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An actuator provides two step control of a dual valve or dual damper, such as in an HVAC system. The gear train includes projections on top and bottom faces of the final gear, the projections being rotationally offset from each other by an angle. Each projection mates into a slot of a Geneva-gear-ty

An actuator provides two step control of a dual valve or dual damper, such as in an HVAC system. The gear train includes projections on top and bottom faces of the final gear, the projections being rotationally offset from each other by an angle. Each projection mates into a slot of a Geneva-gear-type output member, with two such output members accessible, one on the top of the actuator and one on the bottom of the actuator. During the portion of the throw that the upwardly facing projection is in the slot of the upwardly exposed Geneva-type output gear, the final gear rotates the upper output member to control one flow blockage member in the valve or damper. During another portion of the throw, rotation of the final gear does not rotate the upper output member, but instead rotates the lower output member and its flow blockage member.

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1. An HVAC actuator for use in opening and closing a valve or a damper to control fluid flow in an HVAC system in a two step control, the actuator comprising: a motor which can be selectively powered to provide a rotational torque on a motor output shaft;a gear train rotationally coupled to the moto

1. An HVAC actuator for use in opening and closing a valve or a damper to control fluid flow in an HVAC system in a two step control, the actuator comprising: a motor which can be selectively powered to provide a rotational torque on a motor output shaft;a gear train rotationally coupled to the motor output shaft, the gear train having a final gear rotatable about a final gear axis and having a first face perpendicular to the final gear axis, with a first projection on the first face of the final gear, wherein the motor can drive the final gear in either a forward or reverse direction for a throw between a fully open terminal position and a fully closed terminal position;a first output member rotationally coupled to the final gear by having a first output slot which receives the first projection during only a portion of the throw, so during the portion of the throw that the first projection is in the first output slot the final gear rotates the first output member and, during another portion of the throw that the first projection is not in the first output slot, rotation of the final gear does not rotate the first output member; anda second output member rotationally coupled to the final gear so the second output member is rotationally driven by the final gear during the portion of the throw that the first projection is not in the first output slot. 2. The actuator of claim 1, wherein the first output member and the second output member rotate coaxially. 3. The actuator of claim 2, wherein the at least one of the first output member and the second output member comprise an axial through-bore 26, such that the actuator can be used to drive coaxially arranged drive stems of the valve or damper, with one of the drive stems extending through the axial through-bore 26 for control by the other of the first output member and the second output member. 4. The actuator of claim 1, wherein the final gear has a second face perpendicular to the final gear axis, the second face opposing the first face, and wherein the final gear has a second projection on the second face, wherein the second output member is rotationally coupled to the final gear by having a second output slot which receives the second projection during only a portion of the throw, so during the portion of the throw that the second projection is in the second output slot the final gear rotates the second output member. 5. The actuator of claim 4, wherein the first output member and the second output member are identically shaped. 6. The actuator of claim 1, wherein the complete throw between the fully open terminal position and the fully closed terminal position is less than a 360° rotation of the final gear. 7. The actuator of claim 6, wherein the complete throw between the fully open terminal position and the fully closed terminal position is greater than a 135° rotation of the final gear, and wherein the complete throw between the fully open terminal position and the fully closed terminal position causes a rotation of the first output member of about 90° and a rotation of the second output member of about 90°. 8. The actuator of claim 1, wherein the final gear comprises a first wall on its first face having a portion which is cylindrical about the final gear axis, and wherein the first output member comprises an arcuate scallop mating with the first wall such that the first wall prevents the first output member from rotating during a portion of the throw wherein the first projection is not in the first output slot. 9. The actuator of claim 8, wherein the final gear has a second face perpendicular to the final gear axis, the second face opposing the first face, and wherein the final gear has a second projection on the second face, wherein the second output member is rotationally coupled to the final gear by having a second output slot which receives the second projection during only a portion of the throw, so during the portion of the throw that the second projection is in the second output slot the final gear rotates the second output member; andwherein the final gear comprises a second wall on its second face having a portion which is cylindrical about the final gear axis, and wherein the second output member comprises an arcuate stop mating with the second wall such that the second wall prevents the second output member from rotating during a portion of the throw wherein the second projection is not in the second output slot. 10. The actuator of claim 1, wherein second output member rotationally coupled to the final gear so the second output member is also rotationally driven by the final gear during a portion of the throw that the first projection is in the first output slot. 11. The actuator of claim 1, wherein the slot is linear and extends in a radial direction relative to rotation of the first output member. 12. The actuator of claim 11, wherein the slot is defined between a first radially extending wall and a second radially extending wall on the first output member, and wherein the first radially extending wall is longer than the second radially extending wall. 13. The actuator of claim 12, wherein the first radially extending wall includes a sloped entry portion. 14. The actuator of claim 1, wherein the final gear comprises a stall shoulder which contacts the first output member at one of the fully open terminal position and the fully closed terminal position, the stall shoulder creating a positive interference stall point for the motor of the actuator when the actuator has completed its throw. 15. The actuator of claim 1, further comprising: a housing containing the motor and gear train; anda pointer on the outside of the housing to show where the final gear is relative to its total throw. 16. The actuator of claim 1, wherein the gear train comprises at least one intermediate gear, and further comprising a spring on the intermediate gear, with spring force reducing gear lash back when reversing direction. 17. A flow control device for controlling fluid flow through a duct or pipe, comprising: a first flow blockage plate having its position for blocking flow in the duct or pipe controlled by a rotational shaft;a second flow blockage plate having its position for blocking flow in the duct or pipe controlled by a rotational sleeve coaxially disposed on the shaft;each of the first flow blockage plate and the second flow blockage plate in a closed position blocking separate portions of the cross-sectional flow area through the flow control device; andan actuator for use in rotating both the shaft and the sleeve, the actuator comprising: a motor which can be selectively powered to provide a rotational torque on a motor output shaft;a gear train rotationally coupled to the motor output shaft, the gear train having a final gear rotatable about a final gear axis and having a first face perpendicular to the final gear axis, with a first projection on the first face of the final gear, wherein the motor can drive the final gear in either a forward or reverse direction for a throw between a fully open terminal position and a fully closed terminal position;a first output member rotationally coupled to the final gear by having a first output slot which receives the first projection during only a portion of the throw, so during the portion of the throw that the first projection is in the first output slot the final gear rotates the first output member and, during another portion of the throw that the first projection is not in the first output slot, rotation of the final gear does not rotate the first output member, the first output member being secured to one of the shaft and sleeve; anda second output member rotationally coupled to the final gear so the second output member is rotationally driven by the final gear during the portion of the throw that the first projection is not in the first output slot, the second output member being secured to the other of the shaft and sleeve. 18. The flow control device of claim 17 in an HVAC system as a damper using the first flow blockage plate and the second flow blockage plate to control air flow through a duct.