Outboard motor

Information

  • Patent Grant
  • 6824434
  • Patent Number
    6,824,434
  • Date Filed
    Friday, June 27, 2003
    21 years ago
  • Date Issued
    Tuesday, November 30, 2004
    20 years ago
Abstract
An outboard motor includes upper and lower pivot shafts provided respectively in a swivel case and a pair of left and right stern brackets supporting the swivel case via a tilt shaft. Upper and lower end portions of an extendable part of a tilt system are mounted on the upper and lower pivot shafts. First and second mounting parts are provided on the upper pivot shaft so that they are offset in mutually opposite left and right directions from a central position between the pair of stern brackets. The offset of the second mounting part is set smaller than the offset of the first mounting part. Consequently, either a gas-assist type or power type tilt system can be mounted with good balance between the left and right stern brackets, thereby improving the appearance.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to an improvement of an outboard motor comprising a swivel case axially and steerably supporting a propulsion unit, a pair of left and right stern brackets disposed on left and right sides of the swivel case and supporting the swivel case in a vertically tiltable manner via a tilt shaft, and an upper pivot shaft and a lower pivot shaft that are parallel to the tilt shaft and are provided in the swivel case and the left and right stern brackets respectively, upper and lower end portions of an extendable part of a tilt system being mounted on the upper and lower pivot shafts.




2. Description of the Related Art




When a tilt system is mounted in a conventional outboard motor, as disclosed in, for example, Japanese Patent Application Laid-open No. 4-5190, one mounting part is provided on a central part of each of upper and lower pivot shafts. In the case of both a gas-assist type tilt system and a power type tilt system, upper and lower end portions thereof are mounted on the corresponding mounting parts provided on each of the upper and lower pivot shafts at central positions between left and right stern brackets.




In general, the gas-assist type tilt system employs an accumulator tank provided so as to be connected to one side of an assist cylinder and having a comparatively small diameter in the same way as the assist cylinder, whereas the power type tilt system employs a hydraulic pump and an electric motor provided so as to be connected to one side of a hydraulically operated cylinder and having larger diameters than that of the hydraulically operated cylinder. Therefore, if the assist cylinder or the hydraulically operated cylinder is mounted on the mounting parts in the center of the upper and lower pivot shafts, then the accumulator tank or the hydraulic pump and the electric motor are offset leftward or rightward from the central position between the left and right stern brackets, and consequently the entire tilt system is offset from the central position between the two stern brackets, thus impairing the appearance of the outboard motor.




SUMMARY OF THE INVENTION




The present invention has been achieved in view of the above-mentioned circumstances, and it is an object thereof to provide an outboard motor wherein either a gas-assist type or a power type tilt system can be mounted with good balance between left and right stern brackets, thereby improving the appearance.




In order to accomplish the above object, a first aspect of the present invention provides an outboard motor that includes a swivel case axially and steerably supporting a propulsion unit, a pair of left and right stern brackets disposed on left and right sides of the swivel case and supporting the swivel case. In a vertically tiltable manner via a tilt shaft, and upper and lower pivot shafts that are parallel to the tilt shaft and are provided in the swivel case and the left and right stern brackets respectively, upper and lower end portions of an extendable part of a tilt system being mounted on the upper and lower pivot shafts, wherein the upper pivot shaft includes first and second mounting parts that are offset in mutually opposite left and right directions from a central position between the pair of stern brackets, the offset of the second mounting part is set smaller than the offset of the first mounting part, and the upper end portion of the extendable part of the tilt system is mounted selectively on one of the first and second mounting parts according to the type of tilt system.




The tilt system corresponds to a power type tilt system


16


P and a gas-assist type tilt system


16


G of an embodiment of the present invention which will be described later, and the extendable part of the tilt system corresponds to a hydraulically operated cylinder


30


and an assist cylinder


40


.




In accordance with this first aspect, since the upper end portion of the extendable part of the tilt system is selectively mounted on one of the first and second mounting parts of the upper pivot shaft according to the type of tilt system, by adjusting the size of a space formed beneath the other mounting part which is not used and arranging in this space an auxiliary equipment of the tilt system according to the size of the space, the entirety of the tilt system irrespective of the type can be arranged in the central position between the left and right stern brackets, thus achieving a good appearance of the outboard motor and a good weight balance in the left and right directions.




Furthermore, in accordance with a second aspect of the present invention, in addition to the first aspect, there is provided an outboard motor wherein the tilt system is of a power type in which a hydraulic pump and an electric motor are connected to one side of a hydraulically operated cylinder, an upper end part of the hydraulically operated cylinder is mounted on the first mounting part, and the hydraulic pump and the electric motor are disposed on the second mounting part side.




In accordance with this second aspect, the entire power type tilt system can be arranged in the central position between the left and right stern brackets, thus achieving a good appearance of the outboard motor and a good weight balance in the left and right directions.




Moreover, in accordance with a third aspect of the present invention, in addition to the first aspect, there is provided an outboard motor wherein the tilt system is of a gas-assist type in which a cylindrical accumulator tank is connected to one side of an assist cylinder, an upper end part of the assist cylinder is mounted on the second mounting part, and the accumulator tank is disposed on the first mounting part side.




In accordance with this third aspect, the entire gas-assist type tilt system can be arranged in the central position between the left and right stern brackets, thus achieving a good appearance of the outboard motor and a good weight balance in the left and right directions.




Furthermore, in accordance with a fourth aspect of the present invention, in addition to the first aspect, there is provided an outboard motor wherein the pair of left and right stern brackets are provided with a plurality of sets of pairs of left and right adjustment holes arranged in the vertical direction, a stopper pin that determines the tilted down position of the propulsion unit by receiving a stopper surface formed on a front surface of the swivel case is inserted through and supported selectively in one pair of the plurality of sets of adjustment holes so as to adjust the tilted down position of the propulsion unit in a plurality of steps, the swivel case has a second stopper surface formed below the stopper surface, the stern brackets have formed thereon a stopper wall that defines the lowest tilted down position of the propulsion unit by receiving the second stopper surface when the stopper pin is detached from the adjustment holes, and these stern brackets are provided with retention holes that retain the stopper pin detached from the adjustment hole.




In accordance with this fourth aspect, the number of adjustment positions of the tilted down position of the propulsion unit can be increased by one step with a very simple structure in which the second stopper surface is formed on the swivel case below the stopper surface and the stopper walls are formed on the stern brackets, the stopper walls defining the lowest tilted down position of the propulsion unit by receiving the second stopper surface when the stopper pin is detached from the adjustment holes. As a result, since it is unnecessary to increase the number of pairs of adjustment holes, there is no need to enlarge portions of the stern brackets where adjustment holes are to be provided, nor decrease in the turning angle of the propulsion unit. Moreover, in the case where the stopper pin is not in use, it can be retained in the retention holes of the stern brackets, thereby preventing it from being lost.




Furthermore, in accordance with a fifth aspect of the present invention, in addition to the fourth aspect, there is provided an outboard motor wherein, when the second stopper surface is received by the stopper wall, the swivel case is held between the two stern brackets.




In accordance with this fifth aspect, when the propulsion unit is trimmed to the lowest tilted down position, the lateral load acting on the swivel case can be firmly supported by the left and right stern brackets.




Moreover, in accordance with a sixth aspect of the present invention, in addition to the fourth or fifth aspect, there is provided an outboard motor wherein, when the stopper pin is inserted into the adjustment holes or the retention holes, a retaining key is axially supported on one end part of the stopper pin so that the retaining key can pivot between a dropped down position in which the retaining key is coaxial with the stopper pin and can pass through the adjustment holes or the retention holes together with the stopper pin, and a raised position in which the retaining key abuts against an outer side surface of one of the stern brackets, and a spring is fitted to the other end part of the stopper pin, the spring being compressed against an outer side surface of the other stern bracket and biasing the stopper pin in a direction opposite to the retaining pin.




In accordance with this sixth aspect, fitting of the stopper pin into the adjustment holes and the retaining holes and detachment therefrom can be carried out simply, and when the stopper pin is fitted the raised position of the retaining key can be maintained by the resilient force of the spring and noise due to rattling can be prevented.




The above-mentioned object, other objects, characteristics, and advantages of the present invention will become apparent from an explanation of preferred embodiments, which will be described in detail below, by reference to the attached drawings.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a side view of an outboard motor.





FIG. 2

is a vertical cross-sectional side view of a part of

FIG. 1

showing a mode in which a power type tilt system is mounted.





FIG. 3

is a view from arrow


3


in FIG.


2


.





FIG. 4

is a cross sectional view taken along line


4





4


in FIG.


2


.





FIG. 5

is a view, corresponding to

FIG. 2

, showing the lowest tilted down state of a propulsion unit.





FIG. 6

is a cross sectional view taken along line


6





6


in FIG.


5


.





FIG. 7

is a view, corresponding to

FIG. 2

, showing a tilted up state of the propulsion unit.





FIG. 8

is a cross sectional view taken along line


8





8


in FIG.


7


.





FIG. 9

is a view, corresponding to

FIG. 2

, showing a mode in which a gas-assist type tilt system is mounted.





FIG. 10

is a cross sectional view taken along line


10





10


in FIG.


9


.





FIG. 11

is an enlarged view of an essential part in FIG.


10


.





FIG. 12

is a view, corresponding to

FIG. 9

, showing a tilted up state of a propulsion unit.





FIG. 13

is a cross sectional view taken along line


13





13


in FIG.


12


.











DESCRIPTION OF THE PREFERRED EMBODIMENT




A preferred embodiment of the present invention is explained below by reference to the attached drawings.




In the explanation below, the terms ‘front’ (‘forward’), ‘rear’ (‘reverse’), ‘left’, and ‘right’ are used with reference to a hull on which an outboard motor is mounted.




Referring firstly to

FIG. 1

, a propulsion unit U of an outboard motor O includes an extension case


1


and a gear case


2


that is joined to a lower part of the extension case


1


. A water-cooled multi-cylinder four-stroke engine E is mounted in an upper part of the extension case


1


so that a crankshaft


3


is vertical. An engine hood


4


covering the engine E is mounted on an upper end part of the extension case


1


so that the hood can be opened and closed.




Connected to the crankshaft


3


of the engine E is a drive shaft


5


disposed vertically within the extension case


1


. Supported in the gear case


2


is a propeller shaft


7


to the rear end of which a propeller


6


is fixed. Housed within the gear case


2


is a forward/reverse switch-over device


8


which connects the drive shaft


5


to the propeller shaft


7


. While the engine E is being operated, the power transmitted from the crankshaft


3


to the drive shaft


5


is therefore transmitted to the propeller shaft


7


via the forward/reverse switch-over device


8


. The rotational direction of the propeller shaft


7


is controlled by the forward/reverse switch-over device


8


.




Vertically opposite ends of a swivel shaft


12


are fixed to an upper arm


10


and a lower arm


11


. The upper arm


10


supports an upper part of the extension case


1


, and the lower arm


11


supports a lower part of the extension case


1


. A swivel case


13


rotatably supports the swivel shaft


12


and is connected via a horizontal tilt shaft


15


to a pair of left and right stern brackets


14


L and


14


R clamped to a transom T of a hull with the swivel case


13


interposed therebetween. The propulsion unit U therefore can tilt vertically around the tilt shaft


15


.




As shown in

FIGS. 2 and 3

, the swivel case


13


includes a cylindrical case part


17


and an arm part


18


. The case part


17


directly supports the swivel shaft


12


. The arm part


18


extends forward (to the hull side) from an upper part of the case part


17


, and is supported on the tilt shaft


15


. Formed between the case part


17


and the arm part


18


are three ribs


19


L,


19


M, and


19


R, which extend vertically and are arranged laterally at regular intervals. Coaxially bored in the ribs


19


L and


19


R which are on the left and right outer opposite sides, are bearing holes


20


L and


20


R which are disposed parallel to the tilt shaft


15


. Bored in the middle rib


19


M is a through hole


20


M which has the same diameter as that of the bearing holes


20


L and


20


R and which is coaxially arranged therewith. Opposite end parts of an upper pivot shaft


22


running through the through hole


20


M are rotatably supported by the two bearing holes


20


L and


20


R via bushes


21


. The upper pivot shaft


22


has a flange


22




a


formed at its left end and a stopper ring


23


secured to its right end part. Making the flange


22




a


and the stopper ring


23


abut respectively against the outer side surfaces of the rib


19


L and the rib


19


R, restricts the axial movement of the upper pivot shaft


22


. In this way, on the upper pivot shaft


22


, a second mounting part


22


R is provided between the right rib


19


M and the middle rib


19


M, and a first mounting part


22


L is provided between the left rib


19


L and the middle rib


19


M. These first and second mounting parts


22


L and


22


R are disposed so as to be offset from a central position between the left and right stern brackets


14


L and


14


R, and an offset S


2


of the second mounting part


22


R is set smaller than an offset S


1


of the first mounting part


22


L.




A lower pivot shaft


24


is disposed parallel to the upper pivot shaft


22


between lower end parts of the left and right stern brackets


14


L and


14


R. This lower pivot shaft


24


has its opposite end parts fitted into the inner walls of the left and right stern brackets


14


L and


14


R, and is fixed to the two stern brackets


14


L and


14


R via a long bolt


25


running through a hollow part of the lower pivot shaft


24


.




A tilt system for tilting the propulsion unit U as described above is mounted between the two pivot shafts


22


and


24


. There are two types of tilt system, that is, a power type tilt system


16


P and a gas-assist type tilt system


16


R (FIG.


10


). In the present invention, either of the two types of tilt systems


16


P and


16


R can be mounted on the two pivot shafts


22


and


24


.




A mode for mounting the power type tilt system


16


P is firstly explained by reference to

FIGS. 2

to


8


.




A hydraulically operated cylinder


30


of the power type tilt system


16


P is formed from a cylinder main body


31


, an operating piston (not illustrated), and a piston rod


32


. The operating piston is fitted within a cylinder bore of the cylinder main body


31


to define upper and lower chambers therewithin. The piston rod


32


is fixed to the operating piston and projects upward from the cylinder main body


31


. Mounted on a lower right part of the cylinder main body


31


is a hydraulic pump


33


capable of supplying hydraulic pressure alternately to the upper and lower chambers within the cylinder main body


31


. An electric motor


34


for driving the hydraulic pump


33


is connected to an upper part of the hydraulic pump


33


. Joined to the upper end of the piston rod


32


is a connecting ring


32




a,


which is supported by the first mounting part


22


L of the upper pivot shaft


22


. Formed integrally at the lower ends of the cylinder main body


31


and the hydraulic pump


33


are connecting bosses


31




a


and


33




a,


which are supported by the lower pivot shaft


24


. The hydraulic pump


33


and the electric motor


34


have larger diameters than that of the hydraulically operated cylinder


30


.




When the hydraulic pump


33


is operated by forward or reverse rotation of the electric motor


34


, the hydraulic pump


33


supplies hydraulic pressure alternately to the upper and lower chambers of the hydraulically operated cylinder


30


, thus expanding (see

FIGS. 7 and 8

) or contracting (see

FIGS. 2 and 3

) the hydraulically operated cylinder


30


to automatically tilt the propulsion unit U up or down.




Although the hydraulic pump


33


and the electric motor


34


generally have larger diameters than that of the hydraulically operated cylinder


30


, since the first mounting part


22


L, which supports the hydraulically operated cylinder


30


, of the upper pivot shaft


22


is offset leftward from the central position between the left and right stern brackets


14


L and


14


R by the comparatively large offset S


1


, a comparatively large space is provided between the hydraulically operated cylinder


30


and the right stern bracket


14


R. The electric motor


34


and the hydraulic pump


33


integrally connected to the right side of the hydraulically operated cylinder


30


are arranged effectively using this space. As a result, the entire power type tilt system


16


P is arranged in the central position between the two stern brackets


14


L and


14


R, thus achieving a good lateral weight balance of the outboard motor O as well as a good appearance.




A mode of mounting the gas-assist type tilt system


16


G is now explained by reference to

FIGS. 9

to


13


.




As shown in

FIGS. 10 and 11

, an assist cylinder


40


of the gas-assist type tilt system


16


G is formed from a cylinder main body


41


, an operating piston


44


, and a piston rod


45


. The operating piston


44


is slidably fitted within a cylinder bore of the cylinder main body


41


and defines an upper oil chamber


42


and a lower oil chamber


43


therewithin. The piston rod


45


is fixed to the operating piston


44


, runs through the upper oil chamber


42


, and extends upward from the cylinder main body


41


. Formed integrally on the left side of the cylinder main body


41


is a cylindrical accumulator tank


46


, which is parallel to the cylinder main body


41


. This accumulator tank


46


has substantially the same diameter as that of the assist cylinder


40


. A connecting ring


45




a


is integrally joined to the outer end of the piston rod


45


by welding or the like, and is supported by the second mounting part


22


R of the upper pivot shaft


22


as shown in

FIG. 10. A

connecting tube


41




a


is fixed to a lower end part of the cylinder main body


41


by surround casting or press fitting, and is pivotably supported on the lower pivot shaft


24


via a pair of left and right bushes


58


.




Referring again to

FIG. 10

, an inner tube


48


is disposed within the accumulator tank


46


and fixed to a lid


47


in an upper part of the accumulator tank


46


. The lower end of the inner tube


48


is open and communicates with a cylindrical oil passage


49


between the accumulator tank


46


and the inner tube


48


. A free piston


52


is slidably fitted within the inner tube


48


to define an upper high-pressure gas chamber


50


and a lower hydraulic chamber


51


. High-pressure gas having a predetermined pressure is sealed in the high-pressure gas chamber


50


, and the hydraulic chamber


51


is filled with an operating oil. Bored in an upper part of the cylinder main body


41


on one side are a first port


53


communicating with the cylindrical oil passage


49


, a second port


54


communicating with the upper oil chamber


42


, and a third port


55


communicating with the lower oil chamber


43


. A control valve


56


capable of simultaneously opening and closing these first to third ports


53


to


55


is also provided in the upper part of the cylinder main body


41


on said one side. This control valve


56


is operated by a manual lever


57


.




When the control valve


56


is opened, the free piston


52


descends with the pressure of the high-pressure gas chamber


50


to supply the operating oil within the hydraulic chamber


51


from the cylindrical oil passage


49


via the first and second ports


53


and


54


to the upper oil chamber


42


, and at the same time to the lower oil chamber


43


via the first port


53


and the third port


55


, thus applying the pressure of the high-pressure gas chamber


50


to both the upper and lower faces of the operating piston


44


. Since the pressure-receiving area of the upper end of the operating piston


44


is smaller than the pressure-receiving area of the lower end thereof by the area of the cross section of the piston rod


45


, an upward thrust that is equal to the product of the difference in area and the above pressure is applied to the operating piston


44


, and this thrust substantially counterbalances the moment around the tilt shaft


15


due to the self-weight of the propulsion unit U. A user can therefore easily tilt the propulsion unit U up or down while expanding (see

FIGS. 12 and 13

) or contracting (see

FIGS. 9 and 10

) the assist cylinder


40


by placing his hand on the engine hood


4


and applying an operating force to the propulsion unit U in a tilt-up or tilt-down direction. When the control valve


56


is closed, since all of the first to third ports


53


to


55


are closed, connections between the cylindrical passage


49


and the upper and lower oil chambers


42


and


43


are cut off, thus hydraulically holding the operating piston


44


at a desired position.




Since the offset S


2


of the second mounting part


22


R, which supports the assist cylinder


40


, of the upper pivot shaft


22


from the central position between the left and right stern brackets


14


L and


14


R is comparatively small, the assist cylinder


40


is positioned in the vicinity of the central position between the left and right stern brackets


14


L and


14


R. Moreover, since the cylindrical accumulator tank


46


formed on the left side of the assist cylinder


40


, that is, on the first mounting part


22


L side has a comparatively small diameter in the same way as the assist cylinder


40


, the entire gas-assist type tilt system


16


G is effectively arranged centrally between the two stern brackets


14


L and


14


R, thus achieving a good lateral weight balance of the outboard motor O and a good appearance.




A trim system that adjusts the tilted down position of the propulsion unit U is now explained by reference to

FIGS. 2

to


6


.




Bored in the left and right stern brackets


14


L and


14


R are a plurality of sets of pairs of vertically arranged left and right adjustment holes


60


, into one pair of which a stopper pin


61


is selectively fitted. Moreover, stopper walls


62


are integrally formed on inner side surfaces of the left and right stern brackets


14


L and


14


R below the group of adjustment holes


60


, the stopper walls


62


facing the swivel case


13


.




A pair of left and right stopper walls


63


are projectingly provided integrally on a front face of the swivel case


13


. Formed on the pair of stopper walls


63


are arch-shaped first stopper surfaces


64


and flat second stopper surfaces


65


positioned below the first stopper surfaces


64


.




The tilted down position of the propulsion unit U can be set by making the first stopper surfaces


64


of the swivel case


13


abut against the stopper pin


61


selectively fitted into one pair of the adjustment holes


60


of the left and right stern brackets


14


L and


14


R. The tilted down position of the propulsion unit U can be adjusted by changing the position where the stopper pin


61


is fitted into the adjustment holes


60


. In this case, the left and right stopper walls


63


of the swivel case


13


are held between the left and right stern brackets


14


L and


14


R, thus preventing lateral movement of the swivel case


13


. The lateral load acting on the swivel case


13


can therefore be firmly supported by the left and right stern brackets


14


L and


14


R. Furthermore, the lowest tilted down position of the propulsion unit U can be set by detaching the stopper pin


61


from the adjustment holes


60


and making the second stopper surfaces


65


of the swivel case


13


abut against the stopper walls


62


of the stern brackets


14


L and


14


R. Here also the left and right stopper walls


63


of the swivel case


13


are held between the left and right stern brackets


14


L and


14


R, thereby preventing lateral movement of the swivel case


13


. Also In this case, the lateral load acting on the swivel case


13


can be firmly supported by the left and right stern brackets


14


L and


14


R. Since the lowest tilted down position of the propulsion unit U can be set by making the stopper walls


62


abut against the second stopper walls


65


as described above, the number of adjustment steps for the tilted down position of the propulsion unit U can be increased accordingly. It is therefore not necessary to increase the number of sets of adjustment holes


60


, leading to no need of enlarging portions of the stern brackets


14


L and


14


R where adjustment holes


60


are to be bored, nor decrease in the turning angle of the propulsion unit. Moreover, in the case where the stopper pin


61


is not in use, it can be retained in retention holes


66


of the stern brackets


14


L and


14


R, which will be described below, thereby preventing it from being lost.




As shown in

FIG. 4

, formed integrally with one end of the stopper pin


61


are a retaining projection


67


and a knob


68


which is bent toward one side from the axially outer end of the retaining projection


67


. A conical coil spring


69


is fitted around the stopper pin


61


and is caught by the retaining projection


67


. A retaining key


70


is pivotably connected to the other end of the stopper pin


61


via a pivot


71


running transversely through the stopper pin


61


. This retaining key


70


can pivot between a dropped down position A in which it is coaxial with and has the same diameter as the stopper pin


61


, and a raised position B in which it is perpendicular to the stopper pin


61


.




When fitting the stopper pin


61


, the retaining key


70


is set at the dropped down position A and the stopper pin


61


is inserted through a selected pair of adjustment holes


60


with the retaining key


70


ahead. When the coil spring


69


is compressed on the outer side surface of one stern bracket


14


R and, at the same time, the retaining key


70


projects out of the outer side surface of the other stern bracket


14


L, the retaining key


70


is made to pivot to the raised position B and the insertion force is released from the stopper pin


61


. As a result, the retaining key


70


is retained in a state in which it keeps an upright attitude and abuts against the outer side surface of said other stern bracket


14


L due to the resilient force of the coil spring


69


, thus preventing the stopper pin


61


from becoming detached from the adjustment holes


60


and also preventing noise due to rattling of the retaining key


70


. In order to pull the stopper pin


61


out of the adjustment holes


60


, a procedure opposite to the above is conducted.




The retention holes


66


for retaining the unused stopper pin


61


are bored in a lower part of the left and right stern brackets


14


L and


14


R where there is no interference with the swivel case


13


. These retention holes


66


have the same dimensions as those of the adjustment holes


60


, and the thus stopper pin


61


can be easily fitted in the retention holes


66


in the same manner as it is fitted in the adjustment holes


60


.




The present invention is not limited to the above-mentioned embodiment and can be modified in a variety of ways without departing from the spirit and scope of the present invention.



Claims
  • 1. An outboard motor comprising a swivel case axially and steerably supporting a propulsion unit, a pair of left and right stern brackets disposed on left and right sides of the swivel case and supporting the swivel case in a vertically tiltable manner via a tilt shaft, and an upper pivot shaft and a lower pivot shaft that are parallel to the tilt shaft and are provided in the swivel case and the left and right stern brackets respectively, upper and lower end portions of an extendable part of a tilt system being mounted on the upper and lower pivot shafts,wherein the upper pivot shaft is provided with first and second mounting parts that are offset in mutually opposite left and right directions from a central position between the pair of stern brackets, the offset of the second mounting part is set smaller than the offset of the first mounting part, and the upper end portion of the extendable part of the tilt system is mounted selectively on one of the first and second mounting parts according to the type of tilt system.
  • 2. The outboard motor according to claim 1 wherein the tilt system is of a power type in which a hydraulic pump and an electric motor are connected to one side of a hydraulically operated cylinder, an upper end part of the hydraulically operated cylinder is mounted on the first mounting part, and the hydraulic pump and the electric motor are disposed on the second mounting part side.
  • 3. The outboard motor according to claim 1 wherein the tilt system is of a gas-assist type in which a cylindrical accumulator tank is connected to one side of an assist cylinder, an upper end part of the assist cylinder is mounted on the second mounting part, and the accumulator tank is disposed on the first mounting part side.
  • 4. The outboard motor according to any one of claims 1 to 3 wherein the pair of left and right stern brackets are provided with a plurality of sets of pairs of left and right adjustment holes arranged in the vertical direction, a stopper pin that determines the tilted down position of the propulsion unit by receiving a stopper surface formed on a front surface of the swivel case is inserted through and supported selectively in one pair of the plurality of sets of adjustment holes so as to adjust the tilted down position of the propulsion unit in a plurality of steps, the swivel case has a second stopper surface formed below the stopper surface, the stern brackets have formed thereon a stopper wall that defines the lowest tilted down position of the propulsion unit by receiving the second stopper surface when the stopper pin is detached from the adjustment holes, and these stern brackets are provided with retention holes that retain the stopper pin detached from the adjustment hole.
  • 5. The outboard motor according to claim 4 wherein, when the second stopper surface is received by the stopper wall, the swivel case is held between the two stern brackets.
  • 6. The outboard motor according to claim 4 wherein, when the stopper pin is inserted into the adjustment holes or the retention holes, a retaining key is axially supported on one end part of the stopper pin so that the retaining key can pivot between a dropped down position in which the retaining key is coaxial with the stopper pin and can pass through the adjustment holes or the retention holes together with the stopper pin, and a raised position in which the retaining key abuts against an outer side surface of one of the stern brackets, and a spring is fitted to the other end part of the stopper pin, the spring being compressed against an outer side surface of the other stern bracket and biasing the stopper pin in a direction opposite to the retaining pin.
Priority Claims (2)
Number Date Country Kind
2002-191788 Jul 2002 JP
2002-191789 Jul 2002 JP
US Referenced Citations (7)
Number Name Date Kind
5049099 Ito et al. Sep 1991 A
5156561 Kinoshita Oct 1992 A
5358436 Soda et al. Oct 1994 A
6139380 Uematsu Oct 2000 A
6183320 Natsume Feb 2001 B1
6309265 Oguma Oct 2001 B1
6398601 Oguma Jun 2002 B1
Foreign Referenced Citations (1)
Number Date Country
4-5190 Jan 1992 JP