Abstract:
A method and a conversion kit are provided for assembling marine propulsion systems such as those comprised of a Mercruiser Alpha-One-type sterndrive unit, an OMC Cobra-type inboard engine and a transom assembly, and attaching the propulsion systems to marine vessels. The method and the kit use commercially available parts and minimal special hardware. The technique involves a modified transom assembly comprised of an inner transom plate, a gimbal housing, a gimbal ring equipped with machined custom-made hinge pins, two trim cylinders with corresponding trim pins, and a bell housing with specially designed bellows and adaptor nipple. The invention is also applicable to the assembling of other marine propulsion systems that are comprised of equivalent combinations of similar sterndrive units attached to other similar inboard engines by means of transom assemblies.

Description:
[0001]    This application is a non-provisional application for patent entitled to a filing date and claiming the benefit of earlier-filed Provisional Application for Patent No. 61/046,907, filed on Apr. 22, 2008 under 37 CFR 1.53 (c). 
     
    
     FIELD OF THE INVENTION 
       [0002]    This invention relates to a method and kit for assembling marine propulsion systems and securing them to a marine vessel. Particularly, this invention relates to the assembling of marine propulsion systems that are comprised of certain types of outboard sterndrive units connected to certain types of inboard engines by means of transom assemblies that are also used to attach the propulsion systems to the vessels. More particularly, the invention relates to a method and kit for assembling Mercruiser Alpha-One-type sterndrive units and Outboard Marine Corporation (“OMC”) Cobra-type inboard engines and attaching them to a marine vessel by means of transom assemblies. Specifically, the invention relates to a novel technique for adapting Mercruiser Alpha-One-type sterndrive units to OMC Cobra-type inboard engines and transom assemblies using commercially available parts and minimal special hardware. The invention is also further applicable to the assembling of other marine propulsion systems that are comprised of similar combinations of other outboard sterndrive units attached to other similar inboard engines by means of transom assemblies. 
       BACKGROUND OF THE INVENTION 
       [0003]    Inboard-outboard marine propulsion systems, sometimes also referred to as “marine engine packages”, or “I/O propulsion systems”, are well-known in the marine vessel industry. These systems usually consist of an inboard component that includes an internal combustion engine and related hardware, an outboard component often enclosed in a casing with conventional hardware, and a transom assembly that serves the purpose of connecting the inboard component to the outboard component and securing the propulsion system to the vessel. The inboard component and the outboard component are connected to each other by a series of bolts, nuts, pins and other hardware that allow the transmission of power from the inboard component to the outdrive. Additional hardware is provided to secure the propulsion system to the transom of the vessel. Among these inboard-outboard marine propulsion systems, those manufactured by Outboard Marine Corporation (“OMC”) have been used for years in the industry due to their durability and reliability, and many boats and other marine vessels are equipped with these types of systems. OMC inboard-outboard marine propulsion systems are no longer manufactured by OMC, even though their inboard engine components continue to be available as used parts and aftermarket equipment. In addition, inboard engine components of the type made by Volvo Penta and similar manufacturers continue to be available, new, used and as aftermarket equipment. Hardware to secure propulsion systems to the transom of boats and other marine vessels exist which usually consist of various arrangements of support plates, gimbal rings, bell housings, gimbal housings and other such parts. For example, U.S. Pat. Nos. 4,872,531 and 5,238,433 disclose the use of such types of hardware arrangements in conjunction with marine sterndrive units and inboard engines of watercraft inboard-outboard propulsion systems. The hardware arrangements described in these patents, however, have their limitations and are not suitable for adapting Mercruiser Alpha-One-type sterndrive units to OMC Cobra-type inboard engines and transom assemblies using commercially available parts and minimal special hardware. 
         [0004]    It is apparent that a need exists for a technique whereby Mercruiser Alpha-One-type sterndrive units may be adapted to OMC Cobra-type inboard engines and transom assemblies using commercially available parts and minimal special hardware. The present invention is directed toward providing such a technique. 
         [0005]    It is an object of the present invention to provide a method and a kit for the proper and safe assembling of inboard-outboard marine propulsion systems. It is a specific object of the present invention to provide a method and a kit for assembling Mercruiser Alpha-One-type sterndrive units and OMC Cobra-type inboard engines and attaching them to a marine vessel by means of transom assemblies. It is also an object of the present invention to provide a method and a conversion kit for adapting Mercruiser Alpha-One-type sterndrive units to OMC Cobra-type inboard engines and transom assemblies using commercially available parts and minimal special hardware. Another object of this invention is to provide a commercially practicable method and system for the proper and safe assembling of inboard-outboard marine propulsion systems while utilizing conventional components in a novel fashion in a safe and cost-effective manner. These and other objects of the invention will be apparent to those skilled in the art from the description that follows. 
       SUMMARY OF THE INVENTION 
       [0006]    The method and the system of this invention center around the innovative concept of providing a modified transom assembly design, as well as a method for its use and installation. The invention allows the use of Mercruiser Alpha-One-type sterndrive units on marine vessels originally equipped with OMC Cobra-type inboard engines and does not require the replacement of the OMC transom assembly. Conventional hardware is used in assembling the propulsion system Is and securing it to the vessel. The modified transom assembly system of the invention is sometimes referred to as the “Mercruiser® Alpha-One Conversion Kit” or, simply, as the “Mercruiser® Conversion Kit”. Mercruiser and Alpha are believed to be registered marks of the Brunswick Corporation. The invention is also further applicable to the assembling of other marine propulsion systems that are comprised of equivalent combinations of other similar sterndrive units attached to other similar inboard engines by means of transom assemblies. 
         [0007]    The modified transom assembly design of the invention involves the following components: 
         [0008]    (a) An inner transom plate comprised of an inner transom support plate (made of aluminum or some other strong and corrosion-resistant metal or material), equipped with means for connecting an inboard engine on one side and means for attaching a gimbal housing on its other side. The means for connecting an inboard engine on one side include two or more inner transom plate through holes drilled on protruding members of the support plate and companion inner transom plate threaded bolts and nuts, or similar suitable hardware. The means for attaching the gimbal housing to the other side of the support plate are preferably six through holes adapted to receive threaded studs, or similar suitable hardware. 
         [0009]    (b) A gimbal housing comprised of a gimbal housing casting with means for attaching the inner transom plate to its back (mounting) surface and means for connecting to its opposite surface a gimbal ring and the bellows from the bell housing. The means for attaching the inner transom plate to its back surface preferably include six gimbal housing threaded studs and matching nuts. The means for connecting a gimbal ring to its opposite surface preferably comprise symmetrically-located upper and lower gimbal housing through holes adapted to receive retaining pins (“gimbal housing swivel pins”). The means for connecting the bell housing bellows to its opposite surface include at least one pipe-shaped casting, flanged at one end (the “gimbal housing flanged casting”), and adapted to receive a gimbal bearing inside it, and the bell housing bellows on its outside. A clamp and an optional seal are used to secure the parts in place. 
         [0010]    (c) A gimbal ring comprised of a gimbal ring casting made of aluminum (or some other strong and corrosion-resistant metal or material), having a substantially oval overall shape, and provided with a gimbal ring support base at the bottom and several symmetrically-located openings, or “through holes”. A first pair of gimbal ring through holes on the side brackets of the casting is adapted to receive two machine-made hinge pins that allow the bell housing to oscillate up and down. A second pair of gimbal ring through holes are provided on the side brackets, below the first pair and located near the support base of the gimbal ring. This second pair of through holes serves to receive the hydraulic cylinder trim pin described below. A third pair of gimbal ring through holes on the casting support base and the casting top bracket, respectively, align themselves with the upper and lower through holes of the gimbal housing so that gimbal housing swivel pins may be placed in the through holes to secure the gimbal ring to the gimbal housing. The gimbal ring is also provided with two or more spacers, made of strong plastic or similar material, that are attachable to the inner portion of the “ears” of the gimbal ring. The gimbal ring may also include a steering arm or similar means for steering the marine vessel. 
         [0011]    (d) Two trim cylinders and trim pins. The trim cylinders are hydraulic cylinders. The first trim pin penetrates the gimbal ring through holes located near the support base of the gimbal ring and is used to secure two ends of the trim cylinders to the gimbal ring. The second trim pin, on a parallel plane with the first trim pin, is connected to the other ends of the trim cylinders and serves to secure the other ends to the sterndrive. Suitable hardware should also be included. 
         [0012]    (e) A bell housing that comprises a bell housing casting (made of aluminum or some other strong and corrosion-resistant metal or material), sized and shaped to fit inside the gimbal ring and provided with symmetrically-located bell housing through holes that align themselves with through holes in the gimbal ring and allow the bell housing to be secured to the gimbal ring by means of hinge pins. The bell housing also includes the custom-made bell housing u-joint bellows, the bell housing flanges, the bell housing clamps, the bell housing first water hose, the bell housing second water hose, and a bell housing adaptor nipple. 
         [0013]    The method of the invention may be conveniently described with reference to a particularly preferred embodiment and application, that is, the mating of a Mercruiser Alpha-One-type sterndrive to an OMC Cobra-type inboard engine. It should be understood, however, that the method has applications in the proper assembling of other equivalent combinations of similar sterndrive units attached to other inboard engines by means of transom assemblies. In this preferred embodiment, the method of the invention comprises: (a) mating the inner diameter of the gimbal housing end of the Mercruiser Alpha-One-type sterndrive unit&#39;s u-joint rubber bellows to the gimbal housing flange of OMC-Cobra-type engine&#39;s transom assembly by means of a u-joint bellows clamp; (b) attaching the bell housing of the Mercruiser Alpha-One-type sterndrive unit to the OMC Cobra-type engine&#39;s transom assembly&#39;s gimbal ring by means of two custom-made hinge pins that are specifically threaded to match the bell housing threaded holes on the Mercruiser Alpha-One-type sterndrive unit, said two custom-made hinge pins also having smooth bearing surfaces that match the inner diameters of the gimbal ring through holes; (c) attaching the Mercruiser Alpha-One-type sterndrive unit&#39;s seawater pump output hose (bell housing first water hose) to the seawater pump output hose (bell housing second water hose) of the OMC Cobra-type engine&#39;s transom assembly by means of a bell housing adaptor nipple that increases the effective diameter (ID) of the Mercruiser Alpha-type sterndrive unit&#39;s seawater pump output hose (bell housing first water hose) to match the effective diameter (ID) of the seawater pump output hose (bell housing second water hose) of the OMC Cobra-type engine&#39;s transom assembly; and (d) modifying (cut or filed to fit) the Mercruiser Alpha-One-type sterndrive unit&#39;s stops, as needed, to limit the amount of negative trim, and/or to trim down the bow of the marine vessel and optimize the ability to raise and lower the bow of the vessel. Bushings made of fiber or some other suitable material may be inserted and pressed into the gimbal ring through holes in order to minimize wear on the OMC Cobra-type engine&#39;s transom assembly&#39;s gimbal ring. The modified transom assembly may also be provided with two or more spacer guides, made of strong plastic or similar material, that are attachable to the inner portion of the “ears” of the gimbal ring. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0014]    A clear understanding of the key features of the invention summarized above may be had by reference to the appended drawings. Accordingly: 
           [0015]      FIG. 1  is an illustration of the modified transom assembly of the invention showing all of its components. 
           [0016]      FIG. 2  is a diagram of the gimbal ring component and the spacer guides of the modified transom assembly of the invention. 
           [0017]      FIG. 3  is a diagram of the bell housing component of the modified transom assembly of the invention, showing the custom-made bell housing u-joint bellows and the bell housing adaptor nipple. 
           [0018]      FIG. 4  is a diagram of one of the machine-made gimbal ring hinge pins of the invention. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0019]    The various components of the modified transom assembly of the invention are shown in  FIG. 1 . Accordingly, referring to  FIG. 1 , inner transom plate  101  is comprised of inner transom support plate  102 , which is a casting made of aluminum or some other strong and corrosion-resistant metal or material and equipped with means for connecting an inboard engine on one side and means for attaching a gimbal housing on its other side. The inner transom plate is normally placed inside the vessel. (So that its various parts are easily discernible, the inner transom plate is shown, in  FIG. 1 , oriented 180 degrees from the direction in which it normally faces the gimbal housing.) The means for connecting an inboard engine on one side include two or more inner transom plate through holes  105  drilled on protruding members  106  of support plate  102  and companion inner transom plate threaded bolts and nuts (not shown). The means for attaching the gimbal housing to the other side of support plate  102  are preferably six through holes  103  adapted to receive threaded studs or similar suitable hardware  104 . 
         [0020]    Gimbal housing  107  is comprised of gimbal housing casting  108 , which is a casting made of aluminum or some other strong and corrosion-resistant metal or material and equipped with means for attaching inner transom plate  101  to its back (mounting) surface and with means for connecting to its opposite surface a gimbal ring and the bellows from the bell housing. The gimbal housing is normally placed outside the vessel. The means for attaching inner transom plate  101  to the back surface of gimbal housing casting  108  preferably include six or more gimbal housing threaded holes (not shown) and matching studs  115 , as well related hardware  104 . The means for connecting a gimbal ring to the opposite surface of gimbal housing casting  108  comprise symmetrically-located upper and lower gimbal housing through holes  109  adapted to receive upper and lower gimbal housing swivel pins  110 , which are retaining pins. Removable casting  111  is used to conveniently retain lower gimbal housing swivel pin  110  in place. The upper gimbal housing through hole  109  can alternatively receive built-in swivel pin  126  as described below. The means for connecting the bell housing bellows to the opposite surface of the gimbal housing casting  108  include at least one gimbal housing flanged casting  117 , which is a pipe-shaped casting, flanged at one end and adapted to receive the gimbal bearing  112  inside and the bell housing bellows on the outside. The gimbal housing flanged casting is sometimes referred to in this Specification as the “gimbal housing flange”. A clamp (not shown) and an optional seal  113  are used to secure the parts in place. Gimbal housing water tube  114 , described below, is also part of the gimbal housing. 
         [0021]    Gimbal ring  118  is comprised of gimbal ring casting  119 , which is a casting made of aluminum or some other strong and corrosion-resistant metal or material, having a substantially oval overall shape and provided with gimbal ring support base  120  at the bottom and several symmetrically-located openings, or “through holes”. The gimbal ring allows the sterndrive to swing left and right. As shown in  FIG. 1 , gimbal ring support base  120  includes two symmetrically-spaced ear-shaped portions that are sometimes referred to as the “ears” of the gimbal ring. A first pair of gimbal ring through holes  121  on the side brackets of the casting is adapted to receive two machine-made hinge pins  122  and (optional) companion hinge pin bushings  123  that allow the bell housing to oscillate up and down. A second pair of gimbal ring through holes  124  are provided on the side brackets, below the first pair and located near the support base of the gimbal ring. This second pair of through holes serves to receive the hydraulic cylinder trim pin described below. A third pair of gimbal ring through holes  125  on the casting support base and the casting top bracket, respectively, align themselves with the upper and lower gimbal housing through holes  109  so that gimbal housing swivel pins  110  may be placed in the through holes to secure the gimbal ring to the gimbal housing. In a preferred embodiment, built-in swivel pin  126  is used instead of a regular swivel pin  110  to secure the upper portion of the gimbal ring to the gimbal housing. The gimbal ring is also provided with two or more spacer guides, made of strong plastic or similar material, that are attachable to the inner portion of the “ears” of the gimbal ring. The gimbal ring may also include a steering arm or similar means for steering the marine vessel. In the illustration shown in  FIG. 1 , steering lever  127  and lever retaining bolt  128  are used for that purpose. 
         [0022]    The transom assembly also includes two trim cylinders and two trim pins. The two trim cylinders  129  are twin hydraulic cylinders shaped and sized to be mated to the trim pins. The first trim pin  130  is shaped and sized to penetrate and fit snuggly into second pair of gimbal ring through holes  124 , located near the support base of the gimbal ring, and to mate to one end of the two trim cylinders. Suitable hardware  131 , in the form of bushings, washers, clips, caps and the like, is used to connect the cylinders to the trim pins. The first trim pin  130  is used to secure two ends of trim cylinders  129  to the gimbal ring. The second trim pin  132 , on a parallel plane with first trim pin  130 , is connected to the other ends of trim cylinders  129  by suitable hardware  131  and serves to secure the other ends of trim cylinders  129  to the sterndrive. 
         [0023]    The transom assembly also comprises a modified bell housing  133  that comprises a bell housing casting  134 , which is a casting made of aluminum or some other strong and corrosion-resistant metal or material, and sized and shaped to fit inside the gimbal ring. Bell housing casting  134  is provided with symmetrically-located and threaded bell housing holes  137  that align with first pair of gimbal ring through holes  121  in the gimbal ring and allow the bell housing to be secured to the gimbal ring by means of machine-made hinge pins  122  and optional companion hinge pin bushings  123  so that the bell housing is able to oscillate up and down. 
         [0024]    The bell housing  133  also includes the bell housing u-joint bellows  138 , preferably made of rubber or rubber-like material, the bell housing flanges (not shown), which are similar to the flange of gimbal housing flanged casting  117 ), the bell housing gasket  136 , the bell housing clamps  145 , the bell housing first water hose  143 , the bell housing second water hose  144 , and the bell housing adaptor nipple  146 . The bell housing attaches to the gimbal housing and allows the sterndrive to move up and down. Studs  135  and gasket  136  are used to attach the sterndrive (not shown) to bell housing casting  134 . Bell housing u-joint bellows sleeve  139  is used to secure one end of bell housing u-joint bellows  138  to a flange located in bell housing  133 ; gimbal housing u-joint bellows clamp  140  is used to secure the other end of bell housing u-joint bellows  138  to gimbal housing flange  117 . The bell housing u-joint bellows surround and protect a segment of the stemdrive shaft, usually the segment that comprises the u-joints of the shaft. Other bellows, such as bell housing exhaust bellows  141 , and bell housing exhaust bellows clamps (worm gear clamps)  142  may be used, optionally, as exhaust conduits or engine exhaust tubes. Additional bellows and suitable flanges and clamps may also be used to shroud and protect cables and other mechanical parts. 
         [0025]    The bell housing  133  further includes bell housing first water hose  143 , bell housing second water hose  144 , and bell housing adaptor nipple  146 , as well as suitable clamps  145 . Bell housing first water hose  143  is a hose made of rubber or rubber-like material, having a length of anywhere between about 3 and 8 inches, an inside diameter of approximately ¾ inch and an outside diameter of approximately 1 1/8  inch. Bell housing first water hose  143  is connectable on one end to the bell housing water inlet (not shown) and on its other end to bell housing adaptor nipple  146 . Bell housing second water hose  144  is a hose made of rubber or rubber-like material, having a length of anywhere between about 3 and 8 inches, an inside diameter of approximately 1 inch and an outside diameter of approximately 1 5/16  inch. Bell housing second water hose  144  is connectable on one end to bell housing adaptor nipple  146  and on its other end to gimbal housing water tube  114 . Suitable clamps  145  are used to make these connections. The gimbal housing water tube  114  is a molded plastic tube having a length of anywhere between about 6 and 12 inches, a variable-size inside diameter and an outside diameter of approximately 1 inch. Gimbal housing water tube  114  is attached to gimbal housing casting  108  by means of suitable hardware  116 . The gimbal housing water tube is used to transfer water from the bell housing second water hose to the engine for engine cooling purposes. The bell housing first water hose is connected to the bell housing water inlet by means of a water inlet nipple (not shown). The bell housing water inlet is a cavity that receives seawater withdrawn from the sea by means of a cavity in the sterndrive. The bell housing water inlet is preferably cylindrical and runs the depth of the bell housing. The bell housing water inlet may be threaded at its backside (facing the gimbal housing) to best secure it to the water inlet nipple (if the water inlet nipple is also threaded). The water inlet nipple may also be glued, pressed or, if convenient, bolted to the bell housing, or it may even be part of the bell housing casting. Preferably, the water inlet nipple is made of plastic and pressed and glued to the bell housing casting on one end. 
         [0026]    Bell housing first water hose  143  and bell housing second water hose  144  are connected to each other by means of bell housing adaptor nipple  146 . Bell housing adaptor nipple  146  is a 2 1/8 -inch-long unthreaded pipe-shaped conduit provided with an opening at each end. The first opening is substantially round and has an outside diameter (“OD”) of approximately ¾ inch and an inside diameter (“ID”) of approximately ½ inch. The second opening is substantially round and has an outside diameter of approximately 1 inch and an inside diameter of approximately ¾ inch. Worm gear clamps or similar clamping devices are used on both ends of bell housing adaptor nipple  146  in order to secure first water hose  143  and second water hose  144  to it. Bell housing adaptor nipple  146  is preferably made of a strong plastic. The adaptor nipple may also be made of stainless steel, brass or some other metal. 
         [0027]    The gimbal ring component and the spacer guides of the modified transom assembly design of the invention are illustrated in  FIG. 2 , where gimbal ring  201  is shown with first pair of gimbal ring through holes  202  drilled through gimbal ring side brackets  203 , second pair of gimbal ring through holes  204 , drilled through the lower portions of side brackets  203 , and third pair of gimbal ring through holes  205  drilled through the upper and lower supporting brackets  206  and  207 , respectively. Built-in swivel pin  208  fits in upper through hole  205  and functions as a swivel pin to secure the upper portion of the gimbal ring to the gimbal housing. The first pair of gimbal ring through holes  202  is not threaded; the holes are aligned with each other on the same plane; and each of their inner diameters is adapted to receive the smooth-bearing outer surface of the custom-made hinge pin, depicted in  FIG. 4 , below. The second pair of through holes  204  serves to receive the hydraulic cylinder trim pin, as already described. The third pair of gimbal ring through holes  205  on the casting support base and the casting top bracket, respectively, align themselves with the upper and lower gimbal housing through holes so that gimbal housing swivel pins may be placed in the through holes to secure the gimbal ring to the gimbal housing. Spacer guides  209  may be round, square, triangular or of any other convenient shape. They may also mimic the shape of the “ears” of the gimbal ring as shown in  FIG. 2 . The spacer guides should be made of strong plastic or similar minimum-wear material and have a minimum thickness of approximately ½ inch and a maximum thickness of approximately ¾ inch. They may be bolted, glued or otherwise attached to the “ears” of the gimbal ring or, alternatively, they may be bolted, glued or otherwise attached to the sides of the sterndrive. In one preferred embodiment the spacer guides are ½-inch-thick round plastic ring-shaped pads  210 , capable of being bolted to the sides of the sterndrive. 
         [0028]      FIG. 3  is a diagram of two elements of the bell housing component of the modified transom assembly of the invention, showing the custom-made bell housing u-joint bellows  301  and the bell housing adaptor nipple  305 . As illustrated in  FIG. 3 , custom-made accordion-shaped rubber bellows  301  are ridged on their outer surface and on their inner surface, except for the ends; their length is 5 1/4  inches, and their outside diameter (OD), including the ridges, is 5½ inches. Their inside diameter (ID) is 3 7/8  inches, except for the portion that comprises the gimbal housing end, which has an ID of 4 inches. Bell housing end  302  of rubber bellows  301  is sized to retain that end of the bellows and secure it to a flange (not shown) located in the bell housing. Thus, its length is approximately ½ inch, its inside diameter (ID) is 3 7/8  inches, its major outside diameter, including the ridge, is 4 3/8  inches, and its minor outside diameter is 4 1/8  inches. Bell housing u-joint bellows sleeve  303  fits snuggly inside bell housing end  302  of rubber bellows  301  and is sized accordingly. Making and sizing the bell housing end  302  of rubber bellows  301  in this fashion, together with bellows sleeve  303 , allows the assembler to connect the modified bell housing component of the invention to a Mercruiser Alpha-One-type sterndrive unit. Gimbal housing end  304  is sized to retain that end of the bellows and secure it to the gimbal housing flange casting (flange  117  in  FIG. 1 ). Thus, the length of gimbal housing end  304  is approximately ½ inch, its inside diameter (ID) is 4 inches, its major outside diameter, including the ridge, is 4 3/8  inches, and its minor outside diameter is 4 1/4  inches. Bell housing u-joint bellows clamp  305 , used to conveniently secure gimbal housing end  304  of rubber bellows  301  to the gimbal housing flange, fits outside gimbal housing end  304  and is sized accordingly. Making and sizing the gimbal housing end  304  of rubber bellows  301  in this fashion, together with bellows clamp  305 , allows the assembler to connect the modified bell housing component of the invention to an OMC Cobra-type inboard engine. Overall, gimbal housing end  304  has smaller outside and inside diameters than bell housing end  302 . Neither end is ridged on its inside surface. 
         [0029]    Bell housing adaptor nipple  306  is used to connect the bell housing first water hose to the bell housing second water hose. Preferably, bell housing adaptor nipple  306  is a 2 1/8 -inch-long unthreaded pipe-shaped conduit provided with an opening at each end. The first portion  307  of adaptor nipple  306  is about 1 inch long and substantially round. This portion  307 , shown in  FIG. 3  as the upper portion of the nipple, has an outside diameter (“OD”) of approximately ¾ inch and an inside diameter (“ID”) of approximately ½ inch. The second portion  308  is also substantially round, has an outside diameter of approximately 1 inch and an inside diameter of approximately ¾ inch. Portion  307  fits snuggly into one end of the first water hose, while portion  308  fits snuggly into one end of the second water hose. Worm gear clamps or similar clamping devices are used on both ends of bell housing adaptor nipple  306  in order to secure to it the first water hose and the second water hose. Bell housing adaptor nipple  306  may be made of stainless steel, brass or some other metal. Preferably, the adaptor nipple is made of a strong plastic. 
         [0030]    As already described, the bell housing casting is provided with symmetrically-located and threaded bell housing holes that align with a first pair of gimbal ring through holes in the gimbal ring and allow the bell housing to be secured to the gimbal ring by means of two machine-made hinge pins, as well as optional companion hinge pin bushings, so that the bell housing is able to oscillate up and down. Each pin is machined to custom specifications. The kind of machine-made hinge pin used for this purpose is shown in  FIG. 4  as hinge pin  401 , having a first portion  402  comprising a ¾-inch-long solid cylinder, threaded on the outside to 18 threads-per-inch of length, and having a ⅝-inch outside diameter. Hinge pin  401  also has a second portion  403  comprising a ¾-inch-long solid cylinder, having a 1-inch outside diameter. The second portion  403  of pin  401  is not threaded. A socket indentation  404 , shaped and sized to fit an Allen wrench, is provided at the base of second portion  403  for ease of installation. The machined custom-made hinge pins are made of stainless steel or other similarly strong and corrosion-resistant metal. The outside surface of first portion  402  of hinge pin  401  is threaded, as specified above, in order to match and fit inside the symmetrically-located and threaded bell housing holes (shown as holes  137  in  FIG. 1 ), while the outside surface of second portion  403  of hinge pin  401  is not threaded, but is machined to fit in smoothly in gimbal ring through holes on the side brackets of the gimbal ring casting (shown as through holes  121  in  FIG. 1 ). Making and using the two machined custom-made hinge pins in this fashion allows the assembler to properly secure the modified transom system&#39;s bell housing to the gimbal ring so that the bell housing may oscillate up and down and the propulsion system is able to operate properly. 
         [0031]    The modified transom assembly of the invention may be used in conjunction with the method of the invention in order to assemble Mercruiser Alpha-One-type sterndrive units and OMC Cobra-type engines, and attach them to marine vessels. Accordingly, in reference to  FIG. 1 , the method of the invention comprises: (a) mating the inner diameter of the gimbal housing end of the Mercruiser Alpha-One-type sterndrive unit&#39;s u-joint rubber bellows  138  to gimbal housing flange  117  of OMC Cobra-type engine&#39;s transom assembly by means of u-joint bellows clamp  140 ; (b) attaching the bell housing  133  of the Mercruiser Alpha-One-type sterndrive unit to the OMC Cobra-type engine&#39;s transom assembly&#39;s gimbal ring  118  by means of two machine-made hinge pins  122 , threaded to match the bell housing threaded holes  137  on said Mercruiser Alpha-One-type sterndrive unit, said two hinge pins  122  having smooth bearing surfaces matching the inner diameters of gimbal ring through holes  121 ; (c) attaching the Mercruiser Alpha-One-type sterndrive unit&#39;s seawater pump output hose (bell housing first water hose  143 ) to the seawater pump output hose (bell housing second water hose  144 ) of the OMC Cobra-type engine&#39;s transom assembly by means of bell housing adaptor nipple  146 , which increases the effective diameter (ID) of the Mercruiser Alpha-type sterndrive unit&#39;s seawater pump output hose (bell housing first water hose  143 ) to match the effective diameter (ID) of the seawater pump output hose (bell housing second water hose  144 ) of the OMC Cobra-type engine&#39;s transom assembly; and (d) modifying (cut, shaved or filed to fit) the Mercruiser Alpha-One-type sterndrive unit&#39;s stops, as needed, to limit the amount of negative trim, and/or to trim down the bow of the marine vessel and optimize the ability to raise and lower the bow of the vessel. The sterndrive stops are protrusions located on the upper portion of the housing of the sterndrive and designed to limit the degree of negative trim of the vessel. Optionally, fiber bushings  123  may be inserted and pressed into through holes  121  to minimize wear on the OMC Cobra-type engine&#39;s transom assembly&#39;s gimbal ring. 
         [0032]    It will be understood that the appended figures depict preferred embodiments of the present invention and, therefore, are not to be considered as limiting its scope with regard to other embodiments which the invention is capable of contemplating. While the invention has been described in terms of particular embodiments and applications, in both summarized and detailed forms, it is not intended that these descriptions in any way limit its scope to any such embodiments and applications, and it will be understood that various substitutions, changes and variations in the described embodiments, applications and details of the method and system illustrated herein and of their operation can be made by those skilled in the art without departing from the spirit of this invention.