The present invention relates to a method for measuring the amount of accumulated particulate matter for accurately evaluating the amount of accumulated particulate matter trapped in an exhaust gas purification filter in a method of regenerating the exhaust gas purification filter that purifies exhaust gas by trapping particulate matter in exhaust gas from a diesel engine or the like.
A diesel particulate filter for a diesel engine (hereinafter, referred to as DPF) purifies exhaust gas and particulate matter (hereinafter, referred to as PM) by filtering the PM discharged from the diesel engine when the PM passes through porous ceramic walls carrying catalysts. However, since the DPF can trap the limited amount of the PM, the DPF requires “regeneration operation” where the DPF is regularly heated to a high temperature by self-heating or external heating such as electrification to burn off the PM.
In the regeneration, when the amount of accumulated PM is excessively great, damage to the filter is caused by generation of thermal stress. In contrast, when the regeneration is unnecessarily frequently operated to keep the amount of accumulated PM low, the regeneration operation requires extra energy for heating the DPF, and thus fuel consumption deteriorates. In order to improve fuel consumption of a diesel engine, it is necessary to accurately determine the time of regeneration for achieving the necessary minimum frequency of the regeneration without regard to a concern of the DPF being damaged, and to accurately measure the amount of accumulated PM.
In the related art, as a method of measuring the amount of accumulated PM trapped in the DPF, the following methods are disclosed: an evaluation by a pressure difference (pressure loss) between an upstream and a downstream of a filter (for example, refer to PTL 1); and a method of estimating the amount of accumulated PM based on driving hours using a computer (for example, refer to PTL 2). In addition, it is attempted to provide an acoustic source and an acoustic receiver in upstream and downstream exhaust pipes of a filter (for example, refer to PTL 3).
[PTL 1] JP-A-2005-023884
[PTL 2] JP-A-2004-316428
[PTL 3] JP-T-2005-538304
In the related art, in the evaluation by a pressure difference between an upstream and a downstream of a filter, there is a problem in that it is difficult to accurately evaluate accumulation of PM since the pressure loss has a tendency of being saturated early compared to the accumulation of the PM. In the method of estimating the amount of accumulated PM based on driving hours using a computer, there is a problem in that it is necessary to construct a database and to develop a complicated program relative to generation of the PM under driving conditions of individual engines since the amount of generated PM is complicatedly dependent on various conditions such as driving history of an engine. In addition, in the method of providing an acoustic source and an acoustic receiver in exhaust pipes, there is a problem in that an accurate evaluation is difficult due to the influence of temperature, flow velocity or the like of exhaust gas and a sensor deteriorates under exhaust gas atmosphere.
In order to solve the problem, an object of the present invention is to provide a new method of evaluating the amount of accumulated PM so as to determine the time of regeneration for achieving the necessary minimum frequency of the regeneration without regard to a concern of a DPF being damaged.
In order to solve the problem, according to the present invention, there is provided a method of measuring the amount of particulate matter (PM) accumulated in an exhaust gas purification apparatus with which a diesel engine is equipped, wherein a diesel particulate filter (DPF) configured to have a porous ceramic is connected to an intermediate point in an exhaust pipe, a container containing the DPF or the like has an ultrasonic wave transmitter for propagating an ultrasonic wave and an ultrasonic wave receiver for receiving an ultrasonic wave on an exterior thereof, and the amount of the PM accumulated in the DPF is evaluated based on attenuation of a detected signal of the ultrasonic wave propagating through a main DPF body using a control apparatus that processes the detected signal of the ultrasonic wave receiver.
In addition, in the method of measuring the amount of accumulated PM according to the present invention, the control apparatus evaluates the amount of the PM accumulated in the DPF based on attenuation obtained by comparing amplitude of a detected signal of an ultrasonic wave propagating through the main DPF body when the PM is not accumulated with amplitude of a detected signal of an ultrasonic wave propagating through the main DPF body when the PM is accumulated, and the control apparatus determines that it is necessary to operate regeneration of the DPF when the attenuation exceeds a constant value.
In addition, in the method of measuring the amount of accumulated PM according to the present invention, an ultrasonic wave of several MHz frequency range is used.
In addition, in the method of measuring the amount of accumulated PM according to the present invention, a heat insulator made of a material which prevents signal attenuation of an ultrasonic wave is arranged between the main DPF body and the container containing the main DPF body.
In the method of measuring the amount of accumulated PM according to the present invention, since the ultrasonic wave transmitter and the ultrasonic wave receiver are provided on the exterior of the DPF container to detect an ultrasonic wave propagating through the main DPF body, the method is unlikely to be affected by flow velocity or temperature of exhaust gas and the amount of the accumulated PM can be accurately measured. Accordingly, the frequency of regenerating the DPF is set to be the necessary minimum and fuel consumption can be improved. In addition, in a simple configuration in which the ultrasonic wave transmitter and the ultrasonic wave receiver are provided on the exterior of the DPF container to detect an ultrasonic wave propagating through the main DPF body, the amount of the accumulated PM can be accurately detected, a sensor has no risk of deterioration due to a part of the sensor not being exposed to exhaust gas atmosphere, and a measurement can also be performed after retrofit of the apparatus.
In addition, since an ultrasonic wave of several MHz frequency range is used, it is possible to effectively read attenuation of the ultrasonic wave propagating in a lateral direction through the main DPF body in association with the amount of the accumulated PM.
In addition, when a heat insulator made of a material which prevents signal attenuation of an ultrasonic wave is arranged between the main DPF body and the container containing the main DPF body, it is possible to insulate the DPF against heat without deteriorating the precision of measurement.
An ultrasonic wave basically propagates in the partition walls in the DPF. An ultrasonic wave can propagate in the longitudinal direction in a wide frequency range, but in the lateral direction, there is an ultrasonic wave mode that is likely to propagate depending on the size and material of a cell. For example, when an ultrasonic wave propagates in the ceramic at a sound speed of approximately 3,000 m/s and a cell has a size of several millimeters, the ultrasonic wave corresponds to an ultrasonic wave of approximately several MHz. When PM in exhaust gas is trapped and accumulated on the surfaces of the partition walls or in the pores, an ultrasonic wave is attenuated. It is possible to evaluate the amount of accumulated PM by evaluating the attenuation.
To propagate an ultrasonic wave in the DPF, an ultrasonic transmitting element is provided in contact with a side surface of a main DPF body, a container containing the DPF or the like. There is a case where a heat insulator is arranged between the container and the DPF. In any case, when acoustic impedance greatly changes between the transmitting element and the main DPF body, a reflective component of the ultrasonic wave increases, and thus, adhesion of the transmitting element is attempted using an appropriate method. A piezoelectric element or the like is assumed as the transmitting element. Similarly, a receiving element is provided in order for acoustic impedance not to greatly change between the receiving element and the main DPF body.
It is possible to measure an ultrasonic wave propagating in the longitudinal direction, a wave reflected from the inside of the DPF in locations where the ultrasonic wave transmitting element and the receiving element are provided on the DPF, but in one of the embodiments according to the present invention, the transmitting element and the receiving element are provided at opposing positions in the lateral direction, and attenuation of an ultrasonic wave propagating through the honeycomb structure is evaluated.
A waveform of an ultrasonic wave that is transmitted can have a sine wave or a pulse shape as long as the waveform includes a frequency range that is attenuated by the accumulation of PM. When a pulse-shaped ultrasonic wave is used, it is possible to separate a signal other than an anticipated ultrasonic wave component that propagates in the DPF from a travelling time.
A control apparatus serves to send a necessary electric signal to the ultrasonic wave transmitter, to appropriately process a signal from the receiver and to output the amount of the accumulated PM.
Based on the example of the exhaust gas purification apparatus illustrated in
Exhaust gas from a diesel engine flows into the DPF 2 via the exhaust pipe 1. Typically, the DPF 2 is provided in the container via the heat insulating material 6 and the like. The ultrasonic wave transmitter 3 is provided directly on the main DPF 2 body or in contact with the exterior of the container. In
Number | Date | Country | Kind |
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2011-125080 | Jun 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/062783 | 5/18/2012 | WO | 00 | 2/12/2014 |