Driving force transmission apparatus and method of manufacturing the same

What is claimed is: 1. A method of manufacturing a magnetic path forming member of a driving force transmission apparatus including, an outer rotary member and an inner rotary member that are rotatable relative to each other, multiple clutch discs that are arranged between the outer rotary member and the inner rotary member, and that transmit driving force between the outer rotary member and the inner rotary member with use of frictional force, an electromagnet arranged on one axial side of the clutch discs, an armature that is arranged on another axial side of the clutch discs, and that is attracted toward the electromagnet when the electromagnet is energized, and the magnetic path forming member being included in the outer rotary member, is arranged between the clutch discs and the electromagnet, and forms a magnetic path in cooperation with the electromagnet, the clutch discs and the armature when the electromagnet is energized, the method comprising: heating a radially intermediate portion of a workpiece and made of a magnetic material, to melt the radially intermediate portion from one axial face of the workpiece to another axial face of the workpiece to form a keyhole; and disposing an alloy element in a molten pool around the keyhole to demagnetize a melted portion, thereby providing the magnetic path forming member. 2. The method according to claim 1 , including a step of pressing the alloy element to integrate the alloy element with the radially intermediate portion of the workpiece, and subsequently heating the radially intermediate portion to form the keyhole. 3. The method according to claim 1 , wherein a recessed portion that is opened toward one axial side and that accommodates the electromagnet is formed in the magnetic path forming member, further comprising a step of forming the magnetic path forming member by irradiating a radially intermediate portion of a bottom face of the recessed portion of the workpiece with a laser beam from the recessed portion side to form the keyhole, so that, in a demagnetized portion, a radial width of a portion on a side opposite to the recessed portion is made smaller than a radial width of a portion on the recessed portion side. 4. The method according to claim 2 , wherein a recessed portion that is opened toward one axial side and that accommodates the electromagnet is formed in the magnetic path forming member, further comprising a step of forming the magnetic path forming member by irradiating a radially intermediate portion of a bottom face of the recessed portion of the workpiece with a laser beam from the recessed portion side to form the keyhole, so that, in a demagnetized portion, a radial width of a portion on a side opposite to the recessed portion is made smaller than a radial width of a portion on the recessed portion side. 5. The method according to claim 1 , wherein: an annular groove is formed in a clutch disc-side portion of the radially intermediate portion of the workpiece; and the keyhole is formed in a bottom of the annular groove to demagnetize the melted portion. 6. The method according to claim 2 , wherein: an annular groove is formed in a clutch disc-side portion of the radially intermediate portion of the workpiece; and the keyhole is formed in a bottom of the annular groove to demagnetize the melted portion. 7. The method according to claim 3 , wherein: an annular groove is formed in a clutch disc-side portion of the radially intermediate portion of the workpiece; and the keyhole is formed in a bottom of the annular groove to demagnetize the melted portion. 8. The method according to claim 4 , wherein: an annular groove is formed in a clutch disc-side portion of the radially intermediate portion of the workpiece; and the keyhole is formed in a bottom of the annular groove to demagnetize the melted portion.