JP2012002060A - Urea quality diagnostic system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an urea quality diagnostic system capable of accurately diagnosing the quality of urea water in an urea tank.SOLUTION: The urea quality diagnostic system detects the concentration and temperature of the urea water 15 in the urea water tank 16 and diagnoses the quality of the urea water. In the urea quality diagnostic system, the lower limit value β of a determinable water temperature is set individually according to the concentration of the urea water. When the detected urea water temperature is higher than the individually set lower limit value β of determinable water temperature, the quality determination of the concentration is performed, and when the detected urea water temperature becomes below the individually set lower limit value β of the determinable water temperature, the quality determination of the concentration is not performed.

Description

  The present invention relates to an SCR system for reducing NOx in exhaust gas of an engine using urea water, and more particularly to a urea quality diagnostic system for diagnosing quality such as the concentration of urea water injected into an SCR device.

  In order to purify NOx in exhaust gas of a diesel engine, an SCR system using a selective reduction catalyst (SCR), for example, has been developed as an exhaust gas purification system (see, for example, Patent Documents 1 and 2).

  This SCR system uses urea as a reducing agent, supplies urea water to the exhaust gas upstream of the SCR device, and hydrolyzes urea with the heat of the exhaust gas to generate ammonia, which is used as NOx on the SCR catalyst. Is to reduce and purify.

  The urea water is stored in the tank, and the urea injection amount corresponding to the engine speed and the load is calibrated so that the target purification rate can be achieved at a predetermined concentration (for example, 32.5%).

  By the way, when replenishing urea water, if the urea water is diluted with water, the concentration becomes high due to evaporation of moisture, etc., or if a foreign liquid such as salt water enters, the purification performance deteriorates and the worst equipment Problems such as failure (clogging of the injection nozzle) occur.

  As a urea sensor for measuring the urea concentration, liquid level and temperature of this urea water tank, a urea sensor as shown in Patent Document 3 is known. This urea sensor detects a liquid level with a capacitance, detects a concentration with an ultrasonic velocity, and detects a temperature with a heater resistance.

  This urea sensor diagnoses the quality of urea water and detects that the concentration is abnormal or that liquid (salt water, etc.) has been introduced. If the warning is ignored and the vehicle travels a predetermined distance, measures are taken to prevent the engine from being restarted, and the system is protected so that normal urea water is put into the urea tank.

JP 2000-27627 A JP 2005-83223 A JP 2007-47006 A JP 2005-264933 A

  In this way, the urea sensor detects the concentration of urea water, and when it is not within the predetermined concentration range, a warning is given as an abnormal concentration. However, since the concentration is measured at the ultrasonic speed, the urea water There is a problem that the detection accuracy is affected by the temperature of the. In particular, at a temperature below the freezing temperature of urea water (−11 ° C.), the urea water freezes and accurate concentration diagnosis cannot be performed.

  Therefore, conventionally, the concentration is diagnosed when the temperature of the urea water is higher than the temperature at which the aqueous urea does not freeze reliably (for example, −5 ° C.) (Patent Document 4). However, there is no problem on the low density side, but there is a problem that accurate density measurement cannot be performed on the high density side. That is, if the temperature threshold is set to −5 ° C. or higher, the concentration of urea can be measured because it does not freeze. However, if the concentration of urea is high, the concentration of urea decreases as the temperature decreases, and an accurate concentration diagnosis is performed. There is a problem that can not be done.

  Therefore, an object of the present invention is to provide a urea quality diagnosis system that can solve the above-described problems and can accurately diagnose the quality of urea water in a urea tank.

  In order to achieve the above object, a first aspect of the invention relates to a urea quality diagnostic system for detecting the concentration and temperature of urea water in a urea tank and diagnosing the quality of the urea water, according to the concentration of urea water. The lower limit value of the water temperature that can be determined is individually set, and when the detected urea water temperature is higher than the lower limit value of the water temperature that can be individually determined, the quality of the concentration is determined. The urea quality diagnosis system is characterized in that the quality judgment of the concentration is not performed when it falls below.

  In the invention of claim 2, the lower limit value of the water temperature that can be determined when the detected concentration of urea water is higher than a predetermined concentration is set to a saturation temperature at which urea precipitation does not occur at the normal concentration upper limit value of urea water. 1. The urea quality diagnostic system according to 1.

  The invention according to claim 3 is the urea quality diagnosis system according to claim 1, wherein the lower limit value of the water temperature that can be determined when the detected concentration of urea water is lower than a predetermined concentration is set to a freezing temperature at which urea does not freeze.

  The invention according to claim 4 is the urea quality diagnostic system according to any one of claims 1 to 3, wherein when a concentration abnormality is diagnosed, urea injection is prohibited and a warning is given to the driver.

  According to the present invention, when the concentration of urea water in the urea tank is detected, the quality of the urea water is diagnosed in consideration of the temperature condition, thereby exhibiting an excellent effect that an accurate quality diagnosis can be performed. It is.

It is a system diagram showing an embodiment of the present invention. It is a figure which shows the flow of the urea quality diagnostic system of this invention. It is a figure which shows the state of the urea water density | concentration and urea temperature at the time of performing urea diagnosis in this invention. It is a figure which shows the other flow of the urea quality diagnostic system of this invention.

  A preferred embodiment of the present invention will be described below in detail with reference to the accompanying drawings.

  In FIG. 1, an SCR device 11 is connected to an exhaust pipe 10 of a diesel engine, and an injection nozzle 12 for injecting urea water is provided on the upstream side of the SCR device 11 to constitute an SCR system.

  The SCR device 11 includes an oxidation catalyst layer 13 and a ceramic filter 14 with a catalyst. The oxidation catalyst layer 13 is an unburned substance (SOF) mainly composed of hydrocarbon HC contained in PM (particulate matter) in exhaust gas. ) Is collected, PM in the exhaust gas is collected by the catalyst-equipped ceramic filter 14, and the catalyst-attached ceramic filter 14 reacts with ammonia and NOx generated by the thermal decomposition of urea water for denitration. Yes.

  The urea water 15 is stored in the urea tank 16, and the urea water in the urea tank 16 is sucked up through the liquid feed line 18 in the supply module 17 including a pump, supplied to the injection nozzle 12, and injected, and excess urea The water is returned to the urea tank 16 through the recovery line 19.

  The amount of urea water injected from the injection nozzle 12 is controlled by a DCU (Dosing Control Unit) 20. The DCU 20 is connected to an ECU (Engine Control Unit) and injects urea based on the engine rotation speed-load from the ECU and the detection values of the exhaust temperature sensor 21 and the NOx sensor 22 provided on the upstream side of the exhaust pipe 10. The amount of water is determined, and the supply module 17 is controlled based on this.

  The urea tank 16 is provided with a urea sensor 23 that detects the concentration, water level, and temperature of the urea water 15, and the detected values (concentration, water level, temperature) of the urea sensor 23 are input to the DCU 20.

  The urea sensor 23 basically measures the water level by changing the capacitance, measures the concentration by the ultrasonic velocity, and measures the temperature by the heater resistance. Can also be detected. The urea sensor 23 may be an integrated water level sensor, concentration sensor, and temperature sensor as shown in the figure, or may be configured by a sensor that individually detects the water level, concentration, and temperature.

  The DCU 20 diagnoses the quality of the urea water based on the detected temperature and concentration values from the urea sensor 23.

  In the present invention, when detecting and diagnosing the concentration of urea water, the temperature condition of the urea water at that time is added to the determination condition of normal or abnormal, and the water temperature lower limit that can be individually determined for the dark side and the light side A value is set, and an accurate quality diagnosis is performed according to the individual water temperature lower limit value that can be determined.

  In this diagnosis, when it is diagnosed that the concentration is abnormal, urea injection by the supply module 17 is prohibited, and a warning lamp provided in the cabin is turned on or an alarm sound is emitted by a buzzer through the ECU. Is urged to replace the urea water 15 in the urea tank 16 with a regular one.

  The reason why the temperature condition is taken into consideration for the concentration of the urea water will be described with reference to the urea water phase diagram of FIG.

  First, the initial concentration (predetermined concentration) of urea water to be used is 32.5%.

  The state diagram of FIG. 3 represents the freezing temperature line Ls and the saturation temperature line Ld at the urea concentration of urea water and the urea water temperature.

  Usually, urea water freezes at −11 ° C. when the concentration is 32.5% or more, and freezes at 0 ° C. when the concentration is 0% (water), and the freezing temperature at this concentration is frozen. It was set as the temperature line Ls. The broken line along the freezing temperature line Ls indicates a region of ± 3 ° C. with respect to the freezing temperature line Ls.

  The saturation temperature line Ld indicates the relationship between urea water concentration and urea water temperature based on urea solubility (40.0% at 0 ° C, 45.9% at 10 ° C, 51.9% at 20 ° C, 58% at 30 ° C). It showed in. A broken line along the saturation temperature line Ld indicates a region of ± 3 ° C. with respect to the saturation temperature line Ld.

  In FIG. 3, an initial concentration of 32.50% of commercially available urea water is set as a predetermined concentration, and a lower limit value A of an allowable normal concentration is set to, for example, 24%, and an upper limit value B is set to, for example, 48%. A case where it is determined that an abnormality other than (24 to 48%) will be described.

  In the conventional determination, when the urea water is not frozen with certainty including a measurement error with respect to the freezing temperature of −11 ° C., −5 ° C. is set as a determinable water temperature, and when the water temperature is equal to or higher than the determinable water temperature, The concentration of the urea water is determined. In this determination, when the water temperature is -5 ° C. or lower, the urea water concentration can be determined to be abnormal up to 24%. On the dark side, there is an inconvenience that an abnormality can be determined only up to 34% density.

  Therefore, in the present invention, when the concentration is lower than the predetermined concentration (32.5%), the freezing temperature (−11 ° C. to 0 ° C.) at the concentration (32.5 to 0%) based on the freezing temperature line Ls. If the temperature is higher than −5 ° C. (−6 ° C. to + 5 ° C.) and is not reliably frozen, and the lower limit value β can be determined, and the concentration is higher than the predetermined concentration (32.5%), the saturation temperature line Ld A temperature (−6 ° C. to + 35 ° C.) that is + 5 ° C. higher than the saturation temperature (−11 ° C. to 30 ° C.) at the concentration based on (32.5 to 58%) is stored as the lower limit determination value β.

  In the quality diagnosis of urea water, first, the concentration and temperature of the urea water are detected, and the above-described determinable lower limit β is individually set according to the detected concentration.

  Next, the detected temperature and the lower limit value β that can be determined according to the concentration are compared. If the detected temperature is equal to or higher than the lower limit value β that can be determined, a quality diagnosis of urea is performed based on the detected concentration. When the value falls below the lower limit value β that can be determined, the determination is not made.

  That is, for example, when the normal concentration range is 24 to 48%, on the side lower than the predetermined concentration, the freezing temperature of −8 ° C. at the normal concentration lower limit A (24%) is 3 A freezing temperature of -5 ° C, which is higher, is determined as a water temperature lower limit value β. When the concentration is 32.5%, -6 ° C can be determined. When the concentration is 0%, it is determined as + 5 ° C. Set to possible water temperature lower limit β.

  On the side higher than the predetermined concentration, 17 ° C., which is 3 ° C. higher than the saturation temperature of 14 ° C. at the normal concentration upper limit B (48%), which is not reliably deposited, is set as the determinable water temperature lower limit β and the concentration is 32. When it is 5%, −6 ° C. is set as the determinable water temperature lower limit value β, and when the concentration is 58%, 35 ° C. is set as the determinable water temperature lower limit value β.

  As a result, if the detected urea temperature is equal to or higher than the determinable water temperature lower limit β that does not reliably freeze on the low concentration side with respect to the predetermined concentration (32.5%), an appropriate concentration diagnosis can be performed and Misdiagnosis can be prevented by preventing the determination when the water temperature falls below the lower limit value β that can be determined.

  On the higher concentration side with respect to the predetermined concentration (32.5%), if the detected urea temperature is equal to or higher than the determinable water temperature lower limit β at which urea does not deposit reliably, an appropriate concentration diagnosis can be performed and precipitation Misdiagnosis can be prevented by preventing the determination when the water temperature is lower than the lower limit value β that can be determined.

  Next, the flow of the urea quality diagnosis system of the present invention will be described with reference to FIG.

  Diagnosis is started, and in step 1, a determinable water temperature lower limit value β is set from the detected urea water concentration and temperature, and in step 2, it is determined whether or not the detected temperature is equal to or greater than the determinable water temperature lower limit value β. If the detected temperature falls below the determinable water temperature lower limit β in the determination of step 2 (NO), the diagnosis is terminated by not determining in step 3.

  In step 2, when the detected temperature is equal to or higher than the determinable water temperature lower limit β, it is diagnosed in step 4 whether the urea water concentration is equal to or higher than the normal concentration lower limit A (concentration 24%), and the normal concentration lower limit A is set. When it falls below (NO), the abnormality determination is made at step 7, the urea injection is stopped at step 8, the warning lamp is turned on at step 8, and the diagnosis is finished.

  Next, in step 4, when the urea water concentration is equal to or higher than the normal concentration lower limit A (concentration 24%) (YES), it is diagnosed in step 5 whether the urea concentration is lower than the normal concentration upper limit B (concentration 48%). When the normal concentration upper limit B is exceeded (NO), the abnormality determination is made at step 7, the urea injection is stopped at step 8, the warning lamp is turned on at step 8, and the diagnosis is finished.

  If it is determined in step 5 that the urea concentration is equal to or lower than the normal concentration upper limit B (concentration 48%) (YES), normal determination is performed in step 6 and the diagnosis is terminated.

  In this way, by first setting the detectable water temperature lower limit β according to the detected urea concentration individually, diagnosis based on the urea concentration is performed without performing determination under urea freezing and urea saturation precipitation conditions. A reliable diagnosis can be made by performing.

  The control flow of FIG. 2 has explained the control in which the determination possible water temperature lower limit β is individually set according to the urea concentration and the diagnosis is performed by comparison with the detected temperature. Abnormal diagnosis when the normal concentration lower limit A (concentration 24%) is below and when the normal concentration upper limit B (concentration 48%) is exceeded is important in terms of control. Therefore, a control flow as simple control will be described.

  In this control flow, when the detected urea concentration exceeds the normal concentration lower limit value A (concentration 24%) and falls below the normal concentration upper limit value B, it is determined that the urea concentration is normal, and the normal concentration lower limit value A or lower or the normal concentration upper limit value. When the value is equal to or greater than B, the water temperature lower limit values βL and βH that can be determined at the normal concentration lower limit value A and the normal concentration upper limit value B are set. When the values βL and βH are greater than or equal to the values βL and βH, it is determined that there is an abnormality, and when the values are lower than the determinable water temperature lower limit values βL and βH, the quality determination is not performed, so

  The flow of this simple control will be described with reference to FIG.

  The diagnosis is started, and at step 1, it is determined whether or not the detected urea water concentration is equal to or lower than the normal concentration lower limit (for example, 24%) A. If the urea water concentration is equal to or higher than the normal concentration lower limit value A in step 1 (YES), it is determined in the next step 2 whether the urea water concentration is equal to or higher than the normal concentration upper limit value (for example, 48%) B. When it is less than or equal to the upper limit value B, normal determination is made at step 5, and the diagnosis is completed (return).

  When the concentration of urea water is lower than the normal concentration lower limit A in step 1 (NO), the detected urea water temperature is determined as βL ≦ urea water temperature in the next step 4, and βL (for example, −5) When the temperature is equal to or higher than (° C.), the abnormality is determined at step 6, urea injection is prohibited at step 6, and the warning lamp is turned on at step 7 to complete the diagnosis. If the determination at step 4 is less than βL (NO), the determination is terminated at step 9 without determination at step 9.

  Next, when the urea water concentration exceeds the normal concentration upper limit B in the determination of step 2 (NO), the detected urea water temperature is determined to be βH ≦ urea water temperature in the determination of step 3, and βH (for example, 17 ° C.) At this time (YES), abnormality determination is performed at step 6, urea injection prohibition 44 is performed at step 7, and a warning lamp is lit at step 8, and the diagnosis is terminated. Further, when the detected urea water temperature is lower than βH in the determination of step 3, the diagnosis is terminated as it is not determined in step 10.

  In the flow of FIG. 4, the urea water concentration range of 24 to 48% is judged to be normal unconditionally, and the detected temperature and the determinable water temperature lower limit values βL and βH are compared only when the concentration is outside the normal range. Thus, it is possible to make a simple abnormality determination by determining whether the abnormality is determined or not.

DESCRIPTION OF SYMBOLS 10 Exhaust pipe 11 SCR apparatus 12 Injection nozzle 15 Urea water 16 Urea tank 20 DCU
23 Urea sensor

Claims (4)

  In the urea quality diagnosis system that detects the concentration and temperature of urea water in the urea tank and diagnoses the quality of the urea water, the water temperature lower limit value that can be determined according to the concentration of urea water is individually set and detected urea Concentration quality judgment is performed when the water temperature is higher than the individually set lower limit value of the water temperature that can be determined, and the concentration quality is not determined when the water temperature is lower than the individually set lower limit value of the water temperature that can be determined. Urea quality diagnostic system characterized by   The urea quality diagnosis system according to claim 1, wherein the lower limit value of water temperature that can be determined when the detected concentration of urea water is higher than a predetermined concentration is set to a saturation temperature or higher at which urea precipitation does not occur at the normal concentration upper limit value of urea water. .   The urea quality diagnosis system according to claim 1, wherein the lower limit value of water temperature that can be determined when the detected concentration of urea water is lower than a predetermined concentration is set to be equal to or higher than a freezing temperature at which urea does not freeze.   The urea quality diagnosis system according to any one of claims 1 to 3, wherein when a concentration abnormality is diagnosed, urea injection is prohibited and a warning is given to the driver.

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