Pump with residual magnetism attenuation

The invention claimed is: 1. A pump, comprising: a fluid inlet section; a fluid outlet section; a stator axially between the fluid inlet section and the fluid outlet section and including: a plurality of radially inwardly extending legs; a plurality of electrical windings disposed about the plurality of radially inwardly extending legs and arranged to be connected to an electrical power source; a rotor axially between the fluid inlet section and the fluid outlet section, the rotor and the stator defining a fluid flow space radially therebetween; a movable inlet guide configured for guiding fluid flow from the fluid inlet section into the fluid flow space; a movable outlet guide arranged to guide fluid flow from the fluid flow space into the fluid outlet section; and, an attenuating circuit including: a capacitor electrically wired in parallel with a first electrical winding of the plurality of electrical windings; and, a switch electrically connected to the capacitor, wherein: the first electrical winding is wound about a first radially inwardly extending leg of the plurality of radially inwardly extending legs; the rotor is arranged to be rotated inside of the stator by energization of the plurality of electrical windings; during the energization of the plurality of electrical windings: the switch is arranged to electrically connect the capacitor to an electrical ground; and, the electrical power source is arranged to create a voltage in the capacitor; and, following a de-energization of the plurality of electrical windings: the switch is arranged to electrically isolate the capacitor from the electrical ground; and, the capacitor is arranged to discharge the voltage through the first electrical winding. 2. The pump of claim 1 , wherein following the de-energization of the plurality of electrical windings, the voltage is arranged to alternately drive: first electrical current through the first electrical winding a first direction; and, second electrical current through the first electrical winding in a second direction, opposite the first direction. 3. The pump of claim 2 , wherein the capacitor is arranged to alternately drive the first electrical current and the second electrical current to: randomize residual magnetic fields in the first radially inwardly extending leg; and, attenuate residual magnetic saturation in the first radially inwardly extending leg. 4. A reluctance motor comprising: a stator having a plurality of radially extending legs; a rotor supported to rotate with respect to the stator; a plurality of electric coils, each coil being wound around a respective leg of the plurality of radially extending legs; a plurality of capacitors, each capacitor electrically connected in parallel with a respective coil of the plurality of electric coils; a plurality of switching circuits, each switching circuit associated with a respective coil of the plurality of electric coils and a respective capacitor of the plurality of capacitors, each switching circuit configured to alternately connect and disconnect the respective coil and respective capacitor to a voltage source and to a ground; and a controller configured to activate the plurality of switching circuits to induce the rotor to rotate with respect to the stator. 5. The reluctance motor of claim 4 wherein each capacitor has a capacitance selected to produce a decaying oscillating current in the respective coil after the coil and capacitor are disconnected from the voltage source and from the ground. 6. The reluctance motor of claim 5 wherein the decaying oscillating current attenuates a residual magnetic field in the respective radially extending leg. 7. The reluctance motor of claim 4 wherein each of the switching circuits comprise: a first transistor selectively electrically connecting a first terminal of the respective coil and a first terminal of the respective capacitor to the ground; and a second transistor selectively electrically connecting a second terminal of the respective coil and a second terminal of the respective capacitor to the voltage source. 8. The reluctance motor of claim 7 wherein the first transistor is a n-type transistor having a first gate directly connected to the control unit. 9. The reluctance motor of claim 7 wherein the second transistor is a p-type transistor having a second gate indirectly connected to the control unit. 10. The reluctance motor of claim 9 wherein each of the switching circuits further comprises: a third transistor selectively electrically connecting the second gate to the ground and having a third gate directly connected to the control unit; and a resistor electrically connecting the second gate to the voltage source. 11. A pump comprising: the reluctance motor of claim 4 , wherein the rotor defines a plurality of cavities that vary in volume as the rotor rotates with respect to the stator; an inlet section configured to connect a source of fluid to a first subset of the cavities that are increasing in volume and isolate the source of fluid from a second subset of the cavities that are decreasing in volume; and an outlet section configured to connect the second subset of cavities to a fluid sink and isolate the first subset of cavities from the fluid sink. 12. The pump of claim 11 wherein the cavities are defined radially between the rotor and the stator.