Compression ignition engine with igniter and pilot injector

What we claim is: 1. An internal combustion engine comprising: a set of cylinders and interfitting pistons movable within the cylinders to compress air in a combustion chamber region at an end of each cylinder at a compression ratio of no less than 12:1; a main injector assembly communicating with each combustion chamber having a conduit for receiving pressurized fuel leading to a nozzle directing a first spray of received fuel along at least one first spray axis and providing a valve positioned to move between a blocking state blocking fuel passing from the conduit to the nozzle and an unblocking state allowing a flow of the pressurized fuel from the conduit to the nozzle to exit as the first spray; a pilot injector assembly communicating with each combustion chamber having a conduit for receiving pressurized fuel leading to a nozzle directing a second spray of received fuel along at least one second spray axis intersecting the at least one first spray axis so that fuel from the main injector assembly passing along the at least one first spray axis intersects fuel from the pilot injector assembly passing along the at least one second spray axis and providing a second valve positioned to move between a blocking state blocking fuel passing from the conduit to the nozzle and an unblocking state allowing a flow of the pressurized fuel from the conduit to the nozzle to exit as the second spray; and an igniter positioned along the at least one second spray axis to ignite the second spray. 2. The internal combustion engine of claim 1 wherein the first spray of the main injector extends radially outwardly from an injection point at a central axis of the combustion chamber and where the second spray of the pilot injector is directed to intersect the injection point. 3. The internal combustion engine of claim 1 wherein upper surface of the pistons include upwardly open bowl portions having a bowl bottom with a pip extending upwardly. 4. The internal combustion engine of claim 1 wherein including an injector valve controller controlling the first valve and second valve so that the second valve is actuated before the first valve with respect to a combustion cycle starting at top dead center of piston motion. 5. The internal combustion engine of claim 4 wherein the injector valve controller controls the first valve and second valve to inject more than twice as much fuel mass through the main injector than the through the pilot injector during a combustion cycle. 6. The internal combustion engine of claim 1 wherein the igniter is a glow plug and including a glow plug power source providing continuous power to the glow plug during operation of the engine. 7. The internal combustion engine of claim 1 including a chamber at least partially surrounding the igniter for receiving the second spray for exit through at least one chamber exit opening to increase a dwell time of the second spray in a vicinity of the igniter. 8. The internal combustion engine of claim 7 wherein the chamber includes multiple chamber exits. 9. The internal combustion engine of claim 1 further including an igniter controller changing power to the igniter as a function of at least one of engine load and engine speed. 10. The internal combustion engine of claim 1 wherein including a fuel source providing fuel to the main injector and pilot injectors of less than 40 cetane. 11. The internal combustion engine of claim 1 wherein the igniter is not a spark plug. 12. A method of operating an internal combustion engine of a type having: a set of cylinders and interfitting pistons movable within the cylinders to compress air in a combustion chamber region at an end of each cylinder at a compression ratio of no less than 12:1; a main injector assembly communicating with each combustion chamber having a conduit for receiving pressurized fuel leading to a nozzle directing a first spray of received fuel along at least one first spray axis and providing a valve positioned to move between a blocking state blocking fuel passing from the conduit to the nozzle and an unblocking state allowing a flow of the pressurized fuel from the conduit to the nozzle to exit as the first spray; a pilot injector assembly communicating with each combustion chamber having a conduit for receiving pressurized fuel leading to a nozzle directing a second spray of received fuel along at least one second spray axis intersecting the at least one first spray axis so that fuel from the main injector assembly passing along the at least one first spray axis intersects fuel from the pilot injector assembly passing along the at least one second spray axis and providing a second valve positioned to move between a blocking state blocking fuel passing from the conduit to the nozzle and an unblocking state allowing a flow of the pressurized fuel from the conduit to the nozzle to exit as the second spray; and an igniter positioned along the at least one second spray axis to ignite the second spray; the method comprising controlling the main injector and pilot injector assemblies to create a pilot flame fed by the second spray serving to ignite the first spray. 13. The method of claim 12 including controlling the first valve and second valve so that the second valve is actuated before the first valve with respect to a combustion cycle starting at top dead center of piston motion. 14. The method of claim 12 including controlling the first valve and second valve to inject more than twice as much fuel mass through the main injector than the pilot injector during a combustion cycle. 15. The method of claim 12 including providing a same fuel to the main injector and pilot injectors of less than 40 cetane.