KR100983948B1 - Portable flow meter - Google Patents

Abstract

The present invention relates to a precision flow rate measuring device for testing the precision of the test meter by measuring the pressure and temperature of the gas and the instantaneous flow rate and the accumulated flow rate precisely, and the inlet 10 through which the gas is supplied; A regulator 20 for adjusting the pressure of the gas introduced into the inlet 10 by a control valve 21; A sonic nozzle unit 30 for adjusting a flow rate of the gas supplied from the regulator 20 by the selection of the sonic nozzle 31; A discharge port 40 for supplying a gas precisely adjusted to a predetermined pressure and flow rate through the regulator 20 and the sonic nozzle unit 30 to a test meter or a facility requiring a precise flow rate supply; An integrated control unit 50 for controlling the regulator 20 and the sonic nozzle unit 30; The inlet 10, the regulator 20, the sonic nozzle unit 30, the discharge port 40, the integrated control unit 50 is characterized in that consisting of a case 60 is housed therein.
As a result, the gas flows through the sonic nozzle, and the flow rate is low and the flow rate is precisely adjusted, so that the gas can be used as a reference flow meter for inspecting a flow meter such as a gas meter. It can be used to precisely control the flow rate.

Description

Portable Precision Flow Measurement Device {PORTABLE FLOW METER}

The present invention relates to a portable flow measurement device that can be easily carried by the user to accurately measure the flow rate of the gas, more specifically using a sonic nozzle to precisely measure the flow rate under various conditions without replacing the nozzle according to the flow rate The present invention relates to a portable precision flow rate measuring device that can easily check whether or not a flow rate meter such as a gas flow meter is malfunctioning based on the measured flow rate.

Precision flow rate measurement device (reference flow meter) checks whether the gas meter accurately measures the amount of gas flowing in the gas meter and judges whether the product is defective according to the result.In general, the inspection device used for such inspection is By connecting the gas meter to the inspection device, the test gas at the proper pressure and flow rate flows into the gas meter to check whether it is accurately measured. This inspection device must ensure the reliability of the measurement, which is ensured by the accuracy of the measurement. Can be.

Accordingly, various inspection apparatuses have been developed and used as inspection apparatuses for inspecting gas meters, but recently, the flow rate of gas is accurately and precisely measured to determine whether the gas meter is defective or not based on the measured values. As a device, a precision flow rate measuring device using a sonic nozzle is used. This device uses the physical characteristics of the sonic nozzle. The sonic nozzle has a ratio of the upstream pressure and the downstream pressure of the gas passing through the nozzle below a critical pressure ratio. When the flow rate at the nozzle throat is fixed to the speed of sound and the constant flow rate is passed regardless of the downstream state of the nozzle, it is a mechanical element that uses the sonic nozzle. Therefore, it is widely used as a reference flowmeter for inspecting gas meters and the like.

As an example of a precision flow rate measuring apparatus using such a sonic nozzle, Patent No. 10-0566211 (train inspection apparatus for a dry gas meter) has been proposed.

As shown in FIG. 1, the technique of the document includes a plurality of filters 101 and a dryer 102 for removing moisture and foreign matters of the air generated in the air compressor 100 in advance, and the filter 101 and the dryer. A tank (103) for storing the air purified by (102), adjusting means (104, 105, 106) installed to keep the pressure and flow rate of the gas supplied from the tank (103) low, and the adjustment Sonic nozzle 107 is installed so that the gas passed through the means 104, 105, 106 is supplied to form a reference pressure, and the gas passed through the sonic nozzle 107 through the valve 108 a plurality of dry gas Supply pipe 109 arranged in parallel to be supplied to the meter 120, pressure and differential pressure sensor (P) and temperature sensor (installed to detect pressure, differential pressure, temperature from the pressure gauge and thermometer of the dry gas meter 120) T) and dry gas meter ( And a computer 110 installed to check the flow rate of the controller 120 and read it as a defect when it is out of the reference range.

In the technique disclosed in the above document, the components installed independently of each other are connected by pipes to form a flow path, and as the gas flows along the flow path, the flow rate is precisely measured by the sonic nozzle.

However, the above technology has a problem that it is difficult to carry or use in a small place such as a laboratory because each device installed independently is connected through a pipe, its volume is not movable, and it requires a lot of installation space. .

In addition, the conventional precision flow measurement apparatus using the sonic nozzle as described above is provided with a sonic nozzle control unit for controlling the sonic nozzle and a control unit for controlling the opening amount of each valve to configure a console, which is compatible with each control program. There is a problem that it is difficult to control by integration, and in the case of a failure, it is difficult to easily identify the cause of the failure because it manages each maintenance personnel control unit with expertise for each program.

In addition, since each component is installed separately, there is a problem in that the manufacturing cost is expensive, and it is difficult to use as a reference flowmeter for meter reading because it is not portable.

The present invention is to improve the problems of the prior art as described above, the present invention is used as a reference flow meter using a sonic nozzle as a precision flow measurement device, by moving the inspection equipment to the required place by making a compact in a single package It is to provide a portable precision flow measurement device that can inspect the equipment.

The present invention according to the above object and the gas inlet is supplied; A regulator for adjusting the pressure of the gas introduced into the inlet by a control valve; A sonic nozzle unit for adjusting a flow rate of the gas supplied from the regulator by selecting a sonic nozzle; An outlet for supplying a gas precisely adjusted to a predetermined pressure and flow rate through the regulator and the sonic nozzle part to a test meter or a facility requiring a precise flow rate supply; An integrated control unit for controlling the regulator and the sonic nozzle unit; The inlet, the regulator, the sonic nozzle unit, the outlet, and the integrated control unit is achieved by consisting of a case housed therein.

The use of the present invention can be used as a reference flowmeter for inspecting test meters through precise flow rate control of sonic nozzles, or it can supply various gases precisely in a laboratory or production line, and is manufactured in a size that can be carried in a single package, so that the precise flow rate When control is needed, it can be easily moved and used.

In addition, since it is made small, it can be used to replace the meter of the gas meter, and it is easy to maintain because the integrated configuration is controlled through the integrated board.

In addition, each component is installed in a single case, so it does not select a long flow path, so there is less defect in structure and less error in measurement value. There are advantages to it.

In addition, since the Sonic Nozzle is used, various flow rates can be easily controlled by the automatic selection of the nozzle without replacing the nozzle.

1 is a configuration diagram showing an example of a conventional inspection device for a dry gas meter,
Figure 2 is a perspective view showing an example of a portable precision flow rate measuring apparatus according to the present invention,
3 is a block diagram showing an example of a portable precision flow rate measuring apparatus according to the present invention,
4 is a perspective view showing an example of a sonic nozzle unit according to the present invention;
Figure 5 is a flow chart showing an example of a portable precision flow rate measuring apparatus according to the present invention,
Figure 6 (a, b, c) is a flow chart showing an embodiment of a portable precision flow rate measuring device according to the present invention.

Hereinafter will be described in more detail with reference to the accompanying drawings showing an embodiment of the present invention.

The present invention is a case for supplying a precise flow rate in a laboratory of a laboratory or various production lines, or a flow precision measuring device used to check the performance of a flow meter for measuring and measuring the flow rate of a gas, which is composed of a small single package. In order to provide a portable precision flow rate measuring device which is made to be movable and easy to use, as shown in FIG. A regulator 20 for adjusting the pressure of the gas introduced into the inlet 10 by a control valve 21; A sonic nozzle unit 30 for adjusting a flow rate of the gas supplied from the regulator 20 by the selection of the sonic nozzle 31; A discharge port 40 for supplying a gas precisely adjusted to a predetermined pressure and flow rate through the regulator 20 and the sonic nozzle unit 30 to a test meter or a facility requiring a precise flow rate supply; An integrated control unit 50 for controlling the regulator 20 and the sonic nozzle unit 30; The inlet 10, the regulator 20, the sonic nozzle unit 30, the outlet 40, the integrated control unit 50 is composed of a case 60 accommodated therein.

Inlet 10 is a configuration in which the gas is injected so that the gas flows along the configuration installed in the case 60, the end is protruded to the outside to be combined with the supply nozzle of the gas to maintain the airtight without leakage of gas The outside is provided with a threaded portion that can be fastened to each other, or is provided with a one-touch coupler that can be detached and mounted.

At this time, the gas supplied into the case 60 through the inlet 10 passes through the filtering unit 70. The filtering unit 70 is provided with a dust removing filter and a moisture removing filter sequentially, thereby providing two gases. Moisture and dust from the gas are removed as they pass through these filters.

The regulator 20 is connected to the control valve 21 to adjust the pressure of the gas supplied through the inlet 10, which is fixed to the sonic nozzle unit 30 installed in the case 60 as shown in FIG. 2. It is a device that supplies pressure gas.

The sonic nozzle unit 30 is configured to precisely control the flow rate by receiving the gas that has passed through the regulator 20, and the sonic nozzle unit 30 is provided with several sonic nozzles 31 in parallel, Each sonic nozzle 31 is provided with a flow path tube 33, the flow rate control valve 32 for opening and closing the flow path tube (33).

The sonic nozzle unit 30 is automatically selected by the user manually or the nozzle is automatically selected according to an automatic control value preset by the CPU, so there is no need to change the nozzle according to the flow rate, sonic Since the flow rate of the gas passing through the nozzle 31 is minimized, the reliability is not reduced even when a plurality of test meters are connected in parallel or in series.

On the other hand, it further comprises a thermometer (T1) and a pressure gauge (P1) for measuring the temperature and pressure of the gas supplied to the upstream side flow path of the sonic nozzle unit 30, which calculates the flow rate passing through the sonic nozzle 31 In order to do this, the pressure and temperature of the gas supplied to the sonic nozzle 31 must be known, and information about the cross-sectional area of the nozzle neck of the sonic nozzle and the outflow coefficient of the nozzle must be obtained in advance. The discharge coefficients of the nozzles are set in accordance with the sonic nozzles installed, and the values of the pressure and temperature of the gas vary depending on the measurement situation. Therefore, the values are measured in real time through the thermometer (T1) and the pressure gauge (P1). Acquire.

The discharge port 40 is configured to supply the gas that has passed through the sonic nozzle unit 30 to an external facility or to supply the test meter to discharge the gas to the outside of the case 60, in order to be supplied to the external facility as described above. It can be used simply by connecting the outlet 40 and the flow path of the external equipment without a separate device, and in the case of inspecting a plurality of test meters, the diverter valve 45 upstream of the outlet 40 is another outlet The test meter 120 can be inspected by changing the flow path so as to flow to the 41 and connecting the plurality of test meters 120 in parallel or in series to the ends of the changed discharge port 41 to measure the flow rate.

At this time, the test meter 120 measures the integrated flow rate along with the instantaneous flow rate, and accordingly transmits the data passing through the sonic nozzle unit 30 to the integrated control unit 50 to be described later and outputs it through the display unit 61. By comparing the numerical values of the two, it may be determined whether the test meter 120 has an error.

Further equipped with a pressure gauge (P2) and a thermometer (T2) for measuring the pressure and temperature of the gas passing through the divert valve 45 to minimize the error due to the pressure and temperature of the gas measured by the test meter 120 do.

The integrated control unit 50 is an electronic circuit board installed on the inner bottom of the case 60 and provided with a control unit for storing and outputting various data necessary for measuring the flow rate. The integrated control unit 50 displays the set pressure, temperature, and reference flow rate of the gas. 610, and controls the respective components to adjust the opening amount of the various valves or select the sonic nozzle in accordance with the value set by the user.

The case 60 is a housing for accommodating the above configuration in a single package. The case 60 is made compact to be portable and is provided with a display unit 61 for outputting a reference flow rate and various kinds of information measured therein. In addition, a control switch 62 for manual operation is installed.

The display unit 61 outputs measured values such as pressure, temperature, instantaneous flow rate, and accumulated flow rate of the gas in real time, so that the user can easily and quickly recognize them. The above components are all housed in the case 60. The space is configured to be blocked from the outside, thereby preventing damage to the equipment due to external foreign matters.

The present invention as described above will be described in more detail through the following operation sequence.

In the present invention, the gas is first introduced using the inlet 10 as shown in FIG. 5 (S1), and the pressure of the supplied gas is controlled through the regulator 20 and the control valve 21, and then the value thereof is measured by a thermometer ( Acquired through T1) and pressure gauge (P1) and transmitted to the central processing unit of the may board 50 (S2), by selecting the appropriate flow rate according to the inspection object to select the sonic nozzle 31 of the sonic nozzle unit 30 By setting the reference flow rate (S3).

When the reference flow rate is set, the gas is passed through the test meter 120 so that each test meter 120 measures the instantaneous and accumulated flow rate of the gas (S4), and the gas used for the measurement is recovered again or the production line. Supplied.

Obtaining the instantaneous and integrated flow rate information measured by the test meter 120 (S6), by comparing the measurement information of the test meter 120 with respect to the set reference flow rate (S7), the error of the test meter 120 inspected Determine.

In the present invention, as shown in Figure 6 (a, b, c) can be inspected by setting the reference flow rate from at least one to a plurality, wherein the reference flow rate is set differently, such as the minimum, average, maximum flow rate of the test object, respectively This allows for quick and easy inspections for different flow rates.

In addition, each configuration is movable in a single package in the case 60, and is made of a small size is suitable for use for precisely controlling the flow rate in a laboratory of a small laboratory.

10: inlet 20: regulator
21: control valve 30: sonic nozzle
31: Sonic nozzle 32: Flow control valve
33: flow path 40, 41: discharge port
45: divert valve 50: integrated control unit
60: case 61: display unit
62: control switch 70: filtering unit
120: test meter P1, P2: pressure gauge
T1, T2: Thermometer

Claims (6)

In the measuring device for measuring the flow rate of the gas,
An inlet 10 through which gas is supplied;
A regulator 20 for adjusting the pressure of the gas introduced into the inlet 10 by a control valve 21;
A sonic nozzle unit 30 for adjusting a flow rate of the gas supplied from the regulator 20 by the selection of the sonic nozzle 31;
A discharge port 40 for supplying a gas precisely adjusted to a predetermined pressure and flow rate through the regulator 20 and the sonic nozzle unit 30 to a test meter or a facility requiring a precise flow rate supply;
An integrated control unit 50 for controlling the regulator 20 and the sonic nozzle unit 30;
Portable inlet flow rate measuring device, characterized in that the inlet 10, the regulator 20, the sonic nozzle unit 30, the outlet 40, the integrated control unit 50 is composed of a case (60) housed therein.
The method according to claim 1,
Portable precision flow rate measuring device, characterized in that the display unit 61 is further provided on the outside of the case 60 to output the measured values, such as the pressure, temperature, instantaneous flow rate and cumulative flow rate of the gas.
The method according to claim 1,
Portable precision flow rate measuring device further comprises a thermometer (T1) and a pressure gauge (P1) for measuring the temperature and pressure of the gas supplied to the upstream side flow path of the sonic nozzle unit (30).
The method according to any one of claims 1 to 3,
Portable precision flow rate measuring device characterized in that it further comprises a filtering unit 70 for removing the moisture and dust of the gas flowing into the inlet (10).
The method according to any one of claims 1 to 3,
Portable divergence flow rate measuring device further comprises a diverter valve (45) provided on the upstream side of the outlet (40) to switch the flow path to measure the accumulated flow rate of the gas.
The method according to claim 5,
Portable precision flow rate measuring device further comprises a pressure gauge (P2) and a thermometer (T2) for measuring the pressure and temperature of the gas passing through the divert valve (45).

Images