This application claims the benefit of priority to Japanese Patent Application No. 2020-168026 filed on Oct. 2, 2020. The entire contents of this application are hereby incorporated herein by reference.
The present invention relates to a system and a method for controlling an outboard motor.
Conventionally, a system for controlling an outboard motor according to a selected control mode is known. For example, in Japanese Patent Application Laid-Open No. 2019-137278, when the fixed point holding mode is selected by the mode setting switch, the controller executes the fixed point holding mode. In the fixed point holding mode, the controller controls the outboard motor to hold the boat in place.
Preferred embodiments of the present invention provide systems and methods for controlling outboard motors according to a selected control mode.
A system according to a first preferred embodiment of the present invention controls an outboard motor attached to a boat. The system includes an input, a light unit, and a controller. The input is operable by an operator to select a control mode of the outboard motor. The light unit includes a plurality of light sources. The controller is connected to the input and the light unit. The controller is configured or programmed to control the outboard motor according to the control mode. The controller is configured or programmed to control the light unit to light at least a portion of the plurality of light sources in a pattern indicating a movement of the boat according to the control mode.
A method according to a second preferred embodiment of the present invention controls an outboard motor. The outboard motor includes a light unit including a plurality of light sources and is attached to the boat. The method includes receiving a signal indicative of a control mode of the outboard motor, controlling the outboard motor according to the control mode, and controlling the light unit to light at least a portion of the plurality of light sources in a pattern indicating a movement of the boat according to the control mode.
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.
The outboard motors 1a and 1b are attached to a stern of the boat 100. The outboard motors 1a and 1b are arranged side by side in a width direction of the boat 100. Specifically, the outboard motor 1a is located on a port side of the boat 100. The outboard motor 1b is located on a starboard side of the boat 100. The outboard motors 1a and 1b generate thrusts that propel the boat 100, respectively.
In the present preferred embodiment, the direction in which the bracket 11a is provided in the outboard motor 1a is defined as a forward direction, and the opposite direction is defined as a rearward direction. That is, the direction from the outboard motor 1a to the boat 100 is defined as the forward direction, and the direction from the boat 100 to the outboard motor 1a is defined as the rearward direction.
The outboard motor 1a includes a drive unit 2a, a drive shaft 3a, a propeller shaft 4a, and a shift mechanism 5a. The drive unit 2a generates a thrust that propels the boat 100. The drive unit 2a is an internal combustion engine, for example. The drive unit 2a includes a crankshaft 13a. The crankshaft 13a extends in the vertical direction of the outboard motor 1a. The drive shaft 3a is connected to the crankshaft 13a. The drive shaft 3a extends in the vertical direction of the outboard motor 1a. The propeller shaft 4a extends in a front-rear direction of the outboard motor 1a. The propeller shaft 4a is connected to the drive shaft 3a via the shift mechanism 5a. A propeller 6a is attached to the propeller shaft 4a.
The shift mechanism 5a includes a forward gear 14a, a reverse gear 15a, and a dog clutch 16a. By switching the connection of the gears 14a and 15a by the dog clutch 16a, the transmission direction of rotation from the drive shaft 3a to the propeller shaft 4a is switched. As a result, the forward movement and the reverse movement of the boat 100 are switched.
The outboard motor 1a includes a housing 10a. The housing 10a houses the drive unit 2a, the drive shaft 3a, the propeller shaft 4a, and the shift mechanism 5a. The housing 10a includes a bottom cowl 17a, a top cowl 18a, an upper case 19a, and a lower case 20a. The bottom cowl 17a supports the drive unit 2a. The bottom cowl 17a is made of resin, for example. However, the bottom cowl 17a may be made of metal such as aluminum. The top cowl 18a is located above the bottom cowl 17a. The top cowl 18a is attached to the bottom cowl 17a. The upper case 19a is located below the bottom cowl 17a. The lower case 20a is located below the upper case 19a. The lower case 20a houses the propeller shaft 4a and the shift mechanism 5a.
The shift actuator 7a is connected to the dog clutch 16a of the shift mechanism 5a. The shift actuator 7a switches the connection of the gears 14a and 15a by operating the dog clutch 16a. As a result, the forward movement and the reverse movement of the boat 100 are switched. The shift actuator 7a is, for example, an electric motor. However, the shift actuator 7a may be another actuator such as an electric cylinder, a hydraulic motor, or a hydraulic cylinder.
The steering actuator 8a is connected to the outboard motor 1a. The steering actuator 8a rotates the outboard motor 1a around the steering shaft 12a. As a result, a steering angle of the outboard motor 1a is changed. The steering angle is an angle of the propeller shaft 4a with respect to the front-rear direction of the outboard motor 1a. The steering actuator 8a is, for example, an electric motor. However, the shift actuator 7a may be another actuator such as an electric cylinder, a hydraulic motor, or a hydraulic cylinder.
The outboard motor 1a includes a first drive controller 9a. The first drive controller 9a includes a processor such as a CPU and a memory such as a RAM or a ROM. The first drive controller 9a stores programs and data to control the outboard motor 1a. The first drive controller 9a controls the drive unit 2a.
The outboard motor 1b includes a drive unit 2b, a shift actuator 7b, a steering actuator 8b, and a second drive controller 9b. The drive unit 2b, the shift actuator 7b, the steering actuator 8b, and the second drive controller 9b of the outboard motor 1b are the same as the drive unit 2a, the shift actuator 7a, the steering actuator 8a, and the first drive controller 9a of the outboard motor 1a, respectively.
The boat maneuvering system includes a steering wheel 24, a remote controller 25, a joystick 26, and an input device 27. As illustrated in
The steering wheel 24 enables an operator to operate a turning direction of the boat 100. The steering wheel 24 includes a sensor 240. The sensor 240 outputs a steering signal indicative of an operating direction and an operating amount of the steering wheel 24.
The remote controller 25 includes a first throttle lever 25a and a second throttle lever 25b. The first throttle lever 25a enables the operator to adjust a magnitude of the thrust of the outboard motor 1a. Further, the first throttle lever 25a enables the operator to switch a direction of the thrust of the outboard motor 1a between forward and reverse. The first throttle lever 25a is operable from a neutral position in a forward direction and in a reverse direction. The neutral position is between the forward direction and the reverse direction. The first throttle lever 25a includes a sensor 251. The sensor 251 outputs a throttle signal indicative of an operating direction and an operating amount of the first throttle lever 25a.
The second throttle lever 25b enables the operator to adjust a magnitude of the thrust of the outboard motor 1b. The second throttle lever 25b enables the operator to switch a direction of the thrust of the outboard motor 1b between forward and reverse. The configuration of the second throttle lever 25b is the same as that of the first throttle lever 25a. The second throttle lever 25b includes a sensor 252. The sensor 252 outputs a throttle signal indicative of an operating direction and an operating amount of the second throttle lever 25b.
The joystick 26 enables the operator to operate a moving direction of the boat 100 in each of the forward, rearward, left, and right directions. The joystick 26 enables the operator to operate a pivot turning operation of the boat 100. The joystick 26 is able to be tilted from a neutral position in at least four directions of forward, rearward, left, and right. The joystick 26 may be tilted in four or more directions, or may be tilted in all directions. The joystick 26 is able to rotate about the rotation axis Ax1. That is, the joystick 26 is able to be twisted clockwise and counterclockwise from a center position around the rotation axis Ax1.
The joystick 26 includes a sensor 260. The sensor 260 outputs a joystick signal indicative of an operation of the joystick 26. The joystick signal includes a tilting direction and a tilting amount of the joystick 26. The joystick signal includes a twisting direction and a twisting amount of the joystick 26.
The boat maneuvering system includes a boat maneuvering controller 30. The boat maneuvering controller 30 includes a processor such as a CPU and a memory such as a RAM or a ROM. The boat maneuvering controller 30 stores programs and data to control the outboard motor 1a and the outboard motor 1b. The boat maneuvering controller 30 is connected to the first and second drive controllers 9a and 9b via a wire or wirelessly. The boat maneuvering controller 30 is connected to the steering wheel 24, the remote controller 25, the joystick 26, and the input device 27 via the first and second drive controllers 9a and 9b.
The boat maneuvering controller 30 receives the steering signal from the sensor 240. The boat maneuvering controller 30 receives the throttle signal from the sensors 251 and 252. The boat maneuvering controller 30 receives the joystick signal from the sensor 260. The boat maneuvering controller 30 outputs command signals to the first and second drive controllers 9a and 9b based on the signals from the sensors 240, 251, 252, and 260. The command signals are transmitted to the shift actuators 7a and 7b and the steering actuators 8a and 8b via the first and second drive controllers 9a and 9b.
For example, the boat maneuvering controller 30 outputs a command signal to the shift actuator 7a according to the operating direction of the first throttle lever 25a. As a result, the outboard motor 1a is switched between forward and reverse. The boat maneuvering controller 30 outputs a throttle command to the drive unit 2a according to the operating amount of the first throttle lever 25a. The first drive controller 9a controls the output rotation speed of the outboard motor 1a in response to the throttle command.
The boat maneuvering controller 30 outputs a command signal to the shift actuator 7b according to the operating direction of the second throttle lever 25b. As a result, the outboard motor 1b is switched between forward and reverse. The boat maneuvering controller 30 outputs a throttle command to the drive unit 2b according to the operating amount of the second throttle lever 25b. The second drive controller 9b controls the output rotation speed of the outboard motor 1b in response to the throttle command.
The boat maneuvering controller 30 outputs a command signal to the steering actuators 8a and 8b according to the operating direction and the operating amount of the steering wheel 24. When the steering wheel 24 is operated from the neutral position to the left, the boat maneuvering controller 30 controls the steering actuators 8a and 8b so as to rotate the outboard motor 1a and the outboard motor 1b to the right. As a result, the boat 100 turns to the left.
When the steering wheel 24 is operated from the neutral position to the right, the boat maneuvering controller 30 controls the steering actuators 8a and 8b so as to rotate the outboard motor 1a and the outboard motor 1b to the left. As a result, the boat 100 turns to the right. Further, the boat maneuvering controller 30 controls the steering angles of the outboard motor 1a and the outboard motor 1b according to the operating amount of the steering wheel 24.
The boat maneuvering controller 30 outputs command signals to the drive units 2a and 2b, the shift actuators 7a and 7b, and the steering actuators 8a and 8b according to the tilting direction and the tilting amount of the joystick 26. The boat maneuvering controller 30 controls the drive units 2a and 2b, the shift actuators 7a and 7b, and the steering actuators 8a and 8b so as to translate the boat 100 in a direction corresponding to the tilting direction of the joystick 26 at a speed corresponding to the tilting amount.
When the joystick 26 is tilted forward, the boat maneuvering controller 30 moves the boat 100 forward (forward movement mode). When the joystick 26 is tilted rearward, the boat maneuvering controller 30 moves the boat 100 rearward (rearward movement mode).
When the joystick 26 is tilted to the left or right, the boat maneuvering controller 30 laterally moves the boat 100 to the left or right (lateral movement mode). For example, when the joystick 26 is tilted to the right, as illustrated in
The boat maneuvering controller 30 controls the drive units 2a and 2b, the shift actuators 7a and 7b, and the steering actuators 8a and 8b so that the boat 100 pivots in a direction corresponding to the twisting direction of the joystick 26 and at a speed corresponding to the twisting amount (pivot turning mode). For example, the boat maneuvering controller 30 generates forward thrust in one of the outboard motor 1a and the outboard motor 1b, and generates reverse thrust in the other of the outboard motor 1a and the outboard motor 1b to pivot the boat 100.
The boat maneuvering system includes a position sensor 31. The position sensor 31 detects a position of the boat 100. The position sensor 31 is a receiver of a GNSS (Global Navigation Satellite System) such as a GPS (Global Positioning System). However, the position sensor 31 may be a sensor other than the GNSS receiver. The position sensor 31 outputs a signal indicative of the position of the boat 100. The boat maneuvering controller 30 is communicably connected to the position sensor 31. The boat maneuvering controller 30 acquires the position of the boat 100 due to the signal from the position sensor 31. Further, the boat maneuvering controller 30 acquires a speed of the boat 100 due to the signal from the position sensor 31. The maneuvering system may include a separate sensor to detect the speed of the boat 100.
The boat maneuvering system includes a directional sensor 32. The directional sensor 32 detects a course of the boat 100. The directional sensor 32 is, for example, an IMU (Inertial Measurement Unit). However, the directional sensor 32 may be a sensor other than the IMU. The boat maneuvering controller 30 is communicably connected to the directional sensor 32. The boat maneuvering controller 30 acquires the course of the boat 100 from the signal from the directional sensor 32.
The input device 27 is operable by the operator to select a control mode of the outboard motors 1a and 1b. The input device 27 may be provided on the remote controller 25 or the joystick 26. Alternatively, the input device 27 may be provided separately from the remote controller 25 or the joystick 26.
The control mode includes a course holding mode. As illustrated in
The control mode includes a heading holding mode. As illustrated in
Further, as illustrated in
The control mode includes a pattern steering mode. The boat maneuvering controller 30 controls the outboard motors 1a and 1b so as to move the boat 100 according to a predetermined turning pattern in the pattern steering mode. The predetermined turning pattern includes a zigzag turning pattern B1 illustrated in
The control mode include a track point mode. As illustrated in
The control mode includes a fixed point holding mode. As illustrated in
The boat maneuvering controller 30 transmits a command signal to the light unit 40a via the first drive controller 9a. The boat maneuvering controller 30 controls the light unit 40a to light at least a portion of the plurality of light sources 41 to 49 in a pattern indicating the movement of the boat 100 according to the control mode. During the course holding mode, the heading holding mode, the track point mode, the fixed point holding mode, and the movement modes by the joystick 26, the boat maneuvering controller 30 lights at least a portion of the plurality of light sources 41 to 49 so as to indicate the moving direction of the boat 100.
For example, when the boat 100 moves to the right, the boat maneuvering controller 30 alternately repeats the blinking of the light sources in the center column and the blinking of the light sources in the right column, as illustrated in
During the fixed point holding mode, the boat maneuvering controller 30 may blink all of the plurality of light sources as illustrated in
During the pattern steering mode, the boat maneuvering controller 30 lights at least a portion of the plurality of light sources to show a predetermined turning pattern. When the zigzag turning pattern is selected, the boat maneuvering controller 30 lights at least a portion of the plurality of light sources in a zigzag pattern. For example, as illustrated in
When the spiral turning pattern is selected, the boat maneuvering controller 30 lights at least a portion of the plurality of light sources in a spiral pattern. The boat maneuvering controller 30 switches the blinking of the light sources so that the plurality of light sources appear to rotate. For example, as illustrated in
The boat maneuvering controller 30 lights at least a portion of the plurality of light sources to indicate the pivot turning of the boat 100 in response to the twisting operation of the joystick 26. In that case, for example, the boat maneuvering controller 30 may blink a plurality of light sources in the same manner as the pattern illustrated in
When the left and right direction buttons 95 and 98 are operated in the heading holding mode, the boat maneuvering controller 30 lights the plurality of light sources to indicate the movement of the boat 100 in response to the operation of the left and right direction buttons 95 and 98. For example, in the heading holding mode, when the right direction button 98 is operated, as illustrated in
In the outboard motors 1a and 1b according to the preferred embodiments described above, the plurality of light sources are turned on in a pattern indicating the movement of the boat 100 according to the control mode during the execution of the control mode. As a result, it is possible to notify the operation of the outboard motors 1a and 1b to the people around the outboard motors 1a and 1b.
The left light unit 50a includes a plurality of light sources 51 to 54. The right light unit 60a includes a plurality of light sources 61 to 64. The number of light sources of the left light unit 50a and the number of light sources of the right light unit 60a are not limited to four, respectively. The number of light sources in the left light unit 50a and the number of light sources in the right light unit 60a may be more than four or less than four. The boat maneuvering controller 30 controls the light units 50a and 60a to light the plurality of light sources 51 to 54 of the left light unit 50a and the plurality of light sources 61 to 64 of the right light unit 60a in a pattern that indicates the movement of the boat 100 according to the control mode in addition to the lighting of the light unit 40a described above.
For example, when the boat 100 moves to the right, the boat maneuvering controller 30 blinks the plurality of light sources of the right light unit 60a as illustrated in
In the fixed point holding mode, the boat maneuvering controller 30 may blink all of the plurality of light sources in the left light unit 50a and the right light unit 60a.
Although preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described preferred embodiments, and various modifications can be made without departing from the gist of the present invention.
The structure of the outboard motor is not limited to that of the above-described preferred embodiments, and may be changed. For example, the drive unit 2a is not limited to the internal combustion engine, and may be an electric motor. Alternatively, the drive unit 2a may be a hybrid boat maneuvering system of an internal combustion engine and an electric motor. The number of outboard motors is not limited to two. The number of outboard motors may be one or more than two.
The shape or position of the light unit is not limited to that of the above-described preferred embodiments, and may be changed. The light unit is not limited to a circular shape, and may have other shapes. The number or arrangement of light sources is not limited to that of the above-described preferred embodiments, and may be changed.
The boat maneuvering controller 30 may turn on the light source in a state other than the execution of the control mode. For example, the boat maneuvering controller 30 may turn on the light source when the engine is started. The boat maneuvering controller 30 may turn on the light source while driving the engine. The boat maneuvering controller 30 may turn on the light source according to the change in the rotational speed of the engine. The lighting pattern of the light source is not limited to that of the above-described preferred embodiments, and may be changed. The lighting of the light source may be constant lighting or blinking. The plurality of light sources may be turned on at the same time, or may be turned on with a time lag. Further, the lighting and extinguishing of the plurality of light sources may be switched so that the light appears to move.
The boat maneuvering controller 30 may turn on the navigation light of the boat in conjunction with the lighting of the plurality of light sources of the light unit described above. As a result, it is possible to notify the boats or people around the boat 100 that the boat 100 is performing automatic maneuvering. The boat maneuvering controller 30 may include information indicative of that the boat 100 is performing automatic maneuvering in a signal output by the AIS (Automatic Identification System) as well as lighting of the plurality of light sources of the light unit.
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.
Number | Date | Country | Kind |
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2020-168026 | Oct 2020 | JP | national |