BOLT-ON CYLINDER KIT AND METHOD FOR INCREASING THE DISPLACEMENT OF AN ENGINE

Abstract

A cylinder for a V-twin engine includes a section of steel tubing cut to a length. The section of steel tubing includes a first portion having a first wall thickness and a second portion having a second wall thickness less than the first wall thickness. The second wall thickness is less than 0.050 inch. The section of steel tubing includes a first ribbing pattern on an outer surface, within the first portion, and a second ribbing pattern including multiple ribs formed on individual ribs of the first ribbing pattern. A cast body is provided on the first portion of the section of steel tubing so that the section of steel tubing is fixedly secured within the body to form a cylinder sleeve defining a cylinder bore. The second portion having the second wall thickness extends from an end of the body to be received within a bore of a crankcase.

Claims

1. A cylinder for a V-twin engine, the cylinder manufactured by a process comprising: providing a section of steel tubing; cutting the section of steel tubing to length; machining the section of steel tubing in a subtractive process, including forming a first portion having a first wall thickness and a second portion having a second wall thickness less than the first wall thickness, wherein the second wall thickness is less than 0.050 inch, and forming a first ribbing pattern on an outer surface of the section of steel tubing within the first portion, and forming a second ribbing pattern including multiple ribs formed on individual ribs of the first ribbing pattern; and casting a body onto the first portion of the section of steel tubing so that the section of steel tubing is fixedly secured within the body to form a cylinder sleeve defining a cylinder bore, wherein the second portion having the second wall thickness extends from an end of the body to be received within a bore of a crankcase.

2. The cylinder of claim 1, wherein the body includes an exterior surface having a plurality of fins.

3. The cylinder of claim 1, wherein the body is solid, having no internal voids or cooling jackets for cooling liquid.

4. The cylinder of claim 1, wherein the body further includes a flange proximate the end, the flange defining a surface configured to abut a surface of the crankcase, and a plurality of mounting holes extending from the surface through the body.

5. The cylinder of claim 1, wherein a diameter of the cylinder bore is greater than 3.948 inches.

6. The cylinder of claim 1, wherein a diameter of the cylinder bore is about 4.000 inches.

7. The cylinder of claim 6, wherein the outer diameter of the second portion is about 4.068 inches.

8. The cylinder of claim 1, wherein the cylinder sleeve is constructed from SAE grade 4140 steel.

9. The cylinder of claim 1, wherein the second wall thickness is less than 0.040 inches and greater than 0.025 inch.

10. The cylinder of claim 1, wherein the second wall thickness is between 0.033 inch and 0.035 inch.

11. The cylinder of claim 1, wherein at least one of the first and second ribbing patterns is helical.

12. The cylinder of claim 1, wherein the first and second ribbing patterns are formed in intersecting helical patterns having opposite axial components in a given circumferential direction.

13. A cylinder for a V-twin engine, the cylinder comprising: a section of steel tubing cut to a length, the section of steel tubing including a first portion having a first wall thickness and a second portion having a second wall thickness less than the first wall thickness, wherein the second wall thickness is less than 0.050 inch, a first ribbing pattern on an outer surface of the section of steel tubing within the first portion, and a second ribbing pattern including multiple ribs formed on individual ribs of the first ribbing pattern; and a cast body provided on the first portion of the section of steel tubing so that the section of steel tubing is fixedly secured within the body to form a cylinder sleeve defining a cylinder bore, wherein the second portion having the second wall thickness extends from an end of the body to be received within a bore of a crankcase.

14. The cylinder of claim 13, wherein the cast body includes an exterior surface having a plurality of fins.

15. The cylinder of claim 13, wherein the cast body is solid, having no internal voids or cooling jackets for cooling liquid.

16. The cylinder of claim 13, wherein the cast body further includes a flange proximate the end, the flange defining a surface configured to abut a surface of the crankcase, and a plurality of mounting holes extending from the surface through the cast body.

17. The cylinder of claim 13, wherein a diameter of the cylinder bore is greater than 3.948 inches.

18. The cylinder of claim 13, wherein a diameter of the cylinder bore is about 4.000 inches.

19. The cylinder of claim 18, wherein the outer diameter of the second portion is about 4.068 inches.

20. The cylinder of claim 13, wherein the cylinder sleeve is constructed from SAE grade 4140 steel.

21. The cylinder of claim 13, wherein the second wall thickness is less than 0.040 inches and greater than 0.025 inch.

22. The cylinder of claim 13, wherein the second wall thickness is between 0.033 inch and 0.035 inch.

23. The cylinder of claim 13, wherein at least one of the first and second ribbing patterns is helical.

24. The cylinder of claim 13, wherein the first and second ribbing patterns are formed in intersecting helical patterns having opposite axial components in a given circumferential direction.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a side view of a motorcycle according to one embodiment of the invention.

[0011] FIG. 2 is a cross-sectional view of a V-twin engine of the motorcycle of FIG. 1. The engine is in an original, conventional configuration.

[0012] FIG. 3 is a cross-sectional view of one cylinder of the engine of FIG. 2.

[0013] FIG. 4 is a bottom view of an engine cylinder according to one embodiment of the present invention.

[0014] FIG. 5 is a side view of the engine cylinder of FIG. 4.

[0015] FIG. 6 is a cross-sectional view of the engine cylinder taken along line 6-6 of FIG. 5.

[0016] FIG. 7 is a cross-sectional view of the V-twin engine of FIG. 2 after being converted with a pair of the engine cylinders of FIGS. 4-6.

[0017] Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.

DETAILED DESCRIPTION

[0018] FIG. 1 illustrates a motorcycle 50. Although illustrated as a touring motorcycle 50, aspects of the invention may be applicable to other types of motorcycles (i.e., standard, cruiser, sport bike, sport touring, dual-sport, etc.). The motorcycle 50 includes a frame 52, a front wheel 54 coupled to the frame 52 through a steering assembly 56, and a rear wheel 58 coupled to the frame 52 through a swing arm assembly 59. The motorcycle 50 includes an engine 60 coupled to the frame 52 and operatively coupled to the rear wheel 58 through a transmission 62. As described below, the engine 60 can be a factory original engine that is modified to increase displacement in accordance with the structures and methods disclosed herein.

[0019] Illustrated separate from the motorcycle 50 in FIG. 2, the engine 60 includes a pair of cylinders 100 (FIG. 3) oriented in a V-configuration and coupled to a crankcase 64. On one end, a bottom end, each cylinder 100 is positioned in a crankcase bore 66 extending through a crankcase outer surface 68 such that a crankshaft 72 positioned in the crankcase 64 can be coupled to a piston 76 within each of the engine cylinders 100 via a corresponding connecting rod 74. On the other end, a top end, the cylinder 100 receives a cylinder head 70.

[0020] Each of the cylinders 100, as shown in FIG. 3, includes a body 104 and a cylinder liner 108. During construction of the cylinder 100, the body 104 is formed by a casting process around the liner 108. Thus, the cylinder liner 108 is fixedly secured within the body 104. The liner 108 defines a cylinder bore 112 and a spigot 116. The spigot 116, which extends out of the body 104, is configured to be received by the crankcase bore 66. The liner 108 and the spigot 116 share the same inner diameter D.sub.1. However, the liner 108 and the spigot 116 have different outer diameters, such that the spigot 116 has an outer diameter of D.sub.2, and the liner 108 has an outer diameter greater than the spigot outer diameter D.sub.2 above the spigot 116. The difference between the inner diameter D.sub.1 and the outer diameter D.sub.2 of the spigot 116 defines a wall thickness T.sub.1 of the spigot 116. The outer diameter D.sub.2 of the spigot 116 is designed to have a clearance (e.g., 0.025 inch) between the crankcase bore 66 and the spigot 116 to ensure a slip fit between the components.

[0021] The cylinder liner 108 of the factory original cylinder 100 may be constructed of cast iron. In one such example of an existing Harley-Davidson Twin Cam engine, the cylinder liner 108 is cast iron and provided with a spigot wall thickness T.sub.1 of 0.090 inch and an inner diameter D.sub.1 of 3.875 inches. Although durable, the brittle nature of cast iron results in the inability to machine or re-sleeve the cylinder 100 as the spigot 116 will not have the appropriate design characteristics required to achieve a reliable and robust design if the outer diameter D.sub.2 is limited to the size of the existing bore 66. Due to the practical limitations of ordinary cylinder sleeving material, it is common that any big-bore replacement cylinders include a wall thickness equal to or greater than the original cylinder spigot wall thickness T.sub.1, which necessitates increasing the size of the crankcase bores 66. In certain exemplary engines, such as Harley-Davidson Twin Cam engines, the crankcase bores 64 have a diameter of about 4.080 inches, which provides a diametric clearance, for example 0.025 inch, with the outer diameter D.sub.2 of the spigot 116 of the factory original cylinders 100. However, as previously mentioned, it is necessary to enlarge the crankcase bores 66 when retro-fitting the engine 60 with a big-bore kit.

[0022] Shown in FIGS. 4-6 is a big-bore cylinder 200 that increases displacement of the engine 60 and that can easily be retrofitted to the crankcase 64 of the engine 60 originally provided with the cylinders 100 of FIG. 3. Switching to the cylinders 200 increases the displacement of the engine 60 in a simple bolt-on process that eliminates the current labor intensive process described above. In a particular exemplary construction, a pair of the big-bore cylinders 200 convert either one of an existing 96 in.sup.3 Harley-Davidson Twin Cam engine having cylinder bore diameters of 3.750 inches and an existing 103 in.sup.3 Harley-Davidson Twin Cam engine having cylinder bore diameters of 3.875 inches to have a displacement of 110 in.sup.3 by increasing cylinder bore diameters to about 4.000 inches. As described below, the cylinders 200 are designed such that they fit into the existing bores 66 of the crankcase 64 such that the engine 60 can be converted to a larger displacement without having to remove, disassemble, or machine the crankcase 64.

[0023] Each big-bore cylinder 200 includes a body 204 having a finned exterior 208 configured to increase efficiency of heat transfer of the air-cooled engine. As previously mentioned, the existence of the finned exterior 208 and the particular engine class (i.e., air-cooled) merely represent one exemplary embodiment. As such, it will be understood that, in other constructions, the cylinder 200 may be designed for a liquid-cooled engine and may or may not include a finned exterior.

[0024] Additionally, the body 204 includes a first end 212 with a surface 216 configured to mate with a cylinder head 70′ which can be a modified version of the cylinder head 70 of the original engine 60 of FIG. 2. The body 204 further includes a second end 220 with a flange 224 providing a surface configured to abut the crankcase 64. The distance between the first end 212 and the second end 220 define a height H.sub.2 of the cylinder 200 which, in this case, is the same as a height H.sub.1 of the cylinder 100. Furthermore, extending through the body 204 from the surface 216 are a plurality of mounting holes 228 (e.g., four symmetrically arranged mounting holes). Each of the mounting holes 228 is configured to receive a fastener (not shown) to removably couple the cylinder 200 to the crankcase 64.

[0025] The cylinder 200 includes a sleeve 232 fixedly secured within the body 204 to define a cylinder bore 236. The sleeve 232 may be fixedly secured by a casting process whereby the body 204 is formed onto the exterior of the sleeve 232. The sleeve 232 has a main portion 240 and a second portion or spigot 244. The main portion 240 extends from the first end 212 to the second end 220 within the body 204, and the spigot 244 extends out of the body 204 and protrudes past the second end 220. When the cylinder 200 and the crankcase 64 are coupled, the crankcase bore 66 receives the spigot 244, as shown in FIG. 7.

[0026] In some constructions, the sleeve 232 is manufactured from tubing. The tubing can be cut to length, and machined in a subtractive process to form the spigot 244. As depicted in FIG. 6, the main portion 240 has a wall thickness T.sub.z, and the spigot 244 has a spigot wall thickness T.sub.3 different from the wall thickness T.sub.2 of the main portion 240. In the illustrated construction, the spigot wall thickness T.sub.3 is thinner than the wall thickness T.sub.2 of the main portion 240. In order to provide a large bore size with a limited outside dimension, the spigot wall thickness T.sub.3 may be less than 0.060 inch. The spigot wall thickness T.sub.3 may be greater than 0.025 inch, and in some constructions, greater than 0.030 inch. In some constructions, the spigot wall thickness T.sub.3 is less than 0.050 inch, and furthermore, the spigot wall thickness T.sub.3 may be less than 0.040 inch. In some embodiments, the wall thickness T.sub.3 is about 0.034 inch (e.g., 0.033 inch to 0.035 inch). In a construction where the outer diameter D.sub.2 of the spigot portion 244 is about 4.068 inches (e.g., 4.067 inches to 4.069 inches), the thin wall thickness T.sub.3 allows a cylinder bore diameter D.sub.3 that is greater than 3.948 inches. In some constructions, the bore diameter D.sub.3 is about 4.000 inches (e.g., 3.9997 inches to 4.0005 inches). Whether the outer diameter D2 of the spigot portion 244 is at, above, or below 4.068 inches, diametric clearance may be provided between the spigot portion 244 and the crankcase bores 66 to enable a slip fit of the spigot portion 244 into the crankcase bore 66. For example, the nominal diametric clearance is 0.012 inch when the outer diameter D.sub.2 of the spigot portion 244 is 4.068 inches and each of the crankcase bores 66 has a diameter of 4.080 inches.

[0027] The sleeve 232 is constructed from a material that is substantially less brittle than cast iron. For example, the sleeve 232 can be constructed of a type of chromoly steel alloy material. In some constructions, the sleeve 232 is constructed from SAE grade 4140 steel.

[0028] Additionally, the radially exterior surface of the main portion 240 of the sleeve 232 includes an intersecting helical pattern having a helical coarse rib 248 and a helical fine rib 252, each protruded radially outward as shown in FIG. 6. The helical ribs 248, 252 may be provided in the form of two different sized screw threads. The axial component of the helix is opposite for the two helical ribs 248, 252 such that one of the helical ribs 248, 252 is provided in a right hand rotation direction (i.e., clockwise), and the other of the helical ribs 248, 252 is provided in a left hand rotation direction (i.e., counterclockwise), which provides the intersecting pattern. Each of the helical ribs 248, 252 extends a majority of the height H.sub.2 of the main portion 240. The intersecting helical pattern is designed to securely lock the body 204 and the sleeve 232 together against separation or movement, particularly from rotational forces caused by twisting or vibration.

[0029] The design of the cylinder 200 enables it to be used in place of one of the factory original cylinder 100 to increase the displacement of the engine 60 without removal of the crankcase 64 and modification to the crankcase bores 66. The process entails a simple removal procedure of the cylinders 100 and replacement procedure with the corresponding big-bore cylinders 200. FIG. 7 illustrates an engine 60′ that results from converting the engine 60 of FIG. 2 with the installation of the cylinders 200 after removal of the cylinders 100. During installation, the spigot portion 244 of each cylinder 200 is aligned with and inserted into the respective crankcase bore 66, which is unmodified and retains its original size which was provided when accommodating the original, smaller-bore cylinder 100. The installation of the cylinders 200 may be performed as part of a kit of corresponding parts matched with the cylinders 200. For example, converting the engine 60 to the modified engine 60′ may include installation of new pistons 76′(and corresponding piston rings) in addition to the cylinder heads 70′. New connecting rods 74′ may optionally be provided and installed as well, although alternately, the factory original connecting rods 74 may be re-utilized when upsizing the displacement. The engine cylinder 200 may be removably secured to the crankcase 64 with suitable fasteners. Also provided is the cylinder head 70′ for each cylinder 200.

[0030] The embodiment described above and illustrated in the figures are presented by way of example only and are not intended as a limitation upon the concepts and principles of the present invention. As such, it will be appreciated that various changes in the elements and their configuration and arrangement are possible without departing from the spirit and scope of the present invention.