KR101998395B1 - High speed high capacity flow measuring device for repeated pressurized testing of ultra high pressure container - Google Patents

Abstract

The present invention relates to a high-speed large-capacity flow measurement device for a repeated pressurization test of an ultra-high pressure vessel, which comprises: a supply tank in which working fluid is contained; an injection pipe connected to an ultra-high pressure vessel as a test object from the supply tank, and for providing a flow path through which the working fluid is supplied; a pump provided in the injection pipe and pumping the working fluid stored in the supply tank to the ultra-high pressure vessel; a pressure control unit provided on the injection pipe to be disposed between the pump and the ultra-high pressure vessel, and for increasing the pressure of the working fluid pumped by the pump to provide the pressure of the working fluid required in the repeated pressurization test of the ultra-high pressure vessel; a recovery pipe provided between the injection pipe and the supply tank to recover the working fluid discharged from the ultra-high pressure vessel to the supply tank; a water-containing unit provided in the recovery pipe, and for lowering the discharge speed by containing the high-speed large-capacity working fluid discharged from the ultra-high pressure vessel for a set time. According to the present invention, a flowmeter is prevented from being damaged by the discharge impact of the working fluid.

Description

TECHNICAL FIELD [0001] The present invention relates to a high-speed, high-capacity flow rate measuring apparatus for an ultra-

The present invention relates to a high-speed large-capacity flow rate measuring apparatus for repeated pressure testing of ultra-high pressure vessels. More particularly, the present invention relates to a high-speed large- The present invention relates to a high-speed large-capacity flow rate measuring apparatus for repeated pressure test of ultra-high pressure vessels capable of precisely measuring a flow rate of a working fluid discharged from an ultra-high pressure vessel.

It is generally mandatory for a meter to regularly inspect and calibrate whether the metering precision is within a certain range.

The method of calibrating the flow measuring equipment generally measures the metering accuracy relative to the reference volume. As a method of comparing the reference volume, a method using a reference tank is used.

Here, calibration of large capacity volume tanks has been carried out so far that the reference tank is installed higher than the test tank, water is taken into the reference tank repeatedly or repeatedly, or a small reference container is filled with water and poured by hand several times .

However, this method has the disadvantages that it is difficult to use and requires much effort when there is no space for installing the reference tank or when the height of the test tank is large.

In addition, since the reference tank is manufactured for each reference volume of the existing reference tank, when a plurality of volumes are calibrated at the actual site, it is necessary to provide a plurality of reference tanks corresponding to the corresponding volumes. There is a problem that it becomes difficult.

In order to solve the above-mentioned problems, a volume calibrating device for a test tank has been developed. The volume calibrating device according to the related art is connected to a reference container, and the fluid filled in the reference container is transferred and filled in the reference container. And a transfer pump connected between the discharge container and the test tank for transferring the fluid filled in the discharge container to the test tank, wherein the discharge container is provided with a volume control block .

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Registration No. 10-1791237 (published on October 27, 2017, entitled "Volume Calibration Apparatus for Test Tanks").

It is possible to calibrate the volume of the test tank because there is no separate technical structure for accurately measuring the flow rate of the working fluid supplied to the test tank and the flow rate of the working fluid discharged from the test tank according to the prior art There is a problem that it is difficult to accurately measure the flow rate of the working fluid discharged from the ultra-high pressure vessel as a test object during the test.

Therefore, there is a need for improvement.

The present invention relates to an ultra high-pressure vessel which is supplied to an ultra-high-pressure vessel, performs a pressure test, temporarily discharges the working fluid discharged from the ultra-high-pressure vessel in a fresh water portion while discharging it step by step, And it is an object of the present invention to provide a high-speed mass flow rate measuring device for pressurized test.

According to the present invention, there is provided a water supply system comprising: a supply tank in which a working fluid is drained; An injection pipe connected to the ultra-high pressure vessel as a test object from the supply tank and providing a flow path through which the working fluid is supplied; A pump installed in the injection pipe for feeding a working fluid stored in the supply tank to the ultra high pressure vessel; A pressure regulating unit installed in the injection pipe so as to be disposed between the pump and the ultra high pressure vessel and providing a pressure of a working fluid required in repetitive pressing test of the ultra high pressure vessel by raising a pressure of a working fluid being pressure- ; A recovery pipe installed between the injection pipe and the supply tank to recover the working fluid discharged from the ultra high-pressure vessel to the supply tank; A fresh water supply unit provided in the return pipe and for desorbing a high-speed, large-capacity working fluid discharged from the ultra-high-pressure vessel for a set time to lower the discharge rate; And a flow rate measuring unit for measuring a flow rate of the low-speed working fluid discharged from the plurality of units.

In addition, the injection pipe of the present invention is provided with a supply valve for determining whether or not the working fluid supplied to the ultra high-pressure vessel is supplied, and determines whether or not the working fluid discharged from the ultra- A second recovery valve is installed in the recovery pipe so as to be disposed between the fresh water unit and the supply tank.

In addition, the fresh water section of the present invention may further include: a first recovery tank installed in the recovery pipe so that the working fluid discharged from the ultra-high-pressure vessel is drained; And a second recovery tank for desorbing the working fluid discharged from the first recovery tank by a second order.

The flow meter of the present invention may further include: a first flow meter installed in the injection tube so as to be disposed between the supply tank and the pump; A second flow meter installed in the recovery pipe so as to be disposed between the first recovery tank and the second recovery tank; And a water level sensor installed in the second recovery tank for measuring a flow rate of a working fluid being desiccated in the second recovery tank.

A high-speed large-capacity flow rate measuring apparatus for repeated pressure test of an ultra-high pressure vessel according to the present invention comprises a fresh water section for discharging a working fluid discharged from an ultra-high pressure vessel for a predetermined time and discharging the charged fluid in a stepwise manner, The flow rate of the working fluid discharged stepwise is measured in a state in which the discharge rate is reduced, thereby preventing the flow meter from being damaged by the discharge impact of the operating fluid and performing accurate flow rate measurement.

1 is a block diagram showing a high-speed large-capacity flow rate measuring apparatus for repeated pressure test of an ultra-high pressure vessel according to an embodiment of the present invention.

Hereinafter, an embodiment of a high-speed large-capacity flow rate measuring apparatus for repetitive pressure test of an ultra-high pressure vessel according to the present invention will be described with reference to the accompanying drawings.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are terms defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator.

Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a block diagram showing a high-speed large-capacity flow rate measuring apparatus for repeated pressure test of an ultra-high pressure vessel according to an embodiment of the present invention.

Referring to FIG. 1, an apparatus for measuring high-speed, high-capacity flow for repeated pressure testing of an ultra-high pressure vessel according to an embodiment of the present invention includes a supply tank 110 in which a working fluid is drained, 180) for supplying working fluid to the ultra-high pressure vessel (180), and an injection pipe (112) connected to the injection pipe (110) Pressure vessel 180 so as to be disposed between the pump 114 and the ultra-high-pressure vessel 180 and to raise the pressure of the working fluid that is pressure-fed by the pump 114, A pressure regulating section 116 for providing the working fluid pressure required in the repetitive pressing test and an inlet tube 112 and a supply tank 110 for recovering the working fluid discharged from the ultra high pressure vessel 180 to the supply tank 110. [ A recovery pipe 130 provided between the ultra high pressure vessel 1 and the recovery vessel 130, And a flow rate measuring unit 170 for measuring a flow rate of the low-speed working fluid discharged from the plurality of units. The flow rate measuring unit 170 measures the flow rate of the low-speed working fluid discharged from the plurality of units.

Accordingly, when the repetitive pressure test is performed on the ultra-high pressure vessel 180, the high-pressure vessel 180 is pressurized and the high-capacity large-capacity working fluid discharged along the recovery pipe 130 is stored in the fresh water section 150 for a predetermined period of time And the flow rate of the working fluid discharged stepwise after the temporary storage can be accurately measured by the operation of the flow rate measuring unit 170. [

In addition, since the discharge rate of the working fluid discharged along the recovery pipe 130 decelerates to less than a predetermined value while passing through the fresh water part 150, the flow rate measurement part installed in the recovery pipe 130 for sensing the flow rate of the working fluid 170 can be prevented from being malfunctioned and damaged.

The injection pipe 112 of this embodiment is provided with a supply valve 118 for determining whether or not the working fluid to be supplied to the ultra high pressure vessel 180 is supplied and the return pipe 130 is provided with a working fluid The first recovery valve 132 is installed in the fresh water supply unit 150 to supply the working fluid to the fresh water supply unit 150 and the return pipe 130 is disposed between the fresh water supply unit 150 and the supply tank 110, The second recovery valve 134 is installed.

When the pump 114 is driven with the supply valve 118 opened and the first recovery valve 132 closed, the working fluid stored in the supply tank 110 is supplied to the ultra-high pressure vessel Pressure vessel 180, the supply valve 118 is closed, the first recovery valve 132 is opened, and the working fluid discharged from the ultra-high-pressure vessel 180 is discharged. To the supply tank (110) side along the recovery pipe (130).

The fresh water supply unit 150 of the present embodiment includes a first recovery tank 152 installed in the recovery pipe 130 so that the working fluid discharged from the ultra high pressure container 180 is drained, And a second recovery tank 154 for desorbing the working fluid to be discharged secondarily.

The working fluid recovered to the supply tank 110 side along the recovery pipe 130 is discharged into the first recovery tank 152 and the discharge speed is decreased and the working fluid recovered from the first recovery tank 152 to the second recovery tank 154, So that it is possible to precisely measure the flow rate of the working fluid at a low speed.

At this time, the opening amount of the second recovery valve 134 is adjusted according to the driving signal transmitted from the control unit, so that the discharge speed of the working fluid discharged along the recovery pipe 130 can be adjusted. The air layer filled in the second water storage tank 154 is compressed or expanded to cancel the impact due to the flow velocity of the working fluid discharged along the return pipe 130, 170 are reduced.

The flow measuring unit 170 of the present embodiment includes a first flow meter 172 installed in the injection pipe 112 so as to be disposed between the supply tank 110 and the pump 114, A second flow meter 174 installed in the recovery pipe 130 so as to be disposed between the first recovery tank 154 and the second recovery tank 154 and a second flow meter 174 installed in the second recovery tank 154, And a water level sensor 176 for measuring the flow rate.

Therefore, the flow rate of the working fluid supplied to the ultra-high pressure tank along the injection tube 112 is measured by the first flow meter 172, and the flow rate of the working fluid discharged from the ultra high pressure vessel 180 is measured by the second flow meter 174 The volume change and the endurance performance of the ultra-high pressure vessel 180 can be determined by the difference between the flow rate measured by the first flow meter 172 and the flow rate measured by the second flow meter 174.

Further, since the flow rate of the working fluid discharged from the ultra-high pressure vessel 180 is measured by the water level of the second recovery tank 154 measured by the water level sensor 176, the flow rate of the working fluid can be measured more precisely .

Thus, the pressurization test is performed on the ultra-high pressure vessel. The operation fluid discharged from the ultra-high pressure vessel is temporarily stored in the fresh water section and is discharged step by step, and the flow rate of the working fluid discharged from the ultra- It becomes possible to provide a high-speed large-capacity flow rate measuring apparatus for testing.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

Also, although a high-speed large-capacity flow rate measuring apparatus for repetitive pressure testing of ultra-high pressure vessels has been described as an example, the present invention is merely illustrative and the measuring apparatus of the present invention can be used in products other than the high-speed large-

Accordingly, the true scope of the present invention should be determined by the following claims.

110: Supply tank 112: Injection pipe
114: Pump 116: Pressure regulator
118: supply valve 130: return pipe
132: first recovery valve 134: second recovery valve
150: Fresh water part 152: First recovery tank
154: second recovery tank 170: flow rate measurement unit
172: first flow meter 174: second flow meter
176: Water level sensor 180: Ultra high pressure vessel

Claims (4)

A supply tank through which the working fluid is drained;
An injection pipe connected to the ultra-high pressure vessel as a test object from the supply tank and providing a flow path through which the working fluid is supplied;
A pump installed in the injection pipe for feeding a working fluid stored in the supply tank to the ultra high pressure vessel;
A pressure regulating unit installed in the injection pipe so as to be disposed between the pump and the ultra high pressure vessel and providing a pressure of a working fluid required in repetitive pressing test of the ultra high pressure vessel by raising a pressure of a working fluid being pressure- ;
A recovery pipe installed between the injection pipe and the supply tank to recover the working fluid discharged from the ultra high-pressure vessel to the supply tank;
A fresh water supply unit provided in the return pipe and for desorbing a high-speed, large-capacity working fluid discharged from the ultra-high-pressure vessel for a set time to lower the discharge rate; And
And a flow rate measuring unit for measuring a flow rate of the low-speed working fluid discharged from the plurality of units.
The method according to claim 1,
The injection pipe is provided with a supply valve for determining whether or not the working fluid supplied to the ultra high-pressure vessel is supplied. The return pipe is determined whether or not the working fluid discharged from the ultra- And a second recovery valve is installed in the recovery pipe so as to be disposed between the fresh water unit and the supply tank.
The water treatment system according to claim 1,
A first recovery tank installed in the recovery pipe so as to drain the working fluid discharged from the ultra high-pressure vessel; And
And a second recovery tank for secondarily collecting the working fluid discharged from the first recovery tank.
The apparatus according to claim 3, wherein the flow-
A first flow meter installed in the injection tube to be disposed between the supply tank and the pump;
A second flow meter installed in the recovery pipe so as to be disposed between the first recovery tank and the second recovery tank; And
And a water level sensor installed in the second recovery tank for measuring a flow rate of a working fluid that is desalinated in the second recovery tank.

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