1. Field of Invention
The invention relates to an exhaust gas control apparatus and an exhaust gas control method for an internal combustion engine, which is provided with a sulfur concentration sensor that detects a sulfur constituent of exhaust gas.
2. Description of Related Art
A publication of Japanese Patent Application Laid-Open No. JP-A-2001-303937 discloses an exhaust gas control apparatus for an internal combustion engine, which detects a sulfur concentration of exhaust gas by a sulfur oxides (SOx) sensor that is disposed downstream of an occlusion reduction type NOx catalyst. Publications of Japanese Patent Application Laid-Open Nos. JP-A-6-173652 and JP-A-2000-230419 further disclose related art of the invention.
The structure of the generally employed exhaust gas control apparatus as described above may fail to accurately detect the concentration of sulfur contained in the exhaust gas discharged from the internal combustion engine. When an air/fuel ratio of the exhaust gas is lean, the sulfur constituent such as SOx is oxidized, which will be held in the exhaust catalyst such as the occlusion reduction type NOx catalyst in the form of a sulfate. Meanwhile when the air/fuel ratio of the exhaust gas is rich, the sulfur constituent passes through the exhaust catalyst. Most part of the sulfur constituent that has passed through the exhaust catalyst, however, may be reduced into a hydrogen sulfide (H2S) which is difficult to be detected by the SOx sensor.
It is an object of the invention to provide an exhaust gas control apparatus for an internal combustion engine, which improves an accuracy of detection of the sulfur concentration of the exhaust gas and allows an accurate estimation of the S-poisoned level of the exhaust catalyst.
An exhaust gas control apparatus for an internal combustion engine according to the invention is provided with an exhaust catalyst disposed in an exhaust passage of the internal combustion engine, a concentration detection unit that is capable of detecting a total concentration of a sulfur oxide and a hydrogen sulfide contained in an exhaust gas that passes through the exhaust catalyst, and detecting a concentration of the sulfur oxide, and a sulfur concentration estimation unit that estimates a sulfur concentration of a fuel based on a detection value of the concentration detection unit when it is determined that the exhaust gas is at one of a stoichiometric and rich air/fuel ratio.
The exhaust gas control apparatus according to the invention is capable of detecting a total concentration of the sulfur oxides and the hydrogen sulfide by the concentration detection unit. Accordingly the concentration of the sulfur constituent of the exhaust gas can be accurately detected. As the sulfur concentration of the fuel is estimated based on the total concentration, the amount of sulfur adhered to the exhaust catalyst may be accurately estimated.
In the above-structured exhaust gas control apparatus, an air/fuel ratio control unit that controls the air/fuel ratio of the exhaust gas into one of the stoichiometric state and the rich state may be provided. In this case, the air/fuel ratio of the exhaust gas is changed by the air/fuel ratio control unit so as to estimate the sulfur concentration of the fuel at an arbitrary timing.
In the exhaust gas control apparatus as described above, the air/fuel ratio control unit executes a rich spike control in which the air/fuel ratio of the exhaust gas is temporarily brought into the rich state at a predetermined cycle. The air/fuel ratio control unit may be provided with a rich amount increase unit that executes at least one of a control for holding the air/fuel ratio of the exhaust gas in the rich state for a longer time than a time under the rich spike control, and a control for bringing the air/fuel ratio of the exhaust gas into a richer state than a state under the rich spike control. The control of the air/fuel ratio of the exhaust gas upon estimation of the sulfur concentration allows the concentration detection unit to accurately detect the sulfur concentration of the exhaust gas discharged from the internal combustion engine. Under the control for holding the rich state for a longer time than that taken under the rich spike control, the air/fuel ratio of the exhaust gas downstream of the exhaust catalyst may be brought into the rich state while restraining the change in the operation state of the engine. Under the control for bringing the air/fuel ratio of the exhaust gas into richer state than the state under the rich spike control, the amount of the sulfur content passing toward the downstream of the exhaust catalyst may be increased.
In the exhaust gas control apparatus, as the exhaust catalyst, a NOx catalyst of occlusion and reduction type is employed. A NOx occluded amount estimation unit is provided for estimating an amount of NOx that has been occluded in the NOx catalyst. The air/fuel ratio control unit may be structured to control the air/fuel ratio of the exhaust gas into one of the stoichiometric state and the rich state when the NOx occluded amount estimated by the NOx occluded amount estimation unit is determined to be equal to or larger than a predetermined amount. In the case where the NOx catalyst is provided as the exhaust catalyst, when the amount of occluded NOx becomes equal to or larger than a predetermined value, the air/fuel ratio of the exhaust gas is set to the stoichiometric or rich state such that the NOx occluded in the NOx catalyst is released, that is, NOx reduction is performed. This makes it possible to estimate the sulfur concentration of the fuel upon NOx reduction.
The exhaust gas control apparatus for the internal combustion engine may be provided with a catalytic temperature detection unit that detects a temperature of the exhaust catalyst. The sulfur concentration estimation unit may inhibit an estimation of the concentration of sulfur contained in the fuel when it is determined that the temperature detected by the catalytic temperature detection unit is equal to or higher than a predetermined temperature. When the temperature of the exhaust catalyst increases, the sulfur constituent that has been held in the catalyst may be released. Then the concentration detection unit detects both the sulfur constituent in the exhaust gas and the sulfur constituent that has been released from the catalyst. The resultant sulfur concentration, thus, is a false value. In this case, the estimation of the sulfur concentration is inhibited.
The term “inhibition of estimation” used herein may include not only the case where the estimation of the sulfur concentration is inhibited but also the case where the estimation of the sulfur concentration is allowed, and the use of the estimated sulfur concentration is inhibited.
In an exhaust gas control method for an internal combustion engine, in which an exhaust catalyst is disposed in an exhaust passage of the internal combustion engine, and a concentration detection unit that is capable of detecting a total concentration of a sulfur oxide and a hydrogen sulfide contained in an exhaust gas that passes through the exhaust catalyst, and detecting a concentration of the sulfur oxide, a sulfur concentration of a fuel is estimated based on a detection value of the concentration detection unit when it is determined that the exhaust gas is at one of a stoichiometric and rich air/fuel ratio.
According to the invention, the concentration detection unit makes it possible to accurately detect the sulfur concentration of the exhaust gas. Accordingly the accuracy of estimation of the sulfur concentration of the fuel can further be improved. This may allow the accuracy in estimation of the timing for recovering the exhaust catalyst that has been degraded or S-poisoned by accurately estimating the S-poisoned level of the exhaust catalyst.
The foregoing and further objects, features and advantages of the invention will become apparent from the following description of preferred embodiments with reference to the accompanying drawings, wherein like numerals are used to represent like elements and wherein:
The air/fuel ratio of exhaust gas at a position at which the NOx catalyst 8 is provided, which may be called as an exhaust air/fuel ratio, and a temperature of the NOx catalyst 8 are controlled by an engine control unit (ECU) 15. The ECU 15 is a known computer unit that controls an operation state of the engine by operating a fuel injection valve 16 for injecting the fuel into the cylinder 2, a pressure regulating valve of a common rail 17 at which the fuel pressure supplied to the fuel injection valve 16 is stored, or various devices such as a throttle valve 7 and an EGR valve 13 as described above. The ECU 15 controls a fuel injecting operation of the fuel injection valve 16 such that the air/fuel ratio set as a mass ratio of air admitted into the cylinder 2 to the fuel added from the fuel injection valve 16 is controlled into a predetermined target air/fuel ratio. In a normal operation state, the target air/fuel ratio is controlled into a lean state where the amount of air is larger than that of air at a stoichiometric air/fuel ratio. If it is determined that the amount of NOx occluded in the NOx catalyst 8 is equal to or larger than a predetermined amount, an operation of the fuel injection valve 16 is controlled such that the exhaust air/fuel ratio is temporarily brought into the rich state (rich spike) at a predetermined cycle in order to reduce the NOx that has been occluded in the NOx catalyst 8. The ECU controls the exhaust air/fuel ratio as an air/fuel ratio control unit. The ECU 15 is structured to control other devices (not shown). The engine 1 is provided with various sensors such as an exhaust gas temperature sensor and an air/fuel sensor (not shown) as the detection unit for executing the aforementioned various control routines.
An example of the sulfur concentration sensor 10 will be described referring to
The detection performed by the SOx concentration detection unit 20 will be described. Most part of sulfur oxides (SOx, mostly sulfur dioxide SO2) introduced into the SOx concentration detection unit 20 is oxidized by an oxidation catalyst 27A into sulfur trioxide (SO3). The sulfur trioxide SO3 reacts with the metallic silver of the detection electrode 24, which causes electrons to be released from the metallic silver. The residual silver ion (Ag+) moves to the sub-electrode 23. The electrons released from the detection electrode 24 are introduced into the reference electrode 25 via an outside circuit 26. At the reference electrode 25, the electron is combined with oxygen (O2), and oxygen ions (O2−) are generated. The oxygen ion passes through the oxygen ion conductor 22 to move toward the sub-electrode 23. The silver ion and the oxygen ion are reacted with the SO3 on the sub-electrode 23 into the silver sulfate. The aforementioned reactions generate an electromotive force between the detection electrode 24 and the reference electrode 25 under the condition where an oxygen partial pressure is constant. The SOx concentration is detected by measuring the electromotive force. The H2S that has passed through the oxidation catalyst with a weak oxidizing capability is hardly oxidized. As a result, the electromotive force in the SOx concentration detection unit 20 does not reflect the H2S concentration.
As
As the NOx catalyst 8 is poisoned by the sulfur constituent contained in the exhaust gas (S-poisoned), its exhaust gas control capability is gradually deteriorated. The ECU 15 executes the S-recovery process for recovering the gas control capability by releasing the sulfur constituent from the catalyst 8 when it is determined that the total value of the amount of the sulfur content (S amount) entered into the catalyst 8 becomes equal to or predetermined amount that may deteriorate the purifying performance of the catalyst 8, the sulfur content is released from the catalyst 8 so as to recover the purifying capability, that is, S-recovery process. The S amount flowing into the catalyst 8 is calculated based on the amount of the fuel supplied to the engine 1, and the S concentration (prospective concentration) that is assumed to be contained in the fuel. The error between the prospective S concentration and the actual S concentration of the fuel supplied to the engine 1 is relatively large, the estimation accuracy of S-poisoned level of the catalyst 8 is lowered, and the S-recovery process cannot be appropriately performed. The ECU 15 executes the control routine for determining the sulfur concentration of the fuel as shown by a flowchart of
Referring to the flowchart of the control routine as shown in
In step S13, the ECU 15 estimates the concentration of sulfur contained in the fuel based on the obtained total concentration. It is then determined whether the estimated sulfur concentration of the fuel is about the same as the prospective S concentration of the fuel. As the fuel (diesel oil) supplied into an empty fuel tank (not shown) of the engine 1 is produced such that its sulfur concentration becomes within a predetermined range, such sulfur concentration may be set as the initial value of the prospective S concentration of the fuel. The value of the obtained total concentration may vary depending on the air/fuel ratio before execution of the rich spike control, or the amount of oxygen that has been occluded in the catalyst 8. In step S13, if the total concentration is in a tolerance range between the upper limit value and the lower limit value with respect to the center value of the total concentration derived from the prospective S concentration of the fuel, it may be determined that the estimated fuel sulfur concentration is about the same as the prospective S concentration of the fuel.
If it is determined that the estimated fuel sulfur concentration is about the same as prospective S concentration of the fuel, the control routine ends. Meanwhile, if it is determined that the estimated fuel sulfur concentration is not about the same as the prospective S concentration of the fuel, the process proceeds to step S14 where the ECU 15 determines whether the temperature of the NOx catalyst 8 is equal to or higher than a predetermined temperature. The temperature of the NOx catalyst 8 may be estimated by the ECU 15 based on the operation state of the engine 1, or detected by a temperature sensor. In the aforementioned case, the ECU 15 estimates the temperature of the NOx catalyst 8 based on the operation state of the engine as the catalytic temperature detection unit. The temperature at which the sulfur constituent that has been occluded in the catalyst 8 starts desorbing is set as the predetermined temperature. If it is determined that the catalytic temperature is equal to or higher than the predetermined temperature, the control routine ends. Meanwhile, if it is determined that the catalytic temperature is not equal to or higher than the predetermined temperature, the process proceeds to step S15 where the ECU 15 changes the prospective S concentration of the fuel. In this case, the estimated fuel sulfur concentration that has been estimated in step S13, for example, is substituted for the prospective S concentration of the fuel. The ECU 15 counts the total value of the S amount flowing into the catalyst 8 in the other routine to estimate the S-poisoned level of the catalyst 8 for the purpose of determining the timing for executing the aforementioned S-recovery process. For example, the counter value of the S amount flowing into the NOx catalyst 8 is corrected based on, for example, the estimated fuel sulfur concentration, the difference between the estimated fuel sulfur concentration and the prospective S concentration of the fuel and the like. Then the control routine ends.
Execution of the control routine shown in
The other example of the control routine for allowing the ECU 15 to serve as the sulfur concentration estimation unit will be described referring to
Referring to the flowchart of the control routine shown in
The increase in the change-to-rich amount will be described hereinafter. The time taken for the exhaust air/fuel ratio downstream of the NOx catalyst 8 to be brought into the rich state may be short upon change in the exhaust air/fuel ratio under the rich spike control depending on the amount of oxygen occluded in the NOx catalyst 8. When the sulfur concentration of the fuel is estimated, the change-to-rich amount of the air/fuel ratio is increased to be larger than the case under the rich spike control so as to make sure that the exhaust air/fuel ratio downstream of the NOx catalyst 8 is brought into the rich state, and the total concentration is detected.
The change-to-rich amount is increased when the sulfur concentration of the fuel is estimated. This makes it possible to improve the accuracy in detection of the total concentration. Accordingly, the sulfur concentration of the fuel may further be accurately estimated.
The invention is not limited to the aforementioned embodiments but may be implemented in various forms. For example, the invention may be applied not only to the diesel engine but also various types of internal combustion engine in which gasoline or other fuel is used. The exhaust catalyst provided in the exhaust passage is not limited to the occlusion reduction type NOx catalyst. The invention may be applied to the internal combustion engine provided with other type of exhaust catalyst such as the three-way catalyst. For example, in the case where the exhaust air/fuel ratio is in the lean state, the sulfur constituent of the exhaust gas discharged from the engine is oxidized by the sulfate and adhered to the three-way catalyst. Accordingly the sulfur concentration of the fuel can be accurately estimated in the aforementioned case.
The timing at which the routine for estimating the sulfur concentration of the fuel is not limited to that under the rich spike control. For example, the sulfur concentration may be estimated at a timing when the engine is operated at a high load. At the aforementioned timing, the opening degree of the throttle valve is set to be larger such that the exhaust air/fuel ratio is held in the rich state for an elongated time. Accordingly the total concentration may be accurately detected.
In the aforementioned embodiment, the sulfur concentration sensor is structured to have a SOx concentration detection section that detects the SOx concentration and a total concentration detection section that detects the total concentration simultaneously. The sulfur concentration sensor may be structured such that the aforementioned operations for detecting the concentration is alternately performed at an appropriate cycle.
According to the invention, the occlusion reduction type NOx catalyst is expected to hold the NOx therein in an arbitrary mechanism, for example, absorption, adsorption or whatsoever. The poisoning of SOx, and release of the NOx or SOx are not particularly specified herein. The control of the engine operation state in the invention is not limited to the control that relates to the combustion control in the cylinder. The control to be executed in the portion other than the cylinder, for example, addition of the fuel or air in the exhaust passage may be regarded as being within the scope of the invention.
Number | Date | Country | Kind |
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2004-173080 | Jun 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB05/01614 | 6/9/2005 | WO | 2/14/2006 |