JP7352522B2 - water vehicle - Google Patents

Description

The present invention relates to a water vehicle.

Patent Document 1 discloses a ship that sails with its hull raised above the water surface so that the shaking of the hull due to the influence of waves is reduced. The ship disclosed in Patent Document 1 has hydrofoils fixed to the front and rear of the hull, and a propeller fixed to the side of the rear hydrofoil, and the rotational drive of the propeller is controlled. This allows the hull to be raised and lowered in the vertical direction. Further, the ship has a rudder behind the propulsion device, and can change the direction of travel by using the rudder to change the direction of the water flow generated by the propeller.

Utility model registration No. 3172459

In the ship described in Patent Document 1, since the angle of the hydrofoil with respect to the ship body is fixed, it is difficult to precisely control the attitude of the ship body (main body), such as navigating while keeping the ship horizontal. It can be.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a water vehicle that is advantageous for precisely controlling the attitude of a main body that is floated above the water surface.

In order to achieve the above object, an aspect of the present invention provides a waterborne vehicle that moves with a main body floating above the water surface, and includes a first hydrofoil provided on the main body. and a second hydrofoil, a first propulsion device provided at the top and bottom of the first hydrofoil, and a second propulsion device provided at the top and bottom of the second hydrofoil, respectively, The first hydrofoil and the second hydrofoil are arranged along the left-right direction and configured to be able to change elevation angles independently of each other.

According to the present invention, for example, it is possible to provide a water vehicle that is advantageous for precisely controlling the attitude of a main body that is floated from the water surface.

Schematic diagram showing a water vehicle Diagram of a water vehicle viewed diagonally from the front A rear view of the first hydrofoil, the second hydrofoil, and their surrounding structure Diagram to explain the relationship between angle ωY and elevation angle α of a hydrofoil Control block diagram of waterborne vehicle Diagram showing the output relationship of each propulsion machine to control the attitude of the ship

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. Note that the following embodiments do not limit the claimed invention, and not all combinations of features described in the embodiments are essential to the invention. Two or more features among the plurality of features described in the embodiments may be arbitrarily combined. In addition, the same or similar configurations are given the same reference numerals, and duplicate explanations will be omitted.

An embodiment of a water vehicle 100 according to the present invention will be described with reference to FIGS. 1 to 3. FIG. 1 is a schematic diagram showing a water vehicle 100 of this embodiment, and is a view of the water vehicle 100 viewed from the side. FIG. 2 is a diagram of the waterborne vehicle 100 of this embodiment viewed diagonally from the front, and the upper side of the hull 10 is omitted. Moreover, FIG. 3 is a diagram of a first hydrofoil 21 and a second hydrofoil 22, which will be described later, and their surrounding configurations as seen from the rear. Arrows X, Y, and Z in the figure indicate the front-rear direction, width direction (left-right direction), and vertical direction of the water-based vehicle 100, respectively, and the +X direction is the traveling direction (front direction) of the water-based vehicle 100. .

The water vehicle 100 of the present embodiment is a ship that can move with the hull 10 (main body) on which passengers and cargo are mounted floating above the water surface WS. With such a configuration, it is possible to reduce the shaking of the hull 10 due to the influence of waves and the like. Here, in this embodiment, a ship will be described as an example of the water vehicle 100, but the configuration of the water vehicle 100 of this embodiment may also be applied to a small one-person board, a surfboard, etc. can. For example, the water vehicle 100 may be configured so that its operator can sit on the main body, or may be configured so that the operator rides on the main body in other postures, such as standing or lying face down.

The waterborne vehicle 100 of this embodiment includes a first hydrofoil 21 and a second hydrofoil 22. The first hydrofoil 21 and the second hydrofoil 22 are provided at the front part of the hull 10 below the hull 10, and are supported by a first support member 41 attached to the lower part (lower surface) of the hull 10. . Moreover, the first hydrofoil 21 and the second hydrofoil 22 are arranged so as to be lined up along the left-right direction (Y direction), and are configured to be able to change the elevation angle independently of each other. In the case of this embodiment, the first hydrofoil 21 is arranged on the right side (-Y direction side) below the hull 10, and the second hydrofoil 22 is arranged on the left side (+Y direction side) below the hull 10. It is located. The first hydrofoil 21 and the second hydrofoil 22 can rotate independently of each other around an axis parallel to the left-right direction within a predetermined angular range (that is, the angle ωY around the axis can be rotated independently of each other). (changeable) by a first support member 41.

A first propulsion device 31 that generates propulsive force is provided at the upper and lower portions of the first hydrofoil 21, respectively. Specifically, the first upper propulsion device 31U is attached to the upper portion of the first hydrofoil 21, and the first lower propulsion device 31L is attached to the lower portion of the first hydrofoil 21. In the case of this embodiment, the first propulsion device 31 (first upper propulsion device 31U, first lower propulsion device 31L) is, for example, an electric propulsion device having a motor M and a propeller P attached to its rotation shaft. By changing the rotational speed of the propeller P according to the electric power supplied to the motor M, the propulsive force can be changed. In the first hydrofoil 21 configured in this way, the elevation angle (angle around an axis parallel to the left-right direction) is adjusted depending on the output difference (propulsion force difference) between the first upper propulsion machine 31U and the first lower propulsion machine 31L. ωY) can be changed passively. As an example, the angle ωY of the first hydrofoil 21 may be adjusted so that the elevation angle α becomes larger by making the output (propulsion) of the first lower propulsion machine 31L larger than the output (propulsion) of the first upper propulsion machine 31U. It can be changed. On the other hand, by making the output (propulsion) of the first lower propulsion machine 31L smaller than the output (propulsion) of the first upper propulsion machine 31U, the angle ωY of the first hydrofoil 21 is changed so that the elevation angle α becomes smaller. can be done. Note that the relationship between the angle ωY of the hydrofoil (the first hydrofoil 21, the second hydrofoil 22) and the elevation angle α is as shown in FIG.

Similarly, second propulsion units 32 that generate propulsive force are provided at the upper and lower parts of the second hydrofoil 22, respectively. Specifically, a second upper propulsion device 32U is attached to the upper portion of the second hydrofoil 22, and a second lower propulsion device 32L is attached to the lower portion of the second hydrofoil 22. In the case of the present embodiment, the second propulsion device 32 (second upper propulsion device 32U, second lower propulsion device 32L) is, for example, an electric propulsion device having a motor M and a propeller P attached to its rotating shaft. By changing the rotational speed of the propeller P according to the electric power supplied to the motor M, the propulsive force can be changed. In the second hydrofoil 22 configured in this way, the elevation angle (angle around an axis parallel to the left-right direction) is adjusted depending on the output difference (propulsion force difference) between the second upper propulsion machine 32U and the second lower propulsion machine 32L. ωY) can be changed passively. As an example, by making the output (propulsive force) of the second lower propulsion machine 32L larger than the output (propulsion force) of the second upper propulsion machine 32U, the angle ωY of the second hydrofoil 22 can be adjusted so that the elevation angle α becomes larger. It can be changed. On the other hand, by making the output (propulsion) of the second lower propulsion machine 32L smaller than the output (propulsion) of the second upper propulsion machine 32U, the angle ωY of the second hydrofoil 22 is changed so that the elevation angle α becomes smaller. can be done.

Furthermore, the waterborne vehicle 100 of this embodiment may include a third hydrofoil 23. The third hydrofoil 23 is provided below the hull 10 at the rear of the hull 10 and is supported by a second support member 42 attached to the lower part (lower surface) of the hull 10. In the case of this embodiment, the third hydrofoil 23 is arranged on the rear side (-X direction side) of the first hydrofoil 21 and the second hydrofoil 22, and compared to the first hydrofoil 21 and the second hydrofoil 22. It can be placed near the hull 10 (on the +Z direction side). That is, the third hydrofoil 23 is provided so that the distance to the hull 10 is shorter than that of the first hydrofoil 21 and the second hydrofoil 22. Further, the angle of the third hydrofoil 23 with respect to the hull 10 (for example, the angle ωY around an axis parallel to the left-right direction) is fixed. Here, as shown in FIG. 1, the third hydrofoil 23 of this embodiment is configured in a V-shape when viewed from the rear in order to reduce fluctuations in the left-right direction at the rear of the hull 10. However, the present invention is not limited thereto, and the third hydrofoil 23 may have a linear or curved shape when viewed from the rear, for example.

The first hydrofoil 21, the second hydrofoil 22, and the third hydrofoil 23 have a cross-sectional shape (airfoil shape) in which the upper surface is more curved than the lower surface. Due to this cross-sectional shape, the flow velocity of the fluid (water) is higher on the lower surface than on the upper surface of each hydrofoil, so the pressure on the upper surface becomes smaller than the pressure on the lower surface, and the lifting force for raising the hull 10 from the water surface WS is reduced. It can be generated on hydrofoils. In addition, in this embodiment, the first hydrofoil 21, the second hydrofoil 22, and the third hydrofoil 23 are placed below the hull 10 so that the lift generated by each hydrofoil can be efficiently transmitted to the hull 10. However, the invention is not limited to this. For example, using the first support member 41 and/or the second support member 42 configured in an L shape, the first hydrofoil 21 , the second hydrofoil 22 , and the third hydrofoil 23 are attached to a portion other than below the hull 10 . It may also be placed underwater. Furthermore, in the present embodiment, one propulsion device is provided in the upper and lower parts of each of the first hydrofoil 21 and the second hydrofoil 22, but the present invention is not limited to this. A propulsion device may be provided.

Next, an example of controlling the waterborne vehicle 100 (ship) of this embodiment will be described. FIG. 5 is a control block diagram of the waterborne vehicle 100. The water vehicle 100 of this embodiment includes a control unit 50 that controls the attitude of the first hull 10 by controlling the first propulsion device 31 and the second propulsion device 32, as shown in FIG. Specifically, the control unit 50 individually adjusts the output (propulsive force) of the first upper propulsion device 31U, the first lower propulsion device 31L, the second upper propulsion device 32U, and the second lower propulsion device 32L. , the attitude of the hull 10 can be controlled by individually adjusting the elevation angles of the first hydrofoil 21 and the second hydrofoil. The control unit 50 is, for example, an ECU (Electronic Control Unit), and may include a processor represented by a CPU, a storage device such as a semiconductor memory, an interface with an external device, and the like. Furthermore, the water vehicle 100 further includes a battery 51 that stores electric power to be supplied to the first propulsion device 31 and the second propulsion device 32. The control unit 50 can control the propulsive force of each propulsion device by controlling the electric power supplied from the battery 51 to each propulsion device. The control unit 50 and the battery 51 may be mounted on the hull 10.

Furthermore, the waterborne vehicle 100 may further include an attitude detection section 52 that detects the attitude of the hull 10. The attitude detection unit 52 includes, for example, a gyro sensor, and detects the inclination of the hull 10 (that is, pitching, rolling, and yawing of the hull 10) with respect to each of the pitch axis, roll axis, and yaw axis. Based on the detection result of the posture detection section 52, the control section 50 can control the posture (pitching, rolling, and yawing) of the hull 10 so that the hull 10 maintains the target posture (for example, horizontal). Here, the waterborne vehicle 100 may further include a speed detection section 53 that detects the speed of the hull 10 and an acceleration detection section 54 that detects the acceleration of the hull 10, as shown in FIG. Thereby, the control unit 50 can control the speed and acceleration of the hull 10 based on the detection results from the speed detection unit 53 and the acceleration detection unit 54. Each of the detection units 52 to 54 can be mounted on the hull 10.

The water vehicle 100 may further include a reception unit 55 that receives a control instruction (input) for the water vehicle 100 from an operator aboard the hull 10. The control instructions may include, for example, turning the water vehicle 100 to the right, turning to the left, accelerating, decelerating, and the like. The reception unit 55 may be configured to receive the operation of the control stick (helm) by the operator as a control instruction, and may have a sensor that detects the weight shift of the operator on the hull 10, It may be configured to accept weight shift as a control instruction. As an example, when the receiving unit 55 receives a control instruction for turning the water vehicle 100 to the right, the control unit 50 determines that the output of the second propulsion unit 32 is higher than the output (propulsive force) of the first propulsion unit 31. The first propulsion device 31 and the second propulsion device 32 are controlled so that (propulsive force) is increased by an amount corresponding to the control instruction (size of right turn). Thereby, the water vehicle 100 can be turned to the right. On the other hand, when the reception unit 55 receives a control instruction for turning the water vehicle 100 to the left, the control unit 50 determines that the output (propulsion force) of the first propulsion device 31 is higher than the output (propulsion force) of the second propulsion device 32. The first propulsion device 31 and the second propulsion device 32 are controlled so that the amount of force) becomes larger by an amount corresponding to the control instruction (size of left turn). Thereby, the waterborne vehicle 100 can be turned to the left.

Next, attitude control of the hull 10 in the waterborne vehicle 100 of this embodiment will be explained. In the waterborne vehicle 100 of this embodiment, the control unit 50 automatically controls the attitude of the hull 10 based on the detection result of the attitude detection unit 52 so that the hull 10 maintains a target attitude (for example, horizontal). Specifically, the control unit 50 individually adjusts the output of the first upper propulsion device 31U, the first lower propulsion device 31L, the second upper propulsion device 32U, and the second lower propulsion device 32L (that is, the output of the first upper propulsion device 31U, the second lower propulsion device 32L) , 31L, 32U, and 32L), the attitude of the hull 10 can be automatically controlled so that the hull 10 maintains the target attitude.

Here, the control unit 50 can automatically control the attitude of the hull 10 so that the hull 10 maintains the target attitude even when controlling the waterborne vehicle 100 according to a control instruction from the operator. As an example, when receiving a control instruction to turn the water vehicle 100 (turn right or turn left), the control unit 50 may control the turning of the water vehicle 100 while controlling the hull 10 to the target attitude. . Similarly, even when receiving a control instruction to accelerate or decelerate the waterborne vehicle 100 and raise or lower the hull 10 in the vertical direction, the control unit 50 controls the elevation or lowering of the hull 10 while controlling the hull 10 to the target attitude. I can do it.

FIG. 6 shows the output relationship of each propulsion device for controlling the attitude of the hull 10. In FIG. 6, "F _1U " represents the output of the first upper propulsion device 31U, and "F _1L " represents the output of the first lower propulsion device 31L. Further, “F _2U ” represents the output of the second upper propulsion device 32U, and “F _2L ” represents the output of the second lower propulsion device 32L. Note that the output of each propulsion device refers to the propulsive force generated by each propulsion device.

For example, when controlling the rolling of the hull 10, the control unit 50 controls the difference in output of the first propulsion unit 31 between the upper and lower parts of the first hydrofoil 21 and the upper and lower parts of the second hydrofoil 22. The difference with the output difference of the second propulsion device 32 is adjusted. Specifically, when raising the left side of the hull 10 (“+ (left up)” in FIG. 6), the control unit 50 controls the output difference between the first upper propulsion device 31U and the first lower propulsion device 31L (F _1U -F _1L ) is greater than the output difference (F _2U -F _2L ) between the second upper propulsion device 32U and the second lower propulsion device 32L. On the other hand, when lowering the left side of the hull 10 (“-(lower left)” in FIG. 6), the control unit 50 controls the output difference between the first upper propulsion device 31U and the first lower propulsion device 31L (F _1U −F _1L ) is smaller than the output difference (F _2U −F _2L ) between the second upper propulsion device 32U and the second lower propulsion device 32L. In this embodiment, an example was shown in which the rolling of the hull 10 is controlled using the output difference between the upper propulsion machine and the lower propulsion machine, but the rolling of the hull 10 is controlled using the output ratio between the upper propulsion machine and the lower propulsion machine. may control rolling.

When controlling the pitching of the hull 10 , the control unit 50 uses the resultant force of the output of the propulsion machine provided at the upper part of the first hydrofoil 21 and the second hydrofoil 22 and the first hydrofoil 21 and the second hydrofoil 22 . Adjusts the difference between the output of the propulsion unit installed at the bottom of the unit and the resultant force (output difference). Specifically, when raising the front side of the hull 10 (“+ (front raising)” in FIG. 6), the control unit 50 controls the output F _1U of the first upper propulsion device 31U and the output F of the second upper propulsion device 32U. _{Each propulsion force is _ _ _} control the machine. On the other hand, when lowering the front side of the hull 10 (“-(forward lowering)” in FIG. 6), the control unit 50 controls the output F _1U of the first upper propulsion device 31U and the output F _2U of the second upper propulsion device 32U. Each propulsion machine is controlled so that the resultant force (F _1U +F _2U ) is larger than the resultant force (F _1L +F _2L ) of the output F _1L of the first lower propulsion machine 31L and the output F _2L of the second lower propulsion machine. .

When controlling the yawing of the hull 10, the control unit 50 adjusts the output difference between the first propulsion device 31 provided on the first hydrofoil 21 and the second propulsion device 32 provided on the second hydrofoil 22. . Specifically, when rotating the hull clockwise (“+ (clockwise rotation)” in FIG. 6), the control unit 50 controls the output F _1U of the first upper propulsion device 31U and the output F _1L of the first lower propulsion device 31L. Each propulsion device is controlled such that the resultant force of the output F _2U of the second upper propulsion device 32U and the output F 2L of the second lower propulsion device 32L is smaller than the resultant force of the output F 2U of the second upper propulsion device 32U and the output F _2L of the second lower propulsion device 32L. On the other hand, when rotating the hull to the left (“- (left rotation)” in FIG. 6), the control unit 50 controls the resultant force of the output F _1U of the first upper propulsion device 31U and the output F _1L of the first lower propulsion device 31L. Each propulsion device is controlled such that the output force F _2U of the second upper propulsion device 32U and the output F _2L of the second lower propulsion device 32L are greater than the resultant force.

In the waterborne vehicle 100 of the present embodiment, by increasing the angle of attack of the first hydrofoil 21 and the second hydrofoil 22 arranged on the front side of the hull 10, the angle of attack of the first hydrofoil 21 and the second hydrofoil 22 is increased. Can increase lift. In this case, as the hull 10 transitions to a forward rising attitude in the pitch direction, the angle of attack of the third hydrofoil 23 disposed on the rear side of the hull 10 also increases, causing the hull 10 to transition to a forward rising attitude in the pitch direction. The lift of the third hydrofoil 23 increases to cancel the transition. That is, with the configuration of the waterborne vehicle 100 of this embodiment, the hull 10 can be raised and lowered in the vertical direction while maintaining the hull 10 in the target attitude. Further, since the third hydrofoil 23 is closer to the hull 10 than the first hydrofoil 21 and the second hydrofoil 22, when trying to further float the hull 10, the first hydrofoil 21 and the second hydrofoil It leaves the water surface WS before the hydrofoil 22 does. In this case, since the third hydrofoil 23 does not rise any further, it is assumed that only the first hydrofoil 21 and the second hydrofoil 22 rise, and the hull 10 rises forward. However, in the waterborne vehicle 100 of the present embodiment, the control unit 50 controls the attitude of the hull 10 based on the detection result of the attitude detection unit 52 so that the hull 10 maintains the target attitude. When the hydrofoil moves forward, each propulsion machine is controlled to reduce the lift of the first hydrofoil 21 and the second hydrofoil 22. Therefore, the waterborne vehicle 100 can control the floating height of the hull 10 from the water surface WS so that each hydrofoil is located underwater. In this way, with the configuration of the waterborne vehicle 100 of this embodiment, the floating height of the hull 10 can be controlled only by the detection result of the attitude of the hull 10, without directly detecting the floating height of the hull 10. .

As described above, the waterborne vehicle 100 of the present embodiment includes the first hydrofoil 21 and the second hydrofoil 22 arranged in the left-right direction below the hull 10, and the upper and lower portions of the first hydrofoil 21 A first propulsion device 31 is provided at each of the two hydrofoils 22, and a second propulsion device 32 is provided at the upper and lower portions of the second hydrofoil 22, respectively. Further, the first hydrofoil 21 and the second hydrofoil are configured so that the angle of elevation changes according to the output of each propulsion device. With this configuration, the attitude (rolling, pitching, yawing) of the hull 10 can be controlled with high accuracy by adjusting the output of each propulsion device.

<Other embodiments>
In the above embodiment, an electric propulsion device having a motor M is used as the first propulsion device 31 and the second propulsion device 32, but the invention is not limited thereto, and an engine type propulsion device may be used. In this case, each propulsion device may be provided with an engine individually, but one engine is mounted on the hull 10, and the driving force of the engine is transmitted to the propeller P of each propulsion device by a transmission mechanism or the like. It may also be configured to transmit the information.

<Summary of embodiments>
1. The water vehicle of the above embodiment is
A water vehicle (for example, 100) that moves with a main body (for example, 10) floating above the water surface,
a first hydrofoil (e.g. 21) and a second hydrofoil (e.g. 22) provided on the main body;
first propulsion units (for example, 31, 31U, 31L) provided at the upper and lower parts of the first hydrofoil, respectively;
second propulsion machines (for example, 32, 32U, 32L) provided at the upper and lower parts of the second hydrofoil, respectively;
Equipped with
The first hydrofoil and the second hydrofoil are arranged along the left-right direction, and are configured to be able to change elevation angles independently of each other.
According to this configuration, the attitude of the main body (e.g. rolling, pitching, yawing) can be controlled by adjusting the output of each propulsion unit individually and changing the elevation angle of the first hydrofoil and the second hydrofoil individually. It can be controlled with high precision. As a result, it is possible to reduce fluctuations and shaking in the posture of the main body.

2. In the above embodiment,
The first hydrofoil is configured such that the angle of elevation changes depending on the difference in output of the first propulsion device between the upper and lower parts of the first hydrofoil,
The second hydrofoil is configured to have an elevation angle that changes depending on a difference in output of the second propulsion device between an upper portion and a lower portion of the second hydrofoil.
According to this configuration, by individually adjusting the output (propulsive force) of the propulsion machine at the upper and lower parts of each of the first hydrofoil and the second hydrofoil, the first hydrofoil and the second hydrofoil are By individually changing the elevation angle, the attitude of the main body can be controlled with high precision.

3. In the above embodiment,
The hydrofoil further includes a third hydrofoil (for example, 23) fixed to the main body portion on the rear side of the first hydrofoil and the second hydrofoil.
According to this configuration, the posture of the main body portion floated above the water surface can be more stabilized.

4. In the above embodiment,
The apparatus further includes a control section (for example, 50) that controls the attitude of the main body by adjusting the outputs of the first propulsion device and the second propulsion device.
According to this configuration, by individually adjusting the output of each propulsion device, the attitude of the main body can be controlled with high accuracy.

5. In the above embodiment,
The water vehicle is
A first upper propulsion device (for example, 31U) provided at the top of the first hydrofoil and a first lower propulsion device (for example, 31L) provided at the bottom of the first hydrofoil, the first propulsion device Prepare as
A second upper propulsion device (for example, 32U) provided at the top of the second hydrofoil and a second lower propulsion device (for example, 32L) provided at the bottom of the second hydrofoil, the second propulsion device Prepare as
The control unit controls the attitude of the main body by adjusting the output balance of the first upper propulsion machine, the first lower propulsion machine, the second upper propulsion machine, and the second lower propulsion machine.
According to this configuration, by individually adjusting the output of each propulsion device, the elevation angles of the first hydrofoil and the second hydrofoil can be changed individually and with high precision, and the attitude of the main body can be controlled with even more precision. I can do it.

6. In the above embodiment,
Further comprising a detection means (for example, 52) for detecting the attitude of the main body,
The control unit controls the attitude of the main body based on the detection result of the detection means so that the main body maintains a target attitude.
According to this configuration, the attitude of the main body can be controlled with high accuracy. Furthermore, it is possible to automatically control the posture of the main body.

7. In the above embodiment,
The control unit is configured to control a difference between an output difference of the first propulsion device between an upper portion and a lower portion of the first hydrofoil and an output difference of the second propulsion device between an upper portion and a lower portion of the second hydrofoil. The rolling of the main body portion is controlled by adjusting.
According to this configuration, rolling can be controlled as the attitude of the main body by adjusting the output of each propulsion device.

8. In the above embodiment,
The control unit is configured to generate a resultant force of outputs of propulsion machines provided above the first hydrofoil and the second hydrofoil, and a propulsion machine provided below the first hydrofoil and the second hydrofoil. The pitching of the main body is controlled by adjusting the difference between the output and the resultant force.
According to this configuration, pitching can be controlled as the attitude of the main body by adjusting the output of each propulsion device.

9. In the above embodiment,
The control unit controls yawing of the main body by adjusting an output difference between the first propulsion device and the second propulsion device.
According to this configuration, yawing can be controlled as the attitude of the main body by adjusting the output of each propulsion device.

10. In the above embodiment,
The above-mentioned water vehicle is a ship that moves with the hull as the main body floating above the water surface.
According to this configuration, it is possible to reduce fluctuations in attitude and shaking of the ship in a ship that moves with the ship floating above the water surface.

The present invention is not limited to the above-described embodiments, and various changes and modifications can be made without departing from the spirit and scope of the present invention.

10: Hull (main body), 21: First hydrofoil, 22: Second hydrofoil, 23: Third hydrofoil, 31: First propulsion machine, 32: Second propulsion machine, 50: Control unit, 52: Attitude detection unit, 100: Water mobile object

Claims (10)

A waterborne vehicle that moves with its main body floating above the water surface,
a first hydrofoil and a second hydrofoil provided on the main body;
a first propulsion device provided at an upper portion and a lower portion of the first hydrofoil, respectively;
a second propulsion device provided at an upper portion and a lower portion of the second hydrofoil, respectively;
Equipped with
The above-mentioned first hydrofoil and the above-mentioned second hydrofoil are arranged along the left-right direction, and are configured to be able to change elevation angles independently of each other. The first hydrofoil is configured such that the angle of elevation changes depending on the difference in output of the first propulsion device between the upper and lower parts of the first hydrofoil,
The second hydrofoil is configured to have an elevation angle that changes according to a difference in output of the second propulsion device between an upper portion and a lower portion of the second hydrofoil.
The water vehicle according to claim 1, characterized in that: The water vehicle according to claim 1 or 2, further comprising a third hydrofoil fixed to the main body at a rear side of the first hydrofoil and the second hydrofoil. 4. The apparatus according to claim 1, further comprising a control section that controls the attitude of the main body by adjusting outputs of the first propulsion device and the second propulsion device. water vehicle. The water vehicle is
The first propulsion device includes a first upper propulsion device provided at the top of the first hydrofoil and a first lower propulsion device provided at the bottom of the first hydrofoil,
The second propulsion device includes a second upper propulsion device provided at the top of the second hydrofoil and a second lower propulsion device provided at the bottom of the second hydrofoil,
The control unit controls the attitude of the main body by adjusting the output balance of the first upper propulsion machine, the first lower propulsion machine, the second upper propulsion machine, and the second lower propulsion machine. The water vehicle according to claim 4, characterized in that: Further comprising a detection means for detecting the attitude of the main body,
The water vehicle according to claim 4, wherein the control unit controls the attitude of the main body so that the main body maintains a target attitude based on the detection result of the detection means. . The control unit is configured to control a difference between an output difference of the first propulsion device between an upper portion and a lower portion of the first hydrofoil and an output difference of the second propulsion device between an upper portion and a lower portion of the second hydrofoil. The water vehicle according to any one of claims 4 to 6, wherein rolling of the main body is controlled by adjusting. The control unit is configured to generate a resultant force of outputs of propulsion machines provided above the first hydrofoil and the second hydrofoil, and a propulsion machine provided below the first hydrofoil and the second hydrofoil. 8. The water vehicle according to claim 4, wherein pitching of the main body is controlled by adjusting a difference between the output and the resultant force. 9. The control unit controls yawing of the main body by adjusting an output difference between the first propulsion device and the second propulsion device. The water vehicle described in . The water vehicle according to any one of claims 1 to 9, wherein the water vehicle is a ship that moves with a hull as the main body floating above the water surface.