Diaphragm pumps with air savings devices

The invention claimed is: 1. A diaphragm pump comprising: a first diaphragm that separates a first cavity into a first motive fluid chamber and a first pumped media chamber, the first diaphragm being configured to stroke from a first end-of-stroke position to a second end-of-stroke position in response to compressed fluid being communicated from a compressed fluid inlet to the first motive fluid chamber; a cut-off valve configured to (i) communicate compressed fluid from the compressed fluid inlet to the first motive fluid chamber in response to receiving a first pilot signal and (ii) resist communication of compressed fluid from the compressed fluid inlet to the first motive fluid chamber in response to receiving a second pilot signal; a sleeve formed to include (i) a bore extending along a longitudinal axis and (ii) a first sleeve port that opens to the bore, the first sleeve port being fluidly coupled to the cut-off valve via a pilot line; and a spool supported in the bore of the sleeve and formed to include a first spool port, the spool being configured to move with the first diaphragm during at least a portion of the stroke of the first diaphragm such that the spool slides relative to the sleeve and, when the first diaphragm reaches a turndown position that is between the first and second end-of-stroke positions, the first spool port aligns with the first sleeve port to cause the second pilot signal to be supplied to the cut-off valve via the pilot line; wherein at least one of the sleeve and the spool is rotatable about the longitudinal axis to adjust a location of the turndown position relative to the first and second end-of-stroke positions; the sleeve is further formed to include (i) a second sleeve port that opens to the bore and (ii) a third sleeve port that opens to the bore, the third sleeve port being fluidly coupled to the pilot line; the spool is further foil led to include a spool groove in an outer surface of the spool; the spool is also configured to move with the first diaphragm during at least a portion of the stroke of the first diaphragm such that, when the first diaphragm reaches the second end-of-stroke position, the spool groove fluidly couples the second sleeve port to the third sleeve port to cause the first pilot signal to be supplied to the cut-off valve via the pilot line; the spool is further formed to include a passageway extending along the longitudinal axis between the first spool port and an end of the spool that extends into the first motive fluid chamber, such that the first spool port is fluidly coupled to the first motive fluid chamber at least when the first diaphragm is in the turndown position; the second sleeve port is fluidly coupled to an exhaust chamber; the first pilot signal comprises a pressure that does not exceed a threshold; and the second pilot signal comprises a pressure that exceeds the threshold. 2. The diaphragm pump of claim 1 , wherein the first spool port is fluidly coupled to the exhaust chamber at least when the first diaphragm is in the turndown position, and the second sleeve port is fluidly coupled to the compressed fluid inlet. 3. The diaphragm pump of claim 1 , further comprising a second diaphragm that separates a second cavity into a second motive fluid chamber and a second pumped media chamber, the second diaphragm being coupled to the first diaphragm such that the second diaphragm is configured to move reciprocally with the first diaphragm between the first and second end-of-stroke positions, the second diaphragm further being configured to stroke from the second end-of-stroke position to first end-of-stroke position in response to compressed fluid being communicated from the compressed fluid inlet to the second motive fluid chamber; wherein the second sleeve port opens to the bore, the second sleeve port being fluidly coupled to the cut-off valve via the pilot line; and wherein the spool is further formed to include a second spool port, the spool also being configured to move with the second diaphragm during at least a portion of the stroke of the second diaphragm such that the spool slides relative to the sleeve and, when the second diaphragm reaches the turndown position that is between the first and second end-of-stroke positions, the second spool port aligns with the second sleeve port to cause the second pilot signal to be supplied to the cut-off valve via the pilot line. 4. The diaphragm pump of claim 3 , wherein the spool couples the second diaphragm to the first diaphragm such that the second diaphragm is configured to move reciprocally with the first diaphragm between the first and second end-of-stroke positions. 5. The diaphragm pump of claim 3 , further comprising a shaft that couples the second diaphragm to the first diaphragm such that the second diaphragm is configured to move reciprocally with the first diaphragm between the first and second end-of-stroke positions, wherein the spool extends parallel to the shaft. 6. The diaphragm pump of claim 5 , wherein: the second diaphragm engages the spool during at least a portion of the stroke of the first diaphragm to cause the spool to slide relative to the sleeve; and the first diaphragm engages the spool during at least a portion of the stroke of the second diaphragm to cause the spool to slide relative to the sleeve. 7. The diaphragm pump of claim 3 , wherein the spool is further formed to include: a second passageway extending along the longitudinal axis between the second spool port and a second end of the spool that extends into the second motive fluid chamber, such that the second spool port is fluidly coupled to the second motive fluid chamber at least when the first and second diaphragms are in the turndown position. 8. The diaphragm pump of claim 1 , wherein the first sleeve port is fluidly coupled to the exhaust chamber, and the third sleeve port is fluidly coupled to the compressed fluid inlet.