Dryer motor and control

What is claimed is: 1. A drying device for tumble drying articles, the drying device comprising: a non-line frequency variable speed electric motor coupled to a support frame and electrically coupled to a non line-frequency supply voltage, the non-line frequency electric motor being configured to rotate an output shaft having a first end and a second end; a drum coupled to the support frame and coupled to the first end of the output shaft to enable rotation of the drum, the drum having an interior space; a fan member directly connected to the second end of the output shaft, the fan member generating an air flow within the interior space of the drum in response to the output shaft being rotated by the non-line frequency variable speed electric motor; and a controller electrically coupled to the non-line frequency variable speed electric motor, the controller being configured to sense current drawn by the non-line frequency variable speed electric motor and control an angular velocity of the output shaft of the non-line frequency variable speed electric motor to control either a rotation speed of the fan member or a rotation speed of the drum. 2. The drying device of claim 1 further comprising: a frequency generator electrically coupled to the controller and to the non-line frequency variable speed electric motor; and the controller being further configured to control the angular velocity of the output shaft by operating the frequency generator to control a frequency of a voltage signal generated by a frequency generator that is provided to the non-line frequency variable speed motor. 3. The drying device of claim 2 , the controller being further configured to increase the frequency of the voltage signal generated by the frequency generator from a zero frequency to a higher frequency over a plurality of seconds in response to a dryer start signal. 4. The drying device of claim 2 , the controller being further configured to maintain the frequency of the voltage signal generated by the frequency generator at a frequency that enables the non-line frequency variable speed electric motor to compensate for slippage with a load in the drum that is less than a normal load in response to the controller receiving a low load signal from a user interface. 5. The drying device of claim 2 , the controller being further configured to maintain the frequency of the voltage signal generated by the frequency generator at a frequency that enables the non-line frequency variable speed electric motor to compensate for slippage with a load that is greater than a normal load in response to the controller receiving a high load signal from a user interface. 6. The drying device of claim 1 further comprising: a heater configured to heat the air flow generated by the fan member; and the controller including a blower sensor configured to generate an electrical signal indicative of air flow being generated by the fan member, and the controller being further configured to operate the heater to heat the air flow generated by the fan member only in response to the electrical signal generated by the blower sensor indicating that air flow is being generated by the fan member. 7. The drying device of claim 1 , wherein the non-line frequency variable speed electric motor is configured to rotate the output shaft in both a clockwise and a counterclockwise direction, and the drum is configured to rotate in the clockwise and the counterclockwise directions in response to rotation of the output shaft. 8. The drying device of claim 1 further comprising: a belt engaging surface rotatable with the output shaft of the non-line frequency variable speed electric motor, the belt engaging surface configured to engage an endless belt to couple rotation of the output shaft to the drum. 9. The drying device of claim 8 , wherein the belt engaging surface is formed directly on the output shaft of the non-line frequency variable speed electric motor. 10. The drying device of claim 9 further comprising: a bearing cap mounted about the output shaft, the bearing cap having a guide surface configured to maintain the endless belt on the belt engaging surface formed on the output shaft. 11. The drying device of claim 1 , the non-line frequency variable speed electric motor being one of a three phase controlled induction motor, a permanent magnet motor, a switched reluctance motor, and a universal motor. 12. A drying device for tumble drying articles, the drying device comprising: a non-line frequency variable speed electric motor configured to rotate an output shaft having a first end and a second end, the first end of the output shaft having a belt engaging surface, the non-line frequency variable speed electric motor being coupled to a support frame and electrically coupled to a non line-frequency supply voltage; a drum coupled to a support frame and to the first end of the output shaft to rotate the drum, the drum having an interior space; a fan member connected to the second end of the output shaft, the fan member generating an air flow within the interior space of the drum in response to the output shaft being rotated by the electric motor; an endless belt that engages the belt engaging surface and is coupled to the drum to enable the output shaft to rotate the drum; a bearing cap having a guide surface, the bearing cap being mounted about the output shaft to maintain the endless belt on the belt engaging surface of the output shaft; and a controller electrically coupled to the non-line frequency variable speed electric motor, the controller being configured to sense current drawn by the non-line frequency variable speed electric motor and control an angular velocity of the output shaft of the non-line frequency variable speed electric motor to control either a rotation speed of the fan member or a rotation speed of the drum. 13. The drying device of claim 12 , wherein the belt engaging surface is formed directly on the output shaft of the non-line frequency variable speed electric motor. 14. The drying device of claim 12 further comprising: a frequency generator electrically coupled to the controller and to the non-line frequency variable speed electric motor; and the controller being further configured to control the angular velocity of the output shaft by operating the frequency generator to control a frequency of a voltage signal generated by a frequency generator that is provided to the non-line frequency variable speed electric motor. 15. The drying device of claim 12 , the controller being further configured to increase the frequency of the voltage signal generated by the frequency generator from a zero frequency to a higher frequency over a plurality of seconds in response to a dryer start signal. 16. The drying device of claim 12 , the controller being further configured to maintain the frequency of the voltage signal generated by the frequency generator at a frequency that enables the non-line frequency variable speed electric motor to compensate for slippage with a load in the drum that is less than a normal load in response to the controller receiving a low load signal from a user interface. 17. The drying device of claim 12 , the controller being further configured to maintain the frequency of the voltage signal generated by the frequency generator at a frequency that enables the non-line frequency variable speed electric motor to compensate for slippage with a load that is greater than a normal load in response to the controller receiving a high load signal from a user interface. 18