Exhaust gas purification system and exhaust gas purification method

The invention claimed is: 1. An exhaust gas purification system, comprising: a catalyst device provided in an exhaust passage of an internal combustion engine and configured to recover a purification capacity of a catalyst by an air-fuel ratio richness control; and an electronic controller programmed to execute control of the air-fuel ratio richness control by— prohibiting the air-fuel ratio richness control, when a catalyst temperature is at or below a preset lower limit catalyst temperature, starting the air-fuel ratio richness control, when a first timing where an estimated value of an NOx storage amount has reached a preset enrichment start threshold value and a second timing based on a set interval time set in an enrichment interval time map are both satisfied, presetting an enrichment interval correction coefficient based on the catalyst temperature of the catalyst device and on a storage ratio of the estimated value of the NOx storage amount to an enrichment start threshold value of the NOx storage amount, and correct the second timing by multiplying the set interval time by the enrichment interval correction coefficient, and setting the enrichment interval correction coefficient to be larger as the catalyst temperature gets lower, and to be larger as the storage ratio gets lower. 2. An exhaust gas purification system, comprising: a catalyst device provided in an exhaust passage of an internal combustion engine and configured to recover a purification capacity of a catalyst by an air-fuel ratio richness control; and an electronic controller programmed to execute control of the air-fuel ratio richness control by— prohibiting the air-fuel ratio richness control, when a catalyst temperature is at or below a preset lower limit catalyst temperature, starting the air-fuel ratio richness control, when a first timing where an estimated value of an NOx storage amount has reached a preset enrichment start threshold value and a second timing based on a set interval time set in an enrichment interval time map are both satisfied, finishing the air-fuel ratio richness control, when a continuation time for which the rich state is continued after the starting of the air-fuel ratio richness control satisfies both a third timing where an estimated value of an NOx reduction amount has reached an enrichment finish threshold value and a fourth timing where a set continuation time specified in an enrichment continuation time map has elapsed, and correcting the fourth timing by multiplying the set continuation time by a continuation time correction coefficient set according to the catalyst temperature. 3. An exhaust gas purification method, in which a purification capacity of a catalyst in a catalyst device provided in an exhaust passage of an internal combustion engine is recovered by an air-fuel ratio richness control, the method comprising: prohibiting the air-fuel ratio richness control, when a catalyst temperature is at or below a preset lower limit catalyst temperature; starting the air-fuel ratio richness control, when a first timing where an estimated value of an NOx storage amount has reached a preset enrichment start threshold value and a second timing based on a set interval time set in an enrichment interval time map are both satisfied; correcting the second timing by multiplying the set interval time by an enrichment interval correction coefficient preset based on the catalyst temperature of the catalyst device and on a storage ratio of the estimated value of the NOx storage amount to an enrichment start threshold value of the NOx storage amount; and setting the enrichment interval correction coefficient to be larger as the catalyst temperature gets lower, and to be larger as the storage ratio gets lower. 4. An exhaust gas purification method, in which a purification capacity of a catalyst in a catalyst device provided in an exhaust passage of an internal combustion engine is recovered by an air-fuel ratio richness control, the method comprising: prohibiting the air-fuel ratio richness control, when a catalyst temperature is at or below a preset lower limit catalyst temperature; starting the air-fuel ratio richness control, when a first timing where an estimated value of an NOx storage amount has reached a preset enrichment start threshold value and a second timing based on a set interval time set in an enrichment interval time map are both satisfied; finishing the air-fuel ratio richness control, when a continuation time for which the rich state is continued after the starting of the air-fuel ratio richness control satisfies both a third timing where an estimated value of a NOx reduction amount has reached an enrichment finish threshold value and a fourth timing where a set continuation time specified in an enrichment continuation time map has elapsed; and correcting the fourth timing by multiplying the set continuation time by a continuation time correction coefficient set according to the catalyst temperature.