Fuel injector assembly having external filter and method of making same

What is claimed is: 1. A fuel injector assembly comprising: a fuel injector including a nozzle case having a set of nozzle case threads, and an injector body, the injector body having formed therein an actuation fluid inlet and an actuation fluid passage extending in a downstream direction from the actuation fluid inlet, and including a set of injector body threads engaged with the set of nozzle case threads; an annular filter defining a longitudinal axis and including a first axial end snap-fitted with one of the nozzle case or the injector body, such that the annular filter is fixed in location by the snap-fitting upon the one of the nozzle case or the injector body, and a second axial end slip-fitted with the other of the nozzle case or the injector body; and the annular filter further including a perforated wall extending axially between the first axial end and the second axial end and forming a filtration screen covering the actuation fluid inlet and positioned upstream of the actuation fluid inlet to trap particulates in incoming actuation fluid. 2. The fuel injector assembly of claim 1 wherein the first axial end includes an inwardly projecting snap shoulder, and the second axial end includes an end band, and each of the snap shoulder and the end band extending circumferentially around the longitudinal axis. 3. The fuel injector assembly of claim 2 wherein the injector body has a groove formed therein and the snap shoulder is snap-fitted with the injector body within the groove. 4. The fuel injector assembly of claim 3 wherein the end band includes an inner surface and a lead-in chamfer adjoining the inner surface, and the inner surface has a radial clearance with the nozzle case that includes a clearance size equal to or less than a perforation size of perforations within the perforated wall. 5. The fuel injector assembly of claim 4 wherein the perforated wall forms a two-dimensional screen filter, and the end band and the nozzle case together form an edge filter. 6. The fuel injector assembly of claim 4 wherein the clearance is a radial clearance of about 0.075 millimeters or less. 7. The fuel injector assembly of claim 3 wherein the injector body includes a first seal seating shoulder positioned adjacent to the groove, and the nozzle case includes a second seal seating shoulder positioned adjacent to the end band, and wherein the first seal seating shoulder abuts the first axial end of the annular filter, and an axial clearance extends between the end band and the second seal seating shoulder. 8. The fuel injector assembly of claim 1 further comprising: a stack including a tip piece having a nozzle cavity and a plurality of nozzle outlets formed therein; and a plunger positioned at least partially within the stack and having a plunger actuation surface and a fuel pressurization surface. 9. The fuel injector assembly of claim 8 wherein: the fuel injector has a low pressure outlet formed therein, and a valve movable between a first position at which the plunger actuation surface is exposed to a fluid pressure of the actuation fluid inlet, and a second position at which the plunger actuation surface is exposed to a fluid pressure of the low pressure outlet; and the nozzle case has a fuel inlet formed therein, and the fuel pressurization surface is fluidly between the fuel inlet and the plurality of nozzle outlets. 10. A method of making a fuel injector assembly comprising: snap-fitting a first axial end of an annular filter defining a longitudinal axis with a first body component of a fuel injector including one of an injector body and a nozzle case; fixing a location of the annular filter upon the one of an injector body and a nozzle case by way of the snap-fitting of the first axial end; slip-fitting a second axial end of the annular filter with a second body component of the fuel injector including the other of an injector body and a nozzle case; engaging a first set of threads of the first body component with a second set of threads of the second body component, to attach the first body component to the second body component; and positioning, by way of the engagement of the first set of threads with the second set of threads, a perforated wall of the annular filter forming a filtration screen upstream of an actuation fluid inlet in the injector body and an actuation fluid passage extending in a downstream direction from the actuation fluid inlet, and such that the filtration screen covers the actuation fluid inlet, to trap particulates in incoming actuation fluid. 11. The method of claim 10 wherein the snap-fitting of the first axial end of the annular filter includes snap-fitting a snap shoulder of the annular filter within a groove in an injector body, and the slip-fitting of the second axial end of the annular filter includes slip-fitting an end band of the annular filter about an outer surface of a nozzle case. 12. The method of claim 11 further comprising clamping a stack including a tip piece having a nozzle cavity and a plurality of nozzle outlets formed therein and a spacer having a plunger cavity formed therein, between the injector body and the nozzle case by way of the engagement of the first set of threads with the second set of threads. 13. The method of claim 12 further comprising forming a fuel path extending by way of the plunger cavity between a fuel inlet in the nozzle case and the nozzle cavity by way of the clamping of the stack between the injector body and the nozzle case. 14. The method of claim 11 further comprising forming an edge filter with the end band and the nozzle case by way of the slip-fitting of the end band about the outer surface of the nozzle case. 15. The method of claim 11 wherein the slip-fitting of the second axial end occurs simultaneous with the engagement of the first set of threads with the second set of threads. 16. The method of claim 15 wherein the annular filter is fixed in location relative to the injector body by way of the snap-fitting of the first axial end, and further comprising locating the annular filter relative to the nozzle case by way of the engagement of the first set of threads with the second set of threads. 17. The method of claim 16 further comprising reducing a size of an axial clearance between the end band and the nozzle case, to a clearance size greater than zero, by way of the engagement of the first set threads with the second set of threads.