Connecting rod and crosshead assembly for enhancing the performance of a reciprocating pump

What is claimed is: 1. An apparatus for a reciprocating pump assembly, the apparatus comprising: a crosshead comprising: a main body; a cylindrical bore formed through, and at least partially defining a first bearing surface in, the main body, the first bearing surface extending about a first axis; and a window formed in the main body transversely to the first axis, wherein, at the location of the window, the first bearing surface of the crosshead extends more than 180 degrees but less than 360 degrees about the first axis; a connecting rod comprising a cylindrical small end defining opposing end portions and a cylindrical second bearing surface extending between the opposing end portions, the cylindrical small end extending about a second axis and being adapted to extend within the cylindrical bore, and a beam portion adapted to be connected to the cylindrical small end at the second bearing surface, the beam portion and the cylindrical small end being separately formed; and a clamp adapted to be connected to the main body of the crosshead to prevent, or at least reduce, axial displacement of the cylindrical small end along the second axis and relative to the crosshead; wherein, when the cylindrical small end extends within the cylindrical bore and the beam portion is connected to the cylindrical small end, the first and second axes are substantially coaxial and the beam portion extends through the window; and wherein the clamp is sized and shaped so that, when the cylindrical small end extends within the cylindrical bore and the clamp is connected to the main body of the crosshead, the clamp engages both the main body and the respective opposing end portions of the cylindrical small end. 2. The apparatus of claim 1 , wherein the beam portion is adapted to be connected to the cylindrical small end using one or more fasteners. 3. The apparatus of claim 1 , wherein the crosshead further comprises a pair of struts integrally formed with the main body and partially defining the first bearing surface, the struts being formed on opposing sides of the window. 4. The apparatus of claim 1 , further comprising a bearing adapted to extend within the cylindrical bore, the bearing comprising a tubular body defining an interior passage and extending about a third axis, and a cutout formed in the tubular body transversely to the third axis, the cutout being adapted to be substantially aligned with the window so that the tubular body substantially covers the first bearing surface; wherein, when the bearing and the cylindrical small end extend within the cylindrical bore, the cutout is substantially aligned with the window, and the beam portion is connected to the cylindrical small end: the beam portion extends through both the cutout and the window; the bearing is disposed radially between the first bearing surface and the cylindrical small end, thus providing lubrication and/or wear resistance therebetween; and the first, second, and third axes are substantially coaxial. 5. The apparatus of claim 4 , wherein, at the location of the cutout, the tubular body of the bearing extends more than 180 degrees, but less than 360 degrees, about the third axis. 6. The apparatus of claim 1 , wherein the clamp comprises a pair of plates adapted to engage both the main body of the crosshead and the respective opposing end portions of the cylindrical small end, and a tensioner adapted to be connected to, and to apply tension between, the plates; wherein, when the plates engage both the main body of the crosshead and the opposing end portions of the cylindrical small end, and the tensioner is connected to, and applies tension between, the plates, the clamp prevents, or at least reduces, axial displacement of the cylindrical small end along the second axis and relative to the crosshead. 7. A method of assembling a crosshead and a connecting rod for a reciprocating pump, the method comprising: providing the crosshead, the crosshead comprising: a main body; a cylindrical bore formed through, and at least partially defining a first bearing surface in, the main body, the first bearing surface extending about a first axis; and a window formed in the main body transversely to the first axis, wherein, at the location of the window, the first bearing surface of the crosshead extends more than 180 degrees but less than 360 degrees about the first axis; positioning a cylindrical small end of the connecting rod within the cylindrical bore, the cylindrical small end defining opposing end portions and a cylindrical second bearing surface extending between the opposing end portions, and the cylindrical small end extending about a second axis; connecting a beam portion of the connecting rod to the cylindrical small end at the second bearing surface, the beam portion and the cylindrical small end being separately formed; and connecting a clamp to the main body of the crosshead to prevent, or at least reduce, axial displacement of the cylindrical small end along the second axis and relative to the crosshead; wherein, when the cylindrical small end is positioned within the cylindrical bore and the beam portion is connected to the cylindrical small end, the first and second axes are substantially coaxial and the beam portion extends through the window; and wherein the clamp is sized and shaped so that, when the cylindrical small end is positioned within the cylindrical bore and the clamp is connected to the main body of the crosshead, the clamp engages both the main body and the respective opposing end portions of the cylindrical small end. 8. The method of claim 7 , wherein connecting the beam portion to the cylindrical small end of the connecting rod comprising connecting the beam portion to the cylindrical small end using one or more fasteners. 9. The method of claim 7 , wherein the crosshead further comprises a pair of struts integrally formed with the main body and partially defining the first bearing surface, the struts being formed on opposing sides of the window. 10. The method of claim 7 , further comprising positioning a bearing within the cylindrical bore so that: a tubular body of the bearing is engaged with the first bearing surface of the crosshead, the tubular body defining an interior passage and extending about a third axis; and a cutout of the bearing is substantially aligned with the window of the crosshead, the cutout formed in the tubular body transversely to the third axis; wherein, when the bearing and the cylindrical small end are positioned within the cylindrical bore and the beam portion is connected to the cylindrical small end: the beam portion extends through both the cutout and the window; the bearing is disposed radially between the first bearing surface and the cylindrical small end, thus providing lubrication and/or wear resistance therebetween; and the first, second, and third axes are substantially coaxial. 11. The method of claim 10 , wherein, at the location of the cutout, the tubular body of the bearing extends more than 180 degrees, but less than 360 degrees, about the third axis. 12. The method of claim 7 , wherein connecting the clamp to the crosshead comprises: engaging a pair of plates of the clamp with both the main body of the crosshead and the respective opposing end portions of the cylindrical small end; and connecting a tensioner of the clamp to the plates so that the tensioner applies tension between the plates and the clamp prevents, or at least reduces, axial displacement of the cylindrical small end along the second axis and relative to the crosshead. 13. A reciprocating pump assembly, comprising: a fluid end comprising a plunger bore and a plunger adapted to