KR101500349B1 - APPARATUS AND METHOD FOR DETECTING AGED OF LEAN NOx TRAP CATALYST - Google Patents

Abstract

The present invention relates to a method of monitoring an LNT (Lean NOx Trap) catalyst, in which the reducing agent used for NOx regeneration and the NOx regeneration agent used in the rich mode operation for reducing NOx stored in the LNT catalyst to nitrogen are used, To detect the deterioration of the LNT catalyst through the ratio of the reducing agent slipped to the rear end of the LNT catalyst.

The present invention relates to a process for detecting a signal of a first lambda sensor in an operation mode for reducing NOx occluded in an LNT catalyst, a process for detecting the amount of a reducing agent consumed in NOx reduction in a signal of the first and second lambda sensors, Calculating a slip ratio of the reducing agent using the amount of the consumed reducing agent and the amount of the reducing agent to be slipped; comparing the slip ratio of the calculated reducing agent with a threshold value to diagnose whether the LNT catalyst is deteriorated; .

LNT catalyst, reducing agent, rich mode, deterioration detection, slip ratio, lambda sensor

Description

TECHNICAL FIELD The present invention relates to an apparatus and a method for detecting deterioration of an LNT catalyst,

The present invention relates to a monitoring method of an LNT (Lean NOx Trap) catalyst, and more particularly, to a method of monitoring a lean NOx trap catalyst used in a rich mode operation in which NOx occluded in an LNT catalyst is reduced to nitrogen, The present invention relates to an apparatus and method for detecting deterioration of an LNT catalyst, and more particularly, to an apparatus and method for detecting deterioration of an LNT catalyst by detecting the deterioration of the LNT catalyst through a ratio of a reducing agent slip to the rear end of the LNT catalyst.

Since various kinds of harmful substances are contained in the exhaust gas discharged from the engine of the vehicle, various types of catalysts for stabilizing the emission (E / M) are installed.

LNT catalysts using NSC (NOx Storage Catalyst) have been applied to reduce NOx according to exhaust gas regulations for diesel engines.

The LNT catalyst consists of a NOx occlusion catalyst and a DOC (Oxidation Catalyst) (DOC) in one carrier. In the lean mode operation, NOx is occluded in the catalyst coat, Diesel fuel is used as a reducing agent to purify NOx that is occluded by reducing it to harmless nitrogen to the human body.

The LNT catalyst has an extremely high NOx purification efficiency of 70 to 80% or more at an active temperature range of approximately 200 ° C to 500 ° C.

Normally, the diesel engine is operated in a lean mode, in which the amount of air injected into the engine is greater than theoretical equivalent ratio air, and the NOx generated in the lean mode operation is occluded in the LNT catalyst, which is NSC.

In order to reduce NOx stored in the LNT catalyst to nitrogen which is harmless to the human body, the throttle valve is closed by a certain amount to reduce the input air and further convert the combustion mode to the rich mode operation.

In order to operate the rich mode and the lean mode, the signals of the lambda sensor or the NOx sensor installed at the front and the rear of the LNT catalyst are used, but the method of following the target air-fuel ratio by using the lambda sensor is applied due to the cost of the expensive NOx sensor do.

When the NOx occluded in the LNT catalyst reaches a certain level, the operation is switched to the rich mode operation, and the NOx regeneration control is started at the level of 0.92 to 0.94 based on the signal of the lambda sensor installed on the upstream side of the LNT catalyst. The reducing agent such as HC, CO, and H2 generated in the NOx reduction catalyst plays a role of reducing NOx occluded in the LNT catalyst to N2.

In the LNT catalyst, the amount of NOx occluded by the reduction of NOx gradually decreases, and as the reactant gradually decreases, the amount of the reducing agent slip increases as the rich mode continues.

Accordingly, the value detected by the lambda sensor installed downstream of the LNT catalyst gradually converges to the value detected by the lambda sensor installed on the upstream side of the LNT catalyst, thereby indicating that the reducing agent is slipping at the end of the LNT catalyst.

In the case of the LNT catalyst with deteriorated and edoxidized poisoning compared with the normal LNT catalyst, the NOx purification rate is gradually decreased, and the amount of the reducing agent slipping to the rear end of the LNT catalyst is increased.

As shown in FIG. 4, when the LNT catalyst 200 is in a normal state, the LNT catalyst 200 flows into the LNT catalyst 200 in a rich mode operation The reducing agent is used in a considerable amount (a) for reduction (regeneration) of NOx, and the reducing agent (b) to be slipped to the rear end of the LNT catalyst 200 corresponds to a certain amount.

However, when the LNT catalyst 200 is deteriorated, only a part of the reducing agent introduced into the LNT catalyst 200 during the operation in the rich mode is used for reduction (regeneration) of NOx, The amount of the reducing agent (b) to be slip is increased by a considerable amount.

Therefore, OBD-II regulation monitors the deterioration of LNT catalysts and fines are imposed if the regulations are not satisfied.

In the conventional vehicle, the purification rate of the LNT catalyst is determined by using the expensive NOx sensor information provided before / after the LNT catalyst, and the method of determining the deterioration of the LNT catalyst according to the purification rate is applied, There is a disadvantage in that reliability is lacking in the determination.

DISCLOSURE OF THE INVENTION The present invention has been made to solve the above-described problems, and its object is to provide a method of reducing NOx stored in an LNT catalyst, which is used in NOx regeneration from information of a lambda sensor installed at the front end and a rear end of the LNT catalyst, The amount of the reducing agent and the amount of the reducing agent slip to the rear end of the LNT catalyst without being used for regeneration of NOx are detected and the ratio of the amount of the reducing agent is analyzed to detect the deterioration of the LNT catalyst.

An LNT catalyst deterioration detecting apparatus according to an aspect of the present invention for realizing the above object comprises: an LNT catalyst for storing NOx in a lean mode and regenerating NOx by reacting NOx with a reducing agent; A first and second lambda sensors for detecting lambda values before and after the LNT catalyst in the rich mode; And a controller for detecting the amount of the reducing agent consumed in the NOx reduction and the amount of the reducing agent slipped by using the signals of the first and second lambda sensors to calculate the slip ratio and determining whether the LNT catalyst is deteriorated according to the slip ratio.

A method of detecting deterioration of an LNT catalyst according to an embodiment of the present invention includes detecting a signal of a first and second lambda sensors in an operation mode for reducing NOx occluded in an LNT catalyst; Detecting the amount of the reducing agent that is consumed in NOx reduction in the signals of the first and second lambda sensors and the amount of the reducing agent that is not reacted with the reducing agent; Calculating a slip ratio of the reducing agent using the amount of the consumed reducing agent and the amount of the reducing agent slipped; And comparing the calculated slip ratio of the reducing agent with a threshold value to diagnose whether the LNT catalyst is deteriorated.

According to the present invention, the slip ratio of the amount of the reducing agent reacting with the regeneration of NOx and the amount of the slipping reducing agent in the rich mode operation is analyzed to determine whether or not the LNT catalyst is deteriorated. There is an effect of providing stability and reliability in operation.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains.

The present invention can be embodied in various different forms, and thus the present invention is not limited to the embodiments described herein.

1 is a schematic view illustrating an apparatus for detecting deterioration of an LNT catalyst according to an embodiment of the present invention.

The present invention relates to an engine 100 that is a power source of a vehicle and an air amount sensor 110, an LNT catalyst 200, a first lambda sensor 210, a second lambda sensor 220, a temperature sensor 230, ).

The air amount sensor 110 is installed at a predetermined position of the intake manifold and detects the amount of air sucked into the engine 100 while the engine 100 maintains the start-up state, and provides the controller 300 with information on the amount of air.

The LNT catalyst 200 includes a NOx storage catalyst and an oxidation catalyst in a single carrier to store and store NOx in the catalyst bed in the lean mode operation and to react with the reducing agent supplied in the rich mode operation to store the stored NOx It is reduced to nitrogen which is harmless to the human body and purified.

The first lambda sensor 210 detects the lambda value before the LNT catalyst 200 in the operation of the rich mode for reducing NOx and provides the controller 300 with information about the lambda value.

The second lambda sensor 220 detects the lambda value at the end of the LNT catalyst 200 in the operation of the rich mode for reducing NOx and provides the controller 300 with information about the detected lambda value.

The control unit 300 calculates and controls the fuel injection amount in the rich mode from the information of the air amount sensor, estimates the flow amount of the exhaust gas from the fuel injection amount, analyzes the temperature of the LNT catalyst 200 detected by the temperature sensor 230 It is determined whether activation of the LNT catalyst 200 has been performed.

The controller 300 controls the first lambda sensor 210 and the second lambda sensor 220 when the LNT catalyst 200 is activated and the rich mode operation is in progress and HC and CO are supplied. The lambda value of the second lambda sensor 220 is calculated by subtracting the lambda value of the second lambda sensor 220 from the lambda value (lambda = 1) detected through the first lambda sensor 210 so that the amount of the reducing agent is proportional to the lambda value, 200), the amount of the reducing agent slip to the rear end is calculated.

The lambda value detected by the first lambda sensor 210 is subtracted from the lambda value detected through the second lambda sensor 220 to calculate the amount of the reducing agent consumed in the reduction of NOx in the LNT catalyst 200 .

When the amount of the reducing agent consumed in the reduction of NOx in the LNT catalyst 200 and the amount of the reducing agent slipped in the rear end of the LNT catalyst 200 are calculated as described above, the amount of the reducing agent slippage is divided by the amount of the reducing agent supplied (amount consumed + If the slip ratio exceeds the set threshold value, the NOx purification rate of the LNT catalyst 200 is decreased. Therefore, the LNT catalyst 200 is determined to be deteriorated. If the slip ratio is less than the preset threshold value, The NOx purification rate is determined to be normal and the LNT catalyst 200 is determined to be normal.

The threshold value is 1.75 times (0.123 g / mile) of FTP-NOx in the case of vehicles after 13My in North America.

The relationship between the amount of the reducing agent consumed in reducing the NOx and the amount of slip supplied to the LNT catalyst 200 in the rich mode operation is as shown in FIG.

The operation of the present invention including the functions described above will be described in detail with reference to Fig.

The control unit 300 determines that the information detected by the temperature sensor 230 is NOx of the LNT catalyst 200 when the LNT catalyst 200 is activated, (S101) and determines whether or not the regeneration of the LNT catalyst 200 is required (S102).

If the regeneration of the LNT catalyst 200 is not required, the current lean mode operation is maintained and the occlusion of the NOx is maintained. If the regeneration of the LNT catalyst 200 is required, To supply the reducing agent necessary for reducing NOx (S103).

When the operation mode is switched to the rich mode in step S103, the controller 300 controls the first lambda sensor 210 installed on the upstream side of the LNT catalyst 200 and the second lambda sensor 220 installed on the downstream side of the LNT catalyst 200, (S104), the consumption amount of the reducing agent consumed in the reduction of NOx in the LNT catalyst 200 is detected (S105), and the amount of slippage of the reducing agent that is not consumed in the LNT catalyst 200 and is slipped is detected (S106 ).

Since the amount of the reducing agent supplied to the LNT catalyst 200 according to the rich mode operation is proportional to the lambda value, the lambda value detected through the second lambda sensor 220, To calculate the amount of the reducing agent consumed in the reduction of NOx in the LNT catalyst 200.

Then, the lambda value of the second lambda sensor 220 is subtracted from the lambda value (? = 1) detected through the first lambda sensor 210 to calculate the amount of the reducing agent slipping to the rear end of the LNT catalyst 200 .

When the amount of the reducing agent consumed in the NOx reduction process and the amount of the reducing agent slid to the rear end of the LNT catalyst 200 are calculated in the LNT catalyst 200 as described above, the slip ratio is calculated by dividing the slip amount of the reducing agent by the supplied amount of the reducing agent.

The supply amount of the reducing agent is calculated as the sum of the amount of the consumed reducing agent and the amount of the reducing agent to be slipped.

If the slip ratio is calculated in step S107, it is determined whether the slip ratio exceeds a predetermined threshold value (S108). If the slip ratio exceeds the predetermined threshold value, the NOx purification rate of the LNT catalyst 200 is decreased and the LNT catalyst 200 is determined to be deteriorated (S109) and stores the failure code corresponding thereto and instructs the driver through the display means (S110).

However, if the slip ratio is less than the preset threshold value in step S108, the NOx purification rate of the LNT catalyst 200 is in a normal state, so that the LNT catalyst 200 is determined to be normal (S111).

Therefore, it provides stability and reliability in detecting deterioration of the LNT catalyst 200.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It is included in the scope of right.

1 is a schematic view illustrating an apparatus for detecting deterioration of an LNT catalyst according to an embodiment of the present invention.

FIG. 2 is a flowchart schematically illustrating a procedure of detecting deterioration of an LNT catalyst according to an embodiment of the present invention.

3 is a view showing the amount of reducing agent supplied to the LNT catalyst in the rich mode operation of the diesel engine, the amount of the reducing agent used for regeneration of NOx, and the amount of the reducing agent to be slipped.

4 is a graph showing the amounts of a reducing agent used for regenerating NOx and a reducing agent to be slipped in a normal LNT catalyst and a deteriorated LNT catalyst.

Description of the Related Art

100: engine 110: air quantity sensor

200: LNT catalyst 210: first lambda sensor

220: second lambda sensor 300:

Claims (8)

An LNT catalyst that adsorbs NOx in a lean mode and reacts NOx with a reducing agent to regenerate NOx; A first and second lambda sensors mounted on the front and rear ends of the LNT catalyst to detect lambda values; A control unit for calculating a slip ratio by detecting the amount of the reducing agent consumed in the reduction of NOx and the amount of reducing agent slipped by using the signals of the first and second lambda sensors and determining whether the LNT catalyst is deteriorated according to the slip ratio; , ≪ / RTI & The controller calculates the amount of the reducing agent slipping to the downstream of the LNT catalyst by subtracting the lambda value of the second lambda sensor from the lambda value (lambda = 1) Wherein the lambda value of the first lambda sensor is subtracted from the lambda value of the second lambda sensor to calculate the amount of the reducing agent consumed in the reduction of NOx in the LNT catalyst. delete The method according to claim 1, The control unit calculates the slip ratio by dividing the slip amount of the reducing agent by the supplied amount of the reducing agent and determines that the LNT catalyst is deteriorated when the slip ratio exceeds the set threshold value and determines that the LNT catalyst is normal when the slip ratio is less than the set threshold value Characterized in that the deterioration detection device of the LNT catalyst. Detecting a signal of the first and second lambda sensors in an operation mode for reducing NOx occluded in the LNT catalyst; Detecting the amount of the reducing agent that is consumed in NOx reduction in the signals of the first and second lambda sensors and the amount of the reducing agent that is not reacted with the reducing agent; Calculating a slip ratio of the reducing agent using the amount of the consumed reducing agent and the amount of the reducing agent slipped; Diagnosing whether the LNT catalyst is deteriorated by comparing the calculated slip ratio of the reducing agent with a threshold value; / RTI > Wherein the amount of the reducing agent consumed in NOx reduction is calculated by subtracting the lambda value of the first lambda sensor from the lambda value of the second lambda sensor. delete 5. The method of claim 4, Wherein the amount of the reducing agent that is not consumed in the NOx reduction and is slipped is calculated by subtracting the lambda value of the second lambda sensor from the lambda value (? = 1). 5. The method of claim 4, The slip ratio is calculated by dividing the slip amount of the reducing agent by the supply amount (consumption amount + slip amount) of the reducing agent. If the slip ratio exceeds the threshold value, the LNT catalyst is judged as deteriorated. If the slip ratio is less than the threshold value, Wherein the deterioration of the LNT catalyst is detected by the detector. 5. The method of claim 4, Wherein when the deterioration of the LNT catalyst is judged, the malfunction code is stored and the malfunction indication is indicated through the display means.

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