System and method for reducing friction in a counterbalancing spring of a roller shade

The invention claimed is: 1. A roller shade comprising: a roller tube; a shade material attached to the roller tube; and a shade drive unit at least partially disposed within the roller tube and comprising a drive assembly that rotates the roller tube to lower or raise the shade material between a rolled up position and a rolled down position, wherein the shade drive unit comprises: a stationary spring carrier; a rotating spring carrier operably connected to the roller tube and comprising a bore that traversely extends therethrough and a washer receiving cavity recessed into a terminal end of the rotating spring carrier and comprising washer retaining arms inwardly extending within the washer receiving cavity; a counterbalancing spring connected to and longitudinally extending between the stationary spring carrier and the rotating spring carrier, wherein the spring comprises an active portion having a plurality of coils located between the stationary spring carrier and the rotating spring carrier; an output mandrel comprising a first end operably connected to the drive assembly and a second terminal end that extends through the bore of the rotating spring carrier, wherein the output mandrel extends within the entire active portion of the spring between the stationary spring carrier and the rotating spring carrier, wherein during operation the drive assembly rotates the output mandrel and the rotating spring carrier with respect to the stationary spring carrier; and a locking washer comprising locking arms outwardly extending therefrom, wherein the locking washer is inserted into the washer receiving cavity by aligning the locking arms with spaces between the washer retaining arms and rotating the washer until the locking arms are aligned with and below the washier retaining arms thereby longitudinally retaining the washer within the washer receiving cavity; wherein the output mandrel comprises a determined length and the washer is biased against the second terminal end of the output mandrel thereby offsetting the stationary spring carrier from the rotating spring carrier to maintain the spring in a stretched state such that the plurality of coils at the active portion of the spring do not contact each other when the shade material is at the rolled down position. 2. The roller shade of claim 1 , wherein at the rolled down position the spring is at a maximum tension, and wherein the determined length of the output mandrel between the stationary spring carrier and the rotating spring carrier equals to or is larger than a deflected length of the active portion of the spring at the maximum tension. 3. The roller shade of claim 1 , wherein the determined length of the output mandrel is a factor of a diameter of a wire of the spring, a number of coils at the active portion of the spring, and a number of turns between the rolled up position and the rolled down position. 4. The roller shade of claim 1 , wherein the determined length of the output mandrel is determined using the following formula: l mandrel =l deflected +l clearance +l components where, l mandrel is the determined length the output mandrel, l deflected is a deflected length of the active portion of the spring at a maximum tension, l clearance is a predetermined clearance factor, and l components is an adjustment factor that accounts for assembly of the shade drive unit. 5. The roller shade of claim 4 , wherein the deflected length of the active portion of the spring at the maximum tension is determined using the following formula: l deflected =d wire (( N coils −N fastened ×2)+ N turns +1) where, d wire is a diameter of a wire of the spring, N coils is a total number of coils of the spring, N fastened is a number of coils at each end of the spring that are attached to one of the stationary and the rotating spring carriers, N turns is a number of turns between the rolled up position and the rolled down position. 6. The roller shade of claim 1 , wherein the spring is pretensioned when the shade material is at the rolled up position, and wherein the determined length of the output mandrel between the stationary spring carrier and the rotating spring carrier is a factor of a number of pretension turns in the spring at the rolled up position such that the plurality of coils at the active portion of the spring do not contact each other when the shade material is at the rolled down position. 7. The roller shade of claim 4 , wherein the spring is pretensioned when the shade material is at the rolled up position, and wherein the deflected length of the active portion of the spring at the maximum tension is determined using the following formula: l deflected =d wire (( N coils −N fastened ×2)+ N turns +N pretension +1) where, d wire is a diameter of a wire of the spring, N coils is a total number of coils of the spring, N fastened is a number of coils at each end of the spring that are attached to one of the stationary and the rotating spring carriers, N turns is a number of turns between the rolled up position and the rolled down position, and N pretension is a number of pretensioned turns in the spring at the rolled up position. 8. The roller shade of claim 1 , wherein the drive assembly comprises a motor that drives a motor output shaft operably connected to the output mandrel. 9. The roller shade of claim 8 , wherein the shade drive unit comprises a motor housing that houses the motor therein and comprises the stationary spring carrier, wherein the output mandrel extends from an opening in the motor housing, and wherein during operation of the motor rotation of the motor output shaft causes rotation of the rotating spring carrier and thereby the roller tube while the motor housing and the motor remain stationary. 10. The roller shade of claim 8 , wherein the drive assembly further comprises at least one selected from the group consisting of a planetary gear, a clutch, or any combinations thereof. 11. The roller shade of claim 1 , wherein the output mandrel comprises a first mandrel portion connected to a second mandrel portion, wherein the first mandrel portion is operably connected to the drive assembly and wherein the second mandrel portion is attached to the rotating spring carrier. 12. The roller shade of claim 1 , wherein during assembly of the shade drive unit: the spring is positioned over the output mandrel and attached at a first end of the spring to the stationary spring carrier, the rotating spring carrier is slidably mounted over the output mandrel and attached to a second end of the spring while the spring is in an unstretched state, and the rotating spring carrier is slidably pulled away from the stationary spring carrier to stretch the spring to the stretched state and attached to the second terminal end of the output mandrel. 13. The roller shade of claim 1 , wherein the rotating spring carrier comprises a drive wheel operably connected to the roller tube. 14. The roller shade of claim 13 , wherein the bore is shaped to mate with an external surface of the output mandrel such that rotation of the output mandrel causes rotation of the drive wheel. 15. The roller shade of claim 1 , wherein the washer is further secured to the output mandrel via a screw inserted through a hole in the washer and screwed into a threaded hole in the second terminal end of the output mandrel. 16. A roller shade comprising: a roller tube; a shade material attached to the roller tube; and a shade drive unit at least partially disposed w