Fuel injector

We claim: 1. A fuel injector device for injecting fuel supplied by a fuel supply circuit into a combustion chamber of an internal combustion engine, the fuel injector device comprising: an elongated injector body having a longitudinal axis, an injector cavity including at least one injector orifice at a first end of the injector cavity, an inner annular surface having a seat positioned upstream of the at least one injector orifice and a fuel flow surface extending from the seat toward the at least one injector orifice, wherein the inner annular surface is at a seat angle about the longitudinal axis; wherein the fuel flow surface terminates at a second edge, the second edge extends to join with the injector orifice surface in which the at least one injector orifice is located; a nozzle valve element positioned within the injector cavity, the nozzle valve element adapted to move along the longitudinal axis between a maximum open nozzle position, in which fuel flows from the fuel supply circuit through the at least one injector orifice into the combustion chamber, and a closed nozzle position wherein a first end of the nozzle valve element contacts a surface of the seat and fuel flow through the at least one injector orifice is blocked, the first end of the nozzle valve element including a tip, a contact surface positioned to contact the seat when the nozzle valve element is in the closed nozzle position, the nozzle valve element including; a first flow-guiding surface extending from the contact surface toward the tip and opposing the fuel flow surface, wherein the first flow-guiding surface is free of discontinuities and is at a first angle about the longitudinal axis that is greater than the seat angle by at least 4 degrees, and a second flow-guiding surface positioned downstream of the first edge of the first flow-guiding surface forming a second angle relative to the longitudinal axis that is smaller than the seat angle; wherein, when the nozzle valve element is in the maximum open nozzle position, the contact surface is positioned a spaced distance from the seat to form an annular gap having a maximum lift cross-sectional flow area Amax defined by a conical frustum extending across a shortest distance between the seat and the contact surface; wherein a plurality of frusto-conical flow areas Agap(n) is located between the inner annular surface and the first flow-guiding surface; wherein each of the plurality of frusto-conical flow areas Agap(n) is defined by a frustum centered on the longitudinal axis that extends perpendicular from the inner annular surface at any location where the frustum intersects the first flow-guiding surface; and wherein each of the plurality of frusto-conical flow areas Agap(n) satisfies an inequality (0.95)(Amax)<Agap(n)<(1.30)(Amax) when the nozzle valve element is in the maximum open nozzle position; and wherein, the nozzle valve element is in the closed position, the first edge of the nozzle valve member is downstream of the second edge of the fuel flow surface. 2. The fuel injector device of claim 1 , wherein size of the plurality of frusto-conical flow areas Agap(n) increases as the distance from the contact surface in a direction toward an injector sac increases. 3. The fuel injector device of claim 1 , wherein the injector sac includes an injector sac surface and the nozzle valve element tip includes a surface, and at every point along the injector sac surface where a conical frustum may be constructed that extends perpendicularly to the injector sac surface to intersect the nozzle valve element tip, an area Atip(n) is generated, wherein Atip(n) increases in size as a distance along the longitudinal axis to the at least one injector orifice decreases and the longitudinal distance from the contact surface increases. 4. The fuel injector device of claim 1 , wherein each of the plurality of frusto-conical flow areas Agap(n) satisfies the inequality (0.975)(Amax)≤Agap(n)≤(1.150)(Amax). 5. The fuel injector device of claim 1 , wherein the contact surface has a full angle of about 60 degrees centered on the longitudinal axis and wherein the first flow-guiding surface has a full angle of at least 64 degrees and no more than 69 degrees centered on the longitudinal axis. 6. The fuel injector device of claim 4 , wherein a maximum distance the nozzle valve element moves off the seat is 0.150 millimeters. 7. The fuel injector device of claim 1 , wherein the contact surface has a full angle of about 60 degrees centered on the longitudinal axis and wherein the first flow-guiding surface has a full angle of at least 70 degrees and no more than 75 degrees centered on the longitudinal axis. 8. The fuel injector device of claim 7 , wherein a maximum distance the nozzle valve element moves off the seat is 0.300 millimeters. 9. The fuel injector device of claim 1 , wherein the contact surface has a full angle of about 90 degrees centered on the longitudinal axis and wherein the first flow-guiding surface has a full angle of at least 98 degrees and no more than 103 degrees centered on the longitudinal axis. 10. The fuel injector device of claim 9 , wherein a maximum distance the nozzle valve element moves off the seat is 0.100 millimeters. 11. The fuel injector device of claim 1 , wherein the contact surface has a full angle of about 90 degrees centered on the longitudinal axis and wherein the first flow-guiding surface has a full angle of at least 106 degrees and no more than 111 degrees centered on the longitudinal axis. 12. The fuel injector device of claim 11 , wherein a maximum distance the nozzle valve element moves off the seat is 0.200 millimeters. 13. A fuel injector device for injecting fuel into a combustion chamber of an internal combustion engine, the fuel injector de lace comprising: a body comprising: a longitudinal axis, and a cavity including a sac, an orifice communicating with the sac, a seat positioned upstream of the sac and a fuel flow surface extending between the sac and the seat; and a valve element positioned within the cavity and movable along the longitudinal axis between an open position, in which fuel flows through the orifice into the combustion chamber and a closed position in which a first end of the valve element contacts the seat and fuel flow through the orifice is inhibited, the first end of the valve element including a tip, wherein the fuel flow surface terminates at a second edge, the second edge extends to loin with an injector orifice surface in which the orifice is located; the valve element including: a contact surface that contacts the seat when the valve element is in the closed position, a generally straight first flow-guiding surface extending from the contact surface toward the tip terminating at a first edge and opposing the fuel flow surface forming a first angle relative to the longitudinal axis, wherein the first flow-guiding surface is spaced away from the fuel flow surface when the valve element is in the closed position and a second flow guiding surface extending positioned downstream of the first edge of the first flow-guidin gsurface forming a second angle relative to the longitudinal axis that is smaller than the first angle; wherein an annular cross-sectional flow area Agap(n) between the fuel flow surface and the first flow-guiding surface has a first value at a first location adjacent the contact surface and a second value at a second location spaced apart from the contact surface, each of the first location and the second location being upstream of the first edge of the first flow-guiding surface, the second value being larger than the first value; wherein the fuel flow surface