JP3217130B2 - Engine exhaust purification device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engine exhaust purification device.

[0002]

2. Description of the Related Art Generally, a catalyst for purifying exhaust gas is provided in an exhaust passage of an engine. There have been various proposals for an exhaust purification device using such a catalyst. For example, Japanese Utility Model Application Laid-Open No. 61-49014 discloses a method for preventing the catalyst from being clogged by particulates in exhaust gas. An electric heater is provided immediately upstream of the filter, and when the pressure difference between the upstream side and the downstream side of the filter becomes large or when the exhaust gas temperature is low, the electric heater is operated to heat the exhaust gas, It is described that the particulates are burned off.

In Japanese Utility Model Laid-Open Publication No. 2-94316,
It describes that a heater and a catalyst temperature sensor that emit far-infrared rays by heating with a resistance heating body are attached to a catalyst body, and when the catalyst temperature is low, the heater is operated to raise the temperature of the catalyst to an activation temperature.

[0004]

The above-described technique of heating the catalyst body with a heater is useful because the catalyst can be quickly activated, but it takes time for the catalyst temperature to rise to a predetermined activation temperature. There's a problem. That is, a large-capacity catalyst is required to purify the exhaust gas of the engine, and therefore, its heat capacity is usually large. Therefore, at the time of cold start of the engine, it takes time for the temperature of the catalyst to rise, and the amount of unpurified exhaust gas emitted before the catalyst reaches its activation temperature increases.

On the other hand, instead of providing one large-capacity catalyst in the exhaust passage, the catalyst is divided into two catalysts on the upstream and downstream sides of the exhaust passage to make the catalyst capacity relatively small. By providing the heating means in the upstream catalyst, the time required for activating the catalyst may be reduced. In this case, the heating is controlled while detecting the temperature of the upstream catalyst to be heated.

However, it is not known whether the downstream catalyst has reached the desired activation temperature. Therefore, when the downstream catalyst is indirectly heated to the desired activation temperature by heating the upstream catalyst, it is likely to result in excessive heating of the upstream catalyst. This is disadvantageous in terms of power savings.

[0007]

SUMMARY OF THE INVENTION The present invention provides
In order to solve such a problem, the upstream catalyst is directly heated by the heating means. In this case, the catalyst to be subjected to temperature control is changed based on the temperature of the downstream catalyst and the upstream catalyst and the downstream catalyst. The solution is achieved by switching between. Hereinafter, each means for solving the above problems will be described.

[0008] First means (Claim 1) and its operation-A first means is provided with a first catalyst for purifying exhaust gas in an exhaust passage of an engine, and a first catalyst in the exhaust passage. An exhaust purification device for an engine, wherein a second catalyst for purifying exhaust gas is provided upstream of the first catalyst, and the second catalyst is provided with electric heating means for heating the second catalyst. First temperature detecting means for detecting the temperature of the second catalyst, second temperature detecting means for detecting the temperature of the second catalyst, and the temperature of the first catalyst detected by the first temperature detecting means reaches a predetermined activation temperature Previously, based on the temperature of the second catalyst detected by the second temperature detecting means, the operation of the heating means is controlled so that the second catalyst reaches the target temperature, and the temperature of the first catalyst is reduced to the active level. After reaching the temperature , the first Control means for controlling the operation of the heating means so that the catalyst has a target temperature, wherein the target temperature of the first catalyst is the active temperature and lower than the target temperature of the second catalyst. And

The above catalyst may be a three-way catalyst,
A so-called NOx purification catalyst which is effective for purification of NOx (nitrogen oxide) at a lean air-fuel ratio may be used. In addition, the heating means is limited to an electric means because its operation is easily controlled. Also,
Even if the first catalyst and the second catalyst are loaded in separate containers and arranged on the downstream side and the upstream side, respectively, the downstream side and the upstream side are separated by a gap in the same container. May be loaded so as to be located at a position.

In the above means, the first catalyst on the downstream side is heated by the transfer of heat from the second catalyst located on the upstream side, and the temperature of the first catalyst can be increased. In particular, after the upstream second catalyst has reached the activation temperature,
Since the exhaust gas heated by the heat of the catalytic reaction flows to the first catalyst on the downstream side, the temperature of the first catalyst can be quickly raised.

In this means, the operation of the heating means is controlled based on the temperature of the second catalyst until the first catalyst reaches a predetermined activation temperature , so that the temperature of the second catalyst rises excessively. , The temperature of the second catalyst can be raised to the target temperature. That is, if the operation of the heating means is controlled based on the temperature of the downstream first catalyst from the beginning, it is possible to raise the temperature of the first catalyst early, but the upstream side directly heated by the heating means Although there is a concern that the temperature of the second catalyst may abnormally rise, such a situation can be avoided by this means.

After the first catalyst has reached the above-mentioned activation temperature , the operation of the heating means is controlled based on the temperature of the first catalyst. Electric power can be saved by avoiding unnecessary heating of the catalyst. That is, since the target temperature of the downstream first catalyst is lower than the target temperature of the upstream second catalyst, if the state in which the upstream second catalyst is subjected to the temperature control is continued, the second catalyst There is a concern that the temperature of the downstream first catalyst may rise above the target activation temperature due to the heat transfer from the first catalyst, but after the first catalyst reaches the activation temperature , the target of the temperature control is changed to the first activation temperature . Since switching to the catalyst is performed, it is possible to avoid an excessive increase in the temperature of the first catalyst and to avoid unnecessary heating of the second catalyst.

[0013] Further, since the target temperature of the first catalyst is lower than the target temperature of the second catalyst, if the second catalyst is heated by the heating means to reach the target temperature, the temperature of the second catalyst is reduced. The first catalyst heated by the heat transfer reaches the target temperature quickly. Therefore, it is possible to quickly shift from the temperature control of the second catalyst to the temperature control of the first catalyst, which is advantageous in saving electric power by avoiding unnecessary heating of the second catalyst. Further, even after shifting to the temperature control of the first catalyst, the second catalyst is heated by the heating means. However, since the target temperature is high, the temperature of the second catalyst may rise excessively beyond the target temperature. Is avoided, which is advantageous for preventing thermal deterioration of the second catalyst.

-Second means (Claim 2) and its operation-The second means comprises a first catalyst and a second catalyst, similarly to the first means.
On the premise of an exhaust gas purification device for an engine having a heating means for heating the catalyst and the second catalyst, a first temperature detection means for detecting the temperature of the first catalyst and a second temperature detection means for detecting the temperature of the second catalyst Before the temperature of the first catalyst detected by the first temperature detecting means reaches a predetermined activation temperature, a second temperature detected by the second temperature detecting means is determined.
Based on the temperature of the catalyst, the operation of the heating unit is feedback-controlled so that the second catalyst reaches the target temperature. After the temperature of the first catalyst reaches the activation temperature, the first catalyst is activated.
Control means for performing feedback control of the operation of the heating means based on the temperature of the first catalyst detected by the temperature detection means so that the first catalyst reaches the target temperature ;
The target temperature of the first catalyst is the activation temperature and
It is characterized in that it is lower than the target temperature of the second catalyst .

In this means, the operation of the heating means is controlled based on the temperature of the second catalyst until the first catalyst reaches the activation temperature, so that the temperature of the second catalyst is prevented from excessively increasing. The second catalyst can be heated to the desired activation temperature. That is, when the operation of the heating means is controlled based on the temperature of the first catalyst on the downstream side from the beginning, the first
Although it is possible to raise the temperature of the catalyst early, there is a concern that the temperature of the upstream second catalyst directly heated by the heating means may abnormally increase. Can be.

After the first catalyst has reached the activation temperature, the operation of the heating means is controlled based on the temperature of the first catalyst.
The target temperature of the first catalyst is the above-mentioned activation temperature, and
Since the temperature is lower than the target temperature of the second catalyst, an excessive rise in the temperature of the first catalyst is avoided as in the first means described above.
It is Rukoto, it can save power by avoiding wasteful heat the second catalyst further second catalyst
Temperature will not rise excessively beyond its target temperature.
This is advantageous for preventing thermal degradation of the second catalyst .

-Third means (Claim 3) and its operation- The third means reduces the capacity of the second catalyst directly heated by the heating means in each of the above means to that of the first catalyst on the downstream side. The feature is that it is smaller. In other words, this is advantageous in increasing the temperature of the second catalyst early,
As a result, the emission of unpurified exhaust gas during cold start of the engine can be suppressed.

-Fourth means (Claim 4) and its operation-The fourth means relates to a type of catalyst suitable for each of the above means, and the second catalyst is at a lower temperature than the first catalyst. It is characterized in that it is a low-temperature active catalyst that exhibits activity.

In this case, for example, in a three-way catalyst, a catalyst containing platinum, palladium and cerium as a catalyst component is employed as a first catalyst, and a catalyst containing barium in addition to platinum, palladium and cerium as a second catalyst. It is preferable to employ In this case, the second catalyst is a low-temperature active catalyst that exhibits activity at a lower temperature than the first catalyst. Furthermore, when the second catalyst contains zirconium in addition to the cerium and barium, the heat resistance of the second catalyst can be improved. Also,
As the carrier, an alumina pellet carrier, a monolithic monolith carrier made of cordierite coated with alumina, and a carrier using a metal foil honeycomb carrier can be appropriately employed.

However, in this means, since the second catalyst on the upstream side is active at a low temperature, it is advantageous in that the temperature of the second catalyst is quickly raised to the activation temperature to prevent the emission of unpurified exhaust gas. become.

Further, as described above, if the second catalyst is made to have high heat resistance, it becomes possible to heat the second catalyst to a relatively high temperature. It will be advantageous.

[0022]

Therefore, according to the first means, the first catalyst for purifying exhaust gas is provided in the exhaust passage of the engine, and the first catalyst is provided with electric heating means upstream of the first catalyst. Before the temperature of the first catalyst reaches the predetermined activation temperature , the second catalyst is set so as to reach the target temperature, and after the temperature of the first catalyst reaches the activation temperature. Comprises control means for controlling the operation of the heating means so that the first catalyst has a target temperature corresponding to the activation temperature thereof , and the target temperature of the first catalyst is higher than the target temperature of the first catalyst. Since the temperature of the second catalyst is lower than the target temperature of the second catalyst, the temperature of the second catalyst can be raised to a desired activation temperature while preventing the temperature of the second catalyst from excessively rising, and the first catalyst can be heated to a predetermined temperature. To avoid unnecessary heating of the second catalyst after reaching Can save to, it is possible to prevent a further deterioration of the second catalyst.

According to the second means, before the temperature of the first catalyst reaches the predetermined activation temperature, the temperature of the second catalyst is set to the target temperature, and the temperature of the first catalyst is set to the target temperature. Activity
After the neutral temperature has been reached, the first catalyst is allowed to reach its activation temperature.
Applicable target temperature (lower than the target temperature of the second catalyst)
Feed the operation of the above heating means so that
Since the back control is performed, it is possible to raise the temperature of the second catalyst to a desired activation temperature while preventing an excessive rise in the temperature of the second catalyst, and to perform the second control after the first catalyst reaches a predetermined temperature. (2) Electric power can be saved by avoiding unnecessary heating of the catalyst, and furthermore, deterioration of the second catalyst is prevented.
It is Ru can.

According to the third means, since the capacity of the second catalyst directly heated by the heating means is made smaller than that of the first catalyst on the downstream side, the temperature of the second catalyst can be raised quickly. Emission of unpurified exhaust gas can be suppressed.

According to the fourth means, since the second catalyst is a low-temperature active catalyst exhibiting activity at a lower temperature than the first catalyst, the temperature of the second catalyst is quickly raised to the activation temperature. As a result, the emission of unpurified exhaust gas can be prevented.

[0026]

Embodiments of the present invention will be described below with reference to the drawings.

-Overall Configuration- FIG. 1 shows the overall configuration of an engine exhaust gas purification apparatus. In the figure, 1 is an engine body, 2 is an intake passage,
3 is an exhaust passage. In the intake passage 2, an air cleaner 4, an air flow sensor 5, a throttle valve 6, and a surge tank 7 are provided in this order from the upstream side. In the exhaust passage 3, a first catalyst 8 as a main catalyst is provided, and a second catalyst 9 as a pre-installed catalyst with a heater is provided upstream of the first catalyst 8. The catalysts 8 and 9 are provided with first and second temperature detecting means 10 and 11 for detecting the respective catalyst temperatures. Further, an O ₂ sensor 20 is provided upstream of the second catalyst 9.

Each of the first and second catalysts 8 and 9 is a three-way catalyst. The first catalyst 8 contains cerium as a catalyst component. The second catalyst 9 is a low-temperature active catalyst having high heat resistance and containing barium and zirconium as catalyst components in addition to cerium. Both catalysts 8 and 9 are formed by integrally coating a monolithic carrier made of cordierite with the above-mentioned catalyst component by alumina coating. The capacity of the first catalyst 8 as the main catalyst is twice as large as that of the second catalyst.

A secondary air supply passage 12 extends from a downstream portion of the filter 4a of the air cleaner 4 to a portion of the exhaust passage 3 between the O ₂ sensor 20 and the pre-heater catalyst 9. In the secondary air supply passage 12, an air pump 13, an air cut valve 14, and a check valve 15 are provided in this order from the upstream side. The operating pressure of the air cut valve 14 is the negative pressure of the intake air of the engine. Therefore, a negative pressure extraction passage 16 extends from the surge tank 7 to the air cut valve 14, and a three-way solenoid is connected to the negative pressure extraction passage 16. A valve 17 is provided.

In this embodiment, the secondary air is mainly used for feedback control of the inflow air-fuel ratio of the catalysts 8 and 9. That is, the operation of the three-way solenoid valve 17 is controlled by the control unit 18 using a microcomputer using the O ₂ sensor 20 as a signal source.

The heater in the heater-equipped second catalyst 9 is an electric heater using a battery 19 as a power source.
8 controls the energization. This energization control is performed using the intake air temperature sensor of the engine, the engine cooling water temperature sensor, the exhaust gas temperature sensor, the starter switch of the engine, the catalyst temperature sensors 10, 11 and the like as signal sources. Hereinafter, the energization control means will be described.

-Electrification control means- The configuration of this embodiment is shown in FIG. In the figure, reference numeral 21 denotes an energization control means, based on the temperature T1 of the first catalyst 8 detected by the first temperature detection means 10,
The first controller 22 for feedback-controlling the operation of the heating means (the electric heater) 25 so that the catalyst 8 reaches the target temperature T1o, and the temperature T2 of the second catalyst 9 detected by the second temperature detecting means 11 The second control unit 23 performs feedback control of the operation of the heating unit 25 so that the second catalyst 9 reaches the target temperature T2o based on the control, and controls the first control unit 22 and the second control unit 23. And a control switching unit 24 for switching.

The control switching section 24 determines that the temperature T1 of the first catalyst 8 is equal to a predetermined activation temperature (the target temperature in the case of the present embodiment) T
Before the temperature reaches 1o, the second control unit 23 executes the control. After the temperature T1 of the first catalyst 8 reaches the activation temperature T1o, the first control unit 22 executes the control. Perform switching. Further, the target temperature T1o of the first catalyst 8 and the target temperature T2o of the second catalyst 9 have a relationship of T1o <T2o, for example, T1o = 350 ° C. and T2o = 500 ° C. The start and end of the energization control are performed by the start / end determination unit 26.

FIG. 3 is a flow chart showing the specific contents of the energization control. The above-mentioned intake air temperature, cooling water temperature, exhaust gas temperature, etc. at the start of the start of the engine are read by the start / end determining means 26, and when all are below a predetermined value, the starter SW (starter switch) is turned on. In this case, the energization control is started (steps S1 to S
3). The start / end determining means 26 turns on the energization timer at the same time as the control starts. This energization timer is for terminating the energization control, and the set time is determined by experimentally obtaining the time during which the catalyst 8 can maintain the activation temperature without operating the heating means 25. ing.

When the start / end determination means 26 determines that the energization control has been started, the control switching section 24 controls the temperature T1 of the first catalyst 8 detected by the first temperature detection means 10 (FIG. 4).
Until the second temperature reaches the target temperature T1o (feedback control).
Is executed (steps S4 and S5). That is, the second
Based on the temperature T2 of the second catalyst 9 detected by the second temperature detecting means 11, the controller 23 turns on the power supply if the temperature T2 is lower than the target temperature T2o, and if the temperature T2 is higher than the target temperature T2o. If there is, energization control to turn off energization is executed (see the solid line in FIG. 4).

In this case, since the second catalyst 9 is active at a low temperature, the activity is developed before reaching the target temperature T2o (in other words, before reaching the target temperature T1o of the first catalyst 8), and the exhaust gas is exhausted. Start purification. Also, the second catalyst 9
Since the capacity is small, the target temperature T2o is reached early and a high purification rate is obtained, which is advantageous in preventing discharge of unpurified exhaust gas during cold start of the engine. Further, in the case of the energization control, since the second catalyst 9 is prevented from greatly exceeding the target temperature T2o, there is no problem of thermal deterioration of the catalyst.

Further, since the second catalyst 9 has high heat resistance, even if the target temperature T2o is high, it is possible to purify the exhaust gas without deterioration even if the target temperature T2o is high.
Since 2o can be increased, it is advantageous in indirectly increasing the temperature of the first catalyst 8 quickly.

When the temperature T1 of the first catalyst 8 detected by the first temperature detecting means 10 has reached the target temperature T1o, the first control unit 22 replaces the control of the second control unit 23 by turning on the power. Control (feedback control) is executed (step S4 → S6). That is, based on the temperature T1 of the first catalyst 9 detected by the first temperature detecting means 10, the first control unit 22 sets the temperature T1 to the target temperature T1.
If the temperature is less than 1o, the energization is turned on. If the temperature T1 is equal to or higher than the target temperature T1o, the energization control is executed to turn off the energization.

As a result, as shown by the broken line in FIG. 4, the temperature T1 of the first catalyst 8 is prevented from rising and falling along the target temperature T1o, and from being significantly higher than the target temperature T1o or, conversely, significantly lower than the target temperature T1o. It is. In other words, the first catalyst 8 can be maintained near the target temperature T1o while directly heating the second catalyst 9, which is advantageous in increasing the purification rate of the exhaust gas. When the temperature of the catalyst 8 has reached the target temperature T10, there is no need to heat the second catalyst 9 needlessly, which is advantageous in saving power.

When the set time of the energization timer elapses, it is determined that the first catalyst 8 can maintain the activation temperature without the operation of the heating means 25, and the energization control is ended by the start / end determination means 26 ( Steps S7 and S8).

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of an exhaust gas purification device for an engine.

FIG. 2 is a block diagram showing a configuration of an energization control unit.

FIG. 3 is a graph showing a change over time in catalyst temperature.

FIG. 4 is a flowchart of energization control.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Engine main body 3 Exhaust passage 8 1st catalyst 9 2nd catalyst 10 1st temperature detection means 11 2nd temperature detection means 18 control unit 19 battery 21 conduction control means 22 1st control part 23 2nd control part 24 control switching part 25 Heating means

────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Satoru Kawazoe 3-1, Shinchi, Fuchu-cho, Aki-gun, Hiroshima Prefecture Inside Mazda Co., Ltd. (56) References JP-A-5-10117 (JP, A) (58) Survey Field (Int.Cl. ⁷ , DB name) F01N 3/20 F01N 3/24

Claims (4)

(57) [Claims] A first catalyst for purifying exhaust gas is provided in an exhaust passage of an engine, and a second catalyst for purifying exhaust gas is provided in a portion of the exhaust passage upstream of the first catalyst. In an exhaust gas purifying apparatus for an engine, wherein an electric heating means for heating the second catalyst is provided on the second catalyst, a first temperature detecting means for detecting a temperature of the first catalyst, and a temperature detecting means for detecting a temperature of the second catalyst. Before the temperature of the first catalyst detected by the first temperature detecting means reaches a predetermined activation temperature, based on the temperature of the second catalyst detected by the second temperature detecting means. The operation of the heating means is controlled so that the second catalyst reaches the target temperature. After the temperature of the first catalyst reaches the activation temperature , the heating is performed so that the first catalyst reaches the target temperature. Control the operation of the means And a that control means, the target temperature of the first catalyst, the exhaust gas purifying apparatus for an engine, characterized in that lower than the target temperature of the active temperature and is and upper <br/> Symbol second catalyst. 2. A first catalyst for purifying exhaust gas is provided in an exhaust passage of the engine, and a second catalyst for purifying exhaust gas is provided in a portion of the exhaust passage upstream of the first catalyst. In an exhaust gas purifying apparatus for an engine, wherein an electric heating means for heating the second catalyst is provided on the second catalyst, a first temperature detecting means for detecting a temperature of the first catalyst, and a temperature detecting means for detecting a temperature of the second catalyst. Before the temperature of the first catalyst detected by the first temperature detecting means reaches a predetermined activation temperature, based on the temperature of the second catalyst detected by the second temperature detecting means. The feedback control of the operation of the heating means is performed so that the second catalyst reaches the target temperature. After the temperature of the first catalyst reaches the activation temperature, the first temperature detected by the first temperature detection means is detected. Touch And control means for said first catalyst is a feedback control operation of the heating means so that the target temperature based on the temperature, the target temperature of the first catalyst, and the upper is the active temperature
An exhaust gas purifying apparatus for an engine, wherein the temperature is lower than a target temperature of the second catalyst . 3. The exhaust gas purifying apparatus for an engine according to claim 1, wherein the second catalyst has a smaller capacity than the first catalyst. 4. The catalyst according to claim 1, wherein the second catalyst is a low-temperature active catalyst that exhibits activity at a lower temperature than the first catalyst.
An exhaust gas purification device for an engine according to any one of the above.