. Therefore, it is desired to apply the above-described intermittent control technology to a ship equipped with a plurality of propulsion devices.
When all of the plurality of propulsion devices are intermittently controlled at the same time, the plurality of propulsion devices will engage at the same time. Therefore, as the number of propulsion devices increases, the user may feel uncomfortable with sound caused by the plurality of propulsion devices engaging at the same time. Also, when the shift state is switched from the shift-out state to the shift-in state during the intermittent control of the plurality of propulsion devices, the shift mechanism operates to transmit the driving force of the engine to the propeller. In this case, a shift shock and shift noise may occur when the shift mechanism operates.
Preferred embodiments of the present invention provide ship maneuvering systems each capable of suitably reducing sound during intermittent control of a ship, ship maneuvering systems each capable of suitably reducing shift shock and shift noise during intermittent control of a ship, and ship maneuvering methods each capable of suitably reducing the sound, shift shock, and shift noise.
A ship maneuvering system according to a preferred embodiment of the present invention includes a plurality of propulsion devices, a shift actuator, and a controller. The plurality of propulsion devices include a first propulsion device and a second propulsion device. The shift actuator switches a shift state of each of the plurality of propulsion devices. The controller causes the shift actuator to execute intermittent control to intermittently switch the shift state to a shift-in state and a shift-out state. The controller causes the shift actuator of one of the first propulsion device and the second propulsion device to execute the intermittent control during low-speed navigation of the ship.
A ship maneuvering method according to another preferred embodiment of the present invention includes a method executed by a controller to maneuver a ship including a plurality of propulsion devices.
The method includes causing a shift actuator to switch a shift state of each of the plurality of propulsion devices, causing the shift actuator to execute intermittent control to intermittently switch the shift state to a shift-in state and a shift-out state, and causing the shift actuator of one of a first propulsion device and a second propulsion device to execute the intermittent control during low-speed navigation of the ship. The plurality of propulsion devices include the first propulsion device and the second propulsion device.
According to preferred embodiments of the present invention, it is possible to reduce the sound, shift shock, and shift noise during intermittent control of a ship in the ship steering system and the ship steering method.
The above and other elements, features, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments with reference to the attached drawings.
Hereinafter, preferred embodiments will be described with reference to the drawings.
In the following description, the front, rear, left, right, up, and down directions mean the front, rear, left, right, up, and down directions of the ship 1, respectively. For example, a center line C1 extending in the front-rear direction of the ship 1 passes through the center of gravity G of the ship 1. The front-back direction extends along the center line C1. The forward direction heads upward along the center line C1 in
The left-right direction (width direction) is perpendicular to the center line C1 in
As shown in
Specifically, the ship 1 includes a left propulsion device 3a, a right propulsion device 3b, and a middle propulsion device 3c. The left propulsion device 3a and the right propulsion device 3b are examples of “a plurality of first propulsion devices”. The middle propulsion device 3b is an example of “at least one second propulsion device”.
The left propulsion device 3a, the right propulsion device 3b, and the middle propulsion device 3c are disposed side by side in one direction. For example, the left propulsion device 3a, the right propulsion device 3b, and the middle propulsion device 3c are disposed side by side in the width direction (left-right direction) of the ship 1. The middle propulsion device 3 is disposed between the left propulsion device 3a and the right propulsion device 3b.
Specifically, the left propulsion device 3a is disposed on the left side of the center line C1. The right propulsion device 3b is disposed on the right side of the center line C1. The middle propulsion device 3c is disposed between the left propulsion device 3a and the right propulsion device 3b. The middle propulsion device 3c is disposed on the center line C1.
The left propulsion device 3a, the right propulsion device 3b, and the middle propulsion device 3c have the same configuration as each other. Therefore, the propulsion device will be described using the left propulsion device 3a.
The engine 10a is a power source that generates the thrust of the ship 1. The engine 10a is disposed inside the engine cowl 14. The engine 10a includes a crankshaft 17. The crankshaft 17 extends in the vertical direction.
The drive shaft 11 is connected to crankshaft 17. The drive shaft 11 extends downward from the engine 10a. The propeller shaft 12 extends in a direction intersecting the drive shaft 11. The propeller shaft 12 extends in the front-rear direction. The propeller shaft 12 is connected to the drive shaft 11 via a shift mechanism 13. A propeller 18 is connected to the propeller shaft 12.
The housing 15 is disposed below the engine cowl 14. The drive shaft 11, the propeller shaft 12, and the shift mechanism 13 are disposed in a housing 15. The shift mechanism 13 switches the rotation direction of the power transmitted from the drive shaft 11 to the propeller shaft 12.
The shift mechanism 13 includes a forward gear 19, a reverse gear 20, and a clutch 21. The forward gear 19 and the reverse gear 20 mesh with the bevel gear 22. The bevel gear 22 is attached to the drive shaft 11. The clutch 21 selectively engages the forward gear 19 and the reverse gear 20 with the propeller shaft 12. The clutch 21 is able to move between a forward position, a reverse position, and a neutral position.
The clutch 21 engages the forward gear 19 with the propeller shaft 12 in the forward position. Thus, the rotation of the drive shaft 11 is transmitted to the propeller shaft 12, and the propeller shaft 12 rotates in the forward direction.
The clutch 21 engages the reverse gear 20 with the propeller shaft 12 in the reverse position. Thus, the rotation of the drive shaft 11 is transmitted to the propeller shaft 12, and the propeller shaft 12 rotates in the reverse direction.
When the clutch 21 is positioned at the neutral position, the forward gear 19 and the reverse gear 20 are released from the propeller shaft 12. In this case, the rotation of the drive shaft 11 is not transmitted to the propeller shaft 12.
The left propulsion device 3a further includes a shift member 23 and a shift actuator 24a. The shift member 23 is connected to the shift mechanism 13. The shift member 23 operates the shift mechanism 13.
Specifically, the shift member 23 is connected to the clutch 21. The shift member 23 is driven by the shift actuator 24a. Thus, the clutch 21 moves to each of the forward position, the reverse position, and the neutral position.
The shift actuator 24a is connected to the shift member 23. The shift actuator 24a drives the shift member 23. The shift actuator 24a is, for example, an electric motor. The shift actuator 24a switches the clutch 21 to one of the forward position, the reverse position, and the neutral position by driving the shift member 23.
When the clutch 21 is positioned at the forward position and the reverse position, the clutch 21 is in a shift-in state. When the clutch 21 is positioned at the neutral position, the clutch 21 is in a shift-out state. Thus, the shift actuator 24a switches the shift state to one of the shift-in state and the shift-out state via the clutch 21.
The bracket 16 attaches the left propulsion device 3a to the ship 1. The left propulsion device 3 is detachably fixed to the stern of the ship 1 via the bracket 16. The bracket 16 includes a steering shaft 25. The left propulsion device 3a is supported by the bracket 16 so as to rotate around a steering shaft 25.
The ship maneuvering system 2 includes the left propulsion device 3a, the right propulsion device 3b, and the middle propulsion device 3c. As described above, each of the right propulsion device 3b and the middle propulsion device 3c has the same configuration (the configuration in
As shown in
The ship maneuvering system 2 includes a plurality of steering actuators 26a, 26b, 26c. The plurality of steering actuators 26a, 26b, 26c are respectively connected to the left propulsion device 3a, the right propulsion device 3b, and the middle propulsion device 3c.
The steering actuators 26a, 26b, 26c rotate the propulsion devices 3a, 3b, 3c around the steering shaft 25. Thus, the steering actuators 26a, 26b, 26c change the steering angles of the respective propulsion devices 3a, 3b, 3c.
Each of the steering actuators 26a, 26b, 26c includes, for example, a hydraulic cylinder. Each of the steering actuators 26a, 26b, 26c may include an electric cylinder or an electric motor.
The ship maneuvering system 2 further includes a remote control device 30, a steering device 31, and a controller 33.
The remote control device 30 includes a first operation member 34 and a second operation member 35. The first operation member 34 and the second operation member 35 are operated by a user to control the left propulsion device 3a, the right propulsion device 3b, and the middle propulsion device 3c. The remote control device 30 transmits a signal indicating an operation of the first and second operation members 34 and 35 to the controller 33.
Each of the first operation member 34 and the second operation member 35 is, for example, a lever. The first operation member 34 and the second operation member 35 are operable to a forward position, a reverse position, and a neutral position. The first operation member 34 and the second operation member 35 are able to change direction of the thrust of each of the propulsion devices 3a, 3b, 3c and the magnitude of the thrust (a throttle opening).
The steering device 31 is, for example, a steering wheel. The steering device 31 is operated by the user to control the steering angles of the propulsion devices 3a, 3b, 3c. The steering device 31 is operable to a left turning position, a right turning position, and a neutral position. The steering device 31 transmits a signal indicating the position of the steering device 31 to the controller 33.
The controller 33 includes a processor 36 and a memory (an example of a recording portion). The memory 37 includes a volatile memory such as a RAM. The memory 37 includes a nonvolatile memory such as a ROM. The controller 33 may include an auxiliary storage device such as a hard disk and/or an SSD. Further, an external storage device (not illustrated) such as a hard disk and/or an SSD (not illustrated) may be connected to the controller 33.
The processor 36 is, for example, a CPU (Central Processing Unit), and executes processes to control the propulsion devices 3a, 3b, 3c and the steering actuators 26a, 26b, 26c according to a program.
The memory 37 stores programs and data to control the propulsion devices 3a, 3b, 3c and the steering actuators 26a, 26b, 26c.
The memory 37 stores a duty ratio. The duty ratio is the ratio (TI/TO×100) of the shift-in time TI to the shift-out time TO. For example, the duty ratio is used during execution of the intermittent control. The memory 37 stores the duty ratio as an initial value. The memory 37 stores the duty ratio that changes during the intermittent control.
The memory 37 stores a first threshold and a second threshold. The first threshold and the second threshold are used to control the shift actuators 24a, 24b, 24c. The first threshold is larger than the second threshold. In the present preferred embodiment, for example, the first threshold is set to 50%. For example, the second threshold is set to 30%.
The memory 37 stores a target speed which is set when the ship 1 is traveling during a low-speed navigation of the ship 1. The preset target speed may be stored in the memory 37, or the target speed may be stored in the memory 37 by the user inputting the target speed to an input device (not illustrated).
The memory 37 stores the actual speed of the ship 1 during low-speed navigation of the ship 1. The actual speed of the ship 1 may be acquired from a GPS (Global Positioning System) or the like, or may be acquired from a speed detector (not illustrated) mounted on the ship 1.
The controller 33 controls the propulsion devices 3a, 3b, 3c and the steering actuators 26a, 26b, 26c based on the signals from the steering device 31 and the remote control device 30.
Specifically, the controller 33 controls the direction and the magnitude of the thrust of the propulsion devices 3a, 3b, 3c according to the positions of the first and second operation members 34, 35. For example, the controller 33 controls the magnitude of the thrust of each of the left propulsion device 3a, the right propulsion device 3b, and the middle propulsion device 3c by controlling the throttle opening of each of the engines 10a, 10b, 10c.
The controller 33 controls the shift actuators 24a, 24b, 24c according to the positions of the first and second operation members 34, 35. Thus, the clutch 21 of the shift mechanism 13 is switched to one of the forward position, the reverse position, and the neutral position. As a result, the thrusts of the propulsion devices 3a, 3b, 3c are switched to one of forward, rear, and neutral.
The controller 33 causes the shift actuators 24a, 24b, 24c to execute intermittent control to intermittently switch the shift state of each of the plurality of propulsion devices 3a, 3b, 3c to the shift-in state and the shift-out state.
The controller 33 sets the shift state of the ship 1 to the shift-in state by causing the shift actuator 24a to execute the shift-in control. Also, the controller 33 sets the shift state of the ship 1 to the shift-out state by causing the shift actuator 24a to execute the shift-out control.
For example, the controller 33 provides an intermittent control command to at least one of the shift actuators 24a, 24b, 24c. Thus, at least one of the shift actuators 24a, 24b, 24c executes the intermittent control.
The controller 33 controls the steering actuators 26a, 26b, 26c according to the position of the steering device 31. Thus, the steering angles of the propulsion devices 3a, 3b, 3c are controlled.
The low-speed navigation of the ship 1 includes a trawl state, which is a state in which the shift state of each of the plurality of propulsion devices 3a, 3b, 3c is a shift-in state (the state of
The controller 33 acquires the target speed of the ship 1 from the memory 37 (S1). This target speed is stored in the memory 37.
The controller 33 acquires the actual speed of the ship 1 (S2). For example, the controller 33 acquires the actual speed of the ship 1 from, for example, a GPS or the speed detector. The actual speed of the ship 1 is the current speed of the ship 1. This actual speed is recorded in the memory 37.
The controller 33 determines whether or not the actual speed of the ship 1 has reached the target speed (S3). When the actual speed of the ship 1 has reached the target speed (Yes in S3), the controller 33 executes Step 5 (S5) described below. On the other hand, when the actual speed of the ship 1 has not reached the target speed (No in S3), the controller 33 executes Step 4 (S4) described below.
When the actual speed of the ship 1 has not reached the target speed (No in S3), the controller 33 starts adjusting the duty ratio based on the actual speed of the ship 1 and the target speed to bring the actual speed of the ship 1 closer to the target speed (S4). For example, when the actual speed of the ship 1 is higher than the target speed, the controller 33 increases the duty ratio. When the actual speed of the ship 1 is lower than the target speed, the controller 33 reduces the duty ratio.
Thus, the controller 33 brings the speed of the ship 1 closer to the target speed. Thus, the controller 33 executes the feedback control with the duty ratio so that the speed of the ship 1 approaches the target speed. The feedback control is the same or substantially the same as that of the prior art, and the description thereof is omitted here.
When the controller 33 starts adjusting the duty ratio in step 4 (S4), the controller 33 determines whether or not the adjusted duty ratio is larger than the first threshold (S5). When the process does not go through the above Step 4 (S4), that is, the actual speed of the ship 1 has reached the target speed (Yes in S3), the controller 33 determines whether or not the current duty ratio (including the duty ratio as the initial value) is larger than the first threshold (S5).
When the duty ratio is larger than the first threshold (Yes in S5), the controller 33 causes the shift actuators 24a, 24b of the left propulsion device 3a and the right propulsion device 3b to execute intermittent control. Also, the controller 33 causes the shift actuator 24c of the middle propulsion device 3c to execute shift-in control. Thus, as shown in
When the duty ratio is equal to or smaller than the first threshold (No in S5), the controller 33 determines whether or not the duty ratio is equal to or larger than the second threshold (S7). When the duty ratio is equal to or larger than the second threshold (Yes in S7), the controller 33 causes the shift actuators 24a, 24b of the left propulsion device 3a and the right propulsion device 3b to execute the shift-out control, and causes the shift actuator 24c of the medium propulsion device 3c to execute the shift-in control.
Thus, as shown in
When the duty ratio is smaller than the second threshold (No in S7), the controller 33 causes the shift actuator 24c of the middle propulsion device 3c to execute the intermittent control. Thus, as shown in
During the execution of Step 6 (S6), Step 8 (S8), or Step 9 (S9), the controller 33 monitors the state of the ship 1. For example, the controller 33 executes the process of Steps 1 (S1) to 7 (S7) except for Step 6 (S6). Thus, the propulsion devices 3a, 3b, 3c are controlled such as Step 6 (S6), Step 8 (S8), or Step 9 (S9) according to the duty ratio. The above-described flow ends when the controller 33 acquires a stop command of the intermittent control.
In the ship maneuvering system 2 described above, not all of the plurality of propulsion devices 3a, 3b, 3c are intermittently controlled at the same time, but some of the plurality of propulsion devices 3a, 3b, 3c (the propulsion devices 3a, 3b or the propulsion device 3c) are intermittently controlled.
Accordingly, the number of propulsion devices 3a, 3b, 3c that are intermittently controlled is reduced, so that the sound generated in the ship 1 is reduced appropriately. Also, even if the shift state is switched from the shift-out state to the shift-in state during the intermittent control of the propulsion devices 3a, 3b, 3c, the shift shock and the shift noise is reduced when the shift mechanism 13 operates. Further, since the number of shift changes in each of the propulsion devices 3a, 3b, 3c is reduced, wear of the shift mechanism 13 is reduced. In other words, the durability of the shift mechanism 13 is improved.
In the prior art, when the propulsion device is in the shift-out state during the intermittent control, the traveling direction of the ship 1 cannot be changed even if the steering device 31 is operated. On the other hand, in the ship maneuvering system 2, when the duty ratio is equal to or larger than the second threshold, at least one of the propulsion devices 3a, 3b, 3c is always in the shift-in state. Therefore, in the ship maneuvering system 2, when the duty ratio is equal to or larger than the second threshold, the traveling direction of the ship 1 is able to be changed even if the steering device 31 is operated during the intermittent control. In other words, in the ship maneuvering system 2, the steering performance of the ship 1 is improved.
In the above-described preferred embodiments, an example in which the ship maneuvering system 2 is executed with the first threshold and the second threshold has been described. However, the ship maneuvering system 2 can be executed with only the first threshold. In this case, the ship maneuvering system 2 is executed as follows.
As shown in
The controller 33 determines whether or not the duty ratio is larger than the first threshold (S105). When the duty ratio is larger than the first threshold (Yes in S105), as shown in
When the duty ratio is equal to or smaller than the first threshold (No in S105), as shown in
In the above-described preferred embodiments, an example was described in which the number of propulsion devices (3a, 3b, 3c) is three, but the number of propulsion devices can be four or more. For example, when there are four propulsion devices, as shown in
In this case,
When the duty ratio is equal to or less than the first threshold and equal to or larger than the second threshold, as shown in
In the above-described preferred embodiments, an example in which the speed of the ship 1 is adjusted with the target speed has been described, but the speed of the ship 1 can be adjusted with the target duty ratio.
In this case, the memory 37 stores the target duty ratio which is set during the low-speed navigation of the ship 1. The preset target duty ratio may be stored in the memory 37, or the target duty ratio may be stored in the memory 37 by the user inputting the target duty ratio to an input device (not illustrated).
In this case, the controller 33 adjusts the duty ratio so that the duty ratio approaches the target duty ratio. For example, the controller 33 changes the duty ratio stepwise so that the duty ratio approaches the target duty ratio.
For example, the duty ratio is changed stepwise with the difference value stored in the memory 37. The duty ratio is able to be changed stepwise with the difference value input to an input device (not illustrated) by the operator.
In the process in which the duty ratio changes stepwise, the controller 33 executes the process after Step 5 (S5) or Step 105 (S105) with the first threshold and the second threshold (the first threshold in the example of the above-described variation). In this configuration, the same effects as in the above-described preferred embodiments are obtained.
According to preferred embodiments of the present invention, it is possible to reduce the sound, shift shock, and shift noise during intermittent control of a ship.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
This application claims the benefit of priority to U.S. Provisional Patent Application No. 62/823,113 filed on Mar. 25, 2019. The entire contents of this application are hereby incorporated herein by reference.
| Number | Name | Date | Kind |
|---|---|---|---|
| 7325506 | Yamashita | Feb 2008 | B2 |
| 7442102 | Ito | Oct 2008 | B2 |
| 9709996 | Ito | Jul 2017 | B2 |
| Number | Date | Country |
|---|---|---|
| 2016-216018 | Dec 2016 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 62823113 | Mar 2019 | US |
