JP3386521B2 - Remote control device for ship propulsion - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote control device for a ship propulsion device which controls the ship propulsion device by remote control.

[0002]

2. Description of the Related Art When remotely controlling a propulsion device for a ship such as an outboard motor or a stern drive from the driver's seat to perform throttle control or forward / reverse switching, the operating lever in the driver's seat and the marine propulsion device are usually used. I used a mechanical cable to connect them and operated this control lever. However, this type of remote control device has a problem in that the operation of the operating lever becomes heavy when the driver's seat is present in two or more locations, such as in the cabin and in the flying bridge. This is because the mechanical cables connected to the operating lever of each driver's seat are connected to each other by a mechanical junction box, and the mechanical junction box guides the propulsion equipment, increasing the resistance when the mechanical cable advances and retracts. Because it will be. This phenomenon is particularly remarkable in the case of a one-lever remote controller in which throttle control and forward / reverse switching are performed by a single operating lever.

As a remote control device that solves such a problem, there is a remote control device in which a throttle device of a propulsion device and a forward / reverse switching device are operated by an electric actuator. An electric remote control system of this type will be described with reference to FIG.

FIG. 10 is a schematic block diagram showing a conventional remote control device for a ship propulsion device. In the figure, 1 is a ship propulsion device, and 2 is a remote control device for the ship propulsion device 1.
The remote control device 2 controls a throttle actuator 3 connected to a throttle valve device (not shown) of the propulsion device 1 and a shift actuator 4 connected to a forward / reverse switching device (not shown) to operate a lever 5 and a control. It is configured to be controlled by the unit 6.

The throttle actuator 3 and the shift actuator 4 are constructed by connecting a rack and pinion mechanism to a motor as a power source, and a throttle is provided via mechanical cables 3a and 4a connected to the rack of the rack and pinion mechanism. It is connected to a valve device or a forward / reverse switching device. That is, the throttle control and the forward / reverse switching are performed by rotating the motors of the actuators 3 and 4 forward or backward. The moving position of the rack is detected by a rack position sensor (not shown) connected to the rack via a link, and the actual control positions of the forward / reverse switching device and the throttle valve device are fed back to the control unit 6. Is configured to.

The operating lever 5 is supported by a remote control box 7 provided in the driver's seat so as to be swingable in the front-rear direction. This remote control box 7 is provided with a lever operation position sensor 8 for detecting the swing direction and swing angle of the operation lever 5, and the swing operation of the operation lever 5 is detected by this lever operation position sensor 8 to generate an electric signal. Instead of this, the structure is such that it is output to the control unit 6. That is, the swing direction and swing angle of the operating lever 5 are converted into an electric signal and input to the control unit 6.

The control unit 6 includes a sorting unit 6a for sorting the operation content based on the swing direction and swing angle of the operating lever 5 detected by the lever operating position sensor 8, and each of the shift and throttle actuators. The comparison units 6b ₁ and 6b ₂ and the control unit 6 provided
c and the drive unit 6d and the like. Based on the signal output from the lever operation position sensor 8, the sorting unit 6a is in a shift range in which the position of the operation lever 5 is smaller than a predetermined angle with respect to the neutral position, or a throttle having a set angle or more. It is configured to sort out if it is in range. When in the shift range, the signal is sent to the comparison unit 6b ₁ connected to the shift actuator 4, and when in the throttle range, the signal is sent to the comparison unit 6b ₂ connected to the throttle actuator 3. .

The comparison units 6b ₁ and 6b ₂ are configured to compare the control position of each actuator input from the rack position sensor of the throttle actuator 3 or the shift actuator 4 with the swing angle of the operation lever 5. . In addition, the control unit 6c controls the comparison units 6b ₁ and 6b ₂
It is configured to determine whether to rotate the motors of the actuators 3 and 4 in the forward direction or the reverse direction based on the comparison result in 1 and send a control signal corresponding to the determination result to the drive unit 6d. The drive unit 6d is configured to rotate the motor forward or reverse according to the control signal input from the control unit 6c. The electric circuit of the driving unit 6d is mainly composed of two P-channel MOS-FETs and two N-channels.
The structure is such that a channel MOS-FET or the like is connected to the motor.

In the conventional remote control device thus constructed, when the operating lever 5 is swung by tilting it forward, for example, the control unit 6 controls the shift actuator 4 to move forward, and further, the operating lever. When the swing angle of 5 is larger than a predetermined angle, the throttle actuator 3 is controlled so that the throttle opening becomes large with a control amount according to the swing angle. This control is the same when the operation lever 5 is swung rearward.

[0010]

However, there has been a problem that the conventional remote control device using the electric remote control system configured as described above becomes expensive.
This requires a separate actuator and each drive circuit for performing throttle control and forward / reverse switching, and requires a motor, a speed reduction mechanism, and a power M as a power transistor.
This is because expensive parts such as an OS-FET are used for two systems, throttle control and forward / reverse switching.

The present invention has been made to solve such a problem, and an object thereof is to keep the cost low in controlling the throttle control and the forward / reverse switching by an electric actuator.

[0012]

A remote control device for a ship propulsion device according to the present invention is a controller for a main operating means on a driver's side.
Connected to the electric actuator on the propulsion unit side via the roller
Drive the motor in this electric actuator
Propulsion throttle control and forward / reverse switching
In a remote control device for a machine, the electric actuator
The forward / reverse switching member and the first throttle opening / closing switch.
By driving the frame members with the same motor,
It has a structure for throttle control and forward / reverse switching,
Warm-up operation that controls the throttle valve device of the propulsion machine during machine operation
And a warming-up operation control means.
For warming up, which is provided separately from the main operating means when changing seats
A second slot connected to the operation means via the operation connection means.
By operating the shuttle opening / closing cam member and the warm-up operation means,
The electric actuator operated by the main operating means when
A second means for regulating the control of the motor.
The rottle opening / closing cam member is the front / rear of the forward / reverse switching member.
With the advance switching position in the neutral position, the first slot
To open and close the throttle valve separately from the tor open / close cam member
It is composed of . Invention according to claim 2
The remote control device for the ship propulsion device
An electric actuator on the propulsion unit side is connected to the operating means via a controller.
The chute is connected to the inside of this electric actuator
Throttle control of propulsion machine and forward / reverse switching by driving motor
In the remote control device for ship propulsion equipment
The dynamic actuator is provided with a forward / reverse switching member and a first
Make sure that the throttle opening / closing cam members are driven by the same motor.
By using, the throttle control and forward / reverse switching can be performed independently.
Throttle valve device for the propulsion unit during warm-up operation
This warm-up operation control means for controlling
The rotation control means is separate from the main operation means in the driver's seat.
Connected to the provided warm-up operation means via operation connection means
The forward / reverse switching position of the forward / reverse switching member is neutral.
The first throttle opening / closing cam member in the position
A second, separately configured to open and close the throttle valve
Operation of the throttle opening / closing cam member and the warm-up operation means
When the throttle valve is open due to
Control the electric actuator control by the operating means,
The throttle valve is closed by operating the warm-up operation means.
While operating, the electric actuation by the main operating means
With regulation means that allows control of the user
Is.

[0013]

The electronic components used for the motor, the speed reducer, and the motor drive circuit required for throttle control and forward / reverse switching are only one system.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail below with reference to FIGS. 1 is a schematic configuration diagram showing a remote control device for a ship propulsion device according to the present invention, FIG. 2 is an enlarged sectional view showing a shaft portion of an operation lever of the remote control device according to the present invention, and FIG. FIG. 4 is a plan view showing a main part of an actuator used for the remote control device for the ship propulsion device.
4 is a sectional view taken along line IV-IV in FIG. 5, and FIG. 5 is a plan sectional view showing the configuration of the shift mechanism portion in the actuator.
5 shows a cross section taken along line VV of the rotating body and the forward / backward switching lever in FIG.

FIG. 6 is a plan view showing the main part of the actuator, which shows a state in which the forward / reverse switching device is switched to the reverse side while the throttle valve device is idling. Figure 7
FIG. 3 is a plan view showing a main part of the actuator, which shows a state in which the forward / reverse switching device is switched to the reverse side and the throttle valve device is substantially fully opened. FIG. 8 is a plan view of the throttle opening / closing cam used for the actuator. In these figures, the same or equivalent members as those described with reference to FIG. 10 are designated by the same reference numerals, and detailed description thereof will be omitted.

In these drawings, 11 is a remote control device for a ship propulsion device according to the present invention. This remote control device 1
Reference numeral 1 denotes an operating means including an actuator 15 connected to a marine vessel propulsion device 12 via mechanical cables 13 and 14 made of push-pull cables, a control unit 16 for controlling the actuator 15, an operating lever 5, and a select switch 17. Etc. In the present embodiment, a remote control device used for a ship in which a driver's seat is provided in two places such as in a cabin (not shown) and a flying bridge (not shown) will be described. That is, two sets of the operation lever 5 and the select switch 17 are used because they are provided in each driver's seat. The operation
The lever 5 constitutes the main operating means according to the present invention.
Has been.

The actuator 15 is provided with one motor as will be described later. By rotating this motor in the forward direction or in the reverse direction, switching between forward and reverse is performed, and throttle control during forward and reverse is performed. Is configured. More specifically, by rotating the motor in the normal position from the forward position, first, the forward / reverse switching device (not shown) of the propulsion unit 12 is switched to the forward side, and then in the forward rotation, the throttle valve device ( (Not shown) is driven so that the throttle opening gradually increases. When the motor is reversed from the neutral position, the forward / reverse switching device is first switched to the reverse side, and then the throttle valve device is driven so that the throttle opening gradually increases.

In order to switch the rotation direction of the motor of the actuator 15 as described above, the swinging direction and swinging angle of the operating lever 17 are detected by the lever operating position sensor 8 and converted into an electric signal to control unit. 1
This is done by typing in 6. The connecting structure of the operation lever 5 and the lever operation position sensor 8 is as shown in FIG. That is, the operation lever 5 is rotatably supported by the remote control box 7 via the horizontal support shaft 5a, and the rotary shaft 8a of the lever operation position sensor 8 is fitted to the shaft end of the support shaft 5a inside the remote control box 7. I am fit. The lever operation position sensor 8 includes a rotary shaft 8 with respect to the main body 8b.
The main body 8b is supported and fixed to the remote control box 7 by a structure in which a rotation direction and a rotation angle of a are detected and a detection signal is input to the control unit 16.

The control unit 16 includes a sorting section 18
And a comparison unit 19, a control unit 20 and a drive unit 21. The sorting unit 18 determines whether the position of the operation lever 5 is in a shift range smaller than a predetermined angle with respect to the neutral position based on the signal input from the lever operation position sensor 8 or a throttle having a set angle or more. Whether it is in the range or not is discriminated, and when it is in the shift range, a forward shift signal or a backward shift signal is output to the comparison unit 19 based on the swing direction. Further, in the throttle range, the throttle opening signal corresponding to the swing angle is output to the comparison unit 19.

The comparison unit 19 is an actuator 1 described later.
Actuator 15 input from the control position sensor 5
The actual control position is compared with the swing angle of the operating lever 5.

The control unit 20 controls the rotation direction of the motor of the actuator 15 based on the comparison result of the comparison unit 19 and the forward shift signal, backward shift signal or throttle opening signal output from the classification unit 18. And it has a structure that decides whether to continue or stop the rotation. This control unit 2
The control at 0 will be described in more detail. When the forward shift signal is input, the motor is normally rotated so that the actual control position of the actuator 15 input to the comparison unit 19 reaches a predetermined forward switching position. Let When the reverse shift signal is input, the motor is reversely rotated so that the actual control position of the actuator 15 input to the comparison unit 19 reaches a predetermined reverse switching position. The forward switching position mentioned above refers to the control position of the actuator 15 when the forward / backward switching device of the propulsion device 12 is switched to the forward side by the actuator 15, and the reverse switching position is the actuator 15 switching position.
Is the control position of the actuator 15 when the forward / reverse switching device of the propulsion unit 12 is switched to the reverse side by.

Further, when the throttle opening signal is input, the actuator 15 is input to the comparison section 19.
The motor is rotated in the normal or reverse direction so that the actual control position of 1 corresponds to the swing angle of the operating lever 5. The rotation direction of the motor at this time is a forward rotation direction when the shift range is on the forward side, and a reverse rotation direction when the shift range is on the reverse side. It should be noted that the throttle opening is set to increase as the swing angle of the operation lever 5 with respect to the neutral position increases.

That is, when the operating lever 5 is tilted forward by 90 degrees from the neutral position shown in FIG. 1, the sorting unit 18 outputs the forward shift signal and then the throttle opening signal. Therefore, the control unit 20 causes the motor to rotate normally so that the control position of the actuator 15 reaches the forward switching position, and then the control position of the actuator 15 reaches a position according to the swing angle of the operation lever 5. The motor will rotate in the forward direction. Also, if the actuator is tilted about 90 degrees backward from the neutral position, the actuator 1
After the motor is rotated in the reverse direction so that the control position of 5 reaches the reverse switching position, the motor is further rotated in the reverse direction so that the control position of the actuator 15 reaches the position corresponding to the swing angle of the operation lever 5.

Further, when the operating lever 5 is swung within the shift range on the forward side or the reverse side, the sorting section 18
Since only the forward shift signal or the reverse shift signal corresponding to the swinging direction is output from, the actuator 15 drives only the forward / reverse switching device of the propulsion unit 12.

The select switch indicated by reference numeral 17 in FIG. 1 is a button switch for designating which of a plurality of remote control boxes 7 should be operated, and the actuator is controlled only by the remote control box 7 designated thereby. Therefore, this select switch 17
Is near the remote control box 7 or remote control box 7
It is desirable to be installed integrally in the. Also, when switching to the designated remote control box, the lever position of the remote control box 7 before switching and the newly designated remote control box 7
If the lever position of the remote controller box 7 is different, the driver or passenger may suddenly accelerate, suddenly start, or suddenly decelerate, causing a water fall accident or a fall accident. Valid only when in the neutral position. Furthermore, if the lever position of the remote control box 7 before switching is in a position other than neutral,
The control of the actuator is temporarily returned to the neutral position, and thereafter, it is necessary to incorporate safety control such as receiving control from the remote control box 7.

Next, the structure of the actuator 15 for performing throttle control and forward / reverse switching by one motor will be described with reference to FIGS. The actuator 15 is rotatably supported in a device case (not shown) with the direction orthogonal to the paper surface of FIG. 3 as the axial direction, and is connected to the motor 22 via the worm gear 23. It includes a forward / reverse switching lever 25 and a throttle control lever 26, a control position sensor 27 for detecting the rotational position of the rotor 24 (control position of the actuator 15), and the like. The motor 22 and the sensor 27 are connected to the control unit 16 described above. In the present embodiment, an example in which the forward / reverse switching member and the first throttle opening / closing cam member are integrally formed as the rotating body 24 is shown.

The rotating body 24 is formed into a substantially disc shape as a whole, and the worm wheel connecting shaft member 2 is provided at the lower axial center thereof.
4a are connected via a rectangular fitting structure. 28 is a fixing bolt for fixing the rotating body 24 to the shaft member 24a . Shaft member 24 for connecting the worm wheel
The worm wheel 23a is fixed to a, and the control position sensor 27 is connected to the lower axial center of the worm wheel 23a. The control position sensor 27 has a structure that detects the rotation angle of the worm wheel 23a (rotating body 24) and inputs it to the control unit 16. Further, the motor 22 that rotationally drives the rotating body 24 via the worm gear 23 is configured such that when the rotating body 24 rotates counterclockwise in the plan view shown in FIG.

The rotary member 24 has a lower part (a lower part in FIG. 4) corresponding to the forward / reverse switching member, and an upper part corresponding to the throttle opening / closing cam member. There is. As shown in FIG. 5, the lower portion of the rotating body 24 is formed in a circular shape having teeth 29 on a part of the outer peripheral portion. Further, a cam groove 30 is formed at an upper portion of the rotary body 24 in a portion corresponding to the tooth 29 so as to open upward.

The cam groove 30 is formed in an arc shape with the portion just above the tooth 29 being centered on the axis of the rotating body 24, and the portions connected to both ends of the arc portion constitute a cam. There is. The arcuate portion is indicated by reference numeral 30a, and the cam portion is indicated by reference numeral 30b. The cam portion 30b is formed so that the distance from the axial center of the rotating body 24 gradually decreases toward the end of the cam groove 30. The length of the arcuate portion 30a is set so as to correspond to the rotation width of the rotating body 24 when the forward / reverse traveling switching lever 25 described later rotates.

The forward / reverse switching lever 25 is provided with a support shaft 31.
A tooth 32, which is rotatably supported by the device case via the, and meshes with the tooth 29 of the rotating body 24, and a concave curved surface 33 continuous with the tooth 32 are formed. A mechanical cable 13 connected to the forward / rearward travel switching device of the propulsion unit 12 is connected to the arm portion 25a that is eccentrically located below these rotating body connecting portions. The concave curved surface 33 is formed with a curvature substantially equal to that of the outer peripheral surface 24b of the circular portion formed in the lower portion of the rotating body 24.

That is, when the rotating body 24 rotates clockwise, for example, in FIG. 5, the forward-reverse switching lever 25 rotates counterclockwise due to the engagement of the teeth 29 and the teeth 32, and the arm portion 25a moves the mechanical cable 13 in the same figure. It will be pulled right in the middle. The forward / reverse switching device of the propulsion unit 12 is
The mechanical cable 13 is configured to be switched to the reverse side by being pulled as described above. When the rotating body 24 rotates in the opposite direction to the above, the forward / reverse switching device is switched to the forward side. The forward / reverse switching device is configured to be in the neutral position when the rotating body 24 is in the position shown in FIGS. 3 and 5.

When the rotating body 24 rotates and the teeth 29 and 32 are disengaged from each other, the concave curved surface 33 of the forward / reverse switching lever 25 comes into contact with the outer peripheral surface 24b of the rotating body 24 as shown in FIG. . In this state, even if the rotating body 24 continues to rotate further, the concave curved surface 33 comes into sliding contact with the outer peripheral surface 24b as shown in FIG. 7, and the forward / reverse switching lever 25 is kept at the rotating position. Be drunk That is, the forward / reverse switching lever 25 rotates with the rotating body 24 within a certain rotation range in which the teeth 29 and 32 mesh when the rotating body 24 rotates from the neutral position shown in FIGS. 3 and 5. Even if the rotating body 24 rotates beyond the range of rotation, it does not respond to it and is kept in a stopped state. The rotational position of the rotating body 24 when the forward / reverse switching lever 25 stops corresponds to the forward switching position and the reverse switching position.

The throttle control lever 26 is rotatably supported by a support shaft 31 which supports the forward / reverse switching lever 25, and an arm portion 26a extending from the shaft support portion.
The mechanical cable 14 is coupled to the one end of the link member 34, and one end of the link member 34 is rotatably coupled to a portion extending to the side opposite to the arm portion 26a. A roller 35 is attached to the end of the link member 34 on the side opposite to the throttle control lever 26, and the roller 35 is slidably engaged with the cam groove 30 of the rotary member 24 so that the end of the roller side is closed. Are connected to the rotating body 24. The roller 35 is also engaged with a guide hole 37 of a guide plate 36 rotatably fitted to the central boss portion 24c of the rotary body 24.

As shown in FIG. 3, the guide plate 36 is formed in a substantially L-shape in a plan view, and has a guide hole 37 which is an elongated hole extending along the radial direction of the rotating body 24 on one side extending to the right in FIG. And a substantially V-shaped engaging hole 38 is formed on one side extending upward in FIG. The guide plate 36 is provided on the central boss portion 2 of the rotating body 24.
4c has an engaging hole 38 that is rotatably engaged and that engages with a pin 39 provided on a disk 40 that rotates about a shaft 140. The disk 40 is at the position shown in FIG. If the guide plate 36 is located at the position shown in FIG.
It is restricted to rotate around. The disc 40 has a semicircular cutout 40a, and a stopper 42 having a cylindrical member 41 is pressed against the semicircular cutout 40a. This stopper 42 is formed of an elastic body in this embodiment, and the cylindrical member 41 is elastically deformed by the disc 4 by itself.
The end opposite to the cylindrical member 41 is fixed to the device case in a state of being pressed against 0.

A projection 40b is formed on the disk 40 on the side opposite to the semicircular notch 40a in the radial direction, and the projection 40b is attached to an actuator of a limit switch 43 described later. In the state shown in FIG. 3, the disc 40 is pressed against the limit switch 43 by the stopper 42, is sandwiched by the stopper 42 and the limit switch 43, and is held at the illustrated position.

That is, when the rotator 24 rotates, for example, clockwise from the neutral position shown in FIG. 3, the guide plate 36 restricts the movement of the roller 35 in the vertical direction in FIG. When the rotation angle is small, the arcuate portion 30a of the cam groove 30 moves with respect to the roller 35. Then, when the rotation angle of the rotating body 24 increases,
The roller 35 comes into sliding contact with the cam portion 30b as shown in FIG. 7 through the connecting portion between the arc-shaped portion 30a and the cam portion 30b as shown in FIG. When the roller 35 comes into sliding contact with the cam portion 30b, the roller 35 moves along the guide hole 37 toward the axial center of the rotary body 24 in response to the rotation of the rotary body 24, and the link member including the roller 35 is formed. The movement of 34 causes the throttle control lever 26 to rotate counterclockwise in the figure. When the throttle control lever 26 rotates counterclockwise, the mechanical cable 14 connected to the arm portion 26a is pulled. On the other hand, even when the rotating body 24 rotates in the opposite direction to the above, the roller 35 slides in contact with the cam portion 30b located on the opposite side of the cam portion 30b to rotate the throttle control lever 26 counterclockwise. ,
The mechanical cable 14 will be pulled.

The throttle valve device of the propulsion unit 12 connected to the mechanical cable 14 is constructed so that the throttle opening gradually increases as the mechanical cable 14 is pulled. The throttle valve device has a structure in which the propulsion unit 12 is in an idling state in the state shown in FIG. 3 in which the mechanical cable 14 is not pulled.

Further, the arcuate portion 30a of the cam groove 30.
Is the rotation angle of the rotor 24 when the teeth 29 formed on the lower side of the cam groove 30 mesh with the teeth 32 of the forward / reverse switching lever 25, and the central angle of the arc in the arc-shaped portion 30a. Are set so that they match. That is, when the forward / reverse switching lever 25 rotates together with the rotating body 24, the throttle control lever 26 is held at the neutral position because the roller 35 is located in the arcuate portion 30a. Then, the forward / reverse switching lever 25
When it stops responding to the rotor 24 (the two teeth 2
When the meshing of 9 and 32 is disengaged and the forward / reverse switching device is switched to the forward switching position or the reverse switching position), the throttle control lever turns toward the throttle fully open side.

The operation timing of each of the levers 25 and 26 will be described with reference to FIG. In FIG. 8, the alternate long and short dash line N is a neutral position line connecting the axis of the rotating body 24 and the axes of the levers 25 and 26. S ₁ is an arc-shaped portion 30 a of the cam groove 30
And shift end line through the boundary between the cam portion 30b, S ₂ is the full throttle line passing through the tip of the cam portion 30b. That is, when the rotating body 24, the shift end line S ₁ , and the throttle fully open line S ₂ are rotated from the neutral position shown in the figure, only the forward / reverse switching lever 25 is provided until the shift end line S ₁ overlaps the neutral position line N. Turns and shift end line S
_{When the} neutral position line N is located between ₁ and the throttle full-open line S ₂ , only the throttle control lever 26 rotates.

Now, the structure of the disc 40 for restricting the rotation of the guide plate 36 with respect to the rotating body 24 will be described. The disc 40 is integrally provided with a free throttle lever 44, and serves as a warm-up operation means for the driver's seat via the free throttle lever 44 and a warm-up throttle cable 45 connected to the free throttle lever 44.
Is connected to a warm-up operation lever (not shown). In FIG. 3, when pulling this warm-up operation lever, the disc 4
0 is pulled together with the free throttle lever 44, and the shaft 14
Rotational force is applied clockwise around 0. Then, the cylindrical member 41 engaged with the semicircular cutout 40a of the disc 40 resists the spring force of the stopper 42 and rotates the rotating body 24.
Is pushed toward the shaft center side of the rotary body 24 so as to face the semicircular recess 24d formed in the central boss portion 24c of the rotary body 24, and the engagement by the stopper 42 is released. Therefore, the disk 40 rotates clockwise in FIG. 3 about the shaft 140, and the pin 39 rotates the guide plate 36 clockwise through the engagement hole 38 of the guide plate 36. The guide plate 3
Second throttle opening / closing cam member according to the present invention by 6
The throttle cable 45 for warming up is
-Throttle lever 44, disk 40, pin 39, etc.
Thus, the operation connecting means according to the present invention is configured.

At this time, the projection 40b of the disc 40 is disengaged from the operator of the limit switch 43, and the limit switch 43 is turned on. This limit switch 43
Is denoted by reference numeral 4 in FIG. 2 via a solenoid drive circuit (not shown).
It is connected to a lever operation preventing solenoid shown by 6. The lever operation preventing solenoid 46 is provided with a drive pin 46a when the limit switch 43 is turned on.
Is pulled back and engaged with the lever 5b of the support shaft 5a. That is, as described above, when the disc 40 moves with respect to the rotating body 24, the operation lever 5 cannot be operated.

As described above, when the guide plate 36 is rotated clockwise by the warm-up throttle lever, the roller 35 moves along the arc-shaped portion 30a of the cam groove 30, and the link member 34 having this roller 35. The movement of causes the throttle control lever 26 to rotate counterclockwise. Therefore, the throttle valve device of the propulsion unit 12 is driven in the throttle opening direction, and the rotation speed increases. At this time, the forward / reverse switching device is not driven, and thus is maintained in the neutral position. When the rotating body 24 is rotating to perform throttle control and full reverse switching, the cylindrical member 41 of the stopper 42 is attached to the outer peripheral surface of the central boss portion 24d of the rotating body 24 as shown in FIGS. 6 and 7. Since the cylindrical member 41 and the semicircular cutout 40a cannot be released from the engaged state, the warm-up operation lever cannot be operated.

Next, the operation of the remote control device 11 according to the present invention will be described. When the operating lever 5 is operated in the shift range shown in FIG. 1, the control unit 16 causes the motor 22 of the actuator 15 to rotate normally or reversely in accordance with the operating direction. For example, when operated to the forward side, the motor 22 is rotated in the normal direction and the rotating body 24 of the actuator 15 is rotated clockwise in FIG. At this time, the rotating body 24 is rotated until the forward switching position is reached. Whether or not the rotating body 24 has rotated to the forward switching position is detected by the control position sensor 27.
It is performed by comparing whether or not the rotation angle of 4 has reached a predetermined value. This comparison is performed by the comparison unit 19 of the control unit 16.

When the rotating body 24 is rotated to the forward switching position or the reverse switching position, the forward / backward switching lever 25 rotates and the forward / backward switching device of the propulsion unit 12 is driven.

When the operation lever 5 is tilted to the front side or the rear side beyond the shift range, the control unit 16 determines that the rotation angle of the rotating body 24 detected by the control position sensor 27 is the swing angle of the operation lever 5. The motor 22 of the actuator 15 is controlled so as to have a value corresponding to. That is, the rotational position of the throttle control lever 26 is controlled by changing the position of the cam portion 30b with respect to the roller 35. At this time, the rotation angle of the throttle control lever 26 increases as the swing angle of the operation lever 5 increases, and the throttle valve opening in the throttle valve device of the propulsion device 12 gradually increases accordingly.

Therefore, in the remote control device 11 for a ship propulsion device according to the present invention, the electric actuator 15 is provided with the forward / reverse switching member and the throttle opening / closing cam member (these are integrally configured as the rotating body 24). The actuator 15 has a structure in which it is driven by the same motor 22 to perform throttle control and forward / backward switching independently, and the actuator 15 is connected to the operating means (the operating lever 5 and the select switch 17) via the control unit 16, so that the throttle control and the forward / backward traveling are performed. The electronic components used for the motor, the speed reducer, and the motor drive circuit required for switching can be provided for only one system.

Further, as shown in this embodiment, when the actuator 15 is used for throttle control, the concave curved surface 33 of the forward / reverse switching lever 25 is slidably brought into contact with the outer peripheral surface 24b of the rotating body 24. Even if a force is applied from the forward / reverse switching device of the propulsion device 12 to the forward / reverse switching lever 25 via the mechanical cable 13, the concave curved surface 33
Because of the function as a stopper, the forward / reverse switching lever is held at the forward switching position or the reverse switching position.

The rotational position of the rotary member 24 may be detected as shown in FIG. FIG. 9 is a plan view showing another embodiment of the actuator, in which the same or equivalent members as those described in FIGS. 3 to 8 are designated by the same reference numerals and detailed description thereof will be omitted.

In FIG. 9, reference numeral 51 is a sensor for detecting the forward drive side switching position and reverse drive side switching position, and 52 is a sensor for detecting the throttle opening. These sensors 51 and 52 are structured to detect the rotation angles of the rotary shafts 51a and 52a and input them to the control unit 16. Then, the sensor 51 is the rotating shaft 51.
An arm 53 is fixed to a and is connected to a forward / reverse switching lever 25 via a link 54 pivotally supported by the arm 53. Further, the sensor 52 has an arm 55 fixed to a rotary shaft 52 a, and a link 5 pivotally supported by the arm 55.
It is connected to the throttle control lever 26 via 6.

With this structure, it is possible to ignore the effects of backlash and play caused by gears, cams, and links, and it is possible to perform throttle control and forward / reverse switching with higher accuracy. In the example shown in FIG. 9, the links 54, 5
6, the operation of the forward / reverse switching lever 25 and the throttle control lever 26 is transmitted to the respective sensors 51, 52. However, the rotation of the forward / reverse switching lever 25 or the throttle control lever 26 is detected by the sensors 51, 52. You may make it detect by 52 directly. Further, a cam is provided on the forward / rearward travel switching lever 25 and the throttle control lever 26, and the potentio arm attached to the cam is attached to the sensor 5.
It may be provided at 1, 52.

[0051]

As described above, the remote control device for a marine propulsion device according to the present invention has a main operation means on the driver side.
The electric actuator on the propulsion unit side
Connects and drives the motor in this electric actuator
Vessels that control the throttle of propulsion and switch between forward and reverse
In a remote control device for a marine propulsion device, the electric actuator
Open the forward / reverse switching member and the first throttle opening
By driving the closing cam members with the same motor,
With the structure to perform throttle control and forward / reverse switching with the body
Control the throttle valve device of the propulsion unit during warm-up operation
The warm-up operation control means is provided, and the warm-up operation control means is provided.
Is provided in the driver's seat separately from the main operating means.
Second connected to operation means for warm-up through operation connection means
Operate the throttle opening / closing cam member and the warm-up operation means.
While operating, the electric actuator
And a regulation means for regulating the control of the chute,
The throttle opening / closing cam member 2 is the forward / reverse switching member.
In the state in which the forward / reverse switching position of is in the neutral position,
Open and close the throttle valve separately from the throttle opening / closing cam member
It is configured as described above.
The remote control device for the ship propulsion system related to Ming
The electric actuator on the side of the propulsion unit
The actuator is connected and inside this electric actuator
Control the propulsion machine throttle control
In the remote control device of the ship propulsion device that performs switching,
The electric actuator includes a forward / reverse switching member and a first
Driving the throttle opening / closing cam member of the same motor
Throttle control and forward / reverse switching by itself
With a structure that performs
This warm-up operation control means for controlling the
The operation control means is separate from the main operation means in the driver's seat.
Connected to the warming-up operation means provided in the
The forward / reverse switching position of the forward / reverse switching member is in the middle
The first throttle opening / closing cam member in the upright position
Second configured separately to open and close the throttle valve
Of the throttle opening / closing cam member and the operation means for warming up.
When the throttle valve is opened due to the work, the main
Control the control of the electric actuator by the operating means,
And the throttle valve is closed by operating the warm-up operation means.
Sometimes motorized action by the main operation means is Flip
With a regulation means that allows the control of the cheater
Some reason, a motor required for the throttle control and forward-reverse switching, electronic components used in the reduction gear and the motor drive circuit becomes only one system.

Therefore, when the throttle control and the forward / reverse switching are performed by the electric actuator, it is possible to minimize the number of expensive parts. Therefore, the remote control device can be obtained at low cost. Also before
Warm-up with the reverse switching member positioned in the neutral position
As the operation begins, warm-up
In order to open the slot valve for
It can be performed independently of the operation system. Further claims
In a remote control device for a ship propulsion device according to the invention described in 2.
According to this, if the vehicle moves forward or backward after the warm-up operation is completed,
The warm-up operation means to the initial position (slot
If you do not release the regulation by the regulation means (by closing the valve)
Controlling the electric actuator with the main operating means
The engine cannot be rotated after warm-up
The main operation means is operated in a low number.
It

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a remote control device for a ship propulsion device according to the present invention.

FIG. 2 is an enlarged cross-sectional view showing a shaft portion of an operation lever of the remote control device according to the present invention.

FIG. 3 is a plan view showing a main part of an actuator used in the remote control device for a boat propulsion device according to the present invention.

4 is a sectional view taken along line IV-IV in FIG.

5 is a plan sectional view showing a configuration of a shift mechanism portion in the actuator, which shows a section taken along line VV of the rotating body and the forward / reverse switching lever in FIG.

FIG. 6 is a plan view showing a main part of the actuator, which shows a state in which the throttle valve device is idling and the forward / reverse switching device is switched to the reverse side.

FIG. 7 is a plan view showing a main part of the actuator, which shows a state in which the forward / reverse switching device is switched to the reverse side and the throttle valve device is substantially fully opened.

FIG. 8 is a plan view of a throttle opening / closing cam used for an actuator.

FIG. 9 is a plan view showing another embodiment of the actuator.

FIG. 10 is a schematic configuration diagram showing a conventional remote control device for a ship propulsion device.

[Explanation of symbols]

5 control lever 11 Remote control device 12 propulsion machine 13 Mechanical cable 14 Mechanical cable 15 Actuator 16 control unit 22 motor 24 rotator 24b outer peripheral surface 25 Forward / reverse switching lever 26 Throttle control lever 27 Control position sensor 29 teeth 30 cam groove 32 teeth 33 concave surface 34 links 35 Laura 36 Guide plate

Claims (2)

(57) [Claims] 1. A controller for the main operating means on the driver's side.
The electric actuator on the propulsion unit side is connected via
In a remote control device for a ship propulsion device, which drives a motor in the electric actuator to perform throttle control of the propulsion device and forward / reverse switching, the electric actuator includes a forward / backward switching member and a first throttle opening / closing cam. a structure for the throttle control and forward-reverse switching alone by driving the member in the same motor, the warm-up
Warm-up operation that controls the throttle valve device of the propulsion unit during operation
The warm-up operation control means is provided with a control means.
The warm-up operation is provided in the seat separately from the main operation means.
A second slot connected to the working means via an operative connecting means.
The tortle open / close cam member and the warm-up operation means are being operated.
The electric actuator operated by the main operating means
Control means for controlling the control of the
The shuttle opening / closing cam member is the forward / backward movement of the forward / backward movement switching member.
The first slot with the switching position in the neutral position
Open and close the throttle valve separately from the opening / closing cam member.
A remote control device for a ship propulsion device, which is configured . 2. A controller for the main operating means on the driver's side.
The electric actuator on the propulsion unit side is connected via
Drive the motor in this electric actuator
Propulsion of ships by controlling the throttle of propulsion and switching between forward and reverse
In a remote control device for a machine, the electric actuator
The forward / reverse switching member and the first throttle opening / closing cam
By driving the members with the same motor,
It has a structure that performs rottle control and forward / reverse switching, and warms up.
Warm-up operation that controls the throttle valve device of the propulsion unit during operation
The warm-up operation control means is provided with a control means.
The warm-up operation is provided in the seat separately from the main operation means.
Is connected to the working means through the operation connecting means, and the forward / backward movement is performed
When the changeover member forward / reverse switching position is in the neutral position,
Throttle valve separate from the first throttle opening / closing cam member
Second throttle opening / closing cam configured to open and close
The throttle valve is operated by operating the member and the warm-up operation means.
When the
Control the actuator and regulate the warm-up operator
When the throttle valve is closed by operating the step,
Allows control of electric actuators by main operating means
A propulsion device for a ship, comprising:
Remote control device.