WO2020101099A1

WO2020101099A1 - Bubble removing type liquid measurement system

Info

Publication number: WO2020101099A1
Application number: PCT/KR2018/014681
Authority: WO
Inventors: 조경호; 강정식
Original assignee: 주식회사 서원기술
Priority date: 2018-11-13
Filing date: 2018-11-27
Publication date: 2020-05-22
Also published as: KR102004755B1; AU2018274859A1

Abstract

The present invention relates to a liquid measurement system which is a system for measuring a liquid supplied to a storage tank, the liquid measurement system comprising: a supply pipe having one side connected to a supply means which has transferred a liquid from the outside, and having the other side connected to the storage tank so as to enable the liquid to be supplied to the storage tank; a bubble removing part provided in any one portion of the supply pipe so as to remove bubbles generated when the liquid is supplied; a gas-liquid separator provided above the bubble removing part so as to be spaced apart therefrom and separating a liquid from the bubbles generated in the bubble removing part; a measurement part provided in the supply pipe between the bubble removing part and the storage tank so as to measure the flow rate, speed and temperature of the liquid supplied to the storage tank; and a control part for controlling the flow rate of the liquid to be supplied by controlling whether to open or close a control valve provided in the supply pipe, and collecting and managing information measured by the measurement part. Therefore, the liquid measurement system is capable of accurately measuring the amount of liquid, especially oil, by effectively removing bubbles generated when a large amount of liquid is supplied to a storage tank through an external supply means.

Description

Bubble removal liquid weighing system

The present invention relates to a liquid metering system, and more specifically, to suppress the generation of bubbles when supplying a large amount of liquid to the storage tank through an external supply means, and effectively remove the generated bubbles The present invention relates to an air bubble-removing liquid metering system that can accurately measure the amount of liquid supplied, particularly oil.

In general, in the process of storing the liquid in the storage tank, vortices are generated, and accordingly, the amount of the liquid to be stored is not constant because the amount of liquid stored is smaller than the amount of liquid to be stored due to the bubbles generated. It was difficult to measure the amount of stock.

In particular, in the case of oil, the exact amount of oil supplied from refineries to each gas station is very sensitive due to the increasing oil price.

The oil supply device for tank lorry for supplying oil from refinery to each gas station is supplied in the state where all air bubbles are removed from the refinery when supplied to the tank lorry, so the pump is supplied to the storage tank of the gas station without a separate bubble removal device. It was.

In addition, as a conventional technique, techniques for mounting a temperature compensator in a lubricator, which is mainly used for a final consumer, to compensate for a variation in volume according to temperature of a petroleum product, which is a fluid, have been disclosed. A flow meter unit that is disclosed with respect to a flow measurement device and calculates an accurate liquid flow rate at a standard temperature by calculating a volume conversion factor according to a temperature difference is known.

However, in the process of transporting oil through the tank lorry, bubbles are generated as the oil shakes and cavitation occurs when the oil is pumped from the tank lorry into the underground storage tank. It is difficult to quantify the oil in the process of being supplied to the storage tank of the gas station because many bubbles are generated due to the phenomenon that air and water vapor in the liquid are separated and generate bubbles and make a cavity). There were problems to follow.

In order to solve this conventional problem, Patent Document 1 (KR 10-0466317 B1) is connected to an oil supply unit and the oil supply unit, and is connected to an air reservoir holding air by a weight difference between air and liquid and a lower side of the air reservoir. The turbine flow meter unit that detects the rotational signal and the temperature sensor for detecting the temperature signal of the liquid installed in or adjacent to the turbine flow meter unit and the air reservoir is connected to the upper portion of the air reservoir and removes the removed air component downstream of the control valve. Provided is a liquid metering device capable of real-time measurement of liquid flow rate, including a gas-liquid separator sent to the bypass and a computer means for calculating the flow rate and controlling valves, etc. by receiving the temperature signal and the rotation signal.

However, in Patent Document 1 (KR 10-0466317 B1), air can be discharged by an 'a'-shaped air reservoir to the main pipe, but the flow of oil by the' a'-shaped pipe creates a vortex. Not only does it interfere with accurate measurement, it is difficult to calculate an accurate flow rate due to the generation of bubbles due to the vortex, and there is a problem in that the equipment cost is rather high due to complicated equipment.

In order to solve the above problems, the present invention is provided in a supply pipe for supplying a liquid for storing liquid from an external supply means to a bubble removing unit for removing bubbles generated during liquid supply and bubbles removed from the bubble removing unit and discharged. By configuring a gas-liquid separator for separating the liquid contained, and having a measuring unit for measuring the temperature and speed of the liquid in any part of the supply pipe between the air bubble removing unit and the storage tank, the bubbles of the liquid supplied through the external supply means By removing and correcting the volume difference of the liquid according to the temperature, the quantity of liquid supplied to the storage tank can be accurately weighed and supplied, and the liquid is separated from the discharged bubbles to minimize wasted liquid and to eliminate bubbles An object of the present invention is to provide a bubble removal type liquid weighing system that can reduce equipment costs by reducing the size of the equipment by removing unnecessary elements from the equipment.

In order to achieve the above object, the present invention is a system for measuring the liquid supplied to the storage tank, one side is connected to the supply means that has been transporting the liquid from the outside, the other side so that the liquid can be supplied to the storage tank A supply pipe connected to the storage tank through a pipe; A bubble removal unit provided at any part of the supply pipe to remove bubbles generated when the liquid is supplied; A gas-liquid separator which is provided on the upper portion of the bubble removing portion to separate the liquid from the bubbles generated in the bubble removing portion; A measurement unit provided in the supply pipe between the air bubble removing unit and the storage tank to measure the flow rate, flow rate and temperature of the liquid supplied to the storage tank; And a control unit for controlling the opening / closing of the control valve provided in the lower supply pipe to control the flow rate of the discharged liquid, and for collecting and managing the information measured by the measuring unit. Gives

At this time, the bubble removing unit, the supply pipe is connected to each of the upper and lower pipes, the case where the lower surface forms a gentle slope; A ring pipe attached to the inner circumferential surface of the case and connected to the supply pipe connected to the upper part of the case to allow liquid to flow into the case; A hopper provided at a lower portion of the ring pipe to allow the liquid introduced through the ring pipe to flow toward the center of the case and to release bubbles contained in the liquid; An inclined plate provided at a lower portion of the hopper to be inclined so that the liquid flowing down the hopper spreads and flows down to the inner wall of the case, and bubbles contained in the liquid are discharged; A foam breaker provided at a lower portion of the inclined plate to support the inclined plate and comprising a plurality of partition walls dividing the lower space of the case to prevent vortex from occurring in the liquid flowing along the inner wall of the case; And a bubble discharge pipe that penetrates through the center of the case and is connected to a gas-liquid separator spaced apart from the upper portion of the case so as to discharge gas generated from bubbles.

In addition, the bubble removal unit is provided at the bottom of the case and wrapped so as to control the flow of the liquid flowing into the inlet hole connected to the supply pipe, and is formed to extend to the inside of the case to the upper side of the hopper, inclined plate and foam breaker It characterized in that it further comprises a circular cylinder to which the support member is coupled to support.

At this time, in the lower portion of the circular cylinder, a plurality of perforations are further formed so that the liquid flowing down the inner wall of the case along the inclined plate can flow into the supply pipe without generating vortices.

In addition, the inside of the circular cylinder, it is characterized in that it further comprises a buoy that controls the amount of liquid introduced into the circular cylinder, and a certain level of liquid is present in the case to smoothly discharge bubbles.

At this time, the buoy is moved up and down along the bubble discharge pipe penetrating the inside of the circular cylinder, and is characterized in that the height limiting means is combined to limit the height of the vertical movement.

In addition, the ring pipe is characterized in that slits are formed along the lower surface of the ring pipe so that the liquid introduced through the supply pipe can be uniformly dropped.

And, the hopper is characterized in that the upper radius of curvature is formed to form a larger curved surface than the lower radius of curvature.

In addition, the gas-liquid separator, a separator body connected to the bubble discharge pipe so that the bubbles discharged from the bubble removing unit may be introduced; Perforated plate is provided inside the separator body to separate the liquid by causing friction while the bubbles discharged from the bubble removal unit passes; An exhaust pipe connected to a part of the separator body so that the gas passing through the perforated plate can be discharged to the outside; And it characterized in that it comprises a recovery pipe which is respectively connected to the lower end of the separator body and any one portion of the bubble removal portion so that the liquid separated through the perforated plate may flow back into the bubble removal portion.

At this time, in any part of the bubble discharge pipe, the water level is maintained constant by the bubble pressure at the top of the case, and when the pressure exceeds the set pressure, the pressure is adjusted so that the pressure can be arbitrarily adjusted to prevent explosion by discharging bubbles. It characterized in that it further comprises a valve.

By providing the present invention configured as described above, the bubbles generated in the process of supplying liquid to the storage tank and the bubbles generated in the process of transporting the liquid through the external supply means are effectively removed, and the liquid contained in the bubbles is separated and discharged. The waste liquid can be minimized by recovery, and the amount of liquid supplied to the storage tank can be accurately weighed by taking into account the difference in volume of the liquid according to temperature, and all liquids such as milk, urea, and soy sauce can be measured. It is applicable to the supplying process, so it is highly usable and has the effect of increasing the trust with the business owner receiving the liquid.

1 is a schematic diagram showing a defoaming type liquid metering system according to the present invention.

Figure 2 is a block diagram showing a bubble removing portion of the defoaming type liquid metering system according to the present invention.

Figure 3 is a block diagram showing the ring pipe of the bubble removal type liquid metering system according to the present invention.

Figure 4 is a cross-sectional view showing a hopper of the defoaming type liquid metering system according to the present invention.

5 is a block diagram showing the foam breaker and the inclined plate of the bubble removal type liquid metering system according to the present invention.

Figure 6 is a block diagram showing a gas-liquid separator of the bubble removal type liquid metering system according to the present invention.

7 is a block diagram showing a defoaming type liquid metering system according to the present invention.

The present invention, in the best form, in a system for measuring the liquid supplied to the storage tank,

A supply pipe having one side connected to a supply means that has transported liquid from the outside, and the other side being piped to the storage tank so that liquid can be supplied to the storage tank; A bubble removal unit provided at any part of the supply pipe to remove bubbles generated when the liquid is supplied; A gas-liquid separator which is provided on the upper portion of the bubble removing portion to separate the liquid from the bubbles generated in the bubble removing portion; A measurement unit provided in the supply pipe between the air bubble removing unit and the storage tank to measure the flow rate, flow rate and temperature of the liquid supplied to the storage tank; And a control unit for controlling the opening and closing of the control valve provided in the supply pipe to control the flow rate of the supplied liquid, and for collecting and managing the information measured by the measuring unit. present.

Hereinafter, preferred embodiments will be described in detail with reference to the accompanying drawings so that a person having ordinary knowledge belonging to the same technical field can easily implement the present invention.

The present invention effectively removes air bubbles generated when a large amount of liquid is supplied to the storage tank (T) through an external supply means (S), and the air bubble removal type liquid metering can accurately measure the amount of incoming liquid supplied. The present invention relates to a system, and according to the present invention, it can be applied to supplying not only oil but also milk, oil, urea, and soy sauce as a whole, so it can be said to be a liquid metering system with high utility.

As shown in FIGS. 1 to 7, the bubble removal type liquid metering system according to the present invention includes a supply pipe 100, a bubble removing unit 200, a gas liquid separator 300, a measuring unit 400, and a control unit 500 ).

According to an embodiment of the present invention, the supply pipe 100 is connected to the supply means (S), one side of which has been transporting liquid from the outside, and the other side is connected to the storage tank (T) to the supply means (S) ) May serve to supply the liquid transferred from the storage tank (T).

In addition, the supply pipe 100 may be further provided with a control valve 110 that is operated and controlled by the control unit 500 to control the amount of liquid supplied.

At this time, in order to prevent the liquid supplied along the supply pipe 100 from generating vortices and thereby generating a large amount of bubbles, the amount of liquid input is not correct, to any part of the supply pipe 100. The bubble removal unit 200 may be provided to remove bubbles generated when liquid is supplied.

That is, the bubble removal unit 200 may be provided between the supply means (S) and the storage tank (T), each of the supply means (S), bubble removal unit 200 and the storage tank (T) By sequentially connected by the supply pipe 100, by removing the bubbles generated from the liquid supplied from the supply means (S) to the storage tank (T) in the bubble removing unit 200, the quantity intended to be supplied It is possible to supply the liquid of the.

According to an embodiment of the present invention, an upper portion of the bubble removing unit 200 separates liquid from bubbles discharged during the process of removing bubbles from the bubble removing unit 200, and separates the separated liquid again from the bubble removing unit 200 ) May be provided with a gas-liquid separator 300 spaced apart to minimize the wasted liquid.

In addition, the supply pipe 100 between the air bubble removing unit 200 and the storage tank T is provided with a measuring unit 400 for measuring the flow rate, flow rate, and temperature of the liquid supplied to the storage tank T. Can be.

According to an embodiment of the present invention, the measuring unit 400 is a flow rate meter for measuring the amount of liquid and the speed measurement system for measuring the flow rate by the rotation of the rotor provided in the flowmeter and the measurement information of the flow meter and the speed measurement system It may include a transmission unit for transmitting to the control unit 500.

In addition, the measuring unit 400 may be further provided with a temperature measuring system for measuring the temperature of the liquid supplied to the storage tank (T), which takes into account the characteristics of the liquid that can be varied in volume depending on the temperature. The purpose of this is to enable correcting of the correct amount of incoming liquid supplied to the storage tank (T).

In addition, the control unit 500 may be provided in the supply pipe 100 to control whether the control valve 110 for controlling the flow rate of the liquid supplied through the supply means S is opened or closed.

In addition, by collecting and managing information on the flow rate, flow rate, and temperature of the liquid measured by the measuring unit 400, it is possible to accurately check the amount of liquid supplied to the storage tank T.

To this end, the control unit 500 may be further equipped with a display (not shown) to check the measured value in real time.

That is, after calculating the cumulative amount based on the information measured and received by the flow meter, the speed meter, and the temperature meter, the compensation is calculated, and the residual amount is measured and summed to indicate the received quantity calculated on the display to indicate the supplier and the beneficiary. Together, it is possible to accurately check the measured quantity of goods in real time.

At this time, in any part of the bubble discharge pipe 260, the water level is maintained at a constant level by the bubble pressure at the top of the case, and when the pressure exceeds the set bubble pressure, pressure can be arbitrarily adjusted to prevent explosion by discharging bubbles. It characterized in that it further comprises a pressure control valve 600 to allow.

The overall configuration of such a bubble removing liquid metering system is to be understood with reference to FIG.

According to an embodiment of the present invention, the bubble removal unit 200, as shown in Figure 2, the case 210, ring pipe 220, hopper 230, swash plate 240, foam breaker 250 , It may be composed of a bubble discharge pipe 260 and a circular cylinder (270).

The case 210 may be configured such that the supply pipes 100 are respectively connected to the upper and lower pipes, and the lower surface can be configured to have a gentle slope, and the entire interior is formed of a hollow cylindrical shape, thereby forming the case 210. It is preferable to minimize the collision between the liquid flowing therein and the wall surface of the case 210.

That is, the supply means (S) and the supply pipe (100) connected to the pipe is piped to the upper portion of the case (210), and the liquid flows in. It is to be supplied to the storage tank (T) along the supply pipe 100 connected to the lower pipe.

In addition, the ring pipe 220 is attached to the inner circumferential surface of the case 210, and is connected to the supply pipe 100, which is connected to the upper portion of the case 210, the liquid is introduced into the case 210. It can play a role of allowing it to flow.

According to an embodiment of the present invention, as shown in FIG. 3, the ring pipe 220 may have a slit 221 formed along a lower surface of the ring pipe 220 formed in a ring shape.

The ring shape of the ring pipe 220 and the slit 221 formed in a circular shape along the ring shape is the liquid 210 flowing into the ring pipe 220 through the supply pipe 100 to the case 210 This is to minimize the occurrence of vortices in the interior and to allow it to fall uniformly.

In addition, the hopper 230 may be provided at a lower portion of the ring pipe 220.

According to an embodiment of the present invention, the hopper 230 may be made of a conical shape with the upper and lower portions as shown in FIG. 4.

At this time, the upper radius of curvature of the hopper 230 may be configured to be larger than the lower radius of curvature, and the side surface is formed to form a gentle curved surface so that the liquid introduced through the ring pipe 220 is the case 210. As it flows toward the central portion, bubbles contained in the liquid can be released.

According to an embodiment of the present invention, the inclined plate 240 is provided at a lower portion of the hopper 230, the liquid flowing down toward the central portion of the case 210 along the hopper 230 again the case It may be formed to be inclined downward toward the inner wall of the case 210 so as to spread and flow toward the inner wall of the 210.

In this case, the liquid flowing into the case 210 is first collected by the hopper 230, and bubbles contained in the liquid are escaped. Secondly, the bubbles contained in the liquid are expanded along the inclined plate 240. This is to make it easily released.

According to an embodiment of the present invention, the inclined plate 240 may be formed of a double structure of the upper plate and the lower plate.

At this time, the lower plate is to be supported by the foam breaker 250, the upper plate limits the height of the buoy 272, which will be described later, and serves to make the bond with the foam breaker 250 more robust. can do.

In addition, a side plate connecting the upper plate and the lower plate is further provided in order to prevent bubbles flowing from the liquid flowing toward the wall surface of the case 210 along the upper plate and colliding with the lower plate. ) Along the wall surface of the case 210 can be made to flow without any obstruction.

According to an embodiment of the present invention, the foam breaker 250, as shown in Figure 5, may be made of a plurality of partition walls to divide the lower space of the case 210, the inclined plate 240 ), It can also serve to support the inclined plate 240.

That is, a plurality of liquid breakers flowing along the inner wall of the case 210 by the inclined plate 240 form a vortex in the lower space of the case 210 and form the foam breaker 250 to prevent discharge. The partition wall of the case 210 divides the space inside the case 210, and the liquid flowing into each divided space minimizes the generation of vortices while suppressing the generation of bubbles while piping to the bottom of the case 210. It is possible to escape to (100).

According to an embodiment of the present invention, the hopper 230, the inclined plate 240 and the foam breaker 250 are provided at the bottom of the case 210, the circle extending to the inner upper side of the case 210 Support can be fixed by the form 270.

To this end, the hopper 230 and the inclined plate 240 are provided to allow the circular cylinder 270 to penetrate through the center, and the circular cylinder 270 and the hopper 230 and the inclined plate 240 are respectively coupled. A support member 280 to be supported and fixed may be further provided.

In addition, the foam breaker 250 is formed by a partition wall so as to be provided at regular intervals along the circumference of the circular cylinder 270, thereby dividing the inner space of the case 210 without breaking or shaking the foam breaker 250. I can do it.

At this time, the partition wall forming the foam breaker 250 may be configured as an integral part of the lower portion of the circular cylinder 270. In this case, the foam breaker 250 may be provided at any part inside the circular cylinder 270. A coupling member 280 ′ may be further included to support and support the inclined plate 240 and the foam breaker 250 that are provided on the upper portion.

This is because it can make the pressure of the liquid collected by flowing down to be more robust.

In addition, the bubble discharge pipe 260 penetrates through the center of the case 210 and is connected to the gas-liquid separator 300 provided at a distance from the top of the case 210 to serve to discharge gas generated from bubbles. It can be done.

That is, the gas generated by the bubble burst of the liquid discharged by the bubble removing unit 200 is discharged to the gas-liquid separator 300 through the bubble discharge pipe 260, and the gas and liquid in the gas-liquid separator 300 By separating it once more, it is possible to minimize wasted liquid.

In addition, the circular cylinder 270 is wrapped to adjust the amount of liquid flowing into the inlet hole 211 connected to the supply pipe 100 and the pipe at the bottom of the case 210, and accordingly the circular cylinder 270 ), The perforated portion 271 is formed with a plurality of perforations so that the liquid flowing down the wall surface of the case 210 along the inclined plate 240 can flow into the supply pipe 100 without generating vortices. It can be further formed.

According to an embodiment of the present invention, the bubble discharge pipe 260 may be provided to penetrate the center of the case 210 and penetrate the inside of the circular cylinder 270 at the same time, and the circular cylinder 270 A hole for discharging gas generated by removing bubbles from the outside of the circular cylinder 270 may be formed on the wall surface of the circular cylinder 270 connected to and fixed to the lower wall surface of the bubble cylinder and connected to the bubble discharge pipe 260. have.

Therefore, the liquid from which bubbles are removed flows into the circular cylinder 270 through the perforated portion 271 formed in the circular cylinder 270 and is supplied to the storage tank T through the supply pipe 100. The gas generated from bubbles removed from the liquid can be discharged to the gas-liquid separator 300 provided at a distance from the bubble removing unit 200 through the bubble discharge pipe 260.

According to an embodiment of the present invention, the inside of the circular cylinder 270 controls the amount of the liquid introduced into the circular cylinder 270, and a certain level in the case 210 to facilitate the discharge of air bubbles Buoy 272 to allow the liquid of the present may be further included.

In addition, the buoy 272 may move up and down along the bubble discharge pipe 260 penetrating the interior of the circular cylinder 270, and height limiting means 273 may be combined to limit the height of the up and down movement. Can be.

That is, the buoy 272 provides buoyancy up and down according to the amount of liquid introduced so that the bubble discharge pipe 260 can move up and down, so that bubbles can be discharged smoothly in response to the amount of liquid, By limiting the height that can be moved up and down by the height limiting means 273, the liquid is supplied to the storage tank T after air bubbles are sufficiently discharged by allowing a certain level of liquid to exist in the circular cylinder 270. It is to play a role to make it possible.

According to an embodiment of the present invention, the gas-liquid separator 300 may be composed of a separator body 310, a perforated plate 320, a discharge pipe 330, and a recovery pipe 340, as shown in FIG. It is provided on the upper portion of the bubble removal unit 200, it can be connected by the bubble discharge pipe 260 passing through the center of the bubble removal unit 200.

At this time, the separator body 310 refers to the appearance of the gas-liquid separator 300, and may be connected to the bubble discharge pipe 260 so that bubbles discharged from the bubble removing unit 200 can be introduced into the inside.

In addition, it is preferable that the liquid separated from the bubbles is smoothly collected through the gas-liquid separator 300, and the lower portion is formed to be inclined so that the collected liquid can be introduced back into the bubble removing unit 200.

In addition, the perforated plate 320 is a plate having a plurality of perforations, which may be provided inside the separator body 310, and the bubbles discharged from the bubble removing unit 200 flow through the bubble discharge pipe 260. As it passes through the perforated plate 320, friction may be caused to separate the liquid contained in the air bubbles.

At this time, the discharge pipe 330 is the pipe connected to any part of the separator body 310 so that the gas separated from the liquid passing through the perforated plate 320 can be discharged to the outside, and the discharge pipe 330 ) Is preferably connected to the separator body 310 so that it is symmetrical with the bubble discharge pipe 260 based on the central axis of the separator body 310.

This is to prevent the gas separated from the liquid inside the separator body 310 does not smoothly escape and remains to be recombined with the separated liquid, and the bubble discharge pipe 260 that introduces bubbles into the separator body 310 ) And the discharge pipe 330 for discharging the gas separated from the liquid to the outside, the gas from which the liquid is separated can be minimized to remain inside the separator body 310.

In addition, one side of the recovery pipe 340 is connected to the pipe at the bottom of the separator body 310, the other side is connected to the pipe to any part of the bubble removal unit 200, the liquid separated through the perforated plate 320 Can be introduced into the bubble removal unit 200 again.

At this time, the location where the recovery pipe 340 is connected to the bubble removal unit 200 allows the liquid to flow along the hopper 230 located inside the bubble removal unit 200 so that the recovery pipe 340 It is desirable to be able to remove bubbles that may flow along and be generated again.

According to an embodiment of the present invention, the discharge pipe 330 is capable of discharging the gas in a state in which the liquid is separated from the gas-liquid separator 300 to the outside. , It can be processed through the processing device.

That is, when the liquid to be supplied is measured by the storage tank (T) and the liquid to be supplied is a general liquid such as milk, cow's water, or soy sauce, the gas generated is not harmful, and thus discharged directly to the outside through the discharge pipe 330 If the liquid to be supplied is an oil, one side of the discharge pipe 330 is connected to the supply pipe 100 positioned between the measuring part 400 and the storage tank T It is preferable to be able to be injected into the vapor processing apparatus provided in the storage tank (T).

Since gas, which is a gas generated from oil, has a high risk of fire or explosion, it must not be discharged directly to the outside, and it can be safely processed through a vapor processing device generally provided in a storage tank (T) storing oil.

In addition, since the amount of oil input supplied from the measuring unit 400 has been accurately measured, and the small amount of gas generated in the gas-liquid separator 300 does not affect the amount of input, the discharge pipe 330 is the measuring unit ( 400) and is preferably connected to the supply pipe 100 positioned between the storage tank T.

The bubble removal type liquid metering system having the configuration as described above is more easily understood through the block diagram shown in FIG. 7, and by providing the present invention configured as described above, the liquid through the external supply means (S) Air bubbles generated in the process of transporting liquid and bubbles generated in the process of supplying liquid to the storage tank (T) can be effectively removed, and the liquid contained in the bubbles can be separated and recovered to minimize wasted liquid. It is possible to accurately quantify the amount of liquid supplied to the storage tank (T) in consideration of the volume difference of the liquid, and it is applicable to the process of supplying not only oil but also all liquids such as milk, urea, and soy sauce. At the same time, it has the effect of increasing the confidence with the owner who receives the liquid.

The terms and words used in the present specification and claims described above should not be construed as being limited to ordinary or lexical meanings, and the inventor appropriately uses the concept of terms to describe his or her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meanings and concepts consistent with the technical spirit of the present invention.

Therefore, the configuration shown in the drawings and examples described in this specification is only one of the most preferred embodiments of the present invention, and does not represent all of the technical spirit of the present invention, and can be replaced at the time of this application. It should be understood that there may be various equivalents and variations.

Claims

In the system for measuring the liquid supplied to the storage tank,

A supply pipe having one side connected to a supply means that has transported liquid from the outside, and the other side being piped to the storage tank so that liquid can be supplied to the storage tank;

A bubble removal unit provided at any part of the supply pipe to remove bubbles generated when the liquid is supplied;

A gas-liquid separator which is provided on the upper portion of the bubble removing portion to separate the liquid from the bubbles generated in the bubble removing portion;

A measurement unit provided in the supply pipe between the air bubble removing unit and the storage tank to measure the flow rate, flow rate and temperature of the liquid supplied to the storage tank; And

A bubble removal type liquid metering system comprising a control unit for controlling the opening and closing of a control valve provided in the supply pipe to control the flow rate of the supplied liquid, and for collecting and managing the information measured by the measuring unit.
According to claim 1,

The bubble removal unit,

A case in which the supply pipes are respectively connected to the upper and lower pipes, and the lower surface forms a gentle slope;

A ring pipe attached to the inner circumferential surface of the case and connected to the supply pipe connected to the upper part of the case to allow liquid to flow into the case;

A hopper provided at a lower portion of the ring pipe to allow liquid introduced through the ring pipe to flow toward the center of the case and to release bubbles contained in the liquid;

An inclined plate provided at a lower portion of the hopper to be inclined so that the liquid flowing down the hopper spreads and flows to the inner wall of the case, and bubbles contained in the liquid are discharged;

A foam breaker provided at a lower portion of the inclined plate to support the inclined plate, and comprising a plurality of partition walls dividing the inner space of the case to prevent vortex from occurring in the liquid flowing along the inner wall of the case; And

And a bubble discharge pipe connected to a gas-liquid separator spaced apart from the upper portion of the case so as to penetrate the center of the case and discharge gas generated from the bubble.
According to claim 2,

In the air bubble removing unit,

It is provided at the bottom of the case and is wrapped so as to control the amount of liquid flowing into the inlet hole connected to the supply pipe, and is formed to extend upwards inside the case to support the hopper, inclined plate and foam breaker. A bubble removal type liquid metering system further comprising a circular cylinder to which is combined.
According to claim 3,

In the lower portion of the circular cylinder,

A bubble removing liquid metering system, characterized in that a plurality of perforations are further formed so that the liquid flowing down the wall surface of the case along the inclined plate can flow into the supply pipe without generating vortices.
According to claim 3,

Inside the circular cylinder,

A bubble removing liquid metering system further comprising a buoy that controls the amount of liquid introduced into the circular cylinder and allows a certain level of liquid to be present in the case so that bubbles are smoothly discharged.
The method of claim 5,

The buoy,

A bubble removal type liquid metering system, characterized in that a height limiting means is combined to move up and down along the bubble discharge pipe penetrating the inside of the circular cylinder and to limit the height of the up and down movement.
According to claim 2,

The ring pipe,

A bubble removal liquid metering system, characterized in that slits are formed along the lower surface of the ring pipe so that the liquid introduced through the supply pipe can be uniformly dropped.
According to claim 2,

The hopper,

A bubble removal liquid metering system, characterized in that the upper radius of curvature is formed to form a larger surface than the lower radius of curvature.
According to claim 1 and 2,

The gas-liquid separator,

A separator body connected to the bubble discharge pipe so that bubbles discharged from the bubble removing unit may be introduced;

Perforated plate is provided inside the separator body to separate the liquid by causing friction while the bubbles discharged from the bubble removal unit passes;

An exhaust pipe connected to a part of the separator body so that the gas passing through the perforated plate can be discharged to the outside; And

And a recovery pipe connected to a lower portion of the separator body and a portion of the bubble removal portion, respectively, so that the liquid separated through the perforated plate can flow back into the bubble removal portion. .
According to claim 2,

In any part of the bubble discharge pipe,

A bubble characterized in that it further comprises a pressure control valve that allows the pressure to be arbitrarily adjusted to prevent explosion by discharging bubbles when the water level is maintained constant by the bubble pressure at the top of the case, and when the set bubble pressure is greater than or equal to Removable liquid weighing system.