Patent Publication Number: US-10781769-B2

Title: Method of manufacturing an engine block

Description:
The present disclosure relates generally to the manufacture of Aluminum alloy engine block and more specifically to methods of manufacturing cast engine blocks having improved robustness while maintaining weight advantages over other alloys and processes. 
     The use of lightweight Aluminum alloys in cylinder blocks for internal combustion engines has greatly enhanced the vehicle energy efficiency by reducing the overall weight of the vehicle at the same time maintaining most of the capability of the cylinder block. Additional design adaptations to lighter and more compact engine systems have caused some challenges to continuing use of Aluminum alloys as the material of choice for some engine applications. For example, elevated heat stress in certain areas of the cylinder block have cause premature failures due to the geometry of the cylinder block and the inability to properly cool these areas. 
     Accordingly, there is a need in the art for an improved cylinder block design and method for manufacturing the new cylinder block that extends the useful life of the cylinder block in service, prevents catastrophic failure, and provides the design necessary to maintain and improve upon the use of lightweight Aluminum alloys for achieving fuel economy standards. 
     SUMMARY 
     The present disclosure comprises a cylinder block for use in an internal combustion engine. The cylinder block includes a first and second cylinder bores, a first and second cylinder bore liners, and a Siamese insert. The first and second cylinder bores are disposed adjacent to each other. The first and second cylinder bores each comprise a first cylinder bore wall and a second cylinder bore wall, respectively, and a shared cylinder bore wall. The first cylinder bore liner is disposed on a first inner surface of the first cylinder bore wall and the second cylinder bore liner is disposed on a second inner surface of the second cylinder bore wall. The Siamese insert is disposed in a top portion of the shared cylinder bore wall. 
     In one example of the present disclosure, the Siamese insert comprises a high temperature creep resistant alloy and the cylinder block comprises an Aluminum Alloy. 
     In another example of the present disclosure, the Siamese insert comprises an Aluminum-Bronze alloy having between about 8 to 10 wt. % Aluminum, Iron, Nickle, Manganese, Zinc, and Copper. 
     In yet another example of the present disclosure, the Siamese insert comprises an Aluminum-Bronze alloy having about 9.62 wt % Aluminum, 3.93 wt % Iron, 0.62 wt % Nickle, 3.36 wt % Manganese, 0.46 wt % Zinc, and the balance Copper. 
     In yet another example of the present disclosure, the Siamese insert comprises one of an Aluminum alloy, a steel alloy, a bronze alloy, and a ceramic-metal material. 
     In yet another example of the present disclosure, the Siamese insert comprises a top surface that includes a portion of a head deck sealing surface. 
     In yet another example of the present disclosure, the Siamese insert comprises a first and second bore liner pocket, the first bore liner is partially dispose in the first bore liner pocket, and the second bore liner is partially disposed in the second bore liner pocket. 
     In yet another example of the present disclosure, the shared cylinder bore wall comprises a first portion of the first cylinder bore liner, a second portion of the second cylinder bore liner, a third portion of the first cylinder bore wall, a fourth portion of the second cylinder bore wall, and the Siamese insert. 
     The present disclosure further comprises a cylinder block for use in an internal combustion engine. The cylinder block includes a first and second cylinder bores, a first and second cylinder bore liners, and a Siamese insert. The first cylinder bore liner is disposed on a first inner surface of the first cylinder bore wall and the second cylinder bore liner is disposed on a second inner surface of the second cylinder bore wall. The Siamese insert comprises a top surface and a high temperature creep resistant alloy. The Siamese insert is disposed in a top portion of the shared cylinder bore wall and the top surface includes a portion of a head deck sealing surface. 
     In one example of the present disclosure, the Siamese insert comprises an Aluminum-Bronze alloy having between about 8 to 10 wt. % Aluminum, Iron, Nickle, Manganese, Zinc, and Copper. 
     In another example of the present disclosure, the Siamese insert comprises an Aluminum-Bronze alloy having about 9.62 wt % Aluminum, 3.93 wt % Iron, 0.62 wt % Nickle, 3.36 wt % Manganese, 0.46 wt % Zinc, and the balance Copper. 
     In yet another example of the present disclosure, the Siamese insert comprises one of an Aluminum alloy, a steel alloy, a bronze alloy, and a ceramic-metal material. 
     In yet another example of the present disclosure, the Siamese insert comprises a first and second bore liner pocket, the first bore liner is partially dispose in the first bore liner pocket, and the second bore liner is partially disposed in the second bore liner pocket. 
     In yet another example of the present disclosure, the shared cylinder bore wall comprises a first portion of the first cylinder bore liner, a second portion of the second cylinder bore liner, a third portion of the first cylinder bore wall, a fourth portion of the second cylinder bore wall, and the Siamese insert. 
     The present disclosure further comprises a method for manufacturing a cylinder block for an internal combustion engine. The method includes forming a sand core package and mold comprising a cylinder bore liner for each cylinder of the engine. The method further includes casting the cylinder block by pouring a liquid metal alloy into the mold, and cleaning and machining the cylinder block after cooling. 
     In one example of the present disclosure, forming the sand core package and mold comprising the cylinder bore liner for each cylinder of the engine further comprises forming the sand core package and mold comprising the cylinder bore liner for each cylinder of the engine and a Siamese insert disposed between each cylinder bore liner. 
     In another example of the present disclosure, casting the cylinder block by pouring the liquid metal alloy into the mold further comprises pouring a liquid Aluminum alloy into the mold to cast-in-place the cylinder bore liners and Siamese inserts. 
     In another example of the present disclosure, the method further includes fabricating a Siamese insert between each of the cylinder bore liners using a metal alloy additive technique. 
     In yet another example of the present disclosure, the method further includes fabricating a Siamese insert between each of the cylinder bore liners using at least one of laser cladding, cold/kinetic spray, and thermal spray metal adding techniques. 
     In yet another example of the present disclosure, the method further includes fixing a Siamese insert between each of the cylinder bore liners. 
     In yet another example of the present disclosure, the method further includes brazing a Siamese insert between each of the cylinder bore liners. 
     The above features and advantages and other features and advantages of the present disclosure are readily apparent from the following detailed description when taken in connection with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWING 
       The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. 
         FIG. 1  is a perspective view of cylinder bore liners according to the principles of the present disclosure; 
         FIG. 2  is a side view of a cast engine block having cast-in-place cylinder bore liners according to the principles of the present disclosure; 
         FIG. 3  is a side view of a cast engine block having cast-in-place cylinder bore liners and Siamese inserts according to the principles of the present disclosure; 
         FIG. 4  is a perspective and plan view of Siamese inserts according to the principles of the present disclosure; 
         FIG. 5  is a chart depicting test results for an example alloy used in the Siamese inserts according to the principles of the present disclosure, 
         FIG. 6  is a flow chart depicting a manufacturing method for an Aluminum alloy engine block according to the principles of the present disclosure, and 
         FIG. 7  is a cross section of a cylinder block according to the principles of the present disclosure. 
     
    
    
     DESCRIPTION 
     Examples of the present disclosure advantageously provide method of manufacturing a cylinder block  10  for an internal combustion engine. The cylinder block  10 , as depicted after various stages of the method in  FIGS. 1-4 , is arranged in a V8 configuration. However, other configurations of cylinder blocks  10  are considered without departing from the present disclosure. Preferably, at least two cylinder bores  12  of the cylinder block  10  are adjacent to each other and share a portion of a bore wall. Thus, inline, “V”, “W” or flat configurations may all be included in this disclosure. The cylinder block  10  includes several internal and external features including but not limited to cylinder bores  12 , internal water passages  14 , internal oil passages  16 , bolt bosses  18 , structural ribs  20 , and sealing surfaces  22 . More particularly, the cylinder bores  12  include a bore wall  24  having a top end  26  and a bottom end (not shown). The top end  26  is flush with a head deck sealing surface  28  while the bottom end is formed to terminate in a crankcase cavity (not shown). The bore wall  24  of a first cylinder bore  30  is shared with an adjacent second cylinder bore  32 . In this manner, an arrangement of cylinder bores  30 ,  32  having common or shared bore walls  36  are considered to have a Siamese cylinder bore arrangement. One of the major benefits of having a Siamese cylinder bore arrangement is to shorten the length and to reduce the weight of the cylinder block  10  making a more compact engine package that provides the opportunity to save weight in other components of the vehicle. 
     Manufacturing a cylinder block  10  as shown in  FIGS. 1-4  includes casting iron or aluminum based alloys. When using aluminum based alloys, a cylinder bore liner  34  can be included to improve the wear characteristics of the surface  38  of the bore walls  24 . The cylinder bore liner  34  is formed from an iron based alloy and can be cast or press fit into the aluminum cylinder block  10 . Alternatively, the cylinder bore liner  34  can be sprayed onto the parent metal cylinder bore  30 ,  32  using a plasma metal spraying technique or other manufacturing process. 
     Focusing more on  FIGS. 3, 4, and 7 , a cylinder block  10  including a Siamese insert  40  is illustrated. The Siamese insert  40  is disposed at the top end  26  of the shared bore wall  36 . The purpose of the Siamese insert  40  is to replace the cast Aluminum alloy in this area with an alternative alloy having improved high temperature characteristics. For example, a major source of failure of cylinder blocks  10  having Siamese bore arrangements is the deterioration of the aluminum alloy of the sealing surface  22  between the cylinder bores  12  due to high thermal loading and low creep resistance of the cast aluminum alloy. The high thermal loading is higher in this portion of the cylinder bores  12  due to the lack of internal water passages  14  in this area and receiving heat from adjacent cylinder bores  30 ,  32 . Two major failure modes result. The first failure mode is the failure of the head gasket (not shown) to seal between the cylinder bores  12  and water passages  14  due to the recession of the aluminum alloy. The head gasket failure causes high pressure communication between the adjacent cylinders  30 ,  32 . The second failure mode is increase cylinder bore  12  distortion thus causing the piston assembly to not seal against the bore wall  24 . This results in increased blow-by causing a reduction in fuel economy, increase in oil consumption, and poor emissions. 
     The Siamese insert  40  includes a sealing surface  42 , a first bore liner pocket  44 , a second bore liner pocket  46 , a first interface surface  48 , a second interface surface  50 , a first top ridge  52 , and a second top ridge  54 . The Siamese insert  40 , when displayed in a plan view as shown in  FIG. 4 , has an hourglass-like shape that conforms to the cylindrical shape of the first and second cylinder bores  30 ,  32 . The first bore liner pocket  44  receives a bore liner  34  of the first cylinder bore  30  and the second bore liner pocket  46  receives a bore liner  34  of the second cylinder bore  32 . The first and second interface surfaces  48 ,  50  are adjacent to and connect with the cylinder block  10  through the remaining portions of the cylinder bore walls  24 . The method of connection or attachment of the Siamese inserts  40  to the cylinder block  10  maybe any one of a number of metal joining techniques. For example, the Siamese insert  40  may be brazed or soldered into place. Additionally, the Siamese insert  40  may be cast into place in the same manner that the cylinder bore liners  34  are cast into place. 
     Turning now to  FIG. 5 , an example of a Copper based alloy for use in the Siamese inserts  40  is illustrated. The chart  60  provides a composition  62  for the Copper based alloy including about 9.62 wt % Aluminum Al, 3.93 wt % Iron Fe, 0.62 wt % Nickle Ni, 3.36 wt % Manganese Mn, 0.46 wt % Zinc Zn, and the balance Copper Cu. Additionally, data from testing of this particular alloy includes strength testing after several hours at high temperatures. For example, strength tests were run on samples after 100, 500, and 1000 hours at 200° C. and 300° C. 
     Referring now to  FIG. 6 , a method of manufacturing an aluminum cylinder block  10  is detailed and referred to as method  100 . The method  100  begins with a first step  102  as a sand core and sand mold or semi-permanent mold casting process by forming or blowing sand cores including a crankcase or cylinder bore core having a cast-in-place bore liner  34  for each cylinder bore. A second step  104  includes assembling the various individual sand cores of the sand core package. During the assembly of the sand cores a number of Siamese inserts  40  may be placed into the sand core package so that the Siamese inserts  40  are cast-in-place between the cylinder bores  12 . Alternatively, a third step  106  includes casting the cylinder block  10  without the Siamese inserts  40 . In this regard, a fourth step  108  may be to braise or otherwise join the Siamese inserts  40  to the cylinder block  10  between the cylinder bores  12 . Alternatively, a fifth step  110  includes fabricating the Siamese inserts  40  in the cylinder block  10  using an alloy adding technique such as laser cladding, cold/kinetic spray, thermal spray, and a combination of the alloy adding techniques. The alloy adding techniques include a deposition of a high creep strength alloy in place between the cylinder bores  12  forming the Siamese insert  40 . Other alloy adding techniques may be considered without departing from the scope of the disclosure. A sixth step  112  of the method  100  include machining the casting thus achieving a lightweight and compact Aluminum alloy cylinder block having high creep strength alloys disposed between the cylinder bores  12  at the sealing surface  22  of the cylinder head gasket. 
     While examples have been described in detail, those familiar with the art to which this disclosure relates will recognize various alternative designs and examples for practicing the disclosed structure within the scope of the appended claims.