KR100205527B1 - Flow meter test apparatus - Google Patents

Abstract

For flow pulses that transmit uneven flow pulses, a reliable meter factor is tested by a small volume probe to reduce the test time.

During the test, open the bypass valve (2) of the test line in which the flowmeter under test (3) and the small volume probe (4) are connected in series. The CPU 13 calculates the irregularity rate of the fine pulses, and calculates the reproducibility (%) per lane based on the number of flow rate pulses, the number of flow rate pulses, and the irregularity.

Thereafter, the CPU 13 calculates the required number of test probing passes Np by substituting the reproducibility (%) per LAN into another predetermined water level to obtain the required reproducibility (%).

Description

Flowmeter Tester

1 is a block diagram showing an example of the principle configuration of the flowmeter test apparatus of the present invention.

2 is a flowchart of computer software.

3 is a graph showing an example of test results of the relationship between the irregularity and reproducibility of flow pulses.

4 is a graph showing an example of test results of correlation between required reproducibility (%) and probing pass.

5 is a flowchart showing a flowchart of the main computing device of another embodiment in the flowmeter test apparatus of the present invention.

* Explanation of symbols for the main parts of the drawings

1: Oil pipe 2: Bypass valve

3: flow meter under test 3a: flow rate pulse generator

4: SVP (small volume prober) 5: cylinder

6: Passtone 7: Piston Rod

8,9 detector 10 driving part

11,12: conduit 13: CPU (main operation unit)

14; Drive control unit 15,16: on-off valve

The present invention relates to a flowmeter test apparatus for performing a train test using a reference volume pipe to test a flow meter that transmits an irregular flow pulse. More specifically, the flow meter under test uses a small volume prover. The present invention relates to a flowmeter test apparatus having a function of calculating the number of flow test times necessary to obtain a test pass of required repeatability.

The test method of the flow meter includes an absolute test method for comparing a reading of the test flow meter measured by connecting a container having a reference volume and a test flow meter in series and distributing the reference fluid volume to the container with the reference volume or weight. For example, there is a comparative test method obtained from a comparison with a reading flow meter, and an absolute test method is used when a high precision train accuracy is required.

In this absolute test method, it is common to apply the standard tank method and the standard volumetric method to compare with the standard volume. The reference tank method reads and detects the upper and lower levels because the capacity between the upper and lower levels of the reference tank is the reference capacity. The reference volume pipe method is based on the capacity in a predetermined section of the reference volume pipe of a predetermined section.

The reference tank method requires the effort of reading the upper and lower levels and calculating the reference volume from the read value, and inefficient, in the standard volume pipe method, the differential pressure is slightly larger and smaller than the internal diameter of the standard volume pipe. Compared to the number of flow pulses transmitted from the flow meter under test while inserting a spare made of external rubber ball to the extent that it can be operated), and passing this spare through a position detector (called a detector) disposed in the reference section. Because the train test is carried out, it is possible to operate remotely, and it is easy to make automated measurement, and it has the characteristic that reasonable test is possible.

The flowmeter test is required to test the flowmeter in real time according to the appearance of a more accurate flowmeter and the diversification of the measurement fluid, and the flowmeter test apparatus using a small volumetric reference volume pipe in the standard volumetric method (Small volume prober; Small) Prover, which is later called SVP), is used, and the size of the device is such that it can be mounted on a car and returned.

The SVP basically seals the piston so that liquid does not leak into the cylinder with the same cross-sectional area, and is movably inserted to read the discharged flow rate and the flow rate under test according to the piston movement in a predetermined section (determined by the detector position). Volume comparison is made.

As for the test system for SVP, the Manual of Petroleum Measurement Standard, Ch 4-Apt., Published in June 1988 by the American Petroleum Institute (API); Section 3 of Ch'apartmenter4-Proving System (Chapter 4 Probing System) provides a manual on SVP.

The test method of the flowmeter by the SVP is to compare the volume of the reference volume pipe from the outgoing section transmitted by the detector as described above with the number of flow pulses transmitted therebetween. The period until the first flow pulse is sent out, and the difference between the outgoing signal sent by the detector at the end of measurement and the flow pulse sent before and after the outgoing signal is sent, that is, the volume less than the flow pulse interval, A method of obtaining the volume of the half-segment as a harmonic or a difference of the ratios is referred to as the ratio of the number of clock pulses of high frequency (called the double timing method).

However, in the double timing method, it is a condition that a constant flow rate is used in the test and the flow rate pulses are completely transmitted at equal intervals, and the error occurs when the flow rate is not constant or the sending interval of the flow rate pulses is not constant.

The pulse error of the flow rate error varies depending on the type of the flowmeter to be tested. In the case of a turbine meter in which the rotor and the flowmeter transmitter which rotate in proportion to the flow rate are close to each other, the flow rate pulses having excellent SN ratios are transmitted. In the case where a rotational transmission mechanism such as a gear is provided between the electrons and the flow rate transmitter, and a volumetric flowmeter in which the rotation angle and discharge amount of the rotor are not proportional to each other, a pulse error occurs.

According to the API manual, the flowmeter in which the rotor and the flow transmitter are in close proximity is subjected to five tests in order to achieve a train reproducibility of 0.05%, and to calculate the meter factor (flow coefficient; liters / pulse) as these average values. It is.

In the test of the flowmeter which transmits a flow pulse of an uneven pulse interval, the process of increasing the moving number of a probing piston (called the number of probing passes), or setting the tolerance of reproducibility is large.

For example, it is explained that the number of probing passes is required within 0.1% of reproducibility, and as the number of probing passes increases, the reproducibility of the flowmeter increases and at the same time, the quality of the average value is improved.

However, there is no explanation regarding the relationship between the reproducibility required by the number of probing passes and the error of the transmission pulse.

SUMMARY OF THE INVENTION An object of the present invention is to provide a flow rate testing apparatus for obtaining the number of probing passes necessary for obtaining a reproducibility required in a test of a flow meter which is an error of a flow rate pulse.

Another object of the present invention is to provide a flow rate test apparatus which can obtain a reliable meter factor and can save test time by eliminating unnecessary probing passes.

In order to achieve the above object of the present invention, (1) has a flow meter under test to irregularly transmit a flow pulse of a predetermined flow coefficient at a constant flow rate, and a piston capable of reciprocating closely with the liquid in a cylinder having a constant cross section, Means for measuring an irregularity of the flow pulses from a superior pulse output by the flow meter under test in a flow meter test in which the flow rate pulses of the reference volume in the cylinder are compared and the flow rate coefficient of the superior pulses is obtained; In the one measurement frequency in the relationship between the calculation means for calculating the flow rate pulse number from the reference volume and the flow rate coefficient, and the reproducibility of the measurement frequency means for the irregularity rate of the flow pulse period per flow rate pulse injection number known in advance. Means for calculating the reproducibility of the piston and the piston per measurement frequency required to obtain this reproducibility and It is composed of a main lead having a calculation means for calculating the reproducibility of the required flowmeter in relation to the number of probing passes, and a drive control unit for driving the reference volume pipe based on the output of the main operator, or (2) a flow meter under test for irregularly transmitting the flow pulse of the flow coefficient obtained from the constant flow rate; In the flowmeter test, which has a piston that can reciprocate closely with the liquid in a cylinder with a constant cross section, compare the number of flow pulses of a reference volume in a predetermined section in the cylinder, and obtain a flow coefficient, the number of probing passes per measurement number And a flow coefficient calculation means for calculating a rainfall coefficient for each probing pass number, a standard deviation calculation means for calculating a standard deviation of the flow coefficient from the calculated flow coefficient, and the standard deviation is a reproducibility of the prescribed flow coefficient. In the following cases, the test is terminated, and the number of probing passes per measurement is determined according to the magnitude of the standard deviation of the flow coefficient when the reproducibility of the above specification is exceeded. And a driving control section for driving the reference volume pipe by the output of the main computing unit. It will have a gong.

It will be described below in accordance with an embodiment of the present invention.

1 is a block diagram showing an example of the principle configuration of the flowmeter test apparatus of the present invention, in which 1 is an oil pipe, 2 is a bypass valve, 3 is a flow meter under test, 3a is a flow pulse generator, and 4 is SVP ( Small volume probe), 5 is cylinder, 6 is piston, 7 is piston rod, 8 and 9 are detectors, 10 is drive, 11 and 12 are conduits, 13 is CPU (main operation unit), 14 is drive control, 15 And 16 are on / off valves.

In the flow meter test apparatus shown in FIG. 5, the cylinder 5 serving as the reference volume pipe is closed at both ends and the inner diameter is precisely processed. The cylinder 5 includes sealing means for sealing the inner surface of the cylinder 5 (not shown). Piston (6) is inserted into the reciprocating motion so that the liquid does not leak, and the piston rod (7) is fixedly attached to the piston (6), the driving portion (10) at the other end of the piston rod (7) Connected and drives the piston 6 in the axial direction.

In addition, the drive unit 10 includes a position detector (not shown) which detects the movement amount of the piston 6 and transmits the position signal pulse S _{3 at} every minute movement as necessary.

On the outer wall near the end surface of the cylinder 5, the detectors 8 and 9 for transmitting the reference volume signal are disposed and the position signals S ₁ and S ₂ are transmitted as the piston 6 moves.

Here, the valve 2 and the valve 15 and 16 are opened by the drive control device 14 to reciprocate the piston 6 in accordance with the instruction of the CPU 13.

The flowmeter test operation starts the test by the command of the CPU 13 when the piston 6 is in the dotted line position.

The drive control unit 14 opens the valves 15 and 16, closes the valve 2, and drives the piston 6 at a constant speed by the drive unit 10.

When the flow rate is not constant, the moving speed is constantly controlled in comparison with the position signal S ₃ to achieve rectification.

When the piston 6 passes through the detector 9, a signal S ₂ is transmitted and this flow rate pulse P is measured until the piston 6 reaches the detector 8.

During this time, since a high frequency clock pulse (for example, 100 kHz) is transmitted from the CPU 13 and a detector signal (S ₁ ) (S ₂ ) is transmitted, the flow pulses that are initially transmitted are respectively transmitted through the clock pulses. Volume detection is done within the flow pulse and the flow test of one probing pass is completed.

As the flow test of the one probing pass is completed, the piston 6 closes the valve 15, the bypass valve 2 and the valve 16 open, and return to the dotted line position.

The test result is accompanied by an error of inequality because the transmission position of the first flow pulse P is uncertain and uneven with respect to the detector signal S ₁ (S ₂ ).

When several proving passes are made, an error due to an inequality ratio occurs.

This increases the number of probing passes to improve certainty. In order to reduce the reproducibility (%), the reproducibility (%) is obtained as the number of probing passes of several times as one Ran, and this test is repeated twice, and the second LAN is tested.

3 is a graph showing an example of a test result of the relationship between the irregularity and reproducibility of the flow pulse, the flow meter under test is a volume flow rate (A) (B) (C) and a turbine meter having a different principle structure. Things and transmission gears.

The abscissa indicates the standard deviation (σ _I )% of the flow pulse period irregularity with respect to the number of injection pulses (N) of the flow pulse, and the reproducibility R _I (%) of one lance in the vertical axis.

In other words, it is natural, but it is disclosed that in order to reduce the reproducibility R ₁ per LAN, the irregularity σ _I of the flow rate spreading cycle may be reduced.

In addition, the constant C and the constant a (for example, a = 1.0, C = 4) are determined by the irrigation relation.

4 is a graph showing an example of the test result of the correlation between the required reproducibility (%) and the number of probing passes. The flowmeter under test is the same as the flowmeter in FIG.

The horizontal axis represents the required number of probing passes Np per 2 rans, and the reproducibility R ₂ (%) required for the vertical axis.

If you find the number of probing passes per 2 lanes you need in this graph,

The reproducibility (%) decreases as the number of required probing passes (Np) increases, thereby improving reproducibility.

The variable b (e.g., b = 0.8) is determined by the irrigation relation.

According to the present invention, the computer 13 calculates the required number of probing passes Np in accordance with the second and third drawings, and tests the number of necessary probing passes by the instruction of the CPU 13. Is repeated through the drive control unit 14.

2 is a flowchart of computer software,

Step 1: The irregularity (σ _I ) (%) of the flow rate pulses transmitted by the flow meter 3 measured in the bypass valve 2 opening and the piston 6 stopped state is measured.

In this case blow-flow pulse that is sequentially calculated and the standard deviation (σ _I) of the irregularities in the n sampling pulses and the average value (X).

Step 2: The number of blown pulses (Pg) is calculated from the flow rate pulse, the meter factor (1 / p: liter / pulse), and the capacity of the SVP (1 / liter).

Step 3: The irregularity and reproducibility of the flow pulse shown in FIG.

Calculate the reproducibility R ₁ (%) per LAN in the irrigation relation of.

Step 4: Correlation coefficient between the reproducibility and the number of probing passes Np shown in FIG. 3 is represented by Equation (2)

Calculate the required number of probing passes (Np) per 2 LANs under the irrigation relation of.

Step 5: The test mode is determined by an instruction to pass the Np 2 LAN to the CPU 13.

Step 6: Send a command to execute the flow rate test to the drive control unit 14 according to the set test mode.

In the above calculation method, in step 1, first, the irregularity σ _I (%) of the flowmeter under test is calculated as the standard deviation σ _I , and in step 2, the flow rate pulse proportional to the magnitude of the standard deviation σ _I is obtained. The number of flow pulses for blowing was calculated.

In practice, however, since the blown flow pulse number N is determined by the flowmeter under test and SVP, it is unnecessary to specifically calculate the blown flow pulse.

5 is a view showing a flowchart of the main computing device of another embodiment in the flowmeter test apparatus of the present invention.

For example, the number of probing passes (Np) per LAN, that is, the number of piston movements per test, is determined in advance.

The flow coefficient (Meter Facter) is calculated for each probing pass number, and the standard deviation (σ) of the flow coefficient is calculated from this calculation result, and the probing per one column is obtained to obtain the reproducibility determined according to the magnitude of the standard deviation (σ). It is possible to find the number of passes.

Step 1: At a constant flow rate, the number of probing passes Np per LAN is determined five times.

Step 2: The average value M _f of the flow coefficients for each of the probing passes Np of 1-5 times measured in Step 1, and the flow coefficients of M _f1 , M _f2 , ^... , M _f5 is calculated.

Step 3: From the flow coefficients for each probing pass number, M _f1 , M _f2 , ^... , M _f5 and the mean value of the flow coefficients (M _f ), the error variance i (i = 1, 2, -5) is obtained. The standard deviation σ is calculated from the square root of the variance of this error.

Step 4: When the calculated standard deviation sigma is less than or equal to the SVP limit, for example, 0.013%, the standard deviation sigma at this time is printed out with reproducibility% and probing is terminated.

Step 5: If the standard deviation (σ) is greater than the SVP limit of 0.013%, then this B value and the standard deviation (σ) are obtained to obtain a separately defined reproducibility, e.g., B = 0.04%.

The number of probing passes (Np) when the number of ran times in the flow rate test is two times is calculated by substituting for.

(3) is the experimental value (alpha) = 0.8 calculated | required by this inventor.

Step 6: From the standard deviation (σ) value calculated in Step 3 and B = 0.04%, the number of probing passes (Np) is obtained using Eq. (3), and from the small value of the standard deviation (σ) value to the larger value. The probing pass number Np to be obtained is N? 5, N? 10, N? 15, N? 20 and the probing pass number Np of an integer multiple of N = 5 is obtained and set to the corresponding N value.

Step 7: On the basis of the probing pass number Np determined in step 6, in the case of N> 5, a flowmeter test of two LANs is performed at the corresponding probing pass number Np.

Step 8: The data of the flowmeter test result of step 7 is computed to calculate the flow coefficient for each predetermined flow rate for each of the two LANs, and the flow coefficient is calculated as the average value.

Step 9: Print the operation result.

As is apparent from the above description, the present invention has the following effects.

The result corresponding to claim 1; When testing a flowmeter that transmits irregularly uniform pulse train pulses with SVP, in order to increase the reproducibility, the test frequency required for obtaining the required reproducibility is automatically set to increase the reproducibility. As a result, a reliable flow coefficient (meter factor) can be obtained, and the test time can be shortened because unnecessary test times are omitted.

The result corresponding to claim 1; At the specified flow rate, the number of probing passes per test number is determined in advance, and the standard deviation of the flow coefficient is calculated. Based on the standard deviation, the number of probing passes is obtained to obtain reproducibility according to a predetermined experimental value. This is rationalized.

Claims (2)

It has a test flow meter (3) which irregularly transmits a flow pulse of a predetermined flow coefficient at a constant flow rate, and a piston (6) capable of reciprocating closely with a liquid in a cylinder (5) having a constant cross section. Means for measuring the irregularity of the flow pulses from the flow pulses output by the flow meter 3 under test in the flow meter test for comparing the number of flow pulses of the reference volume within a predetermined section and obtaining the flow coefficient of the flow pulses; In the one measurement frequency in relation to a calculation means for calculating the flow rate pulse number from the reference volume and the flow rate coefficient, and the reproducibility of the measurement frequency per irregular rate of the flow rate pulse cycle of the flow rate pulse injection means. The means for calculating the reproducibility of the reproducibility and the number of probing passes for moving the piston 6 per measurement number required to obtain this reproducibility and the reproducibility required. Is composed of a main operator (13) having calculation means for calculating the reproducibility of the required flow meter (3) and a drive control unit (14) for driving the reference volume pipe based on the output of the main operator (13). Flowmeter test apparatus, characterized in that. It has a test flow meter (3) which irregularly transmits a flow pulse of a flow coefficient obtained at a constant flow rate, and a piston (6) which can reciprocate closely with a liquid in a cylinder (5) having a constant cross section, and the cylinder (5) In the flowmeter test in which the flow rate pulses of the reference volume in a predetermined section are compared and the flow rate coefficient of the flow rate pulses is obtained, A flow coefficient calculation means for obtaining the number of probing passes per measurement number and calculating a flow coefficient for each probing pass number, a standard deviation calculation means for calculating a standard deviation of the flow coefficient from the calculated flow coefficient, and the standard When the deviation is less than or equal to the reproducibility of the specified flow coefficient, the test is terminated. When the reproducibility is exceeded, the number of probing passes per measurement is determined according to the magnitude of the standard deviation of the flow coefficient. And a drive controller 14 for driving the reference volume pipe by the output of the main calculator 13, with a main operator 13 having a determination function of double the number of measurement times when the number is exceeded. Flowmeter tester.