Hardness verification utilizing ultrasonic velocities

Wherefore, we claim: 1. A method of determining a hardness of a component to be tested by utilizing an ultrasonic meter, the method comprising the steps of: selecting an elongate component to be tested which has a central longitudinal axis and a first end surface that is perpendicular to the longitudinal axis; positioning a probe of the ultrasonic meter relative to the component such that the probe is concentric with the longitudinal axis of the component and a signal from an emitter of the probe is emitted along the longitudinal axis and through the first end surface into the component to be tested and travels along the longitudinal axis; emitting the signal from the emitter of the probe along the longitudinal axis and through the first end surface into the component to be tested, and the emitted signal passing through the component to be tested along the longitudinal axis; reflecting the emitted signal off an opposed second end surface of the component to be tested directly back along the longitudinal axis through the component to be tested toward a detector of the probe, and the probe being positioned relative to the component such that the emitted signal is reflected directly back along the longitudinal axis through the first end surface to the detector of the probe; detecting the reflected emitted signal via the detector of the probe; and determining a hardness of the component to be tested based upon a velocity of the emitted signal through the component to be tested. 2. The method of determining the hardness of the component to be tested according to claim 1 , further comprising the steps of locating both the emitter and the detector closely adjacent one another in an end face of the probe, and the end face being perpendicular to a longitudinal axis of the probe. 3. The method of determining the hardness of the component to be tested according to claim 2 , further comprising the steps of positioning the probe so that the longitudinal axis of the probe is coincident with the longitudinal axis of the component and the end face of the probe abuts the first end surface of the component to be tested. 4. The method of determining the hardness of the component to be tested according to claim 1 , further comprising the steps of: determining a minimum threshold value; accepting the component to be tested which have a value above the minimum threshold value; and rejecting the component to be tested which have a value below the minimum threshold value. 5. The method of determining the hardness of the component to be tested according to claim 1 , further comprising the steps of: determining a minimum threshold value; accepting the component to be tested which have a value equal to or above the minimum threshold value; and rejecting the component to be tested which have a value below the minimum threshold value. 6. The method of determining the hardness of the component to be tested according to claim 4 , further comprising the step of determining the minimum threshold value by testing at least one component to be tested which has a known hardness. 7. The method of determining the hardness of the component to be tested according to claim 4 , further comprising the step of verifying a reliability of the minimum threshold value by testing at least one component to be tested which has a known hardness less than the minimum threshold value. 8. A system for determining a hardness of a component to be tested which comprises an ultrasonic meter, the system comprising: an elongate component to be tested which has a central longitudinal axis and a first end surface that is perpendicular to the longitudinal axis of the component; the ultrasonic meter having a probe comprising a longitudinal axis, the probe being aligned with the component to be tested such that the probe is concentric with the longitudinal axis of the component and the longitudinal axis of the probe is coaxial to the longitudinal axis of the component to be tested, and the probe emitting a signal from an emitter of the probe along the longitudinal axis of the probe and through the first end surface of the component to be tested; the emitter of the probe being located for emitting the signal along the longitudinal axis of the probe and through the first end surface into the component to be tested so that the emitted signal passes through the component to be tested and along the longitudinal axis of the component and is reflected by an opposed second end surface of the component to be tested back through the component to be tested toward a detector of the probe along the longitudinal axis of the component to be tested; the detector of the probe detects the reflected signal, and a hardness of the component to be tested is determined based upon a velocity of the emitted signal passing through the component to be tested and along the longitudinal axis of the component to be tested. 9. A method of determining a hardness of a ball joint following heat treatment during manufacture thereof utilizing an ultrasonic meter to ascertain acceptability of the bail joint, the method comprising: selecting at least first and second ball joints having longitudinal axes that extend from planar surfaces on first axial ends of the first and the second ball joints to fiat surfaces on axially opposite ball ends of the first and the second ball joints, and the first ball joint having a known hardness, and the second ball joint having a known hardness that is different than the known hardness of the first ball joint, and the planar surfaces and the flat surfaces of the first and the second ball joints, respectively, being perpendicular to the longitudinal axes of the respective first and the second ball joints; positioning a probe of the ultrasonic meter relative to the first ball joint such that the probe is concentric with the longitudinal axis of the first ball joint and a flat axially leading surface of the probe is parallel to and mates with the planar surface of the first ball joint, and the leading surface of the probe supporting an emitter and a detector; emitting first ultrasonic signals from the emitter of the probe through the planar surface of the first ball joint, the first ultrasonic signals passing along the longitudinal axis of the first ball joint and being reflected by the flat surface of the first ball joint directly back along the longitudinal axis thereof to the detector of the probe; detecting the reflected first ultrasonic signals with the detector of the probe; determining a velocity of the first ultrasonic signals through the first ball joint; positioning the probe of the ultrasonic meter relative to the second ball joint such that the probe is concentric with the longitudinal axis of the second ball joint and the flat axially leading surface of the probe is parallel to and mates with the planar surface of the second ball joint; emitting second ultrasonic signals from the emitter of the probe through the planar surface of the second ball joint, and the second ultrasonic signals passing along the longitudinal axis of the second ball joint and being reflected by the fiat surface of the second ball joint directly back along the longitudinal axis thereof to the detector of the probe; detecting the reflected second ultrasonic signals with the detector of the probe; determining a velocity of the second ultrasonic signals through the second ball joint; selecting a third ball joint having a longitudinal axis that extends from a planar surface on a first axial end of the third ball joint to a flat surface on an axially opposite ball end of the third ball joint, and the third ball joint having an unknown hardness, and the planar surface and the flat surface of the third ball joi