Friction welding method and friction welding apparatus

What is claimed is: 1. A friction welding method programmed in which an end surface of a first workpiece and an end surface of a second workpiece are made to engage in relative rotation while the end surfaces are in mutual contact as a compressive load is applied thereto so as to generate heat due to friction at a joint interface between the workpieces, the relative rotation of the workpieces is thereafter stopped, and an upset process pressure is applied to the workpieces, wherein the frictional heat is generated by performing a preliminary friction process started by contact between the end surface of a first workpiece and the end surface of the second workpiece and a main friction process continued from the preliminary friction process, wherein in the preliminary friction process, the compressive load employed is less than a lower threshold of a bend-producing compressive load domain that would cause bending of at least one of the first workpiece and the second workpiece but the compressive load and the relative rotation between the workpieces are such as will cause the heat due to friction in the preliminary friction process to be capable of causing plastic deformation at the workpiece end surfaces to correct any irregularities in the workpiece end surfaces so that there will be substantially no bending of the workpieces, and wherein the lower threshold of the bend-producing compressive load domain is determined based on the end surface state before contact between the first workpiece and the second workpiece and end surface diameters of the first workpiece and the second workpiece. 2. The friction welding method according to claim 1 , wherein in the preliminary friction process, when the end surface of the first workpiece and the end surface of the second workpiece are brought into contact with each other, the compressive load employed is closer to the lower threshold of the bend-producing compressive load domain than it is to an upper limit of a non-plastically-deforming compressive load domain within which the heat due to friction capable of causing plastic deformation at the workpiece end surfaces is not generated. 3. The friction welding method according to claim 1 , wherein after the end surfaces of the workpieces are brought into contact with each other, in the main friction process, the relative rotational speed of the workpieces is made higher than the relative rotational speed at the time of contact between the end surfaces of the workpieces. 4. The friction welding method according to claim 1 , wherein after the end surfaces of the workpieces are brought into contact with each other, in the main friction process, the compressive load and the relative rotational speed of the workpieces are made higher than those at the time of contact between the end surfaces of the workpieces to make the heat due to friction higher than the heat due to friction at the time of contact between the end surfaces of the workpieces. 5. The friction welding method according to claim 1 , wherein the relative rotational speed of the workpieces is maintained at constant rotational speed while the heat due to friction is generated. 6. A friction welding apparatus that causes relative rotation of an end surface of a first workpiece and an end surface of a second workpiece while the end surfaces are in mutual contact as a compressive load is applied thereto so as to generate heat due to friction at a joint interface between the workpieces, thereafter causing the relative rotation of the workpieces to stop, and then causing application of an upset process pressure to the workpieces, the friction welding apparatus comprising: a pair of holding devices each having a chuck unit holding a workpiece and arranged with the chuck parts facing each other; a movement drive source associated in a drivable manner with at least one of the paired holding devices and moving the workpieces respectively held by the chuck parts of the pair of holding devices in a relatively approaching direction; a rotary drive source associated in a rotationally drivable manner with at least one of the chuck parts of the pair of holding devices and relatively rotating the workpieces held by the chuck parts; a compressive load detecting unit detecting a compressive load acting between the end surfaces of the workpieces held by the chuck parts of the pair of holding devices which press against each other; and a control unit programmed to control the movement drive source and the rotary drive source based on information from the compressive load detecting unit when the end surfaces of the workpieces held by the chuck parts of the pair of holding devices are brought into contact with each other, so that the compressive load acting between the end surfaces of the workpieces which press against each other is less than a lower threshold of a bend-producing compressive load domain that would cause bending of the workpieces but the compressive load and the relative rotational speed between the workpieces are such as will cause the heat due to friction which is generated between the workpiece end surfaces to be capable of causing plastic deformation between the workpiece end surfaces, wherein the control unit includes a storage unit storing as setting information the rotational speed of the rotary drive source and the compressive load at the time of contact between the end surfaces of the workpieces, and a controller controlling the movement drive source and the rotary drive source based on the information from the compressive load detecting unit and the setting information stored in the storage unit when the end surfaces of the workpieces held by the chuck parts of the pair of holding devices are brought into contact with each other, so as to cause the end surfaces of the workpieces to press against each other with a compressive load that is less than the lower threshold of the bend-producing compressive load domain and so as to cause the compressive load and the relative rotational speed between the workpieces to be such as will generate heat due to friction between the workpiece end surfaces that is capable of causing plastic deformation to occur between the workpiece end surfaces as a result of that heat due to friction. 7. The friction welding apparatus according to claim 6 , wherein the storage unit is set to store, as the compressive load at the time of contact between the end surfaces of the workpieces, a compressive load which is closer to the lower threshold of the bend-producing compressive load domain than it is to an upper limit of a non-plastically-deforming compressive load domain within which the heat due to friction capable of causing plastic deformation at the workpiece end surfaces is not generated, and wherein the controller is set to control the movement drive source when the end surfaces of the workpieces held by the chuck parts of the pair of holding devices are brought into contact with each other, so that the compressive load acting between the end surfaces of the workpieces which press against each other is made equal to the compressive load stored in the storage unit. 8. The friction welding apparatus according to claim 6 , wherein the storage unit is set to store a compressive load larger than the compressive load at the time of contact between the end surfaces of the workpieces as a compressive load acting between the end surfaces of the workpieces which press against each other after the end surfaces of the workpieces are brought into contact with each other and to store a relative rotational speed higher than the relative rotational speed at the time of contact between the end surfaces of the workpieces as a relative rotational speed after the end surfaces of the workpieces are