RU2017125943A - METHOD AND SYSTEM FOR DETECTING SOLID PARTICLES IN EXHAUST GASES - Google Patents

Claims (35)

1. The method in which: adjusting the opening amount of the inlet of the particulate sensor located in the exhaust stream in accordance with the flow rate of the exhaust gas upstream of the particulate sensor; and pass the exhaust gases past the plurality of plates to change the flow to the sensor element of the particulate matter sensor located near the plurality of plates for changing the flow. 2. The method according to claim 1, wherein the regulation includes increasing the opening amount of the inlet when the exhaust gas flow falls below a threshold flow rate, and further includes decreasing the opening size of the inlet when the exhaust gas flow exceeds the threshold flow rate. 3. The method of claim 2, wherein the particulate sensor includes a flow deflector and a flow regulator located at the inlet, the flow regulator and flow deflector connected to different, opposite surfaces of the PM sensor to form a gap between the flow regulator and the flow deflector at the inlet. 4. The method of claim 3, wherein increasing the opening amount includes increasing the gap between the flow deflector and the flow regulator by turning the flow regulator in a first direction away from the flow deflector. 5. The method of claim 4, wherein reducing the opening amount includes reducing the gap between the flow deflector and the flow regulator by turning the flow regulator in a second direction opposite to the first direction toward the flow deflector. 6. The method according to claim 3, in which the plurality of plates for changing the flow comprises parallel plates and / or corner plates separated by a gap and located near the outlet of the particle sensor, while the plurality of plates for changing the flow are separated from the flow deflector by some distance. 7. The method according to claim 6, in which the exhaust gases are additionally directed through a gap formed at the inlet between the flow regulator and the flow deflector into the gap formed between the plurality of plates to change the flow towards the sensor element of the particulate sensor located near the outlet particle sensor. 8. The method of claim 7, further comprising detecting leaks in the particulate filter upstream of the particulate sensor and indicating a malfunction of the particulate filter based on the particle deposition rate on the sensor of the particulate sensor. 9. The method according to p. 8, in which the threshold intensity is based on the desired intensity of the deposition of particles on the sensor element of the particle sensor. 10. A method for a particulate matter (PM) sensor, wherein: increasing the flow of exhaust gases to the sensitive element of the PM sensor located inside the PM sensor, wherein the PM sensor is located in the exhaust gas duct, in response to the exhaust gas flow rate in the exhaust gas duct being below a threshold value; reduce the flow of exhaust gases to the sensitive element of the PM sensor in response to the fact that the exhaust gas flow is above a threshold value; and exhaust gases are passed between the plurality of flow deflectors to a sensitive element of the PM sensor located near and downstream of the plurality of flow deflectors. 11. The method according to p. 10, in which the increase in the flow of exhaust gases includes the rotation of the flow regulator located near the inlet of the PM sensor in the first direction, and the reduction of the flow of exhaust gases includes the rotation of the flow regulator in the second direction, opposite first direction. 12. The method according to p. 11, in which the rotation of the flow regulator in the first direction further includes moving the flow regulator away from the plate to change the flow located in or near the inlet of the PM sensor, and the rotation of the flow regulator in the second direction further includes moving the flow controller toward the plate to change the flow of the PM sensor assembly. 13. The method of claim 12, wherein the plurality of flow deflectors are spaced apart from each other, and each of the plurality of flow deflectors includes a flat semicircular plate with an opening that allows the first part of the exhaust gas to flow from the opening into the gap between the plurality of flow deflectors towards the sensitive element of the PM sensor, and the second part of the exhaust gases flow towards the openings of the adjacent flow deflector, and the openings of adjacent flow deflectors from a plurality of flow deflectors have various sizes. 14. The method of claim 13, wherein the plurality of flow deflectors are parallel to each other, and wherein the gaps between adjacent flow deflectors are the same. 15. The method of claim 13, wherein the plurality of flow deflectors are corner plates, and wherein the gaps between adjacent flow deflectors are not the same. 16. The method according to p. 13, in which additionally: capture the first set of particles in the exhaust stream at the inlet of the PM sensor; picking up a second set of particles from a plurality of flow deflectors, the particles of the second set of particles being smaller than the particles of the first set of particles; directing a third set of particles in the exhaust stream from the gap between adjacent flow deflectors toward a PM sensor element located on or near a plurality of flow deflectors to facilitate deposition of a third set of particles on the PM sensor element, the particles of the third set of particles being smaller than the particles of the first set particles and a second set of particles; and indicate a leak in the particulate filter located upstream of the PM sensor when the deposition rate of the third set of particles on the PM sensor element exceeds the threshold intensity. 17. A particulate matter (PM) sensor comprising: a first flow diverter located near the inlet of the PM sensor; a plurality of second flow deflectors, wherein the plurality of second flow deflectors are separated from the first flow deflector by a distance; a PM sensor element, wherein at least a portion of the PM sensor element is located between the highest flow deflector and the lowest flow deflector of the plurality of second flow deflectors; and a movable plate located at or near the inlet of the PM sensor, configured to control the opening amount of the inlet. 18. The sensor according to claim 17, further comprising a controller with machine-readable instructions stored in long-term memory for: translating the movable plate to an end position that coincides with the first position with a smaller amount of opening of the inlet or the second position with a larger value of opening of the inlet, or between the first and second positions, based on the flow of exhaust gases upstream of the PM sensor. 19. The sensor according to claim 18, in which the transfer of the movable plate to its final position includes moving the movable plate closer to the first position than to the second position with increasing exhaust gas flow, and further includes moving the flow regulator closer to the second position, than to the first position while reducing the exhaust gas flow. 20. The system of claim 19, wherein the controller contains additional instructions for: indications of a leak in the particulate filter upstream of the PM sensor when the current particle deposition rate on the PM sensor exceeds the required particle deposition rate on the PM sensor.