Method of manufacturing two tubes simultaneously and machine for use therein

What is claimed is: 1. A method of manufacturing a tube having a hollow interior for housing an axle shaft, which transmits rotational motion from a prime mover to a wheel of a vehicle, with the tube formed in at least a first machine and a second machine each having a fixed base and a press structure movable toward the fixed base, a first die assembly coupled to the fixed base of the first machine, a second die assembly coupled to the fixed base of the first machine and further defined as an initial stage second die assembly and a later stage second die assembly, a first mandrel coupled to the press structure of the first machine, a second mandrel coupled to the press structure of the first machine and spaced from the first mandrel further defined as an initial stage second mandrel and a later stage second mandrel, a third die assembly coupled to the fixed base of the second machine, and a third mandrel coupled to the press structure of the second machine, said method comprising the steps of: placing a billet into a cavity of the first die assembly; pressing the billet into the cavity of the first die assembly with the first mandrel coupled to the press structure of the first machine to form a bore at one end of the billet thereby producing a pre-formed billet; moving the pre-formed billet from the cavity of the first die assembly to a cavity of the initial stage second die assembly; pressing the pre-formed billet into the cavity of the initial stage second die assembly with the initial stage second mandrel coupled to the press structure of the first machine to elongate the pre-formed billet and form a hollow interior therein thereby producing a preliminarily extruded tube; moving the preliminarily extruded tube from the cavity of the initial stage second die assembly to a cavity of the later stage second die assembly; pressing the preliminarily extruded tube into the cavity of the later stage second die assembly with the later stage second mandrel coupled to the press structure of the first machine to further elongate the preliminarily extruded tube thereby producing the extruded tube; moving the extruded tube from the cavity of the later stage second die assembly to a cavity of the third die assembly; and pressing the extruded tube into the cavity of the third die assembly with the third mandrel coupled to the press structure of the second machine to elongate the extruded tube and decrease a thickness of a wall of the extruded tube thereby producing a drawn tube. 2. The method as set forth in claim 1 , wherein a total extruded tube manufacturing time to complete the steps of placing a billet, pressing the billet to produce the pre-formed billet; moving the pre-formed billet, and pressing the pre-formed billet to produce the extruded tube is from 15 to 20 seconds. 3. The method as set forth in claim 1 , wherein the step of pressing the pre-formed billet is further defined as the step of backward extruding the pre-formed billet with the initial stage second die assembly and the initial stage second mandrel by cycling the single press structure towards and then away from the fixed base to elongate the pre-formed billet and form the hollow interior therein thereby producing the preliminarily extruded tube. 4. The method as set forth in claim 1 , wherein the step of pressing the preliminary extruded tube is further defined as the step of backward extruding the preliminarily extruded tube with the later stage second die assembly and the later stage second mandrel by cycling the single press structure towards and then away from the fixed base to further elongate the preliminarily extruded tube thereby producing the extruded tube. 5. The method as set forth in claim 1 , wherein a total drawn tube manufacturing time to complete the steps of placing a billet, pressing the billet to produce the pre-formed billet; moving the pre-formed billet, and pressing the pre-formed billet to produce the extruded tube, moving the extruded tube, and pressing the extruded tube to produce the drawn tube is from 20 to 240 seconds. 6. The method as set forth in claim 1 , wherein the thickness of the wall of the drawn tube is from 3 to 12 millimeters and the drawn tube has a yield strength of at least 600 MPa. 7. The method as set forth in claim 6 , wherein the yield strength of the drawn tube is at least 700 MPa. 8. The method as set forth in claim 1 , wherein the step of pressing the extruded tube into the cavity of the third die assembly is further defined as drawing the extruded tube by cycling the press structure of the second machine towards and then away from the fixed base to elongate the extruded tube and decrease a thickness of a wall of the extruded tube thereby producing a drawn tube. 9. The method as set forth in claim 1 , further comprising a step of machining an end of the drawn tube to produce a full float hollow axle tube having a hollow interior that spans a length of the full float hollow axle tube. 10. The method as set forth in claim 1 , wherein the drawn tube has a drawn wall having a thickness with the thickness of the drawn wall non-uniform about a circumference of the drawn tube. 11. The method as set forth in claim 1 , further comprising a step of delaying the extruded tube transportation to the third die assembly to cool the extruded tube. 12. The method as set forth in claim 11 , wherein the step of delaying the extruded tube transportation to the third die assembly is further defined as the steps of placing the extruded tube onto a cooling conveyor until the desired temperature of the extruded tube is reached and inserting the extruded tube into the third die assembly. 13. A method of manufacturing a tube having a hollow interior for housing an axle shaft, which transmits rotational motion from a prime mover to a wheel of a vehicle, with the tube formed in at least a first machine and a second machine each having a fixed base and a press structure movable toward the fixed base of the first machine, a first die assembly coupled to the fixed base of the first machine, a second die assembly coupled to the fixed base of the first machine and further defined as an initial stage second die assembly and a later stage second die assembly, a first mandrel coupled to the press structure of the first machine, a second mandrel coupled to the press structure of the first machine and spaced from the first mandrel further defined as an initial stage second mandrel and a later stage second mandrel, a third die assembly coupled to the fixed base of the second machine, and a third mandrel coupled to the press structure of the second machine, said method comprising the steps of: placing a first billet into a cavity of the first die assembly; placing a first pre-formed billet having a bore defined in one end thereof into a cavity of the initial stage second die assembly; placing a first preliminarily extruded tube having a hollow interior into a cavity of the later stage second die assembly; placing a first extruded tube into a cavity of the third die assembly; moving the press structure of the first machine toward the fixed base after the steps of placing the first billet into the first die assembly, placing the first pre-formed billet into the initial stage second die assembly, and placing the first preliminarily extruded tube into the later stage second die assembly such that the first mandrel contacts the first billet in the first die assembly, the initial stage second mandrel contacts the first pre-formed billet in the initial stage second die assembly, and the later stage second mandrel contacts the first preliminarily extruded tube in the later stage second die assembly to