A particulate detection system (10, 1010) includes a sensor section (100) and a sensor drive section (300). A flow EIF of a measurement target gas EI passes through the sensor section, and an amount M of particulates S is detected. The sensor section (100) includes an ion applying section (100e) which generates ions CP, discharges ion-adhering electrified particulates SC, and collects unadhered ions CPF. The sensor drive section includes a sensor current value obtainment section (530) for obtaining a sensor current value Ss corresponding to the amount QH of flowed out charge, a flow velocity obtainment section (510) for obtaining, the flow velocity Vg of the external gas flow, and a particulate amount obtainment section (550, 1550) for obtaining the amount M of particulates S. The influence of flow velocity Vg is mitigated using the sensor current value Ss and the flow velocity Vg.

Methods and systems are provided for diagnosing an exhaust diverter valve in an engine system and adjusting the diverter valve position to regulate vehicle exhaust noise so that the same exhaust diverter valve can be used to reduce emissions and expedite engine heating during a cold-start as well as regulate exhaust noise. In one example, a method for diverter valve diagnostics may include determining diverter valve degradation during an engine cold-start, when the diverter valve is closed, based on the change in the temperature upstream of the diverter valve from the temperature at engine start. In another example, a method for exhaust noise adjustment may include adjusting the diverter valve position to provide a target exhaust backpressure that produces a desired change in vehicle exhaust noise.

An engine assembly for a vehicle and method for determining piston component temperature. The assembly includes an engine defining at least one cylinder, the engine including at least one piston disposed in the at least one cylinder, the at least one piston and the at least one cylinder together defining at least in part at least one variable volume combustion chamber; and at least one temperature sensor connected to the engine, the at least one temperature sensor being arranged to measure a temperature of fluid within the at least one combustion chamber.

A method for thermostat failure detection in an engine cooling system is provided. The engine cooling system includes a coolant pump and a thermostat for providing a coolant flow between an engine and a radiator. The method includes determining one or more engine parameters. Further, a pressure difference between a coolant pump inlet pressure and a coolant pump outlet pressure is determined corresponding to the one or more engine parameters. The thermostat failure is detected when the determined pressure difference is outside a predefined range of pressure change defined corresponding to the determined one or more engine parameters.

A flow measuring device includes a housing including a bypass passage and a flow sensing chip located in the bypass passage and including a sensing surface portion. A throttle portion that is a part of a flowing passage wall facing a sensing surface portion throttles a cross-sectional area of a bypass passage. A position where the throttle portion starts is referred to as a start point position, and a position of the throttle portion where a distance between a gravity center of the sensing surface portion and the throttle portion is shortest is referred to as an end point position. The start point position and the end point position define an imagination line, and the imagination line and the flowing direction define an angle that is in a range from 0 degrees to 20 degrees.

A control device for an internal combustion engine that includes: a first detection unit detecting, as a first parameter, a temperature of a nozzle tip of an injector; and a second detection unit detecting, as a second parameter, a heat quantity of a cylinder head, and executes a dew condensation determination by using at least one of the first parameter and the second parameter, the control device includes: a third detection unit detecting an evaluation value allowing to evaluate a state of the internal combustion engine, a threshold value for selecting which parameter of the first and second parameters is selected being set with respect to the evaluation value, wherein the control device switches a parameter to be used to the first parameter, to the second parameter, or to both the first and second parameters in accordance with the evaluation value when executing the dew condensation determination.

A system includes plural, different sensors configured to be operably connected to a first vehicle. The sensors obtain status data indicative of a state of a cooling system of the first vehicle. The system includes a digital twin system having processors configured to modify the status data having sampling rates or resolutions that differ such that the status data that is modified has a common sampling rate resolution as that of other data. The processors create a digital twin matrix of the status data. The digital twin matrix is indicative of the state of the cooling system. The processors also determine a health score of the cooling system or simulate operation of the cooling system based on the digital twin matrix. The digital twin system is configured to change or control actual operation of the cooling system based on the health score or the operation that is simulated.

A warm-up device is provided in a cooling-water circuit, through which cooling water is circulated so as to pass through an engine. The warm-up device has a heat accumulating passage, in which a heat accumulating device is provided, and an accumulating-device bypassing passage bypassing the heat accumulating device. A waste-heat collecting device is provided in the cooling-water circuit so that heat is collected from exhaust gas from the engine and such collected heat is accumulated in the heat accumulating device. The cooling water is circulated through the heat accumulating device during a start-up operation of the engine in order to heat the cooling water flowing into the engine so as to quickly warm up the engine.

This invention encompasses embodiments for multi-modal integrated simultaneous measurement of various aspects of fluids contained in circulating systems such as automotive reciprocating engines and vehicle transmissions. These circulating systems perform constant internal lubrication, and heat and contaminant removal to protect the internal moving parts from the inherent friction and damage in normal operation. Most commonly this is achieved with fluids based on hydrocarbon and/or related synthetics, which, over time, can lose their protective properties, and vary in their performance or breakdown/decay due to internal and external events. Several components within the lubricant fluid can be measured and can provide insight into the efficacy of the system to perform its designed mission. Described herein is a real-time, simultaneous, integrated, multi-modal sensor system for early warning notification that can be further enhanced using specifically designed nanoparticles that can be introduced into the system, engineered to specifically bind with the contaminants and/or undergo an irreversible state change upon certain experienced conditions to both increase the detectability as well as provide for a framework to improve filter performance.

In a method according to the present invention for calculating the combustion ratio R.sub.C of fuel added to an exhaust passage, the temperature T.sub.o of the exhaust gas flowing in the exhaust passage located downstream of a region in which the fuel added to the exhaust passage is burned is acquired; the thermal capacity C.sub.E of the exhaust gas is acquired; the energy quantity Q.sub.F of the fuel supplied to the exhaust passage is acquired; an increase T.sub.o in exhaust temperature T.sub.o immediately before the exhaust gas is heated is obtained; a change ratio dT.sub.o of the exhaust temperature T.sub.o immediately before the exhaust gas is heated is obtained; a parameter Z relevant to the exhaust gas flowing in the exhaust passage is acquired; and the combustion ratio R.sub.C of the fuel added to the exhaust passage is calculated in accordance with R.sub.C=(C.sub.E/Q.sub.F)(Z.Math.dT.sub.o+T.sub.o).