KR20190083313A - Intelligent flow measurement method and intelligent pressure measurement method - Google Patents

Abstract

The present invention relates to an intelligent flow rate measuring method for measuring a flow rate of a fluid flowing in a pipe using an ultrasonic flowmeter. The intelligent flow rate measuring method specifically comprises a step of measuring a flow rate of a first time point, a step of determining a control deviation range according to the flow rate of the first time point, a step of measuring a flow rate of a second time point, and a step of determining whether the flow rate of the second time point is within the control deviation range. The step of determining a control deviation range according to the flow rate of the first time point comprises a step of deriving a control deviation of a maximum measurable flow rate of the ultrasonic flowmeter, and a step of deriving a control deviation according to a degree of sensitivity determined by the flow rate using the control deviation of the maximum measurable flow rate.

Description

TECHNICAL FIELD [0001] The present invention relates to an intelligent flow measurement method and an intelligent pressure measurement method,

The present invention relates to an intelligent flow measurement method and an intelligent flow measurement method that can be used in pipe network analysis to help manage a network.

A pipe network is a complex waterway that forms an isolated system by connecting a number of pipes such as industrial water supply pipes, city water supply and sewage pipes, and heat supply networks. To operate such a network effectively, pipe network analysis is essential.

The network analysis is used to monitor the status of the pipeline, whether an event such as valve shutoff has occurred, to monitor the occurrence of problems such as leaks in the pipeline, or to control the network management system for efficient network operation.

Such pipe network analysis is based on silver flow measurement. That is, the measurement error of the flow meter leads to the error of the pipe network analysis. Particularly, the flow rate of the flowmeter varies depending on the flow rate. In actual operation, the flow rate is not constant, so that the accuracy of the pipe network analysis is further lowered and efficient management of the pipe network becomes difficult. In particular, even when the type of fluid is changed or the inside diameter of the pipe changes, the error level of the flow meter changes.

As a result, fluctuations in the error level of the flowmeter cause difficulties in setting the control deviation for controlling the flowmeter.

Therefore, a flow rate or pressure measurement method that can determine the control deviation by a new method is needed for efficient control of the flow meter.

An object of the present invention is to provide an intelligent flow measuring method capable of efficiently controlling an ultrasonic flowmeter even in the case of a specific amount or a low flow rate by considering the sensitivity according to a flow rate change.

In addition, we propose an intelligent flow measurement method that can be used effectively even when the type of fluid in a pipe installed with a flow meter changes or the fluid temperature changes.

On the other hand, other unspecified purposes of the present invention will be further considered within the scope of the following detailed description and easily deduced from the effects thereof.

According to an aspect of the present invention, there is provided an intelligent flow rate measuring method for measuring a flow rate of a fluid flowing through a piping using an ultrasonic flowmeter. Specifically, one embodiment includes measuring a flow rate at a first time point; Determining a control deviation range according to a flow velocity at a first time point; Measuring a flow rate at a second time point; And determining whether a flow velocity at a second time point is within a control deviation range, wherein the step of determining a control deviation range according to the flow velocity at the first time point comprises deriving a control deviation of the maximum measurable flow velocity of the ultrasonic flowmeter ; And deriving a control deviation according to the sensitivity determined by the flow velocity using the control deviation of the maximum measurable flow velocity.

According to another aspect of the present invention, there is provided an intelligent flow rate measuring method for measuring a flow rate of a fluid flowing through a pipe using an ultrasonic flow meter. Specifically, another embodiment includes: measuring a Reynolds number at a first time point; Determining a control deviation range according to the Reynolds number at the first time point; Measuring a Reynolds number at a second time point; And determining whether the Reynolds number of the second time point is within a control deviation range, wherein the step of determining a control deviation range according to the Reynolds number of the first time point includes: determining a control deviation of the maximum measurable Reynolds number of the ultrasonic flowmeter ; And deriving a control deviation according to the sensitivity determined by the Reynolds number using the control deviation of the maximum measurable Reynolds number.

According to another aspect of the present invention, there is provided an intelligent pressure measurement method for measuring a pressure of a fluid flowing through a pipe using a pressure gauge. Specifically, another embodiment includes measuring a pressure at a first time point; Determining a control deviation range according to the pressure at the first time point; Measuring a pressure at a second time point; And determining whether the pressure at the second time point is within the control deviation range, wherein the step of determining the control deviation range according to the pressure at the first time point comprises: deriving a control deviation of the maximum measurable pressure of the pressure gauge step; And deriving a control deviation according to the sensitivity determined by the pressure using the control deviation of the maximum measurable pressure.

The intelligent flow measurement method according to an embodiment of the present invention derives a control deviation according to the sensitivity increasing as the flow rate decreases from the control deviation in the maximum measurable flowmeter to thereby change the control deviation range for each flow velocity, It is possible to control the flow meter efficiently.

Further, the intelligent flow rate measuring method according to an embodiment of the present invention may be configured such that the control deviation, which is a determination index for controlling the flow meter, is set based on the Reynold's number, It is advantageous that the temperature can be effectively used even when the temperature of the liquid is varied.

On the other hand, even if the effects are not explicitly mentioned here, the effect described in the following specification, which is expected by the technical features of the present invention, and its potential effects are treated as described in the specification of the present invention.

1 is a schematic block diagram of an ultrasonic flow meter capable of using an intelligent flow measurement method according to an embodiment of the present invention.
2 is a schematic flow chart of an intelligent flow measurement method in accordance with an embodiment of the present invention.
FIG. 3 is a reference graph for explaining control of a flow meter using a determination factor derived according to an intelligent flow measurement method according to an embodiment of the present invention.
* The accompanying drawings illustrate examples of the present invention in order to facilitate understanding of the technical idea of the present invention, and thus the scope of the present invention is not limited thereto.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may obscure the subject matter of the present invention.

1 is a schematic block diagram of an ultrasonic flow meter capable of using an intelligent flow measurement method according to an embodiment of the present invention.

Referring to FIG. 1, a method of measuring a flow velocity using an ultrasonic vibrator is expressed as follows.

Q = A x V

At this time,

Q: Fluid flow rate

A: Cross-sectional area of the flow path

V: average velocity of fluid

That is, if the cross-sectional area of the fluid in the flow path and the flow rate of the fluid are known, the flow rate can be calculated. The cross-sectional area of the fluid is equal to the cross-sectional area of the flowpath, assuming that the fluid fills the flowpath.

On the other hand, the measurement of the flow rate of the fluid in the ultrasonic flowmeter is generally obtained by the propagation time difference method. That is, a pair of ultrasonic transducers are provided so as to face each other at the A point of the flow path and the B point located downstream of the A point in the flow direction of the fluid at a certain angle (?) With respect to the flow direction of the fluid. Let C be the sound speed at which the ultrasonic waves emitted from the ultrasonic vibrator are transmitted through the fluid, C be the average velocity of the fluid, L be the distance between the ultrasonic vibrators, B arrival time to the point of time t of the ultrasound firing in _AB and the point B reaches the point a are each as follows: t _BA.

The propagation time when the ultrasonic wave is fired in the forward direction (point A to point B) with respect to the traveling direction of the fluid is shorter than the propagation time when the ultrasonic wave is fired in the reverse direction with respect to the traveling direction of the fluid (point A to point B) . The time difference Δt is expressed as follows.

항은 무시할 수 있을 정도로 작으므로, 위의 식은 다음과 같이 정리할 수 있다.At this time, if it is liquid or the maximum flow velocity value is relatively small (for example, 10 ㎧ or less)

Since the term is negligibly small, the above equation can be summarized as follows.

The flow rate is calculated by multiplying the cross-sectional area of the fluid by one of the flow velocities thus obtained.

However, since the measurement method of the ultrasonic flowmeter uses the difference DELTA t which is a very short time difference, the measurement error increases as the flow rate decreases.

On the other hand, among the ultrasonic flow meters, the battery-powered ultrasonic flow meter needs to control the measurement period of the flow meter to prevent unnecessary power consumption when there is no flow rate through the oil pipe or when there is no change in the measured flow rate.

For this purpose, a method of increasing the measurement interval is used when the flow rate measured at the second time point is within the control deviation, compared with the flow rate measured based on the first time point. For example, the flow rate is measured at intervals of 1 second. If the variation of the measured flow rate is within the control deviation, the measurement period is increased to 2 seconds, and if the variation of the flow rate measured at the interval of 2 seconds is also within the control deviation, Increase the period to 4 seconds. If the amount of change in the measured flow rate deviates from the control deviation, the measurement interval may be reduced again or returned to the initial measurement interval.

If the control deviation is 1%, if the fluid flows at a velocity of 10 m / s at the first point in time, if the fluid flows at a velocity of 0.99 ~ 1.01 m / s at the second point of time, the measurement interval is increased to prevent unnecessary power consumption something to do.

However, this method is problematic at low flow rates. For example, if the control deviation is 1%, if the fluid flows at a velocity of 0.1 m / s at the first point of time, then the measurement interval is increased only if the fluid flows at a velocity of 0.099-0.001 m / s at the second point of time . However, at low flow rates, there is a high possibility of deviating from a 1% control deviation due to friction between the fluid and the pipe wall, and measurement errors of the flow meter itself.

Therefore, it is necessary to use intelligent flow measurement method which can change the control deviation according to the existing flow rate.

2 is a schematic flow chart of an intelligent flow measurement method in accordance with an embodiment of the present invention.

Referring to FIG. 2, an intelligent flow rate measuring method according to an embodiment of the present invention includes steps of measuring a flow rate at a first time point (S10), determining a control deviation range according to a flow rate at a first time point (S20) A step S30 of measuring the flow rate at the second time point and a step S40 of determining whether the flow rate at the second time point is within the control deviation range.

A first step (S30) of measuring the flow velocity (V ₁₎ step (S10) and flow rate (V ₂₎ of the second time to measure the time can be carried out in an ultrasonic flow meter, in particular using a battery-powered ultrasonic flow .

Claim to specifically look at with respect to the step (S20) for determining a control deviation range in accordance with the first flow rate (V ₁₎ of the start point.

First, a step S21 of deriving a control deviation of the maximum measurable flow velocity of the ultrasonic flowmeter is performed. In the intelligent flow measurement method according to an embodiment of the present invention, the measurement error (CD _max ) of the maximum measurable flow velocity of the corresponding ultrasonic flowmeter can be obtained using the error (E _max ) of the maximum measurable flow velocity. This is because the error of the maximum measurable flow velocity (E _max ) is the smallest error within the measurable flow rate range.

Can be used as it is an error (E _max) at the maximum measurable flow rate (V ₁₀₀₎ as the control deviation (CD _max) of the maximum measurable flow rate (V _100), but not limited to, the maximum measurable by the correction value The control deviation (CD _max ) of the maximum measurable flow velocity can be corrected from the error (E _max ) of the flow velocity.

In other words, it is multiplied by the correction value to the error (E _max) at the maximum measurable flow rate (V ₁₀₀₎ to determine the control deviation (C _max) at the maximum measurable flow rate (V _100).

For example, the more errors (E _max) at the maximum measurable flow rate (V ₁₀₀₎ error (E _max) of 1%, and the control deviation (CD _max) the maximum measuring flow rate of a? In (V ₁₀₀₎ 20% wide, the control deviation CD is 1.2%.

However, if the flow rate is small, that is, if the flow velocity is small, the error becomes large. Therefore, in order to control the flow meter efficiently and accurately, it is necessary to vary the control deviation according to the flow velocity.

The intelligent flow measurement method according to an embodiment of the present invention derives a control deviation CD according to the sensitivity determined by the flow velocity V by using a measurement deviation CD _max of the maximum measurable flow velocity V ₁₀₀ (Step S22).

At this time, the control deviation CD calculated according to the sensitivity is characterized in that the control deviation CD increases gradually or stepwise as the flow velocity decreases.

For example, the control deviation CD according to the sensitivity of an arbitrary flow velocity V can be calculated in the following linear form.

However, since the control deviation (CD) at a specific flow velocity (V) does not change linearly, the control deviation according to the sensitivity can be calculated in the following nonlinear form for more accurate control of the ultrasonic flowmeter.

If the control deviation (CD) is calculated by multiplying the first control deviation (CD) to the flow velocity (V ₁₎ at the time it determines the control deviation range in accordance with the flow velocity (V ₁₎ of the first point.

For example, the flow rate of a first time point ₍₁ V) is 0.1 m / s, if the control deviation (CD) at that time is 100% 0 ~ 0.2 m / s is the variation control range.

When thus the control deviation range determining method comprising: determining that the step of measuring the flow velocity (V ₂₎ of the second point in time (S30) is performed and, the flow rate (V ₂₎ of the second point located within the control deviation range (S40) the .

In a second flow velocity of the point (V ₂₎ determining that the position in the control deviation range (S40), if placed in the second flow rate (V ₂₎ is controlled variation range of the start point may increase the measurement interval of the ultrasonic flow meter , whereas if the second time flow rate (V ₂₎ located outside the control range of deviation can be reversed as to reduce the measurement interval of the ultrasonic flow meter, or the initial state.

At this time, it is possible to use a judgment factor DE defined in the following equation (step S40) to determine whether it is within the control deviation range.

That is, if the determination factor DE is less than 1, the measurement interval of the ultrasonic flowmeter is increased. If the determination factor DE is greater than 1, the measurement interval of the ultrasonic flowmeter can be reduced or returned to the initial state.

At this time, increasing the measurement interval may be performed when the determination factor DE is 1 or less, but it may be set to be performed when the determination factor DE is 1 or less consecutively.

On the other hand, the above sensitivity equation can be applied to a pressure gauge. That is, the intelligent pressure measuring method according to another embodiment of the present invention uses a measurement deviation (CD _max ) of the maximum measurable pressure (P ₁₀₀ ) to calculate a control deviation CD according to the sensitivity determined by the pressure P . ≪ / RTI >

At this time, the control deviation CD calculated according to the sensitivity is characterized in that the control deviation CD increases gradually or stepwise as the flow velocity decreases.

For example, the control deviation CD according to the sensitivity of an arbitrary pressure P can be calculated in the following linear form.

However, since the control deviation (CD) at a specific pressure (P) does not change linearly, the control deviation according to the sensitivity can be calculated in the following nonlinear form for more accurate control of the ultrasonic flowmeter.

If the control deviation (CD) is calculated by multiplying the pressure (P ₁₎ control deviation (CD) in a first point in time to determine the control deviation range in accordance with the pressure (P ₁₎ of the first point.

Thus, when the control deviation range determined by measuring the pressure (P ₂₎ of the second time is performed, and the step of determining that the second pressure of the point (P ₂₎ is located within the control range of the deviation is performed.

Pressure of the second point (P ₂₎ in step to determine if a location within the control deviation range, the if the location in the pressure (P ₂₎ The control deviation range of the second time point may increase the measurement interval of the pressure gauge, whereas the second If the pressure at the starting point (P ₂ ) is outside the control deviation range, the measuring interval of the pressure gauge can be reduced or returned to the initial state.

At this time, the step of determining whether it is within the control deviation range may use the judgment factor DE defined by the following equation.

That is, when the determination factor DE is 1 or less, the measurement interval of the pressure gauge is increased. If the determination factor DE is greater than 1, the measurement interval of the pressure gauge can be reduced or returned to the initial state.

At this time, increasing the measurement interval may be performed when the determination factor DE is 1 or less, but it may be set to be performed when the determination factor DE is 1 or less consecutively.

Again, the flow measurement method will be described. However, it will be apparent to those skilled in the art that a flow meter can be applied to a pressure gauge within the scope of the following description.

FIG. 3 is a reference graph for explaining control of a flow meter using a determination factor derived according to an intelligent flow measurement method according to an embodiment of the present invention.

3, the ultrasonic flowmeter to which the intelligent flow rate measuring method according to the embodiment of the present invention is applied, increases the measurement interval by doubling because the determination factor (DE) measured at Time 1 is smaller than 1, Measure the flow rate.

Since the determination factor DE measured at Time 3 and Time 5 is continuously smaller than 1, the measurement interval is increased four times. The ultrasonic flowmeter then measures the flow rate at Time 9 and Time 13.

The judgment factor DE measured at Time 13 exceeds 1. Therefore, the ultrasonic flowmeter returns the measurement interval to the initial state and measures the flow rate at Time 14.

Again, since the determination factor (DE) of Time 14 and Time 15 that were measured at the initial measurement interval is continuously less than 1, the measurement interval is doubled and the flow rate is measured at Time 17 and Time 19.

By using the determination factor DE as described above, it is possible to more easily control the measurement interval of the ultrasonic flowmeter.

Meanwhile, the intelligent flow rate measuring method according to another embodiment of the present invention can be performed by converting the flow rate into a Reynold's number.

That is, the intelligent flow rate measuring method according to another embodiment of the present invention includes the steps of measuring the Reynolds number at the first time point, determining the control deviation range according to the Reynolds number at the first time point, determining the Reynolds number at the second time point And determining whether the Reynolds number at the second time point is within the control deviation range.

The inertia force due to the flow velocity and the viscous force according to the rate of change of the flow velocity are the main physical quantities that determine the characteristics of the fluid flow. This is because the characteristics of the flow depend on the relative weight of the inertial force and the viscous force generated by the flow. At lower velocities, viscous forces are dominant over inertial forces, and flow represents a laminar flow. On the other hand, when the flow velocity is high, the inertial force is dominant rather than the viscous force, and it exhibits a very complicated turbulent flow. The Reynolds number is a dimensionless parameter that does not have a unit that represents the relative proportion of the viscous and inertial forces. The Reynolds number is defined as the relative ratio of the inertial force to the viscous force, and more specifically, (pipe diameter × flow velocity) / (tie point coefficient).

On the other hand, Reynolds numbers for distinguishing laminar flow and turbulent flow are different depending on where the fluid flows, such as a pipe, a channel or a flat plate.

[Table 1]

This Reynolds number corresponds to a very effective means to deal with the law of matter, irrespective of the kind of fluid, flowing shape, environment, and so on.

In particular, when the temperature condition is within a certain range, such as the upper and the sewage pipes, the Reynolds number (Re) can be generalized as follows. At this time, the temperature condition for generalizing the Reynolds number is 0 to 50 ° C.

β(비례계수) × V(유속) × D(직경)Re

β (proportional coefficient) × V (flow rate) × D (diameter)

In addition, the kinematic viscosity can also be calculated simply in the following equation. Where t is the temperature in degrees Celsius.

Therefore, it is possible to convert the flow rate used in the intelligent flow measurement method according to the embodiment of the present invention into the Reynolds number.

Accordingly, the step of determining the control deviation range according to the Reynolds number at the first time (Re ₁ ) will be described in detail.

First, a step S21 of calculating an error of the maximum value of the measurable Reynolds number of the ultrasonic flowmeter is performed.

Reynolds number up to measure (Re ₁₀₀₎ error (E _max) the maximum measurable Reynolds number, but can be used as it is as a control deviation (CD _max) of (Re _100), is not limited to, up to by a correction value from The control deviation (CD _max ) of the maximum measurable Reynolds number can be adjusted from the error (E _max ) of the measurable Reynolds number.

That is, the maximum measurable Reynolds number (Re ₁₀₀₎ multiplied by the correction value to the error (E _max) in determining the control deviation (C _max) at the maximum can be measured Reynolds number (Re _100).

For example, the maximum measurable Reynolds number (Re ₁₀₀₎ error in the error (E _max) of 1%, and the? Of the control deviation (CD _max) number of the maximum measured Reynolds number (Re ₁₀₀₎ of the (E _max ), The control deviation (CD) is 1.2%.

However, since the error becomes larger as the flow rate becomes smaller, it is necessary to vary the control deviation according to the Reynolds number in order to control the ultrasonic flowmeter efficiently and accurately.

Accordingly, the intelligent flow measurement method according to an embodiment of the present invention includes deriving a control deviation (CD) according to the sensitivity determined by the Reynolds number using the control deviation (CD _max ) of the maximum measurable Reynolds number (S22 ) Is performed.

In this case, the step of deriving the control deviation CD according to the sensitivity is characterized in that the control deviation CD increases gradually or stepwise as the Reynolds number decreases.

For example, the control deviation (CD) at a specific Reynolds number (Re) can be calculated in the following linear form.

However, since the control deviation (CD) at a specific Reynolds number (Re) does not change linearly, the control deviation can be calculated in the following nonlinear form for more accurate control of the ultrasonic flowmeter.

When the control deviation CD is calculated, the control deviation range according to the Reynolds number at the first time is determined by multiplying the Reynolds number at the first time by the control deviation CD.

Thus, when the control deviation range determined by measuring the Reynolds number of the second point (Re ₂₎ is performed, and the method comprising: determining whether two Reynolds number of the start point (Re ₂₎ is located within a range of deviation control is performed.

Reynold's number of the second point in time in determining whether (Re ₂₎ is located in a control deviation range, the Reynolds number of the second point in time if (Re ₂₎ is located in a control deviation range may increase the measurement interval of the ultrasonic flow meter, Conversely, if the Reynolds number of the second point (Re ₂₎ is located outside the control range of variation it may be reversed as to reduce the measurement interval of the ultrasonic flow meter, or the initial state.

Further, the intelligent flow rate measuring method according to another embodiment of the present invention can use a judgment factor as in the embodiment.

The scope of protection of the invention is not limited to the description and the expression of the embodiments explicitly described in the foregoing. It is again to be understood that the present invention is not limited by the modifications or substitutions that are obvious to those skilled in the art.

Claims (8)

1. An intelligent flow rate measuring method for measuring a flow rate of a fluid flowing through a piping by using an ultrasonic flowmeter,
Measuring a flow rate at a first time point;
Determining a control deviation range according to a flow velocity at a first time point;
Measuring a flow rate at a second time point; And
And determining whether the flow velocity at the second time point is within a control deviation range,
Wherein the step of determining a control deviation range according to the flow velocity at the first time point comprises:
Deriving a control deviation of the maximum measurable flow rate of the ultrasonic flowmeter; And
And deriving a control deviation according to the sensitivity determined by the flow velocity using a control deviation of the maximum measurable flow rate.
The method according to claim 1,
Wherein the control deviation according to the sensitivity increases gradually or stepwise as the flow velocity decreases.
The method according to claim 1,
When the control deviation CD _max at the maximum measurable flow velocity (V ₁₀₀ )
The control deviation CD according to the sensitivity of the arbitrary flow velocity V

Of the flow rate of the fluid.
The method according to claim 1,
When the control deviation CD _max at the maximum measurable flow velocity (V ₁₀₀ )
The control deviation CD according to the sensitivity of the arbitrary flow velocity V

Of the flow rate of the fluid.
The method according to claim 1,
Wherein the step of determining whether the flow velocity at the second time point is within the control deviation range comprises:
If the flow velocity at the second time point is within the control deviation range, the measurement interval of the ultrasonic flowmeter is increased,
Wherein the measurement interval of the ultrasonic flowmeter is reduced or returned to the initial state when the flow velocity at the second time point is outside the control deviation range.
The method according to claim 1,
Wherein the step of determining whether the flow velocity at the second time point is within the control deviation range comprises:
By the flow velocity V1 at the first time point, the flow velocity V2 at the second time point, and the control deviation CD according to the sensitivity

(DE) defined as < RTI ID = 0.0 >
If the determination factor DE is less than 1, the measurement interval of the ultrasonic flowmeter is increased,
Wherein the measurement interval of the ultrasonic flowmeter is reduced or returned to the initial state when the determination factor (DE) is greater than 1.

1. An intelligent flow rate measuring method for measuring a flow rate of a fluid flowing through a piping by using an ultrasonic flowmeter,
Measuring a Reynolds number at a first time point;
Determining a control deviation range according to the Reynolds number at the first time point;
Measuring a Reynolds number at a second time point; And
And determining whether the Reynolds number of the second time point is within the control deviation range,
Wherein the step of determining the control deviation range according to the Reynolds number at the first time point comprises:
Deriving a control deviation of the maximum measurable Reynolds number of the ultrasonic flowmeter; And
And deriving a control deviation according to the sensitivity determined by the Reynolds number using a control deviation of the maximum measurable Reynolds number.
1. An intelligent pressure measuring method for measuring a pressure of a fluid flowing through a pipe using a pressure gauge,
Measuring a pressure at a first time point;
Determining a control deviation range according to the pressure at the first time point;
Measuring a pressure at a second time point; And
And determining whether the pressure at the second time point is within the control deviation range,
Wherein the step of determining the control deviation range according to the pressure at the first time point comprises:
Deriving a control deviation of the maximum measurable pressure of the pressure gauge; And
And deriving a control deviation according to the sensitivity determined by the pressure using the control deviation of the maximum measurable pressure.

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