JPH02234021A - Fuel flow rate measuring method for automobile - Google Patents

Abstract

PURPOSE:To simply measure a fuel flow rate by calculating an exhaust gas discharge derived by using a dilute stream method from exhaust gas concentration and exhaust gas flow rate data, by a carbon balance method. CONSTITUTION:The total quantity of exhaust gas G from an automobile which allows a running state to appear by using a simulation running testing device is led into a CVS device 1 together with dilution use air A. Subsequently, a part of the gas G diluted by the air A is fed as diluted exhaust gas G' to an exhaust gas concentration measuring part 11 through a gas supply duct line 8. Also, from the device 1, an inlet temperature, pressure, etc. of a venturi 2 are outputted as exhaust gas flow rate data (a), and inputted to a fuel flow rate measuring arithmetic unit 15. Moreover, the total CO2 concentration detected by a CO2 analysis meter 13 is inputted as exhaust gas (b) to the unit 15. Subsequently, in the unit 15, the data (a), the concentration (b) and atmospheric pressure data (c) are processed by a dilute stream method, the total CO2 exhaust weight is determined, and also, the total CO2 exhaust weight is processed by a carbon balance method, and a fuel flow rate is measured.

Description

[Detailed description of the invention] [Industrial application field] TECHNICAL FIELD The present invention relates to a method for measuring fuel flow rate in an automobile.

(Prior Art) Conventionally, to measure the fuel flow rate of a car, a flow rate sensor was attached to the fuel supply pipe between the car's fuel tank and the carburetor, and the measurement was performed using this flow rate sensor. [Problems to be Solved by the Invention] However, the above-mentioned conventional method for measuring fuel flow rate in automobiles has the following problems. That is, in the above measurement method, a flow rate sensor is attached when testing a car, whereas when a general user drives a car, the flow rate sensor is not attached.
In addition, the piping route is different when a flow sensor is installed and when it is not installed, and due to this difference,
The problem was that there were considerable differences in vehicle performance, including flow characteristics (e.g. acceleration/deceleration response and output characteristics). In addition, the above measurement method has the problem that it requires work other than measurement, such as the need for the manufacturer to install and remove the flow rate sensor in order to test the vehicle, which is very troublesome. The present invention has been made with the above-mentioned considerations in mind, and its purpose is to operate under the same conditions as normal driving conditions, that is, without affecting the performance of the vehicle in any way, and to perform measurements other than measurement. To provide a method for easily measuring the fuel flow rate of an automobile without requiring much work.

[Means to solve the problem]

In order to achieve the above-mentioned object, the method for measuring the fuel flow rate of an automobile according to the present invention supplies exhaust gas from the automobile to an analysis needle via a CVS device to determine the exhaust gas concentration, and calculates the exhaust gas concentration and the above-mentioned The exhaust gas exhaust weight is calculated by calculating the exhaust gas flow rate data from the CVS device using the dilute stream method, and the weight of the wandering gas exhaust is calculated by applying the carbon balance method. It is designed to measure instantaneous fuel flow rate. [Operation] A portion of the exhaust gas from a car is supplied to, for example, a 008 analyzer via a CVS device, and the CO2 concentration of the exhaust gas is measured. Then, this coal degree, exhaust gas flow rate data from the CVS device (for example, temperature and pressure at the ventilator inlet), atmospheric pressure data, etc. are processed using the dilute stream method to determine the exhaust gas discharge weight, and further, Since the instantaneous fuel flow rate is determined by calculating the weight of exhaust gas emissions using the carbon balance method, there is no need to attach a flow rate sensor to the fuel supply piping, and the fuel flow rate is calculated under the same conditions as during normal operation. It is possible to evaluate the performance of a car. [Examples] Examples of the present invention will be described below with reference to the drawings. FIG. 1 shows a schematic configuration of an apparatus for carrying out the method for measuring fuel flow rate of an automobile according to the present invention, and in this figure, l
1 is a CVS device for sampling exhaust gas G from a car (not shown), and includes a venturi 2. to obtain a constant flow rate.
Equipped with blower 3, etc. A pipe line 4 for introducing exhaust gas G and a pipe line 5 for introducing dilution air A are provided on the upstream side of the ventilator 2 and are connected at a point 6. A gas supply line 8 is connected to a point 7 between the venturi 2 and the venturi 2. 9 is a three-way valve installed in the gas supply pipe 8, and its first port 9a
is connected to the connection point 7 side, and the second port 9b is connected to the exhaust gas concentration measuring section ll side, which will be described later.
It is connected to the.

In this CVS device 1, the total amount of exhaust gas G from a car that has been made to exhibit, for example, a predetermined 10-mode driving condition using a simulated driving test device (not shown) such as a chassis dynamometer, is stored together with dilution air A. be introduced. Then, a part of the exhaust gas G suitably diluted with the dilution air A is sent to the exhaust gas concentration measuring section 11 via the gas supply pipe B as the diluted exhaust gas G'. In addition, this CVS equipment "Il
The inlet temperature of the venturi 2, its pressure, etc. are outputted from l as exhaust gas flow rate data a, and this data a is input to a fuel flow rate measurement/arithmetic device 15, which will be described later. 1l
is an exhaust gas concentration measuring section that oxidizes all of the CO and HC gases contained in the diluted exhaust gas G' to produce CO! oxidation means l2 such as an oxidation catalyst, CO obtained by this oxidation means 12, and diluted exhaust gas G'
The total coal concentration in the diluted exhaust gas G' is analyzed.
It is equipped with a z analyzer 13, a pump 14 for suction, etc. Then, mCO. detected by the 008 analyzer 13. The concentration is inputted as exhaust gas concentration b to a fuel flow rate measurement and calculation device 15, which will be described later. Reference numeral 15 denotes a fuel flow rate measurement/arithmetic device, which is composed of, for example, a CPU, and is connected to the CVS device 1.
Wandering gas flow rate data a from exhaust gas concentration measuring section 11
The total CO It is configured to calculate the fuel flow rate by determining the weight of CO exposed and further processing this total weight of exposed CO by applying the carbon balance method. That is, the total CO! To calculate the discharge weight, use the dilute stream method as follows: Cot g(t)=ρ・QM(t)(Cot M(t
)-CO! D(t)) ・・・・・・(
The calculation is performed using the formula 1). In addition, here, Cow g(t): I-Ital CO. Discharge weight (g/
t) D: CO*Density Cg/1) COx M(t): Diluted exhaust gas CO! 9a degrees [%] c
ot D(t): COt concentration in dilution air [%] QM
(t): Represents the CVS total flow rate (f/t), and furthermore, the QM(t) is expressed by the following formula. In addition, here, C, :CVS Venturi flow rate failure Tw ;CVS Venturi population temperature [°C]Pv :C
VS Vencheri inlet pressure (Hg) P,: Atmospheric pressure [■H
g) respectively. And to find the instantaneous fuel flow rate, apply the carbon balance method? The calculation is performed using the formula FE.

In addition, here, e<t>: Instantaneous fuel flow rate (1/t) KCO. :CO! Carbon weight ratio KFE: represents the carbon weight (g/j!) in the fuel 12. Therefore, the desired fuel flow rate can be determined using the above equations (1) to (3).

In the above embodiment, all CO and HC gases contained in the diluted exhaust gas G' are converted into CO2, and the fuel flow rate is determined based on the total CO2 concentration in the diluted exhaust gas G'. However, the present invention is not limited to this, and the coi 1 degree, CO concentration, and HC gas concentration in the diluted exhaust gas G' are individually measured, and these concentrations are input to the fuel flow rate measurement calculation device 15. , perform a given operation? You can do it like this. That is, FIG. 2 shows a schematic configuration of the apparatus configured as described above, and the exhaust gas concentration measurement section 11 in this figure includes a CO analysis section 21. CO ■ analysis section 22,} {C analysis section 2
3 are provided in parallel with each other, and 24, 25.26 are the respective analysis units 21, 22. CO analyzer, CO analyzer, IC analyzer installed in 23, and 27~
29 is a suction pump. Then, the CO concentration detected in the analyzers 24 to 26, CO! The concentration and the HC gas concentration are respectively input to the fuel flow rate measurement calculation device 15. Therefore, in order to determine the fuel flow rate in this example, first, the exhaust weight of CO, CO, HC gas is calculated using the dilute stream method, and Cog(L)-Co density/Q
M(t)(COM(t)-COD(t)l
・・・・・・(4) CO! g(t)-Cot density・
QM(t)(Co,M(t)−COiD(t))
......(5) HCg(t)-HC density・QM(
The calculation is performed using the formula: t) (HcM(t)?HCD(t)1. Here, QM(t): CVS total flow rate (ffi/t) COM(t
) + diluted exhaust gas CO concentration (ppm) Co. M(t)
: Diluted exhaust gas COt concentration [%] HCM (t): Diluted exhaust gas HC concentration (ppsc) COD (t): CO concentration in air for dilution (ppm) coi D (t)? CO in the air for dilution ■ Concentration (%)} 1 cD (t) + HC in the air for dilution
iJ degree (ppmc), and furthermore, the QM
(t) is expressed by the following formula.

In addition, here, c. :CVS venturi flow coefficient Ty:CVS venturi inlet temperature ('C)Pv :CV
S Vencheri inlet pressure (mHg) P. :Atmospheric pressure (10g
) respectively. Then, to find the instantaneous fuel flow rate, apply the carbon balance method to determine the instantaneous fuel flow rate. (t) - (K C O - C O g
(t) + K C O t ・CO. (t)+
KHC − HCg(t)) /KFE・・・・・・(
The calculation is performed using the formula 8).

In addition, here, j! (t): Instantaneous fuel flow rate (ffi/t) KCO j
Carbon weight ratio in Co KCO. jco. Carbon weight ratio in HC S Carbon weight ratio in HC KFE: Represents the weight of carbon in 1 liter of fuel (g/j!). Therefore, the desired fuel flow rate can be determined using equations (4) to (8) above. [Effects of the Invention] As explained above, according to the present invention, there is no need to attach a flow rate sensor to the fuel supply flow path, and the instantaneous fuel flow rate can be measured in a so-called non-contact state. The fuel flow rate of a car can be easily measured under the same conditions, that is, without any effect on the car's performance, and with almost no work other than measurement required.

[Brief explanation of the drawing]

Claims (1)

[Claims] Exhaust gas from a car is supplied to an analyzer via a CVS device to determine the exhaust gas concentration, and this exhaust gas concentration and exhaust gas flow rate data from the CVS device are processed using a dilute stream method. 1. A method for measuring a fuel flow rate of an automobile, characterized in that the weight of exhaust gas discharged is obtained by calculating the weight of exhaust gas discharged, and the instantaneous fuel flow rate is measured by calculating the weight of exhaust gas discharged by applying a carbon balance method.