Method and apparatus for pressure equalization in rotary compressors

What is claimed is: 1. A rotary compressor system comprising: a compressor housing comprising: a compressor motor; a suction side; a discharge side; a compression chamber disposed between the suction side and the discharge side; and an overload-protection switch electrically coupled in series with the compressor motor and adapted to cut power to the compressor motor responsive to an overload event; a solenoid valve comprising a valve fluidly coupled between the compression chamber and a location upstream of the suction side and a drive coil electrically coupled in series with the overload-protection switch; a parallel combination comprising a capacitor in parallel with a combination of the drive coil and a resistor wired in series, wherein the parallel combination is in series between a power source and a terminal of the compressor motor; and wherein interruption of electrical current to the compressor motor interrupts electrical current to the drive coil thereby opening the valve to equalize pressure between the suction side and the discharge side. 2. The rotary compressor system of claim 1 , wherein the resistor is wired to tune a voltage drop across the resistor and the solenoid valve. 3. The rotary compressor system of claim 1 , further comprising: an accumulator coupled to the suction side; and wherein the valve is fluidly coupled to the accumulator via a pressure-equalization tube. 4. The rotary compressor system of claim 1 , further comprising: an outdoor unit comprising: the compressor housing; and a condenser coil fluidly coupled to the discharge side of the compressor housing; and an indoor unit comprising: an evaporator coil fluidly coupled to the condenser coil; and a circulation fan adapted to blow air from an enclosed space over the evaporator coil. 5. A method of equalizing pressure in a rotary compressor system, the method comprising: fluidly coupling a valve of a solenoid valve between a compression chamber of a compressor housing and a location upstream of a suction side of the compressor housing; electrically coupling a drive coil of the solenoid valve in series with an overload-protection switch; electrically coupling a capacitor in parallel to a combination of the drive coil and a resistor wired in series, wherein the capacitor, the drive coil and the resistor form a parallel combination in series between a power source and a terminal of the compressor motor; wherein, when the overload-protection switch is tripped, the drive coil receives no power and the valve is in an open position to permit equalization of pressure between the suction side of the compressor housing and a discharge side of the compressor housing; and wherein, when the overload-protection switch is in a closed position, the drive coil receives power and the valve is in a closed position to permit a compressed refrigerant to exit the compressor housing via the discharge side. 6. The method of claim 5 , wherein a voltage drop across the drive coil is configured to be equal to a voltage drop across the capacitor. 7. The method of claim 6 , wherein the voltage drop across the drive coil is adjusted by the resistor. 8. The method of claim 5 , wherein, responsive to the valve opening, fluid flows from a compression chamber within the compressor housing to the location upstream of the suction side.