Material dispensing system

What is claimed is: 1. A material deposition system comprising: an extruder for deposition materials, the extruder comprising two or more material entry ports, a mixing chamber, and an exit orifice; and a controller coupled with the extruder, the controller configured and arranged to dynamically change delivery rates of the deposition materials to be mixed in the mixing chamber before flowing from the exit orifice; wherein the controller combines a desired volume flow rate of material to flow from the exit orifice with a mix ratio to specify the delivery rates of the deposition materials; wherein the extruder comprises two or more liquefication zones, each of the liquefication zones being associated with a respective one of the entry ports and each being configured and arranged to deliver a respective liquefied material to the mixing chamber, and wherein each of the liquefication zones has an entry cross sectional area and an exit cross sectional area, and the exit cross sectional area is less than the entry cross sectional area; and wherein each of the liquefication zones has at least one internal cross sectional area that is less than the entry cross sectional area and greater than the exit cross sectional area such that material travelling through the liquefication zone reduces in cross sectional area more than once as it travels from its entry port to the mixing chamber. 2. The material deposition system of claim 1 , wherein the deposition materials are thermoplastic materials in filament form, the system comprises filament drive systems configured and arranged to feed the thermoplastic materials in filament form into the entry ports, and the controller is coupled with the filament drive systems and configured and arranged to dynamically change the mix ratio when operating the filament drive systems to control one or more properties of the material to flow from the exit orifice. 3. The material deposition system of claim 2 , wherein the controller comprises a system controller and a ratio controller, the ratio controller being separate from and coupled with the system controller. 4. The material deposition system of claim 3 , wherein the ratio controller is configured and arranged to receive a first control input that commands the desired volume flow rate of material to flow from the exit orifice, a second control input that commands the mix ratio, and encoded information that specifies which of the filament drive systems to operate. 5. The material deposition system of claim 4 , wherein the filament drive systems comprise stepper motors, the first control input comprises a train of pulses, and the second control input varies a speed of the stepper motors such that a sum of volume flow rates of filaments going into the entry ports equals the desired volume flow rate commanded by the first control input. 6. The material deposition system of claim 2 , wherein the extruder comprises a mixing element that fills at least 40% of the mixing chamber, wherein the mixing element comprises a tapered helix that extends from a first side of the mixing chamber to a second side of the mixing chamber and creates a twisted path that is longer than a total length of the mixing chamber. 7. The material deposition system of claim 6 , wherein the extruder comprises a thermally conductive element and a removable nozzle, the two or more liquefication zones comprise cavities within the thermally conductive element, the removable nozzle includes the exit orifice, and the mixing chamber is formed by at least a first surface of the thermally conductive element and a second surface of the removable nozzle when the removable nozzle is mounted adjacent to the thermally conductive element. 8. The material deposition system of claim 6 , wherein the exit cross sectional area of each liquefication zone adjacent to the mixing chamber is less than 0.75 square millimeters, the mixing chamber has a mixing volume that is less than 3 cubic millimeters, and an area of the exit orifice is less than 0.75 square millimeters. 9. An extruder for a three dimensional printer that deposits materials in liquid form, the extruder comprising: two or more entry ports for the materials of the three dimensional printer; a mixing chamber for liquefied materials of the three dimensional printer; a mixing element that fills a substantial portion of the mixing chamber; and an exit orifice through which the liquefied materials are delivered to an object being printed by the three dimensional printer; wherein the extruder comprises a thermally conductive element and a removable nozzle, the removable nozzle includes the exit orifice, and the mixing chamber is formed by at least a first surface of the thermally conductive element and a second surface of the removable nozzle when the removable nozzle is mounted adjacent to the thermally conductive element; and wherein the mixing element, which is separate from the nozzle, comprises a helix that creates a twisted path that is longer than a total length of the mixing chamber. 10. The extruder of claim 9 , wherein at least 40% of the mixing chamber is filled by the mixing element. 11. The extruder of claim 9 , wherein the mixing element extends from a first side of the mixing chamber to a second side of the mixing chamber. 12. The extruder of claim 9 , wherein the deposition materials are thermoplastic materials in filament form, the extruder comprises two or more liquefication zones, each of the liquefication zones being associated with a respective one of the entry ports and each being configured and arranged to deliver a respective liquefied material to the mixing chamber, and wherein each of the liquefication zones has an entry cross sectional area and an exit cross sectional area, and the exit cross sectional area is less than the entry cross sectional area. 13. The extruder of claim 12 , wherein each of the liquefication zones has at least one internal cross sectional area that is less than the entry cross sectional area and greater than the exit cross sectional area such that material travelling through the liquefication zone reduces in cross sectional area more than once as it travels from its entry port to the mixing chamber. 14. The extruder of claim 12 , wherein the exit cross sectional area of each liquefication zone adjacent to the mixing chamber is less than 0.75 square millimeters, the mixing chamber has a mixing volume that is less than 3 cubic millimeters, and an area of the exit orifice is less than 0.75 square millimeters. 15. An additive manufacturing system comprising: a build platform; and an extruder for deposition materials to be applied to a three dimensional (3D) object to be 3D printed in the build platform; wherein the extruder comprises at least two nozzles of different types, and a first of the at least two nozzles is configured and arranged to dispense multiple materials with a controllable ratio; wherein the first of the at least two nozzles has an exit orifice with a first exit area, a second of the at least two nozzles has an exit orifice with a second exit area, and the second exit area is different than the first exit area; wherein the at least two nozzles comprise a third nozzle that has an exit orifice with a third exit area, and the third exit area is different than both the second exit area and the first exit area, such that the second nozzle dispenses material in a finer size than the first nozzle, and the third nozzle dispenses material in a coarser size than the first nozzle; wherein the at least two nozzles comprise a fourth nozzle, and the extruder comprises a nozzle chassis to whi