KR101286166B1 - Signal detect circuit for vortex - Google Patents

Abstract

PURPOSE: A signal detecting circuit for a vortex flowmeter is provided to rapidly diagnose malfunction by enabling to measure output waveforms of each block of a flow rate detection circuit. CONSTITUTION: A signal detecting circuit for a vortex flowmeter comprises a piezoelectric element (10), a detection circuit (20), and a selective preamplifier (30). Signals detected by the piezoelectric element are amplified by a charge amplifier (21), and the selective preamplifier detects the signals amplified by the charge amplifier by using a filter selected from several filters which are arranged corresponding to a sort of fluid and a size of a pipe. The signals detected by the selective preamplifier are applied to a duty control element (40) after being converted into pulse signals by using a clamping amplifier (22) and a comparator (23). The pulse signals output from the duty control element are input to a main control unit (52) after being transmitted through a low pulse cutoff (51) eliminating minimum flow rate signals so that a flow rate is calculated. The main control unit receives the input of a temperature sensor (53) so that the temperature is compensated. A value calculated by the main control unit is output through a display unit (54) and a universal serial bus (USB) module.

Description

Signal detect circuit for vortex flowmeter

The present invention relates to a vortex flowmeter signal detection circuit for stably separating and displaying a signal detected by a vortex flowmeter, which is a method of measuring the flow rate of a fluid.

The vortex flowmeter, which measures the flow rate, measures the flow rate by detecting the piezoelectric element that karman's vortex occurs in proportion to the flow velocity downstream of the delta perpendicular to the flow of the fluid. It is possible to measure over a wide flow range and temperature range, and is widely used as a flow meter with excellent durability and low pressure loss.

Such a vortex flow meter accurately detects a sensor signal composed of a piezoelectric element, and stably separates the detected signal from noise to increase the reliability of the vortex flow meter. Conventional vortex flowmeters include a flow rate detection circuit and a flow rate for detecting a sensor signal. It is difficult to expect stable signal detection and calculation because noise between the flow rate calculation circuits that calculate the flow rate is not blocked, and an error occurs depending on the temperature of the place where the flow rate detection is performed. The duplication of data was cumbersome because it was not installed.

In particular, the existing vortex flowmeter must have a separate filter according to the type of the measurement fluid (water, gas, steam, gas, etc.) and the pipe size, so unless a custom vortex meter according to the type of the gas and the pipe size is provided, Measurement error was inevitable.

According to the present invention, when detecting a signal measured by a sensor in an existing vortex meter, the error according to the temperature of the place where the detection is made is accompanied by a problem that a measurement error occurs because the error due to the type of the measuring fluid and the pipe size is not actively corrected. It is to solve the problem that occurs and the noise between the detection circuit and the measurement circuit is mixed to ensure a stable detection and measurement without measurement error.

The present invention includes a preamplifier for detecting a signal detected by a piezoelectric element by selecting one of a plurality of filters corresponding to a fluid type and a pipe size, and the signal detected by the preamplifier is a clamping amplifier and a comparator. The detection circuit is configured to be applied to the duty control element after the control, and the pulse signal output from the duty control element is input to the main control unit through a low pulse cutoff to remove the lowest flow signal, thereby performing a flow rate calculation. The main control unit receives temperature input from the sensor and compensates for the temperature. The value calculated by the main control unit is output through the display unit and the USB module. It is made by constructing.

According to the present invention, the power supply of the flow rate detection circuit and the flow rate calculation circuit is separated, so that the flow rate detection circuit is stable, and 16 filters can be selected to be applied to various pipe sizes. It is possible to measure the output waveform of each block of the flow detection circuit so that the fault diagnosis is quick, and the built-in temperature sensor makes it easy to determine the state of the flow detection circuit and the surrounding environment, and the interface is supported by the USB module.

In particular, the present invention has a built-in 16 filters corresponding to the fluid and the pipe size to cope with various fluids (water, gas, steam, etc.) and pipe size is to increase the efficiency compared to the production of the flow meter.

1 is a circuit diagram of the present invention

According to the present invention, the signal detected by the piezoelectric element constituting the vortex flowmeter is stable and error-free signal detection through the detection circuit, the signal detected by the detection circuit is calculated as the flow rate in the main control unit of the measurement circuit and output The filter can be selected and used according to the type of fluid and pipe size in the detection circuit to increase the efficiency compared to the production of the flow meter, and to separate the power supply of the detection circuit and the measurement circuit to prevent noise from entering the measurement circuit. Temperature compensation is performed at the same time, while data output is made through the USB module.

In the present invention, the piezoelectric element generates a vortex frequency according to the flow of the fluid, the signal is amplified through the charge amplifier and then through the selective preamplifier, in the selective preamplifier to select the filter using the selector In this case, the selective preamplifier can stably detect the signal detected by the piezoelectric element according to the pipe size and the type of the fluid.

The signal amplified by the selective preamplifier is applied to a post-duty control element through a clamping amplifier and a comparator, and in the duty control element to obtain a stable and standardized detection signal by varying the duty. Disconnect the power supply from the measurement circuit to prevent noise from mixing.

The present invention makes it possible to detect and confirm the output waveforms of the optional preamplifier, clamping amplifier and comparator.

The pulse output from the duty control element is made through the low pulse cutoff element and then the flow rate calculation is made in the main control unit, but the compensation is performed by the temperature detected by the temperature sensor during the flow rate calculation. The flow rate is displayed on the display while the data is transmitted to and from the computer via the communication element.

In the present invention, the USB module is used to connect the USB module to the main control unit to store data via USB.

The present invention of such a configuration will be described in detail with reference to the accompanying drawings.

The piezoelectric element 10 of the present invention is a detection element used in the vortex flowmeter to obtain a vortex frequency proportional to the flow rate, and the signal obtained from the piezoelectric element 10 is amplified through the charge amplifier 21, the piezoelectric The element 10 may be integrally formed with the detection circuit 20 and the measurement circuit 50 or may be separately separated, and in any case, the signal obtained from the piezoelectric element 10 may be selected through the charge amplifier 21. The preamplifier 30 is delivered.

The signal detected by the piezoelectric element 10 of the present invention and the signal amplified by the charge amplifier 21 are shown below the piezoelectric element 10 and the charge amplifier 21 in the drawing.

The signals obtained from the piezoelectric element 10 and amplified by the charge amplifier 21 are converted into various fluids (water, gas, steam, etc.) through an optional preamplifier 30 having 16 filters corresponding to the fluid and the pipe size. By obtaining a signal corresponding to the pipe size, the efficiency of the flow meter is increased.

In the present invention, the optional preamplifier 30 includes 16 filters corresponding to the fluid and the pipe size, and selects one of the built-in filters using the selector 31 to obtain the best signal. This eliminates the hassle of having to provide a separate vortex flowmeter according to the type of fluid and the pipe size.

In the conventional vortex flow meter, it is difficult to obtain a precise frequency signal corresponding to the type of fluid and the pipe size by using a fixed filter element instead of the selective preamplifier 30 whose filter is selected by the selector 31. .

The signal selected by the selective preamplifier 30 is clamped while passing through the clamping amplifier 22, and is then compared with the reference voltage by the comparator 23 to obtain a pulse wave, and the pulse wave obtained by the comparator 23 is Is applied to the duty control element 40.

Here, the frequency signal passing through the selective preamplifier 30, the frequency signal passing through the clamping amplifier 22, and the square wave pulse passing through the comparator 23 are selected preamplifier 30, clamping amplifier 22 and As shown below the comparator 23.

The duty control element 40 of the present invention is to adjust the duty so that the flow rate calculation is made correctly, and the duty control element 40 transmits a signal of the detection circuit 20 to the measurement circuit 50. As described above, by separating power from the detection circuit 20 side and the measurement circuit 50 side from each other, it is possible to prevent noise from entering the power line.

In other words, the duty control element 40 of the present invention prevents the mixing of noise and makes the calculation easy by changing the duty of the pulse in which the signal detected by the piezoelectric element 10 is changed into a pulse wave.

The pulse signal output from the duty control element 40 is passed to the main control unit 52 through a low pulse cutoff 51 for removing the flow rate below the minimum flow rate for each pipe size so as to calculate the flow rate.

The main control unit 52 of the present invention calculates the flow rate by calculating the pulse signal, but the flow rate is an error occurs according to the temperature of the measurement place, so that the temperature compensation is performed by checking the measured value of the temperature sensor 53 Allow the calculation to be done.

The flow rate calculated by the main control unit 52 allows the display to be made through the display unit 54 while the signal value calculated by the main control unit 52 can be transmitted to the outside through the USB module 55. Data is transmitted and received to and from the computer through the communication device 56.

In the present invention, the current driver (current driver) is to output a current of 4 ~ 20mA stably, the CMC connected to the output line is a power supply noise canceling device, OC on / off is a device for controlling the open collector output, Inverse Current Protect is a reverse current protection device, Over Voltage Protect is a protection device against overvoltage input, Surge Protect is a protection device against lightning, and such a configuration is a general configuration, and a detailed description thereof will be omitted.

According to the present invention, the vortex frequency proportional to the flow velocity obtained in the piezoelectric element 10 is amplified through the charge amplifier 21 and then selected through the optional preamplifier 30 having 16 filters corresponding to the fluid and the pipe size. In addition, the signal selected by the selective preamplifier 30 is obtained as a pulse through the clamping amplifier 22 and the comparator 23.

Here, the optional preamplifier 30 includes 16 filters corresponding to the fluid and the pipe size, and then selects one of the built-in filters using the selector 31.

The pulse obtained from the comparator 23 is applied to the main control unit 52 after the power line is separated through the duty control element 40 so as to calculate the flow rate, but the pulse signal output from the duty control element 40 is After passing through the low pulse cutoff 51 to remove below the minimum flow rate for each pipe size is transferred to the main control unit 52 so that the flow rate calculation is made.

The main control unit 52 of the present invention calculates a flow rate by calculating a pulse signal, but checks the measured value of the temperature sensor 53 so that a flow rate calculation with temperature compensation is performed so that a precise flow rate calculation is performed.

10 piezoelectric element 20 detection circuit
30: optional preamplifier 31: selector
40: duty control element 50: measuring circuit
52: main control unit 53: temperature element
54: display unit 55: USB module
56: communication device

Claims (3)

The signal detected by the piezoelectric element 10 constituting the vortex meter is amplified by the charge amplifier 21, and the signal amplified by the charge amplifier 21 is a plurality of filters provided corresponding to the type of fluid and the pipe size. And a selectable preamplifier 30 for selecting one of the selectors 31 to detect the signal, and the signal detected by the selectable preamplifier 30 is converted into a pulse signal through the clamping amplifier 22 and the comparator 23. Configure the detection circuit 20 to be converted and then applied to the duty control element 40;
The pulse signal output from the duty control element 40 is inputted to the main control unit 52 after the low pulse cutoff 51 for removing the lowest flow signal, so that the flow rate calculation is performed, and the main control unit 52 The temperature compensation is applied to the temperature sensor 53, and the value calculated by the main control unit 52 is outputted through the display unit 54 and the USB module 55, while the communication device 56 is used. A signal detection circuit for a vortex flow meter, characterized in that the measuring circuit 50 is configured to make a data input and output to and from the computer.
2. The duty control element 40 according to claim 1, wherein the duty control element 40 which receives the pulse of the detection circuit 20 and changes the pulse duty to the main control unit 52 of the measurement circuit 50 is a power source of the detection circuit 20. A signal detection circuit for a vortex flow meter, characterized in that the line and the power supply line of the measuring circuit (50) are separated to prevent noise mixing.
2. The signal detection circuit for a vortex flow meter according to claim 1, wherein fault diagnosis is performed quickly so that an output waveform of each block constituting the detection circuit (20) can be measured.

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