Air filter systems and methods of using the same

The invention claimed is: 1. An air filter system comprising: a tube sheet configured to separate a housing into a dirty air chamber and a clean air chamber; a pulse collector defining a passageway that extends through the pulse collector from a filter end opening at a filter end of the pulse collector element to a tube sheet opening at a tube sheet end of the pulse collector; an aperture in the tube sheet, wherein the tube sheet end of the pulse collector is configured for attachment to the tube sheet such that the tube sheet opening of the pulse collector is aligned with the aperture such that air passing from the dirty air chamber into the clean air chamber through the aperture passes through the passageway of the pulse collector; a filter element attached to the filter end of the pulse collector such that air passing into the passageway of the pulse collector through the filter end opening of the pulse collector passes through an interior volume of the filter element before reaching the filter end opening, wherein the filter element comprises a filter element opening at a junction between the filter end of the pulse collector and the filter element; a pulse generator located in the clean air chamber and positioned to deliver pulses of air into the interior volume of the filter element, the pulses of air passing through the aperture and the passageway of the pulse collector before reaching the interior volume of the filter element, wherein the pulse generator is configured to deliver the pulses of air along a pulse axis that extends from the pulse generator through the aperture in the tube sheet, the tube sheet opening in the pulse collector, and the filter end opening in the pulse collector, wherein the pulse generator comprises a pulse outlet located on the pulse axis and through which the pulses of air are delivered along the pulse axis, the pulse outlet defined by opposing walls that do not diverge with respect to the pulse axis, and wherein the pulse outlet defines a pulse outlet hydraulic diameter; and a yoke supporting the filter element, the yoke extending away from the pulse collector along the pulse axis, wherein the yoke comprises two or more support beams aligned with the pulse axis, wherein the two or more support beams are arranged asymmetrically about the pulse axis, and wherein the filter element comprises an end cap comprising notches that align with and receive the two or more support beams when the filter element is in only one rotational orientation relative to the pulse axis; wherein a pulse distance measured along the pulse axis from the pulse outlet to the filter element opening is 30 or more times the pulse outlet hydraulic diameter. 2. A system according to claim 1 , wherein the pulse distance is within a range that is 50 times or less and 30 times or more the pulse outlet hydraulic diameter. 3. A system according to claim 1 , wherein a hydraulic diameter of the filter element opening is 112% or less of a hydraulic diameter of the filter end opening of the pulse collector. 4. A system according to claim 1 , wherein the hydraulic diameter of the filter element opening is within a range that is 90% or more of the hydraulic diameter of the filter end opening of the pulse collector and 112% or less of a hydraulic diameter of the filter end opening of the pulse collector. 5. A system according to claim 1 , wherein an absolute value of a difference between a hydraulic diameter of the filter element opening and a hydraulic diameter of the filter end opening of the pulse collector is within 2% or less of the hydraulic diameter of the filter element opening. 6. A system according to claim 1 , wherein the pulse collector comprises a filter section and a pulse section, wherein the filter section and the pulse section meet at a junction located between the filter end and the tube sheet end of the pulse collector; wherein a portion of the passageway defined by the pulse section comprises a hydraulic diameter that increases when moving from the junction to the tube sheet opening; and wherein a portion of the passageway defined by the filter section comprises a hydraulic diameter that remains constant when moving from the junction to the filter end. 7. A system according to claim 6 , wherein the filter section comprises a filter section length measured along the pulse axis from the filter end to the junction and the pulse section comprises a pulse section length measured along the pulse axis from the tube sheet end to the junction, wherein the filter section length is less than or equal to the pulse section length. 8. A system according to claim 6 , wherein the pulse section comprises opposing walls defining the portion of the passageway in the pulse section that diverge from the pulse axis at an included angle that is greater than zero (0) degrees and less than or equal to ten (10) degrees. 9. An air filter system comprising: a tube sheet configured to separate a housing into a dirty air chamber and a clean air chamber; a pulse collector defining a passageway that extends through the pulse collector from a filter end opening at a filter end of the pulse collector element to a tube sheet opening at a tube sheet end of the pulse collector; an aperture in the tube sheet, wherein the tube sheet end of the pulse collector is configured for attachment to the tube sheet such that the tube sheet opening of the pulse collector is aligned with the aperture such that air passing from the dirty air chamber into the clean air chamber through the aperture passes through the passageway of the pulse collector; a filter element attached to the filter end of the pulse collector such that air passing into the passageway of the pulse collector through the filter end opening of the pulse collector passes through an interior volume of the filter element before reaching the filter end opening, wherein the filter element comprises a filter element opening at a junction between the filter end of the pulse collector and the filter element; a pulse generator located in the clean air chamber and positioned to deliver pulses of air into the interior volume of the filter element, the pulses of air passing through the aperture and the passageway of the pulse collector before reaching the interior volume of the filter element, wherein the pulse generator is configured to deliver the pulses of air along a pulse axis that extends from the pulse generator through the aperture in the tube sheet, the tube sheet opening in the pulse collector, and the filter end opening in the pulse collector, wherein the pulse generator comprises a pulse outlet located on the pulse axis and through which the pulses of air are delivered along the pulse axis, the pulse outlet defined by opposing walls that do not diverge with respect to the pulse axis, and wherein the pulse outlet defines a pulse outlet hydraulic diameter; wherein the filter element is supported on a yoke extending away from the pulse collector along the pulse axis, wherein the yoke comprises two or more support beams aligned with the pulse axis, wherein the two or more support beams are arranged asymmetrically about the pulse axis, and wherein the filter element opening comprises alignment features arranged to align with the two or more support beams when the filter element is in only one rotational orientation relative to the pulse axis; and wherein a pulse distance measured along the pulse axis from the pulse outlet to the filter element opening is 30 or more times the pulse outlet hydraulic diameter. 10. A system according to claim 9 , wherein the pulse distance is within a range that is 50 times or less and 30 times or more the pulse outlet hydraulic diameter. 11. A