The present invention relates to a fuel injection control apparatus for an internal combustion engine.
A conventionally known fuel injection control apparatus of a so-called twin needle type adjusts the backside pressures of outer and inner needle valves, which are coaxially accommodated within a valve body, so as to adjustment the lifts of the outer and inner needle valves, to thereby control the injection of fuel (refer to, for example, Japanese Patent Application Laid-Open (kokai) No. 2005-320904).
The fuel pump 20 sucks fuel stored in the fuel tank T and discharges the fuel. The fuel discharged from the fuel pump 20 and having high pressure (rail pressure Pcr) is supplied to the common rail 30. The fuel having the rail pressure Pcr is supplied to the injectors 40 from the common rail 30 through a fuel supply channel C1, which will be described later. Each of the injectors 40 injects the fuel into a combustion chamber (not shown) of an internal combustion engine (particularly, a diesel engine).
The injector 40 has a body 41. The body 41 has first nozzle holes (first nozzle hole group) 41a formed at its tip portion, which faces the combustion chamber of the internal combustion engine, and second nozzle holes (second nozzle hole group) 41b located toward its tip (downward in
A cylindrical piece 44 independent of the body 41 is disposed in the predetermined space of the body 41 and is unitarily fixed to the body 41. A lower end portion of the inner circumferential surface of the piece 44 is fitted to an upper end portion of the outer circumferential surface of the outer needle valve 42. Thus, the predetermined space of the body 41 is divided into a nozzle chamber R1 and a control chamber R2.
The nozzle chamber R1 is provided on the tip side of the outer and inner needle valves 42 and 43. The pressure (rail pressure Pcr) of fuel in the nozzle chamber R1 applies force to the outer and inner needle valves 42 and 43 from the tip side in a valve opening direction. In a state in which the outer and inner needle valves 42 and 43 are opened, the fuel in the nozzle chamber R1 is injected into the combustion chamber through the first and second nozzle holes 41a and 41b.
The control chamber R2 is provided on a back side (upper side in
The apparatus shown in
A 2-position 3-port control valve 45 is installed in the fuel inflow channel C2 and the fuel drain channel C3. The control valve 45 functions such that, when communication is established in the fuel inflow channel C2, the fuel drain channel C3 is shut off (first position as shown in
Next, referring to
When the closed outer and inner needle valves 42 and 43 are to be opened (when a valve closed state is to be changed to a valve opened state (lift>0)), the operational position of the control valve 45 is changed from the above-mentioned first position to the above-mentioned second position (see time tA). By this positional change, the fuel begins to be drained from the control chamber R2 through the fuel drain channel C3. As a result, at and after time tA, the control pressure Pc lowers from the rail pressure Pcr.
In the first conventional apparatus, the outer needle valve 42 is lower than the inner needle valve 43 in the ratio of a control pressure Pc receiving area on the back side to a rail pressure Pcr receiving area on the tip side. Accordingly, an “outer needle valve opening pressure P1” (a control pressure Pc at the time of transfer of the outer needle valve 42 from a closed state to an opened state) is higher than an “inner needle valve opening pressure P2 (a control pressure Pc at the time of transfer of the inner needle valve 43 from the closed state to the opened state).
Thus, when the control pressure Pc which is lowering from the rail pressure Pcr reaches the outer needle valve opening pressure P1, only the outer needle valve 42 opens (moves upward in
When the outer needle valve 42 opens, the fuel having the rail pressure Pcr enters between the outer needle valve 42 and an outer needle valve seat portion 41c. For this reason, only immediately after the outer valve opening time, the outer needle valve 42 rises at a speed corresponding to the differential pressure between the rail pressure Pcr and the control pressure Pc. Subsequently, the outer needle valve 42 rises at a speed corresponding to the flow rate of fuel passing through the orifice Z1 (outflow rate Qout). Also, this speed of the outer needle valve 42 depends on the rate of change of the control pressure Pc.
The upper end surface 42a of the outer needle valve 42 which moves upward as mentioned above comes into contact with the lower surface 43a of the flange portion of the inner needle valve 43 (i.e., the gap δL becomes 0; see time tC). Subsequently, the outer and inner needle valves 42 and 43 can rise only unitarily. Hereinafter, a unitary body of the outer and inner needle valves 42 and 43 may be called “the unitary needle valve.” The time when the upper end surface 42a of the outer needle valve 42 comes into contact with the lower surface 43a of the flange portion of the inner needle valve 43 may be called “the needle valve contact time.”
When the lowering control pressure Pc reaches the inner needle valve opening pressure P2, the inner needle valve 43 also opens (moves upward in
Similar to the outer needle valve 42, in this unitary needle valve (inner needle valve 43), when the inner needle valve 43 opens, the fuel having the rail pressure Pcr enters between the inner needle valve 43 and an inner needle valve seat portion 41d. For this reason, only immediately after the inner valve opening time, the inner needle valve 43 rises at a speed corresponding to the differential pressure between the rail pressure Pcr and the control pressure Pc. Subsequently, the inner needle valve 43 rises at a speed corresponding to the outflow rate Qout. Also, this speed of the inner needle valve 43 depends on the rate of change of the control pressure Pc.
When the opened outer and inner needle valves 42 and 43 are to be closed (when the valve opened state is to be changed to the valve closed state), the operational position of the control valve 45 is changed from the second position to the first position (see time tE). By this positional change, the drainage of fuel from the control chamber R2 through the fuel drain channel C3 is halted, and the inflow of fuel into the control chamber R2 through the fuel inflow channel C2 is started. As a result, at and after time tE, the control pressure Pc rises toward the rail pressure Pcr.
At and after time tF, which is slightly after time tE, the unitary needle valve lowers (moves downward in
The above-mentioned first conventional apparatus may involve the following phenomenon: immediately after the needle valve contact time (see time tC in
A conceivable measure to cope with this problem is, for example, to reduce the differential pressure between the rail pressure Pcr and the backside pressure of the inner needle valve 43, thereby restraining the degree of bounce of the inner needle valve. From this point of view, the inventor of the present invention has proposed a fuel injection control apparatus of the twin needle type shown in
The above-mentioned second conventional apparatus differs from the first conventional apparatus only in the following three points. First, a space corresponding to the control chamber R2 of the first conventional apparatus is divided into an outer control chamber R2o and an inner control chamber R2i. This division is established as follows: an upper end portion of the outer circumferential surface of the inner needle valve 43 is fitted into a lower end portion of the inner circumferential surface of a cylindrical member 46 unitarily fixed to the body 41. Thus, the pressure of fuel in the outer control chamber R2o (outer control pressure Pco) and the pressure of fuel in the inner control chamber R2i (inner control pressure Pci) apply forces to the outer and inner needle valves 42 and 43, respectively, from the back side in a valve closing direction.
Secondly, the cylindrical member 46 has a communication channel 47 formed therein for establishing communication between the outer control chamber R2o and the inner control chamber R2i. Thirdly, the common end of the fuel inflow channel C2 and the fuel drain channel C3 which is located on a side toward the control chamber is connected only to the outer control chamber R2o.
Next, referring to
Accordingly, the differential pressure between the rail pressure Pcr and the inner control pressure Pci (inner differential pressure δPci) at the needle valve contact time (see time tC) in the second conventional apparatus can change while being smaller than the differential pressure δPc between the rail pressure Pcr and the control pressure Pc at the needle valve contact time in the first conventional apparatus. As a result, even when the outer needle valve 42 collides against the inner needle valve 43 as mentioned above, the degree of bounce of the inner needle valve can be restrained.
As mentioned above, at the time of opening of the outer needle valve 42, because of entry of fuel having the rail pressure Pcr between the outer needle valve 42 and the outer needle valve seat portion 41c, the rising speed of the outer needle valve 42 immediately after the outer valve opening time depends on the differential pressure between the rail pressure Pcr and the outer control pressure Pco (outer differential pressure δPco).
As can be understood from
Incidentally, immediately after the outer valve opening time, there is a tendency that the higher the rising speed of the outer needle valve 42, the higher the rate at which fuel is injected from the first nozzle holes (first nozzle hole group) 41a (injected fuel quantity per unit time). The higher the fuel injection rate, the greater the acceleration of the atomization of fuel injected from the first nozzle holes (first nozzle hole group) 41a (i.e., the diffusion of injected fuel in a combustion chamber). At low load, because of low combustion temperature, the greater the acceleration of the atomization of injected fuel, the higher the unburnt HC content of exhaust gas. That is, at low load, there is a tendency that the higher the rising speed of the outer needle valve 42 immediately after the outer valve opening time, the higher the unburnt HC content of exhaust gas.
Thus, there arises a new problem in that, at low load, the unburnt HC content of exhaust gas in the second conventional apparatus becomes higher than that in the first conventional apparatus.
Also, as in the case of opening of the outer needle valve 42, at the time of opening of the inner needle valve 43, because of entry of fuel having the rail pressure Pcr between the inner needle valve 43 and the inner needle valve seat portion 41d, the rising speed of the inner needle valve 43 immediately after the inner valve opening time depends on the inner differential pressure δPci.
As will be understood from
Incidentally, in a period (hereinafter, may be called “the seat choke period Tch”) in which the lift of the inner needle valve 43 changes within a range not greater than a minimal lift Lmin, there arises a phenomenon in which an orifice is substantially formed between the inner needle valve 43 and the inner needle valve seat portion 41d (hereinafter, this phenomenon may be called “the seat choke phenomenon”). When the seat choke phenomenon occurs, because of low fuel pressure in the second nozzle holes (second nozzle hole group) 41b, the atomization of fuel injected from the second nozzle holes (second nozzle hole group) 41b is restrained. Accordingly, the longer the seat choke period Tch, the greater the restraint of the atomization of injected fuel. As a result, smoke is apt to be generated in exhaust gas.
Meanwhile, there is a tendency that the lower the rising speed of the inner needle valve 43 immediately after the inner valve opening time, the longer the seat choke period Tch. Accordingly, the seat choke period Tch in the second conventional apparatus is longer than that in the first conventional apparatus. As a result, there arises a new problem in that the smoke content of exhaust gas in the second conventional apparatus is higher than that in the first conventional apparatus.
Thus, in the second conventional apparatus, since the outer differential pressure δPco immediately after the outer valve opening time is set large, and the inner differential pressure δPci immediately after the inner valve opening time is set small, two new problems arise, namely, a high unburnt HG content in exhaust gas at low load, and a high smoke content in exhaust gas.
The two new problems can be solved by setting the outer differential pressure δPco immediately after the outer valve opening time to a small value, and also setting the inner differential pressure δPci immediately after the inner valve opening time to a large value.
Thus, an object of the present invention is to provide a fuel injection control apparatus of a twin needle type in which the outer differential pressure immediately after the outer valve opening time can be set small and in which the inner differential pressure immediately after the inner valve opening time can be set large.
A fuel injection control apparatus according to the present invention comprises a body having the above-mentioned first and second nozzle holes; the above-mentioned outer and inner needle valves; the above-mentioned nozzle chamber; the above-mentioned outer and inner control chambers; a high pressure generating section; the above-mentioned fuel supply channel; a first fuel inflow channel for connecting the fuel supply channel and the outer control chamber or the inner control chamber; the above-mentioned communication chamber; a fuel drain channel for connecting the inner control chamber and a fuel tank; and a first control valve installed in the fuel drain channel and adapted to allow and shut off communication through the fuel drain channel.
The first fuel inflow channel may be configured to connect the fuel supply channel and the outer control chamber. Preferably, a first orifice is installed in the first fuel inflow channel, and a second orifice is installed in the fuel drain channel.
According to the above-mentioned configuration, when the first control valve allows communication through the fuel drain channel, fuel in the outer control chamber flows into the inner control chamber through the communication channel, and the fuel in the inner control chamber flows out to the fuel tank through the fuel drain channel. The flow of fuel through the communication channel generates a differential pressure between the inner control pressure and the outer control pressure. By virtue of the generation of the differential pressure, the outer control pressure can change while being higher than the inner control pressure; the outer differential pressure can change while being small; and the inner differential pressure can change while being large.
Thus, the outer differential pressure immediately after the outer valve opening time can be set small. Accordingly, the speed of the outer needle valve immediately after the outer valve opening time can be rendered low. As a result, there can be restrained an increase in the unburnt HC content of exhaust gas at low load, which could otherwise result from an abrupt increase in fuel injection rate immediately after the outer valve opening time.
Also, the inner differential pressure immediately after the inner valve opening time can be set large. Accordingly, the speed of the inner needle valve immediately after the inner valve opening time can be rendered high. As a result, the seat choke period immediately after the inner valve opening time can be shortened, so that there can be restrained an increase in the smoke content of exhaust gas, which could otherwise result from the seat choke phenomenon.
Preferably, the fuel injection control apparatus according to the present invention further comprises a piece provided separately from the body, unitarily fixed to the body, and adapted to separate the nozzle chamber and the outer control chamber from each other, and the piece has a stopper for limiting a lift of the outer needle valve.
According to the above-mentioned configuration, in a state in which the lift of the inner needle valve is “0,” the collision of the outer needle valve against the inner needle valve can be prevented. Accordingly, bounce of the inner needle valve can be prevented. Also, since the stopper is provided on the piece, which is a member provided separately from the body, as compared with the case where the stopper is provided on the body, there can be readily fabricated a fuel injection control apparatus in which bounce of the inner needle valve can be prevented.
Preferably, the fuel injection control apparatus according to the present invention further comprises a second fuel inflow channel for connecting the fuel supply channel and the inner control chamber, and a second control valve installed in the second fuel inflow channel and adapted to shut off the second fuel inflow channel when the first control valve allows communication through the fuel drain channel, and to allow communication through the second fuel inflow channel when the first control valve shuts off the fuel drain channel. In this case, preferably, in view of reduction in size of the fuel injection control apparatus, the first control valve and the second control valve are configured to be integral with each other.
Generally, even immediately before the inner valve closing time, similar to the case immediately after the inner valve opening time, the seat choke phenomenon occurs. For shortening the seat choke period immediately before the inner valve closing time, the lowering speed of the inner needle valve immediately before the inner valve closing time may be rendered high.
The above-mentioned configuration is based on the findings mentioned above. According to the configuration, as compared with the case where only the first fuel supply channel is provided, the total flow rate of fuel which flows into the inner control chamber when the fuel drain channel is shut off can be rendered high. Accordingly, as compared with the case where only the first fuel supply channel is provided, the lowering speed of the inner needle valve immediately before the inner valve closing time can be rendered high. As a result, the seat choke period immediately before the inner valve closing time can be shortened.
Embodiments of a fuel injection control apparatus according to the present invention will next be described with reference to the drawings.
The first embodiment differs from the aforementioned second conventional apparatus only in the following three points. First, in place of the 2-position 3-port control valve 45 of the second conventional apparatus, a 2-position 2-port on-off control valve 48 for opening and closing the fuel drain channel C3 is installed. The on-off control valve 48 corresponds to the aforementioned first control valve.
Secondly, the fuel inflow channel C2 is provided independent of the on-off control valve 48, and an end of the fuel inflow channel C2 which is located on a side toward the control chamber is connected to the outer control chamber R2o. The fuel inflow channel C2 has an orifice Z2 installed therein and having the same cross-sectional area of opening as that of the orifice Z1. Irrespective of whether the on-off control valve 48 is opened or closed, the fuel inflow channel C2 establishes communication between the fuel supply channel C1 and the outer control chamber R2o at all times. Additionally, an end of the fuel drain channel C3 which is located on the side toward the control chamber is connected to the inner control chamber R2i. The fuel inflow channel C2 corresponds to the aforementioned first fuel inflow channel, and the orifice Z1 and the orifice Z2 correspond to the aforementioned second orifice and the aforementioned first orifice, respectively.
Thirdly, the piece 44 has a ringlike stopper 44a, which projects radially inward from its inner circumferential surface. The stopper 44a limits the lift of the outer needle valve 42 such that the maximum lift becomes a value L2 (<the value L1 mentioned above). Thus, bounce of the inner needle valve can be prevented.
Next, referring to
Thus, according to the first embodiment of the fuel injection control apparatus according to the present invention, the outer differential pressure δPco immediately after the outer valve opening time can be set small, and the inner differential pressure δPci immediately after the inner valve opening time can be set large. As a result, there can be restrained an increase in the unburnt HC content of exhaust gas at low load, which could otherwise result from an abrupt increase in fuel injection rate immediately after the outer valve opening time. Also, there can be restrained an increase in the smoke content of exhaust gas, which could otherwise result from the seat choke phenomenon.
Notably, even though the inner differential pressure δPci immediately after the inner valve opening time is set large, since load when the inner needle valve 43 opens is relatively large (i.e., combustion temperature is relatively high), an increase in the unburnt HC content of exhaust gas caused by an abrupt increase in fuel injection rate immediately after the inner valve opening time is unlikely to occur.
Additionally, as shown in
The present invention is not limited to the above-described embodiment. Numerous modifications and variations of the present invention are possible without departing from the scope of the invention. Modifications of the first embodiment will next be described.
Thus, irrespective of whether the on-off control valve 48 is opened or closed, fuel can flow into the inner control chamber R2i at all times. Accordingly, in a state in which the on-off control valve 48 is closed, as compared with the first embodiment, the rising rate of the inner control pressure Pci can be high. As a result, as compared with the first embodiment, the seat choke period Tch immediately before the inner valve closing time can be shortened.
Next, the fuel injection control apparatus 10 of an internal combustion engine according to a second embodiment of the present invention will be described.
The second embodiment differs from the first embodiment only in that, in place of the on-off control valve 48 of the first embodiment, a 2-position 3-port control valve 49 is employed and that a second fuel inflow channel C4 for connecting the fuel supply channel C1 and the inner control chamber R2i through the control valve 49 is provided. When the control valve 49 shuts off the fuel drain channel C3, communication through the second fuel inflow channel C4 is established (first position as shown in
Next, referring to
Thus, according to the second embodiment of the fuel injection control apparatus according to the present invention, as compared with the first embodiment, the seat choke period Tch immediately before the inner valve closing time can be shortened.
Also, as shown in
As a result, even when the lowering speeds of the outer and inner needle valves 42 and 43 vary, as compared with the first embodiment, the respective degrees of variations of the outer valve closing time and the inner valve closing time can be rendered small. That is, as compared with the first embodiment, the degree of variations of total injected fuel quantity can be rendered small.
The present invention is not limited to the above-described embodiment. Numerous modifications and variations of the present invention are possible without departing from the scope of the invention. For example, the second embodiment employs only a single 2-position 3-port control valve 49. However, the control valve 49 may be replaced with two on-off control valves as follows: a first on-off control valve and a second on-off control valve are installed in the fuel drain channel C3 and the second fuel inflow channel C4, respectively, and operate in such an interlocking relation that, when the first (second) on-off control valve is opened (closed), the second (first) on-off control valve is closed (opened). In this case, the first and second on-off control valves correspond to the aforementioned first and second control valves, respectively.
Additionally, in the above-described embodiments, the stopper 44a is disposed on the piece 44. However, the stopper 44a may be disposed on the body 41 itself.
Number | Date | Country | Kind |
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2007-232703 | Sep 2007 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2008/066503 | 9/8/2008 | WO | 00 | 3/4/2010 |