JP4291627B2 - Method for removing particulate matter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for removing particulate matter in an exhaust purification device.
[0002]
[Prior art]
Conventionally, the differential pressure before and after a particulate filter (hereinafter referred to as “filter”) that can collect particulate matter contained in the exhaust gas discharged from the engine body is detected. A deposition amount estimation method for estimating a total deposition amount of particulate matter on a filter based on pressure is known. Further, the particulate matter removal method for burning and removing the particulate matter before the total amount of the particulate matter estimated as described above becomes an amount that deteriorates the flow of the exhaust gas. Is known as well.
[0003]
As such a particulate matter removing method, for example, a method described in Patent Document 1 is known. In the method described in Patent Literature 1, the differential pressure across the muffler provided in the exhaust wake of the filter is detected simultaneously with another sensor while detecting the differential pressure across the filter with a sensor. Then, the flow rate of the exhaust gas flowing into the filter is calculated from the differential pressure across the muffler, and the total amount of particulate matter deposited on the filter is estimated from the flow rate of the exhaust gas and the differential pressure across the filter. . When the estimated total accumulation amount exceeds a predetermined amount, the filter is heated to remove particulate matter, and the flow resistance to the exhaust gas by the filter is prevented from increasing. Yes.
[0004]
[Patent Document 1]
Japanese Utility Model Publication No. 62-190841
[Patent Document 2]
Japanese Patent Application Laid-Open No. 07-189656
[0005]
[Problems to be solved by the invention]
By the way, the particulate matter includes a component insoluble in an organic solvent such as soot (hereinafter referred to as “soot”) and a component soluble in an organic solvent such as SOF (hereinafter referred to as “SOF”). The soot combustion temperature at which soot begins to burn is higher than the SOF combustion temperature at which SOF begins to combust. In the method described in Patent Document 1, particulate matter is removed by increasing the temperature of the filter without distinguishing between soot and SOF. Therefore, if it is determined that a large amount of particulate matter is deposited on the filter, a large amount of SOF having a low combustion temperature is deposited on the filter, and the filter is sufficiently deposited on the filter even if the temperature of the filter is not so high. Even when the particulate matter can be removed, the filter is always maintained at a temperature higher than the soot combustion temperature for a certain period of time, and fuel and energy are consumed wastefully.
[0006]
Therefore, an object of the present invention is to provide a particulate matter removing method for efficiently removing particulate matter deposited on a filter.
[0007]
[Means for Solving the Problems]
In order to solve the above-described problem, in the first invention, a filter capable of collecting particulate matter in exhaust gas, and when the total amount of particulate matter deposited on the filter exceeds a limit amount, the filter is used. In a method for removing particulate matter deposited on a filter such that the flow resistance against exhaust gas becomes greater than a certain value, SOF removal control is performed to raise the temperature of the filter below the soot combustion temperature and above the SOF combustion temperature. SOF removal control is executed when it is estimated that the amount of particulate matter newly deposited on the filter since the previous execution is equal to or greater than a predetermined deposition amount that is smaller than the limit deposition amount, Immediately after that, the total amount of particulate matter deposited on the filter is estimated, and if the estimated total amount of deposit is greater than or equal to the above limit deposit amount, the filter temperature is raised above the soot combustion temperature. That.
According to the first aspect of the invention, since the SOF accumulated on the filter is removed by the SOF removal control, and the total amount of particulate matter deposited on the filter is estimated, the estimated total deposition amount is The total deposition amount is shown. Then, only when the total amount of soot accumulation exceeds the limit accumulation amount, soot is removed by raising the temperature of the filter above the soot combustion temperature. Therefore, the number of times of raising the temperature of the filter to the soot combustion temperature is minimized. When the temperature of the filter is raised above the soot combustion temperature, a large amount of fuel and energy is consumed. Therefore, by reducing the number of times the filter is heated up to the soot combustion temperature, the amount of fuel and energy consumed can be reduced. Can do.
The “total deposition amount” indicates the total amount of particulate matter actually deposited on the filter, and “the amount of particulate matter newly deposited on the filter since the previous execution of the SOF removal control”. Is the amount of particulate matter that accumulates on the filter during two successive SOF removal controls.
[0008]
In a second aspect, in the first aspect, the amount of particulate matter newly deposited on the filter is estimated based on the operating time of the internal combustion engine.
According to the second invention, when the particulate matter is not forcibly removed, the total accumulation amount of the particulate matter on the filter is shorter than the operation time of the internal combustion engine required to reach the limit accumulation amount from almost zero. Every time the operation time elapses, that is, at a relatively short operation time interval, the SOF is removed. Therefore, the total amount of particulate matter deposited on the filter can always be maintained close to the total amount of soot accumulated on the filter, and the flow resistance to the exhaust gas by the filter can be kept relatively small.
[0009]
In the third invention, in the first or second invention, the total amount of the particulate matter deposited on the filter is estimated by supplying the mass flow rate of air flowing into the engine combustion chamber and the engine combustion chamber per unit time. Calculating the mass flow rate of the inflowing exhaust gas to the filter from the amount of fuel to be calculated, and calculating the volumetric flow rate of the inflowing exhaust gas to the filter from the mass flow rate of the inflowing exhaust gas and the temperature of the inflowing exhaust gas to the filter, This is done by calculating the total amount of particulate matter deposited from the calculated volume flow of the inflowing exhaust gas and the actual differential pressure across the filter.
According to the third invention, the mass flow rate of the air flowing into the engine combustion chamber, the amount of fuel supplied to the engine combustion chamber per unit time, and the temperature of the exhaust gas flowing into the filter are supplied to the filter. The volume flow rate of the inflowing exhaust gas is calculated. Here, the amount of fuel to be calculated is supplied to the engine combustion chamber directly from the fuel injection valve attached to the engine combustion chamber or indirectly from the fuel injection valve attached upstream of the engine combustion chamber. However, since the fuel is considered to be almost completely combusted or vaporized in the compression / expansion stroke of the internal combustion engine, the exhaust gas is completely in a gaseous state. The volume of exhaust gas in a gaseous state is determined based on its total mass and temperature. Therefore, the mass flow rate of the inflowing exhaust gas is obtained from the mass flow rate of the air flowing into the engine combustion chamber and the fuel amount supplied to the engine combustion chamber, and the obtained mass flow rate of the inflowing exhaust gas and the temperature of the inflowing exhaust gas By calculating the volume flow rate of the exhaust gas flowing into the filter from the filter, the volume flow rate of the exhaust gas flowing into the filter can be accurately calculated.
If the volumetric flow rate of the inflowing exhaust gas to the filter can be accurately calculated in this way, the influence of the flow rate of the inflowing exhaust gas on the differential pressure across the filter detected by a pressure sensor or the like can be eliminated. It becomes possible to accurately estimate the total amount of accumulated material.
[0010]
According to a fourth aspect, in the third aspect, the total accumulation amount of the particulate matter is calculated by calculating the differential pressure across the filter in a state where the particulate matter is not deposited on the filter for each volume flow rate of the inflowing exhaust gas. When the volumetric flow rate of the inflowing exhaust gas is equal to the calculated volumetric flow rate of the inflowing exhaust gas, the differential pressure before and after the filter in the state where the particulate matter is not accumulated and the differential between the front and back of the actual filter This is done by comparing the pressure.
According to the fourth invention, the estimation error of the total deposition amount caused by the manufacturing error or the like for each filter can be reduced by using the differential pressure before and after the filter in the state where the particulate matter is not deposited as a reference. .
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the particulate matter removing method of the present invention will be described with reference to the drawings. FIG. 1 shows a diesel-type compression self-ignition internal combustion engine in which the particulate matter removing method of the present invention is used. The present invention is also applicable to a spark ignition type internal combustion engine.
[0012]
Referring to FIG. 1, 1 is an engine body, 2 is a cylinder block, 3 is a cylinder head, 4 is a piston, 5 is a combustion chamber, 6 is an electrically controlled fuel injection valve, 7 is an intake valve, 8 is an intake port, 9 Is an exhaust valve, and 10 is an exhaust port. The intake port 8 is connected to a surge tank 12 via a corresponding intake branch pipe 11, and the surge tank 12 is connected to a compressor 15 of an exhaust turbocharger 14 via an intake duct 13.
[0013]
A throttle valve 17 driven by a step motor 16 is arranged in the intake duct 13, and a cooling device 18 for cooling intake air flowing in the intake duct 13 is arranged around the intake duct 13. In the internal combustion engine shown in FIG. 1, engine cooling water is guided into the cooling device 18 and the intake air is cooled by the engine cooling water. On the other hand, the exhaust port 10 is connected to an exhaust turbine 21 of an exhaust turbocharger 14 via an exhaust manifold 19 and an exhaust pipe 20, and an outlet of the exhaust turbine 21 is connected to a particulate filter (hereinafter referred to as “filter”) via an exhaust pipe 22. It is connected to a casing 24 having a built-in 23.
[0014]
The exhaust manifold 19 and the surge tank 12 are connected to each other via an exhaust gas recirculation (hereinafter referred to as “EGR”) passage 25, and an electrically controlled EGR control valve 26 is disposed in the EGR passage 25. Around the EGR passage 25, an EGR cooling device 27 for cooling the EGR gas flowing in the EGR passage 25 is disposed. In the internal combustion engine shown in FIG. 1, engine cooling water is guided into the EGR cooling device 27, and the EGR gas is cooled by the engine cooling water.
[0015]
On the other hand, each fuel injection valve 6 is connected to a fuel reservoir, so-called common rail 28, through a fuel supply pipe 6a. Fuel is supplied into the common rail 28 from an electrically controlled fuel pump 29 with variable discharge amount, and the fuel supplied into the common rail 28 is supplied to the fuel injection valve 6 through each fuel supply pipe 6a. A fuel pressure sensor 30 for detecting the fuel pressure in the common rail 28 is attached to the common rail 28, and a fuel pump 29 is used so that the fuel pressure in the common rail 28 becomes the target fuel pressure based on the output signal of the fuel pressure sensor 30. The discharge amount is controlled.
[0016]
The electronic control unit 40 is composed of a digital computer, and is connected to each other by a bidirectional bus 41. A ROM (read only memory) 42, a RAM (random access memory) 43, a CPU (microprocessor) 44, an input port 45 and an output port 46 are connected. It comprises.
[0017]
A load sensor 50 that generates an output voltage proportional to the amount of depression of the accelerator pedal 49 is connected to the accelerator pedal 49, and the output voltage of the load sensor 50 is input to the input port 45 via the corresponding AD converter 47. Further, the input port 45 is connected to a crank angle sensor 51 that generates an output pulse every time the crankshaft rotates, for example, 30 °. A differential pressure sensor 52 for detecting a differential pressure between the exhaust upstream and the exhaust downstream of the filter 23 (hereinafter referred to as “front-rear differential pressure”) is provided between the exhaust upstream side and the exhaust downstream side of the filter 23. Further, a temperature sensor 53 for detecting the temperature of exhaust gas flowing into the filter 23 is provided upstream of the exhaust of the filter 23. Further, an air flow meter 54 for detecting the mass flow rate of air flowing into the combustion chamber 5 is provided on the intake passage. The differential pressure sensor 52, the temperature sensor 53, and the air flow meter 54 are connected to the input port 45 via a corresponding AD converter 47. The output port 46 is connected to the fuel injection valve 6, the throttle valve driving step motor 16, the EGR control valve 26, and the fuel pump 29 via a corresponding drive circuit 48.
[0018]
By the way, in the internal combustion engine as described above, harmful particulate matter (particulate matter) is included in the exhaust gas, and the filter 23 prevents the particulate matter from being released into the atmosphere as it is. It is collected at. However, the filter 23 cannot collect particulate matter infinitely. If the particulate matter collected by the filter 23 increases, the filter 23 is clogged and the flow resistance against the exhaust gas by the filter 23 is increased. Becomes larger, and the pressure loss of the exhaust gas caused by the filter 23 becomes larger.
[0019]
For this reason, in many internal combustion engines, the total amount of particulate matter deposited on the filter 23 (hereinafter referred to as “total amount of particulate matter deposited on the filter 23”) is the amount of exhaust gas passing through the filter 23. When the flow resistance received by the filter 23 reaches a total accumulation amount (hereinafter referred to as a “limit accumulation amount”) that is greater than a certain value (for example, an extent that adversely affects the engine operating state), almost all Control is performed to raise the temperature of the filter 23 to a temperature at which the particulate matter is burned and removed, and to maintain the temperature for a predetermined time (hereinafter referred to as “filter regeneration control”). By executing such control, the filter 23 is returned again to a state where the particulate matter is hardly deposited. Therefore, in many internal combustion engines, the total accumulation amount of the particulate matter on the filter 23 is maintained below the above limit accumulation amount.
[0020]
In order to perform filter regeneration control, it is necessary to accurately estimate the total amount of particulate matter deposited on the filter 23. For example, when the estimated total deposition amount of particulate matter is smaller than the actual total deposition amount of particulate matter, the filter 23 may actually deposit more particulate matter than the limit deposition amount. . At this time, the flow resistance of the filter 23 becomes very large, and the temperature of the filter 23 becomes the durability of the filter due to the combustion heat of particulate matter accumulated in a large amount on the filter 23 in the filter regeneration control to be executed thereafter. The temperature may be exceeded, and the filter 23 may deteriorate. On the other hand, when the estimated total deposition amount of the particulate matter is larger than the actual total deposition amount of the particulate matter, the filter regeneration control is actually performed when the particulate matter that is less than the limit deposition amount of the filter 23 is deposited. Is executed. Usually, when the filter regeneration control is executed, energy consumption for increasing the temperature of the filter and the amount of fuel consumed increase, so it is preferable that the number of times of executing the filter regeneration control is small. As described above, if the filter regeneration control is executed in a state where the total accumulation amount of the particulate matter is smaller than the limit accumulation amount, the consumption amount of energy and fuel is unnecessarily increased. Therefore, it is necessary to estimate the total amount of particulate matter deposited on the filter 23 as accurately as possible.
[0021]
In many cases, the estimation of the total amount of particulate matter deposited on the filter 23 is performed based on the differential pressure across the filter 23. That is, when the differential pressure across the filter 23 increases, the total amount of particulate matter deposited increases, and when the differential pressure across the filter 23 decreases, the total amount of particulate matter deposited increases. It is running low.
[0022]
However, the differential pressure across the filter 23 varies not only according to the total amount of particulate matter deposited on the filter 23 but also according to the volume flow rate of exhaust gas flowing into the filter 23 (hereinafter referred to as “inflow exhaust gas”). To do. That is, even if the total amount of particulate matter deposited on the filter 23 is the same, if the volumetric flow rate of the inflowing exhaust gas increases, the differential pressure across the filter 23 increases and the volumetric flow rate of the inflowing exhaust gas decreases. In this case, the differential pressure across the filter 23 decreases.
[0023]
Therefore, the relationship among the differential pressure across the filter 23, the volume flow rate of the exhaust gas flowing into the filter 23, and the total amount of particulate matter deposited on the filter 23 is as shown in FIG. FIG. 2 (a) shows the relationship between the volume flow rate of the inflowing exhaust gas and the differential pressure across the filter 23. The solid lines a, b and c indicate the total amount of particulate matter deposited on the filter 23. The case of zero, the case of few, and the case of many are shown, respectively.
[0024]
Therefore, in the deposition amount estimation method of the present invention, the relationship between the volume flow rate of the inflowing exhaust gas, the differential pressure across the filter 23, and the total deposition amount of the particulate matter is experimentally obtained in advance and shown in FIG. Thus, it is stored in the ROM 42 of the ECU 40 as a map. When the internal combustion engine is actually used, the filter 23 is based on the differential pressure across the filter 23 detected by the differential pressure sensor 52, the volume flow rate calculated by a method described later, and a map stored in the ROM 42. The total amount of particulate matter deposited on the surface is estimated.
[0025]
Next, a method for calculating the volume flow rate of the inflowing exhaust gas will be described. First, the air flow meter 54 detects the mass flow rate of air (fresh air) flowing into the combustion chamber 5 (hereinafter referred to as “air mass flow rate”), and based on an injection command from the ECU 40 to the fuel injection valve 6. Then, the mass of fuel injected from all the fuel injection valves 6 into the combustion chamber 5 per unit time (hereinafter referred to as “fuel mass flow rate”) is calculated. Basically, only the above-described air and fuel are supplied to the combustion chamber 5 from the outside, so that the total mass of the substance supplied to the combustion chamber 5 per unit time is the mass flow rate of the air, the mass flow rate of the fuel, and so on. Is the total. According to the law of conservation of mass, the mass of the substance supplied to the combustion chamber 5 does not change before and after the combustion of the fuel. Therefore, the mass flow rate of the exhaust gas discharged from the combustion chamber 5 is the same as the mass flow rate of the air and the mass flow rate of the fuel. And the total.
[0026]
The exhaust gas volume flow rate can be calculated by dividing the exhaust gas mass flow rate obtained as described above by the exhaust gas density. Here, since almost all of the fuel supplied into the combustion chamber 5 is burned or vaporized in the combustion stroke of the internal combustion engine, almost all the exhaust gas discharged from the combustion chamber 5 is in a gaseous state. For this reason, the density of the exhaust gas is a function of the temperature of the exhaust gas.
[0027]
Here, in the internal combustion engine used in the present invention, the temperature of the exhaust gas flowing into the filter 23 is detected by the temperature sensor 53. Therefore, the density of the exhaust gas can be calculated from the detected temperature of the inflowing exhaust gas. Therefore, in the present invention, the exhaust gas volume flow rate is calculated based on the exhaust gas density thus calculated and the exhaust gas mass flow rate.
[0028]
When the volume flow rate of the exhaust gas is calculated in this way, the accuracy of the volume flow rate calculated is higher than when the volume flow rate of the exhaust gas is calculated based on, for example, the differential pressure across the muffler. That is, when the volume flow rate is calculated based on the differential pressure across the muffler, the volume flow rate cannot be calculated accurately if particulate matter is deposited on the muffler or the muffler is deformed. Such a problem does not occur when the volume flow rate of the exhaust gas is calculated by the above method.
[0029]
Conventionally, for example, a differential pressure sensor for detecting a differential pressure across the muffler must be provided in order to calculate the volume flow rate of the exhaust gas. On the other hand, in general, even in an internal combustion engine that does not execute the accumulation amount estimation method of the present invention, an air flow is determined in order to determine parameters relating to the operation of the internal combustion engine, such as a fuel injection amount, on the intake passage of most internal combustion engines. A meter is provided. Therefore, in the internal combustion engine that executes the accumulation amount estimation method of the present invention, it is not necessary to provide an additional device in the internal combustion engine only for executing the accumulation amount estimation method of the present invention. Can be reduced.
[0030]
In the above embodiment, the density of the inflowing exhaust gas to the filter 23 is calculated based only on the temperature of the inflowing exhaust gas. In addition to the temperature of the inflowing exhaust gas, the air-fuel ratio (combustion chamber) of the inflowing exhaust gas is calculated. The mass of the inflowing exhaust gas may be calculated based on the mass ratio of the air and the fuel supplied to 5) or the pressure of the inflowing exhaust gas, or both the air-fuel ratio and the pressure of the inflowing exhaust gas. By calculating the density of the inflowing exhaust gas in this way, the density of the inflowing exhaust gas can be calculated more accurately, and thus the total amount of particulate matter deposited on the filter 23 can be determined more accurately. The air-fuel ratio of the exhaust gas is calculated from the air mass flow rate and the fuel mass flow rate.
[0031]
Further, the method for calculating the volume flow rate of the inflowing exhaust gas shown in the above embodiment can be used similarly when the EGR gas is included in the intake gas flowing into the combustion chamber 5. This is because when the EGR gas is recirculated, that is, during the execution of the EGR control, the exhaust gas having a mass flow rate substantially the same as the mass flow rate of the EGR gas flowing into the combustion chamber 5 is re-entered into the intake passage as EGR gas. Therefore, even when the EGR control is being executed, the exhaust gas having a mass flow rate substantially the same as the mass flow rate of the air and fuel flowing into the combustion chamber 5 flows to the filter 23.
[0032]
Furthermore, in the said embodiment, the total deposition amount of a particulate matter is estimated based on the volume flow rate and the differential pressure before and after. On the other hand, the pressure difference (hereinafter referred to as “differential pressure difference”) between the differential pressure across the filter 23 and the differential pressure across the filter 23 actually detected in a state where particulate matter is not deposited on the filter. The total amount of particulate matter deposited may be estimated based on the differential pressure difference and the volume flow rate. That is, a map of the differential pressure difference and the volume flow rate is prepared in advance instead of the map of the volume flow rate and the differential pressure before and after. For example, the differential pressure across the filter 23 when the filter 23 is used for the first time after manufacture is detected and stored in the ROM 42 of the ECU 40. At the time of use, the differential pressure difference was calculated from the detected differential pressure across the filter 23 and the differential pressure before and after the filter 23 stored in the ROM 42 and corresponding to the detected volume flow rate. Based on the differential pressure difference and the detected volume flow rate, the total amount of particulate matter deposited on the filter 23 is estimated.
[0033]
By using the differential pressure across the filter 23 in a state where particulate matter is not deposited in this manner as a reference, a manufacturing error between the filters 23 relating to the differential pressure across the filter 23 when no particulate matter is deposited. Can be compensated.
[0034]
Next, a control routine of the accumulation amount estimation method of the present invention will be described with reference to the flowchart of FIG. First, in step 100, the mass flow rate Qma of the air flowing into the combustion chamber 5 is detected by the air flow meter 54, the fuel mass flow rate Qmf is calculated based on the injection command to the fuel injection valve 6, and the temperature sensor 53 performs filtering. The temperature Te of the exhaust gas flowing into the engine 23 is detected, and the differential pressure sensor 52 detects the differential pressure Pd across the filter 23. Next, at step 101, the exhaust gas mass flow rate Qme is calculated from the air mass flow rate Qma and the fuel mass flow rate Qmf detected at step 100. Next, in step 102, the exhaust gas volume flow rate Qve is calculated from the exhaust gas mass flow rate Qme calculated in step 101 and the inflowing exhaust gas temperature Te, and the process proceeds to step 103. In step 103, the total deposition amount Mp of the particulate matter on the filter 23 is obtained from the volume flow rate Qve of the exhaust gas calculated in step 102, the differential pressure Pd across the filter 23, and the map shown in FIG. And the control routine ends.
[0035]
By the way, the particulate matter is roughly classified into a component insoluble in an organic solvent such as soot (hereinafter referred to as “煤”) and a component soluble in an organic solvent such as a soluble organic material (SOF) ( Hereinafter, it is referred to as “SOF”. As a property of these components, the SOF combustion temperature at which SOF begins to burn is lower than the soot combustion temperature at which soot begins to burn. For example, the SOF combustion temperature is 250 ° C. to 300 ° C. or higher, and the soot combustion temperature is 500 ° C. to 600 ° C. or higher. Therefore, when removing the SOF accumulated on the filter 23, the temperature of the filter 23 may be lower than that when removing the soot accumulated on the filter 23. Therefore, in this case, the temperature of the filter 23 is increased. The consumption of fuel and energy used for the is very small.
[0036]
Conventionally, the total accumulation amount of the particulate matter on the filter 23 is estimated by summing the accumulation amounts of both soot and SOF, and the soot combustion temperature is reached based on the estimated total accumulation amount of the particulate matter. The temperature of the filter 23 was raised and maintained at that temperature to remove particulate matter deposited on the filter 23. In this case, even if a large amount of SOF is accumulated and the filter 23 is heated to the SOF combustion temperature, the same operation can be performed even when the SOF is burned and the particulate matter collecting ability of the filter 23 is recovered. Done.
[0037]
However, as described above, since the SOF combustion temperature is considerably lower than the soot combustion temperature, when the amount of fuel and energy used for raising the temperature of the filter 23 is taken into consideration, when a large amount of SOF is accumulated on the filter 23. It is preferable to raise the filter 23 to the SOF combustion temperature and burn the SOF to recover the particulate matter collecting ability of the filter 23. That is, it is preferable that the number of times of raising the temperature of the filter 23 to the soot combustion temperature is small. Therefore, in the present invention, the particulate matter deposited on the filter 23 is removed by the following method.
[0038]
In the particulate matter removal method of the present invention, the SOF is removed from the particulate matter by performing control to raise the temperature of the filter 23 to the SOF combustion temperature (hereinafter referred to as “SOF removal control”) by the temperature raising process. Later, the total deposition amount of the particulate matter on the filter 23 is estimated by the above-described deposition amount estimation method. In this case, the estimated total deposition amount of particulate matter indicates the total deposition amount of soot. Then, when the total accumulation amount of soot becomes equal to or greater than the above limit accumulation amount, control is performed to raise the temperature of the filter 23 to the soot combustion temperature (hereinafter referred to as “soot removal control”) by the temperature raising process. Then, the particulate matter deposited on the filter 23 is removed.
[0039]
Further, the SOF removal control is performed at relatively short predetermined operation time intervals. Here, the predetermined operation time interval is longer than the operation time required for the total accumulation amount of the particulate matter on the filter 23 to reach the limit accumulation amount from at least when the particulate matter is not forcibly removed. A short time interval.
[0040]
FIG. 4A shows the relationship between the operation time and the total amount of particulate matter deposited on the filter 23. Here, the solid line indicates the total amount of particulate matter including soot and SOF deposited on the filter 23, and the alternate long and short dash line indicates the amount of soot among the particulate matter deposited on the filter 23. ing.
[0041]
In FIG. 4A, the SOF removal control is performed every predetermined operation time interval Δt, and thus the SOF is removed every predetermined operation time interval. That is, the time t when the particulate matter is hardly deposited on the filter 23.₀T when a predetermined operation time interval Δt has elapsed since₁In addition, the SOF removal control is performed in which the temperature of the filter 23 is raised to the SOF combustion temperature by the temperature raising process and the temperature is maintained for such a time that the SOF accumulated on the filter 23 is removed. The time when the SOF accumulated on the filter 23 is removed (or the time when the SOF removal control is finished) t.₂Then, the total amount of particulate matter (ie, soot) deposited on the filter 23 is estimated.
[0042]
As can be seen from FIG.₂Since the total accumulation amount of soot has not reached the limit accumulation amount, the temperature raising process of the filter 23 is completed without raising the temperature of the filter 23 to the soot combustion temperature. Time t when the predetermined operation time interval Δt has elapsed_ThreeAgain, the temperature of the filter 23 is raised to the SOF combustion temperature by the temperature raising process. Such control is performed at time t._Three~ T₇The soot accumulates on the filter 23 as it is repeated at time t.₇Time t after the SOF removal control is executed and the SOF deposited on the filter 23 is removed.₈Further, if the total amount of particulate matter (that is, soot) deposited on the filter 23 is estimated, the total amount of soot accumulated is equal to or greater than the limit deposition amount. Therefore, time t₈, Soot removal control is executed, that is, the filter 23 is heated to the soot combustion temperature by further temperature raising processing, and soot accumulated on the filter 23 is combusted and removed.
[0043]
By removing the particulate matter deposited on the filter 23 in this way, the temperature of the filter 23 is raised to the soot combustion temperature only when the amount of soot accumulated on the filter 23 reaches the limit deposition amount. can do. Therefore, the number of times of raising the temperature of the filter 23 to the soot combustion temperature can be reduced, so that the consumption of fuel and energy can be reduced. In addition, since the consumption amount of fuel and energy when raising the temperature of the filter 23 to the SOF combustion temperature is very small, even if the temperature of the filter 23 is raised to the SOF combustion temperature several times as described above, The consumption of fuel and energy can be reduced.
[0044]
Next, the control routine of the particulate matter removal method of the present invention will be described with reference to the flowchart of FIG. First, in step 120, the counter value COUNT is obtained by adding 1 to the original counter COUNT value. Here, the counter represents the elapsed time, and indicates that the predetermined operation time has elapsed when the value COUNT of the counter becomes equal to or greater than the predetermined value a. Next, at step 121, it is determined whether or not the counter value COUNT is equal to or greater than the predetermined value a, that is, whether or not the predetermined operation time has elapsed, and it is determined that the counter value COUNT is smaller than the predetermined value a. If so, the control routine is terminated.
[0045]
On the other hand, if it is determined in step 121 that the counter value COUNT is greater than or equal to the predetermined value a, the process proceeds to step 122. In step 122, SOF removal control is executed. Next, in step 123, the total deposition amount Mp of the particulate matter on the filter 23 is estimated by the deposition amount estimation method described above. In step 124, it is determined whether or not the total deposition amount Mp estimated in step 123 is greater than or equal to a predetermined limit deposition amount Mpa, and it is determined that the total deposition amount Mp is less than the limit deposition amount Mpa. In step 125, the counter value COUNT is reset to zero, and the control routine is terminated.
[0046]
On the other hand, if it is determined in step 124 that the total deposition amount Mp is greater than or equal to the limit deposition amount Mpa, the process proceeds to step 126. In step 126, it is determined whether or not the soot removal control execution condition is satisfied. Here, the case where the soot removal control execution condition is satisfied includes the case where the filter 23 is likely to be raised to the soot combustion temperature, for example, the case where the internal combustion engine is operated at a high load and high rotation, and the like. It is done. If it is determined that the soot removal control execution condition is not satisfied, the process returns to step 126 again. On the other hand, if it is determined in step 126 that the soot removal control execution condition is satisfied, the routine proceeds to step 127, where soot removal control is executed. Next, at step 128, the counter value COUNT is reset to zero, and the control routine is terminated.
[0047]
In the particulate matter removal method of the present invention, as described above, the SOF removal control is executed at every predetermined operation time interval Δt. This advantage will be described with reference to FIG. FIG. 4B is a time chart of the total amount of particulate matter deposited on the filter 23 when the timing for executing the SOF removal control is determined based on the total amount of particulate matter deposited on the filter 23. As in FIG. 4A, the solid line indicates the total deposition amount of particulate matter containing soot and SOF, and the alternate long and short dash line indicates the total deposition amount of soot.
[0048]
In FIG. 4B, the SOF removal control is not executed until the total deposition amount of the particulate matter on the filter 23 reaches the reference deposition amount from a substantially zero state. Here, the reference deposition amount is an amount larger than the limit deposition amount and is a reference deposition amount for executing the SOF removal control. When the total accumulation amount of the particulate matter reaches the reference accumulation amount, SOF removal control is executed, the temperature of the filter 23 is raised to the SOF combustion temperature, and the volume of SOF in the filter 23 is removed. When the total deposition amount of the particulate matter immediately after removing the SOF, that is, the total deposition amount of soot is less than the limit deposition amount, soot removal control is not executed. When such control is repeated and the total deposition amount of the particulate matter immediately after the execution of the SOF removal control becomes equal to or greater than the limit deposition amount, the soot removal control is performed and the particulate matter is deposited on the filter 23. The traps that are present are removed.
[0049]
As can be seen by comparing FIG. 4 (a) and FIG. 4 (b), in the case of FIG. 4 (b), the SOF removal control is hardly executed while the total amount of accumulated soot is small. While the SOF removal control is executed at short operation time intervals after the total deposition amount increases, in the case of FIG. 4A, the SOF removal control is constantly performed regardless of the total deposition amount of soot. Is running. Therefore, when the SOF removal control is executed every predetermined operation time, the total deposition amount is maintained to be smaller on average than when the execution timing of the SOF removal control is determined based on the total deposition amount. Yes. That is, it can be seen that the pressure loss due to the filter 23 can be kept low when the particulate matter removal method of the present invention is executed. Note that the number of executions of the SOF removal control is almost the same between the case of FIG. 4A and the case of FIG. 4B. That is, the amount of fuel and energy consumed can be determined based on either the operating time or the amount of deposit if the operating time interval is appropriately set when determining the execution timing of the SOF removal control based on the operating time interval. It can be seen that there is almost no change even if the execution timing of the control is determined.
[0050]
In the above-described embodiment, the execution timing of the SOF removal control is determined based on the operation time interval. However, not the operation time interval but the travel distance of the vehicle on which the internal combustion engine is mounted, the accumulated rotation speed, and the above-described accumulation. The execution timing of the SOF removal control may be determined based on any parameter as long as it is a parameter that can estimate the amount of particulate matter deposited, such as an amount estimation method. It is preferable to execute the SOF removal control every time it is estimated that a predetermined amount of particulate matter has been newly deposited after the SOF removal control is executed. Here, the predetermined accumulation amount is an accumulation amount smaller than the above limit accumulation amount. For example, when travel distance is used as such a parameter, SOF removal control is executed for each predetermined travel distance. In this case, the predetermined travel distance is a travel shorter than the travel distance required until the total accumulation amount of the particulate matter on the filter 23 reaches the limit accumulation amount when the particulate matter is not forcibly removed. Distance.
[0051]
However, the determination of the execution timing of the SOF removal control is not based on the accumulation amount estimation method described above, but based on the operation time interval, travel distance, or integrated rotation speed (hereinafter referred to as “operation time interval, etc.”). preferable. The reason for this will be briefly described. When the accumulation amount on the filter 23 is estimated by the above-described accumulation amount estimation method, the calculation amount in the ECU 40 increases, and the calculation load on the CPU 44 increases. Therefore, the total accumulation amount by the above-described accumulation amount estimation method. It is preferable that the estimated number of times is small. On the other hand, when the accumulation amount is estimated based on the operation time interval, the travel distance, or the accumulated rotational speed, the CPU 44 is hardly subjected to a calculation load. Therefore, when determining the execution timing of the SOF removal control based on the operation time interval or the like, the estimation of the total deposition amount by the above-described deposition amount estimation method is only immediately after the end of the SOF removal control, and the calculation load on the CPU 44 is reduced. can do.
[0052]
Next, a method for the temperature raising process will be briefly described. In the present invention, the temperature raising process delays the timing of injecting the fuel into the combustion chamber of the internal combustion engine, or injects a small amount of fuel after injecting the fuel for driving the engine into the combustion chamber 5 of the internal combustion engine, An electric heater or a glow plug is provided upstream of the filter 23, and the electric heater or the glow plug is operated to raise the temperature of the exhaust gas. Further, when an ignition plug for igniting fuel is provided in the combustion chamber, the temperature raising process is also performed by increasing the temperature of the exhaust gas by delaying the ignition timing of the fuel by the ignition plug. be able to.
[0053]
Alternatively, after a fuel for driving the engine is injected into the combustion chamber of the internal combustion engine, a small amount of fuel is injected, and the fuel is discharged as it is without being burned, or fuel is added to the exhaust gas upstream of the filter 23 The temperature raising process can also be performed by providing a device for performing the above operation, adding fuel to the exhaust gas from this device, supplying the fuel to the filter 23, and combusting the fuel in the filter 23. .
[0054]
In addition, the filter 23 used in the present invention may be a filter having the ability to remove particulate matter without raising the temperature of the filter 23 to the above-described SOF combustion temperature or soot combustion temperature. Hereinafter, the particulate matter removing action of the filter will be described.
[0055]
In FIG. 6, a case where platinum (Pt) is used as a noble metal catalyst and potassium (K) is used as an active oxygen generator will be described as an example. However, other noble metals, alkali metals, alkaline earth metals, rare earths, Even if a transition metal is used, the same particulate matter removing action is performed.
[0056]
6A and 6B schematically show enlarged views of the surface of the carrier layer formed on the surface of the partition wall of the filter 23 and on the pore surface of the partition wall. 6A and 6B, reference numeral 60 denotes platinum particles, and reference numeral 61 denotes a carrier layer containing an active oxygen generator such as potassium.
[0057]
First, when the ratio of air and fuel supplied to the intake passage and the combustion chamber is referred to as the air-fuel ratio of the exhaust gas, if the air-fuel ratio of the exhaust gas flowing into the filter 23 is lean,_X, Especially NO and NO₂NO is generated in the exhaust gas._xIt is included. Thus, the filter 22 has excess oxygen and NO._XExhaust gas containing
[0058]
When the exhaust gas flows into the filter 23, the oxygen in the exhaust gas becomes O as shown in FIG.₂ ^-Or O^2-It adheres to the surface of platinum in the form of On the other hand, NO in the exhaust gas is O on the surface of platinum.₂ ^-Or O^2-Reacts with NO₂(2NO + O₂→ 2NO₂). Then the generated NO₂And NO in exhaust gas₂Is oxidized on platinum and absorbed by the active oxygen generator 61, and nitrate ions (NO) as shown in FIG._Three ^-) In the form of active oxygen generator 61 and nitrate (KNO)_Three) Is generated. That is, oxygen in the exhaust gas is held in the active oxygen generator in the form of nitrate ions.
[0059]
By the way, in the combustion chamber, particulate matter mainly composed of carbon (C) is generated. Therefore, these particulate matters are contained in the exhaust gas. Particulate matter in the exhaust gas contacts and adheres to the surface of the active oxygen generator 61 as shown in FIG. 6B when the exhaust gas flows through the filter 23.
[0060]
When the particulate matter 62 adheres on the active oxygen generating agent 61, a concentration difference is generated between the surface of the active oxygen generating agent 61 and the inside thereof. Oxygen is held in the form of nitrate ions in the active oxygen generator 61, and the held oxygen tends to move toward the contact surface between the particulate matter 62 and the active oxygen generator 61. As a result, nitrate (KNO) formed in the active oxygen generator 62_Three) Is decomposed into K, O, and NO, and O goes to the surface of the active oxygen generator 61 while NO is released from the active oxygen generator 61 to the outside. The NO released to the outside in this way is oxidized on the downstream platinum by the mechanism described above, and is again held in the form of nitrate ions in the active oxygen generator 61.
[0061]
By the way, O toward the contact surface between the particulate matter 62 and the active oxygen generator 61 is nitrate (KNO)._ThreeSince the oxygen is decomposed from a compound such as), it is an active oxygen having unpaired electrons and extremely high reactivity. When these active oxygens come into contact with the particulate matter 62, the particulate matter 62 is oxidized without emitting a luminous flame within a short time (several seconds to several tens of minutes), and the particulate matter 62 disappears completely. Accordingly, the particulate matter 62 is oxidized and removed in this manner, and the particulate matter 62 is difficult to deposit on the filter 23.
[0062]
【The invention's effect】
According to the particulate matter removal method of the present invention, the consumption of fuel and energy can be suppressed by reducing the number of times the filter is heated to the soot combustion temperature, and as a result, the particles deposited on the filter The particulate matter can be efficiently removed.
[0063]
According to the third and fourth inventions, it is possible to accurately estimate the flow rate of the inflowing exhaust gas and accurately estimate the total deposition amount of the particulate matter.
[Brief description of the drawings]
FIG. 1 is a diagram showing an entire internal combustion engine that executes a particulate matter removal method of the present invention.
FIG. 2 is a diagram showing the relationship among the volume flow rate of inflowing exhaust gas, the differential pressure across the filter, and the total amount of particulate matter deposited.
FIG. 3 is a flowchart of a deposition amount estimation method according to the present invention.
FIG. 4 is a time chart of the total amount of particulate matter deposited on the filter.
FIG. 5 is a flowchart of the particulate matter removal method of the present invention.
FIG. 6 is a view for explaining the particulate matter removing action of the filter used in the present invention.
[Explanation of symbols]
5 ... Combustion chamber
6 ... Fuel injection valve
23 ... Particulate filter (filter)
24 ... casing
40. Electronic control unit (ECU)
52. Differential pressure sensor
53 ... Temperature sensor
54 ... Air flow meter

Claims (4)

A particulate filter capable of collecting particulate matter in exhaust gas, and when the total amount of particulate matter deposited on the particulate filter exceeds the limit deposition amount, the flow resistance against the exhaust gas by the particulate filter is a constant value. In a method for removing particulate matter deposited on a particulate filter that is larger than the above,
The amount of particulate matter newly deposited on the particulate filter since the previous execution of soluble organic matter removal control that raises the temperature of the particulate filter below the soot combustion temperature and above the soluble organic matter combustion temperature is the above limit. Soluble organic substance removal control is executed when it is estimated that the amount exceeds a predetermined amount less than the predetermined amount, and immediately after that, the total amount of particulate matter deposited on the particulate filter is estimated. And the particulate matter removal method which raises the temperature of a particulate filter to the soot combustion temperature or more when the estimated total accumulation amount is more than the said limit accumulation amount. The method for removing particulate matter according to claim 1, wherein the amount of particulate matter newly deposited on the particulate filter is estimated based on an operation time of the internal combustion engine. The estimation of the total amount of particulate matter deposited on the particulate filter is based on the mass flow rate of air flowing into the engine combustion chamber and the amount of fuel supplied to the engine combustion chamber per unit time. The mass flow rate of the gas is calculated, the volume flow rate of the inflow exhaust gas to the particulate filter is calculated from the mass flow rate of the inflow exhaust gas and the temperature of the inflow exhaust gas to the particulate filter, and the calculated inflow exhaust gas The particulate matter removal method according to claim 1 or 2, wherein the particulate matter removal method is performed by calculating a total deposition amount of the particulate matter from a volume flow rate of the particulate matter and an actual differential pressure across the particulate filter. The calculation of the total accumulation amount of the particulate matter is performed by detecting the differential pressure before and after the particulate filter in a state where the particulate matter is not deposited on the particulate filter for each volume flow rate of the inflowing exhaust gas. When the volumetric flow rate is the calculated volumetric flow rate of the inflowing exhaust gas, the differential pressure before and after the particulate filter when no particulate matter is deposited is compared with the differential pressure before and after the actual particulate filter. The particulate matter removing method according to claim 3, wherein the particulate matter removing method is performed.

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