Slide measuring system for filling pouches and associated method

What is claimed: 1. A system for measuring tobacco for packaging in pouches, the system comprising: a hopper including a hopper cavity configured to hold a granular material; and a measuring system including a measuring cavity and a tube that is slidable in the hopper cavity between a first position unaligned with the measuring cavity and a second position over and aligned with the measuring cavity, the measuring system including, a first valve disposed between a vacuum source and the measuring cavity, the first valve being configured to selectively place the vacuum source in fluid communication with the measuring cavity, and a second valve disposed between a pressurized gas source and the measuring cavity, the second valve being configured to selectively place the pressurized gas source in fluid communication with the measuring cavity independent of a position of the first valve, wherein the first valve is configured to continuously communicate a vacuum to the measuring cavity, the measuring system configured to move a portion of the granular material from the hopper cavity to the measuring cavity when the tube is in the first position, and the measuring system configured to move the portion of the granular material from the measuring cavity, through the tube, to a pouch making machine by operating the second valve to supply pressurized gas that overcomes the vacuum when the tube is in the second position. 2. The system of claim 1 , further comprising: a conduit connected to the tube, the tube and the conduit defining a flow path between the measuring cavity and the pouch making machine when the tube is in the second position. 3. The system of claim 1 , wherein the measuring cavity is in a bottom plate of the hopper. 4. The system of claim 1 , wherein the measuring system includes a pin having a bore in fluid communication with the measuring cavity, a location of the pin within a hole defines a volume of the measuring cavity, and the location of the pin within the hole is adjustable to selectively adjust the volume of the measuring cavity. 5. The system of claim 4 , further comprising: a controller configured to receive a weight of at least one pouch made by the pouch making machine with the granular material from the measuring cavity; compare the weight to an upper threshold and a lower threshold; and change the location of the pin in the hole based on the weight. 6. The system of claim 1 , further comprising: a wear element connected to an end of the tube and contacting a plate that defines the measuring cavity. 7. The system of claim 6 , wherein the tube is biased toward the plate that defines the measuring cavity. 8. The system of claim 1 , wherein the tube has a continuously tapered inside diameter. 9. The system of claim 1 , wherein the tube is supported by a slide that causes the tube to move in a reciprocating manner between the first position and the second position; and the hopper comprises moveable end blocks connected to the slide. 10. The system of claim 1 , further comprising: a sifter configured to sift the granular material, the sifter including a compartment having a screen and a moveable wiper, the granular material moving through the screen to the hopper; a feeder configured to provide the granular material to the sifter; a level sensor in the hopper; and a controller configured to move the moveable wiper in the sifter, agitate the feeder, or move the moveable wiper in the sifter and agitate the feeder based on a signal from the level sensor. 11. The system of claim 1 , further comprising: a feeder configured to provide the granular material to a sifter, the feeder including a number of lanes and the sifter including a number of compartments corresponding to the number of lanes; a respective level sensor in each of the compartments of the sifter; and a controller configured to individually control agitation of the respective lanes of the feeder based on signals from the respective level sensors. 12. The system of claim 1 , further comprising: a manifold connected to the measuring system, the manifold configured to communicate the vacuum source to the first valve and the pressurized gas source to the measuring cavity. 13. The system of claim 12 , further comprising: an accumulator connected between the manifold and the vacuum source. 14. The system of claim 13 , wherein the measuring system includes a plurality of the measuring cavities, the first valve includes a plurality of first valves, the plurality of first valves being disposed between the vacuum source and the plurality of the measuring cavities, respectively, the second valve includes a plurality of second valves, the plurality of second valves being disposed between the pressurized gas source and the plurality of measuring cavities, respectively, the manifold includes a plurality of manifold ports fluidly connected to the plurality of the measuring cavities, and the accumulator includes a plurality of accumulator ports fluidly connected to the plurality of manifold ports. 15. A system for measuring tobacco for packaging in pouches, the system comprising: a hopper having a hopper cavity configured to hold a granular material; and a measuring system including, a plurality of measuring cavities a plurality of tubes slidable in the hopper cavity, a plurality of first valves disposed between a vacuum source and the plurality of measuring cavities, respectively, the plurality of first valves being configured to selectively place the vacuum source in fluid communication with the plurality of measuring cavities, and a plurality of second valves disposed between a pressurized gas source and the plurality of measuring cavities, respectively, the plurality of second valves being configured to selectively place the pressurized gas source in fluid communication with the plurality of measuring cavities, wherein the measuring system is configured to continuously communicate a vacuum to each of the plurality of measuring cavities, move the plurality of tubes to a first position that uncovers the plurality of measuring cavities, fill the plurality of measuring cavities with respective portions of the granular material using the vacuum while the plurality of tubes are in the first position, move the plurality of tubes to a second position over and aligned with the plurality of measuring cavities, and move the respective portions of the granular material from the plurality of measuring cavities, through the plurality of tubes, respectively, to a pouch making machine using pressurized gas that overcomes the vacuum while the plurality of tubes are in the second position. 16. The system of claim 15 , wherein the plurality of measuring cavities is a first plurality of measuring cavities, the measuring system includes a second plurality of measuring cavities different from the first plurality of measuring cavities, the plurality of tubes are over and aligned with the second plurality of measuring cavities in the first position, the measuring system is configured to fill the second plurality of measuring cavities with second respective portions of the granular material while the plurality of tubes are in the second position, and the measuring system is configured to move the second respective portions of the granular material from the second plurality of measuring cavities to the pouch making machine while the plurality of tubes are in the first position. 17. The system of claim 15 , wherein the plurality of tubes are supported by a slide th