The present invention relates to an outdrive unit mounted outside of a boat.
A sterndrive, which is one type of an inboard-outboard drive, is a main device comprising an engine and an outdrive unit. The engine is mounted inside the hull, and transmits driving power to the outdrive unit, which is mounted outside the hull. Recently, sterndrive units that allow trolling have also been developed as per user demands. Among such sterndrive units are, for example, those disclosed in Patent Literatures 1 and 2.
In the sterndrive unit disclosed in Patent Literature 1, a hydraulic clutch and a hydraulic circuit for operating the hydraulic clutch are located inboard. The hydraulic circuit also includes a switching valve for switching between forward and reverse propulsion, and a pressure-reducing valve for trolling. However, the hydraulic clutch and hydraulic circuit located inboard reduce the space available inside the boat. For this reason, Patent Literature 2 discloses locating a hydraulic clutch for trolling in an outdrive unit mounted outboard.
Because there is not a large amount of space that can be used inside an outdrive unit, it is necessary to save space in the positioning of a hydraulic circuit. Easy maintenance is also desired for an outdrive unit. However, in the device of Patent Literature 2, although the hydraulic clutch is located outboard, there is no specific disclosure of a hydraulic circuit for trolling control.
The present invention has been made in order to solve the above-described problem. An object of the invention is to provide an outdrive unit that allows space to be saved in the positioning of a hydraulic circuit for trolling, and that enables easy maintenance of the hydraulic circuit for trolling.
The invention provides an outdrive unit mounted outside of a boat, including a propeller for propulsion; a hydraulic clutch that controls driving of the propeller; a transmission mechanism that transmits drive power from the hydraulic clutch to the propeller; a hydraulic circuit that operates the hydraulic clutch; and a housing that houses at least one of the hydraulic clutch, transmission mechanism, and hydraulic circuit. The hydraulic circuit includes a switching valve that switches a rotational direction of the propeller; a pressure-reducing valve for trolling that reduces a pressure of a pressurized oil supplied to the hydraulic clutch; a filter for the pressurized oil introduced to the pressure-reducing valve; and a hydraulic pump that supplies the pressurized oil to the hydraulic clutch. The outdrive unit further includes a base on which the switching valve, pressure-reducing valve, and filter are mounted, the base being detachably mounted in the housing.
In this structure, the switching valve, pressure-reducing valve, and filter that constitute the hydraulic circuit are mounted all together on the base, thereby saving space. Moreover, because the hydraulic circuit for trolling control is located on the base, maintenance on trolling can be easily performed by detaching the base. Furthermore, cables necessary for controlling the switching valve and pressure-reducing valve can be drawn together from the base into the boat, enabling easy maintenance of the cables as well. Note that the shape of the base is not limited; the base may have a box shape that can house the switching valve and the like, or it may be made of a plate-like substrate.
The outdrive unit may further include a sensor that detects rotation of the transmission mechanism or hydraulic clutch. This enables detection of the trolling speed, such that trolling at a desired speed can be realized by controlling the pressure-reducing valve according to the detected rotation. The sensor can also be located on the base, further facilitating maintenance.
The outdrive unit may further include a power-generating device that is mounted on the base and that generates electrical power by the rotation of the transmission mechanism or hydraulic clutch; and a control device that is mounted on the base and that controls the switching valve and pressure-reducing valve. The control device can be operated with the electrical power generated by the power-generating device. Thus, power can be saved.
The control device can be operated wirelessly from inside the boat. This reduces the number of cables to be drawn from inside the boat. Of course, the control device can also be operated via cables from inside the boat.
In the outdrive unit, the base may be mounted on a stern side of the hydraulic clutch, and the hydraulic pump may also be mounted in the base. In this case, the hydraulic pump is connected to the clutch shaft of the hydraulic clutch, and is driven by the rotation of the clutch shaft.
In this structure, the hydraulic circuit that includes the hydraulic pump is mounted on the base, allowing the maintenance of the hydraulic circuit to be easily performed by detaching the base. Particularly because the base is mounted on the stern side of the hydraulic clutch, it can be easily detached. The base may be directly mounted to the hydraulic clutch, or may be mounted thereto via a fixing member. In the base, the switching valve and pressure-reducing valve may be located below the hydraulic pump. The hydraulic pump is located on the stern side of the hydraulic clutch, thereby saving space. The base may also be directly mounted on the stern side of the hydraulic clutch, or may be mounted to the hydraulic clutch via a partition or the like. When a partition or the like is used, the sensor may be secured to the partition.
Furthermore, a detachable cover may be provided on a stern side of the housing, allowing the base to be accessed by opening the cover. This provides quick access to the base by opening the cover, further facilitating maintenance. A plurality of such covers may also be provided. For example, a dual cover may be provided in order to prevent water ingress.
The outdrive unit according to the invention allows space to be saved in the positioning of a hydraulic circuit for trolling, and enables easy maintenance of the hydraulic circuit for trolling.
One embodiment of the outdrive unit according to the invention will be described below, referring to the drawings. A portion of a boat equipped with the outdrive unit is also described herein.
As shown in
The outdrive unit is now described in further detail. The outdrive unit 3 includes a body portion 31 connected to the transom portion 21, and a housing 32 pivotally connected to an aft end of the body portion 31. As shown in
The housing 32 includes an upper housing 321 and a lower housing 322 that are arranged in the vertical direction. Further, a bell housing 323, which is inserted through an opening in the gimbal ring 312, is connected to a fore end of the upper housing 321. Both side surfaces of the gimbal ring 312 are connected to trim-shaft members (illustration omitted) disposed on both sides of the bell housing 323, whereby the bell housing 323 can pivot about the gimbal ring 312 in the vertical direction. The pivoting is performed by a pair of hydraulic cylinders 5 disposed on both sides of the housing 32. Each hydraulic cylinder 5 has a fore end attached to the gimbal ring 312, and an aft end attached to the upper housing 321. Thus, during travel, extending the hydraulic cylinders 5 causes the housing 32 to pivot upward, i.e., trimming out, and retracting the hydraulic cylinders 5 causes the housing 32 to pivot downward, i.e., trimming in.
As shown in
As shown in
A hydraulic control unit 9 incorporating a hydraulic pump 91, a hydraulic circuit for controlling a clutch hydraulic oil, and the like is mounted to a stern-side end of the clutch shaft 61. The hydraulic control unit 9 has a casing 10, in which the hydraulic pump 91 is located. The hydraulic pump 91 is a gear pump with a pair of gears. A gear 91a, which is one of the gears constituting the gear pump, is engaged with the end of the clutch shaft 61 and rotates with the clutch shaft 61, whereby oil is pumped from an oil sump described below so that the hydraulic oil is supplied to the clutch 8. A trochoid pump, for example, may be used as the hydraulic pump 91. Furthermore, as shown in
As shown in
As shown in
Further, an oil sump is formed fore of the propeller shaft 74 in the lower housing 322. The oil contained in the oil sump is pumped through the hydraulic pump 91, and used as a hydraulic oil and lubricating oil for the clutch 8. The oil supplied to the clutch 8 as a lubricating oil drops down through gaps in the periphery of the bevel gear 731 located on the upper end of the drive shaft, and through the oil passage located around the periphery of the drive shaft 73, and then returns to the oil sump.
The hydraulic circuit of the outdrive unit is described next.
When electrical current is not applied to the forward/reverse electromagnetic switching valve 101, return springs 101a, 101b cause the forward/reverse electromagnetic switching valve 101 to shift to a position for stopping the oil supply to the clutch 8. In the event that electrical current cannot be applied to the forward/reverse electromagnetic switching valve 101 because of electrical problems such as a disconnection, the return springs 101a, 101b cause the hydraulic oil supply to be discharged via a drain, so that the clutch 8 is disengaged, and the boat stops.
The operation of the outdrive unit with the above-described structure is described next. As stated above, when the shift lever 52 is placed in a forward position F, hydraulic oil is supplied to the forward piston 83a of the clutch 8 via the forward/reverse electromagnetic switching valve 101, causing the clutch shaft 61 and forward gear 71 to be connected. This causes power from the input shaft 11 to be transmitted to the drive shaft 73 via the forward gear 71, causing the propeller blades 4 to rotate in the forward direction. Conversely, when the shift lever 52 is placed in a reverse position R, hydraulic oil is supplied to the reverse piston 83b of the clutch 8 via the forward/reverse electromagnetic switching valve 101, causing the clutch shaft 61 and reverse gear 72 to be connected. This causes the reverse gear 72 to be rotated, causing the propeller blades 4 to rotate in the reverse direction. Furthermore, a half-clutch position can be attained by adjusting the electromagnetic proportional pressure-reducing valve 102 using the controller 51, thereby enabling trolling. During trolling, the number of revolutions of the propeller blades 4 is detected by a sensor 201 provided in the casing. The degree of opening/closing of the electromagnetic proportional pressure-reducing valve 102 is then adjusted to a number of revolutions that is suitable for trolling.
As described above, according to this embodiment, the forward/reverse electromagnetic switching valve 101, electromagnetic proportional pressure-reducing valve 102, and filter 103 are mounted on the casing 10. This allows maintenance to be easily performed by detaching the casing 10. Particularly because the casing 10 is located at the aftermost position of the housing 32, it is readily accessible by detaching the cosmetic cover 321b and interior cover 99. This further facilitates maintenance. Moreover, because the hydraulic circuit for trolling control is located on the casing 10, maintenance on trolling can be performed all together by detaching the casing 10.
While one embodiment of the present invention has been described above, the invention is by no means limited to the foregoing embodiment, and various modifications are possible without departing from the gist of the invention. For example, although the controller 51 is located inboard in the foregoing embodiment, it may also be located in the outdrive unit.
Furthermore, in the foregoing embodiment, the number of revolutions of the propeller blades 4 is controlled by detecting the rotation of the forward or reverse gear using the sensor 201; however, for example, as shown in
Furthermore, because the hydraulic circuit associated with trolling, which contains the pressure-reducing valve 102 and the like, is located all together in the casing 10, an outdrive unit that does not have a trolling function can be easily made capable of trolling by mounting the casing 10 thereto.
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Number | Date | Country | |
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20110033298 A1 | Feb 2011 | US |