JPS63256819A - Vortex flowmeter - Google Patents

Abstract

PURPOSE:To prevent noise generated when a throttle valve is closed from being measured as a vortex frequency and to detect a correct vortex frequency by adding a gate circuit on the output side of an f-v converting circuit and fixing the passing band of a 2nd variable frequency filter in a specific band when the opening degree of the throttle valve is smaller than a specific value. CONSTITUTION:A vortex signal from the vortex generation body 2 of a flowmeter 1 is received by a waveform shaping circuit 8, whose output signal is processed by the loop consisting of a phase comparator 9, a loop filter 10, and a voltage-controlled phase shifting circuit 7 and also inputted to a 1st variable frequency filter 12 through an LPF. The output of this filter 12 is processed and outputted by a 2nd variable frequency filter 13 and a waveform shaping amplifying circuit 14. The passing frequency band of the filter 12 is varied with the output of the f-v converting circuit 15 which inputs the output of the circuit 14 and the opening degree signal of the throttle valve is applied to a gate circuit 16 provided on the output side of the circuit 15. Then the passing band of the filter 13 is fixed in the specific passing band according to the valve opening signal.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a vortex flow meter used in an engine, and in particular, to a vortex flow meter that can be used in an engine without erroneously measuring noise generated when a throttle valve is closed.
This makes it possible to detect the correct vortex frequency.

[Conventional technology]

Conventionally, regarding vortex flowmeters used in engines, for example, Japanese Patent Publication No. 15045/1982, Japanese Patent Publication No. 24363/1982, Japanese Patent Publication No. 18332/1989, Japanese Patent Publication No. 58/58
Publication No. 6415 is known. FIG. 1 is a block diagram showing a vortex flow meter according to the present invention, which will be described later. FIG. 1 will be referred to when explaining the [prior art].

This FIG. 1 also includes a portion of the prior art.

First, in FIG. 1, the portion shown in the above-mentioned Japanese Patent Publication No. 58-56415 will be described. In FIG. 1, an ultrasonic transmitter 4 and an ultrasonic receiver 5 are arranged facing each other via a flowmeter 1 having a vortex generator 2, and a Karman vortex is generated downstream of the vortex generator 2. The ultrasonic transmitter 4 is connected to the ultrasonic oscillator circuit 6 so that the ultrasonic wave propagates across the flow in the column 3.
excite.

The ultrasonic wave that crosses the flow of the Karman vortex street is phase modulated by the Karman vortex street 3 and is received by the ultrasound receiver 5. This received signal is waveform-shaped by a waveform shaping circuit 8 and then output to a phase comparator 9.

On the other hand, the output of the ultrasonic oscillation circuit 6 that excites the ultrasonic transmitter 4 is applied to the voltage controlled phase shift circuit 7.

This voltage-controlled phase shift circuit 7 maintains the high frequency stability of the ultrasonic oscillation frequency signal and controls only the phase shift angle. Ko01! Pressure control phase shift circuit 7
The phase of the output of the ultrasonic oscillation circuit 4 is shifted by the phase comparator 9.
Add to.

The phase comparator 9, the ultrasonic oscillation circuit 6, the voltage controlled phase shift circuit 7, and the loop filter 10 constitute a phase locked loop. Note that 1) is a low-pass filter.

A phase comparator 9 compares the phases of the output of the waveform shaping circuit 8 and the output of the voltage controlled phase shift circuit 7, adds the comparison result to the loop filter 10, and removes unnecessary frequency components of the comparison result from the loop filter 10. Remove with .

Depending on the output voltage of the loop filter 10, the voltage controlled phase shift circuit 7 controls the phase shift angle of the output signal of the ultrasonic oscillation circuit 6 and outputs it to the phase comparator 9.

Thereby, the output of the voltage controlled phase shift circuit 7 is synchronized with the ultrasonic reception signal, and as a result, the output of the loop filter 10 directly becomes a phase demodulated output.

However, in the case of this publication, the vortex frequency is disturbed by noise other than the signal received by the ultrasonic receiver 5 and by low-frequency undulations caused by the flow of the fluid.

To solve this problem, a "vortex flow meter" has been proposed by the same applicant as the applicant of the present invention. The vortex flowmeter of this prior application will be further described with reference to FIG. In addition to the configurations indicated by reference numerals 1 to 1), the invention of this prior application has newly added parts as described below.

That is, the output of the phase comparator 9 is input to the loop filter 10, and is also input to the first variable frequency filter 12 via the low-pass filter 1).

This first variable frequency filter 12 is a bypass filter, and passes high frequency components of the output signal of the low-pass filter 1) to the second variable frequency filter 13.
Send to.

This second variable frequency filter 13 is a low-pass filter, and passes low frequency components to the waveform shaping circuit 14.
I am trying to output it to .

This first. In the second variable frequency filter 12.13, the first variable frequency filter 12 serving as a bypass filter has a lower limit passing frequency fj, as shown in FIG.
Noise components at frequencies below are removed, and the second variable frequency filter 13, which serves as a low-pass filter, removes engine noise components at frequencies above its upper limit passing frequency fU. Therefore, the distance between the lower limit passing frequency fL and the upper limit passing frequency fU is the first. Second
This is the passband of the variable frequency filters 12 and 13.

The noise of this engine is relatively low frequency noise caused by the pulsation of the air flow, and the so-called wind noise generated when air passes through the air valve. This is high frequency noise, or high output frequency noise that occurs when Tase Charge is activated.

These noises vary in their generation area, and the air flow rate also varies depending on the instantaneous behavior of the engine, so the bandwidth of the vortex frequency is quite wide, so the first... It is combined with second variable frequency filters 12 and 13.

This first. The vortex frequency signal that has passed through the second variable frequency filter 12, 13 is waveform-shaped and amplified by the waveform shaping amplification circuit 14, and a vortex frequency signal is output.

At the same time, the eddy frequency signal is frequency-voltage (hereinafter f-
(referred to as V) is converted into a voltage corresponding to the frequency by a conversion circuit 15, and this voltage controls the passbands of the first and second variable frequency filters 12 and 13.

As a result, the first. The passband of the second variable frequency filter changes, and the width of the passband indicated by diagonal lines in FIG. 2 changes.

[Problem that the invention seeks to solve]

When this vortex flowmeter measures the amount of intake nitrogen in an engine equipped with a supercharger, the vortex signal wave is disturbed by ultrasonic noise generated by the supercharger. This turbulence increases as the rotation of the supercharger increases, but normally the amount of intake air also increases, and the turbulence is caused by the first variable frequency filter 12 shown in FIG.
With respect to the signal A at the 0 input end, distortion is removed from the signal B that has passed through the second variable frequency filter 13, as shown in FIG. 4 fb).

However, when the throttle valve is suddenly closed, the rotation of the supercharger does not suddenly decrease due to inertia etc. even though the amount of intake air decreases. Figure 5 (b) for the signal at the input terminal of
), the signal at the output end of the second variable frequency filter 13 has a waveform with extremely poor SA.

With this waveform, noise is mistakenly judged to be a signal, and after passing through the second variable frequency filter 13, an extremely high frequency is output. This causes engine stoppage and rough idling.

This invention was made to solve this problem, and it is possible to detect the correct vortex frequency without erroneously measuring the noise generated when the throttle valve is closed, and to achieve a vortex flow rate that is extremely difficult for the engine. The purpose is to obtain a measurement.

[Means for solving problems]

The vortex flow meter according to the present invention includes a first variable frequency filter that bypasses the vortex signal generated in response to the flow rate of the fluid to be measured, and a second frequency variable filter that bypasses the output of the first variable frequency filter. A variable filter, a waveform shaping amplifier circuit that shapes and amplifies the output of the second variable frequency filter, and converts the vortex frequency output output from the waveform shaping amplifier circuit into a voltage and converts it into a voltage. a frequency-voltage conversion circuit that controls the passband of the second variable frequency filter; and a frequency-voltage conversion circuit that controls the passband of the second variable frequency filter; It is provided with a means for fixing to.

[For production]

In this invention, the vortex signal generated in response to the flow rate of the fluid to be measured is introduced into the first variable frequency filter to bypass only the high frequency components, and the second variable frequency filter only filters the low frequency components. Extract only the vortex signal component that has passed and removed the noise component, waveform shape and amplify this vortex signal component to output a desired vortex signal, and convert the voltage corresponding to the frequency of this vortex signal to a frequency-voltage conversion circuit. , and at this voltage the 1st. The passband of the second variable frequency filter is controlled, and when the opening degree of the throttle valve becomes less than a predetermined value, the passband of the second variable frequency filter is fixed to a predetermined passband.

〔Example〕

Embodiments of the vortex flowmeter of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of one embodiment. In FIG. 1, the description of the parts described in the "Prior Art" column will be omitted to avoid duplication.

In this invention, a gate circuit 16 is newly added in addition to the parts indicated by numerals 1 to 15 in FIG.
The output voltage of the -V conversion circuit 15 is also applied to the second variable frequency filter 13 via the first variable frequency filter 12 and the gate circuit 16. A valve opening signal of a throttle valve (not shown) for controlling the amount is inputted from a throttle sensor (not shown). This throttle sensor uses a variable register or the like.

When a valve opening signal indicating that the opening of the throttle valve has become below a predetermined value is applied to the gate circuit 16, the gate circuit 1
6 is a trap to fix the passband of the second variable frequency filter to a predetermined passband.

Next, the operation of the present invention will be explained.
The operation up to the control of the passband of the frequency variable filters 12 and 13 has already been described.
Here, only the features of this invention will be explained.

Conventional problems occur only in the rapid deceleration region, so the opening of the throttle valve is detected, and when the opening of the throttle valve becomes less than a predetermined amount, the gate circuit 16 is activated by the valve opening signal. The output voltage of the V conversion circuit 15 is clipped and the second variable frequency filter 13 is fixed at a low range as shown in FIG.

As a result, high frequency components are forcibly removed, as shown in Figure 3 (
Even if a signal wave with superimposed noise as shown in FIG. 3(b) is input to the first variable frequency filter 12, the noise as shown in FIG. The removed signal is extracted.

Note that the gate circuit 16 may be bypassed in response to the throttle valve opening to control the passband of the second variable frequency filter.

〔Effect of the invention〕

As explained above, this invention fixes the pass band of the second variable frequency filter to the predetermined pass band when the valve opening of the throttle valve is less than a predetermined opening, so that the problem occurs when the throttle valve is closed. It becomes possible to detect the correct vortex frequency without erroneously measuring noise as the vortex frequency.

[Brief explanation of drawings]

FIG. 1 is a block diagram of an embodiment of the vortex flowmeter of the present invention.
Fig. 2 is a diagram showing the relationship between the output frequency and the variable filter passing frequency for explaining the present invention and the conventional vortex flowmeter, and Fig. 3 is a diagram showing the vortex flowmeter of the present invention at low rotation speed after sudden engine deceleration. Figure 4 is a waveform diagram of the input side and output side of the frequency variable filter of a conventional vortex flowmeter during high engine rotation.
The figure is a waveform diagram of the input side and output side of the variable frequency filter of a conventional vortex flowmeter at low rotation speeds after sudden deceleration of the engine. DESCRIPTION OF SYMBOLS 1... Flowmeter, 2... Vortex generator, 3... Karman vortex street, 4... Ultrasonic transmitter, 5... Ultrasonic receiver,
6... Ultrasonic oscillation circuit, 7... Voltage control phase shift circuit, 8... Waveform shaping circuit, 9... Phase comparator, 10
...Loop filter, 1) ...Low pass filter%
12... WXl frequency variable filter, 13... Second frequency variable filter, 14... Waveform shaping amplifier circuit, 15... fV conversion circuit, 16... Gate circuit.

Claims (3)

[Claims] (1) A detection means for detecting a vortex signal generated in response to the amount of air taken into the engine, a first frequency variable filter circuit that high-passes the output of this detection means, and a low-pass the output of this first frequency variable filter circuit. a second variable frequency filter circuit that shapes and amplifies the output signal of the second variable frequency filter to output a vortex frequency corresponding to the intake air amount of the engine; a waveform shaping amplifier circuit that receives the vortex frequency output; a frequency-voltage conversion circuit that converts the voltage into a voltage corresponding to the frequency and controls the pass bands of the first and second variable frequency filters using this voltage; and an opening degree of a throttle valve that controls the intake air amount of the engine. 1. A vortex flow meter comprising means for fixing the passband of the second variable frequency filter to a predetermined passband when the frequency becomes less than a predetermined amount. (2) The vortex flowmeter according to claim 1, wherein the passband of the second variable frequency filter is controlled by a gate circuit that clips to a predetermined value in response to the throttle valve opening. (3) The vortex flowmeter according to claim 1, wherein the second variable frequency filter pass band is controlled by a gate circuit that bypasses in response to the throttle valve opening.