KR101794789B1 - OIL LEAK DETECTING DEVICE USING VOCs FROM OIL IN THE TUBE WELL - Google Patents

Abstract

The present invention relates to a leaked oil detection device to detect leaked oil of an oil storage facility using harmful gas generated in oil collected in a tube well. The present invention provides the leaked oil detection device, comprising: a tube well excavated from the ground surface to an underground space to collect leaked oil leaked from an oil storage facility; and a harmful gas measurement unit coupled to an upper end of the tube well to detect harmful gas generated from the oil.

Description

TECHNICAL FIELD [0001] The present invention relates to an oil leakage detecting apparatus for detecting oil leakage in a oil storage facility using harmful gas generated from oil captured in a tank,

The present invention relates to an apparatus for detecting leakage of oil storage facilities.

Oil storage tanks installed at gas stations and oil distribution pipes that supply oil to oil pumps at oil storage tanks are usually buried underground. Oil storage tanks buried in the basement and oil distribution pipes are liable to leak oil due to cracks after a long time, but it is technically not easy to detect them.

As a conventional technique for solving such a problem, Korean Utility Model Registration No. 20-0398442 discloses a piping leakage monitoring apparatus. BACKGROUND ART [0002] Conventional art is a lubrication apparatus that is connected to a oil storage tank embedded in a lubrication oil supply line to supply oil to a lubrication line and supplies oil thereto. The lubrication apparatus is provided between the oil supply pipe and the oil storage tank, And a pressure gauge connected to the auxiliary pipe and measuring pressure change inside the oil supply pipe and configured to detect the leakage. The check valve is connected to the check valve to communicate with the check oil pipe.

However, the prior art detects a change in pressure only and detects leakage of the oil.

The inventor of the present invention has studied for a long time to solve such a problem, developed through trial and error, and finally completed the present invention.

An object of the present invention is to provide an oil leakage detection apparatus that detects oil leakage in a oil storage facility using noxious gas generated from oil collected in a reservoir adjacent to a oil storage facility.

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

In order to accomplish the above object, the present invention provides a pipe-shaped canister for collecting leaking oil that is buried underground and leaked from a oil storage facility; And

And a noxious gas measuring unit coupled to an upper end of the pipe to detect noxious gas generated in the oil. The noxious gas detecting unit detects leakage of oil from the oil storage facility using noxious gas generated from the oil collected in the pipe. Device.

In a preferred embodiment, the canals are preferably buried deeper than the oil storage tanks or delivery tubes embedded in the basement.

In a preferred embodiment, the wells include fine holes into which groundwater or oil flows.

In a preferred embodiment, the noxious gas measuring unit includes a body portion including a fastening means for fastening to the upper end of the tube;

A gas inflow hole formed through the body and through which a noxious gas rising along the tube is passed; And

And a noxious gas measuring sensor connected to the gas inlet hole.

In a preferred embodiment, the noxious gas measurement sensor is a Volatile Organic Compounds (VOCs) detection sensor.

In a preferred embodiment of the present invention, a leaking determination unit for receiving a signal from the noxious gas measurement sensor, an ultrasonic sensor installed in a delivery pipe for transferring oil, and a leakage detection sensor provided in the oil storage tank, It is good to include.

According to the present invention as described above, the present invention has an effect of detecting leakage of a fuel oil storage facility by using noxious gas generated in a canister buried near a fuel oil storage facility. It is easy to obviate the need to directly embed the oil detection sensor deep inside the tunnel.

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

1 is a view showing a schematic embodiment of an oil leakage detection apparatus of the present invention.
2 is a view showing a preferred embodiment of the leakage detection device of the present invention.
3 is a view showing a preferred embodiment of the noxious gas measuring part of the present invention.
* The accompanying drawings illustrate examples of the present invention in order to facilitate understanding of the technical idea of the present invention, and thus the scope of the present invention is not limited thereto.

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

1 is a view showing a schematic embodiment of an oil leakage detection apparatus of the present invention.

1, the oil storage facility includes a oil storage tank 1, a oil delivery pipe 9, and an oil leakage detection device 10. As shown in FIG.

The oil storage tank (1) stores the oil. It is buried at a certain depth in the basement. The oil storage tank (1) is connected to the oil delivery pipe (9). Oil leakage detection device 10 is buried at a position adjacent to oil storage tank 1 and oil delivery pipe 9.

When leakage occurs in the oil storage tank (1), oil flows into the soil below the tank (7). When the oil meets the groundwater (6), it moves in accordance with the flow of groundwater (5). When leakage occurs in the oil supply pipe (9), oil flows into the soil below the delivery pipe (8), and when the oil meets the ground water (6), it moves in accordance with the flow of ground water (5).

The oil leakage detection device 10 is formed in the housing. The oil leakage detection device 10 can directly collect the oil permeated in the soil flowing out from the oil storage tank 1 or the delivery pipe 9 or indirectly collect the oil that moves along the ground water. For this purpose, the tunnel is drilled deeper than the oil storage tank (1) or the delivery pipe (9) buried underground. The tunnel is excavated in the direction in which the groundwater flows out through the oil storage tank (1) or the delivery pipe (9).

The leakage determination unit 300 receives signals from the noxious gas measurement unit 10, the ultrasonic sensor installed in the delivery pipe for transferring the oil, and the leakage detection sensor installed in the oil storage tank, and controls the leakage of the oil storage facility. In the preferred embodiment, the leakage determining unit 300 may include a sensor communication unit, an operation unit, a screen output unit, a printer unit, a speaker unit, and a local communication unit. The sensor communication unit includes sensor input terminals (ch1 to ch20) of multiple channels. Each of the input terminals is connected to a sensor provided in the leak detection device 10, an ultrasonic sensor provided in a delivery pipe for transferring the oil, and a leakage detection sensor provided in the oil storage tank. In a preferred embodiment, the sensor communication unit can exchange control signals and measurement result signals with the sensors in accordance with a communication standard such as RS-485. The calculation unit controls the sensor communication unit and receives and analyzes the measurement result data. The arithmetic unit outputs a test start signal to the sensor for each specific period (for example, every one hour), and receives the measurement result data from the sensor. The calculation unit analyzes the inputted measurement result data to determine whether or not the measurement result is leaked. In addition to the measurement result data, the operation unit can collectively analyze vibration, temperature, check valve state, and the like to finally judge whether or not the leakage has occurred. The screen output unit outputs the analysis result to the display device. The analysis result may include a water level of the oil storage tank, a notification map indicating a leaking point mapped to the oil supply pipe installation map, and the like. The printer unit can output the leakage, the position of the leak line, and the measurement time to the printer. The speaker unit can output a leak alarm to the speaker. The local communication unit can provide a terminal for connecting a LAN cable.

2 is a view showing a preferred embodiment of the leakage detection device of the present invention.

2, the leakage detection device 10 includes a tubular body, a tubular body inserted into the tubular body, and a toxic gas measuring part 20 fastened to the tubular upper end or preferably the upper end of the tubular body.

The tunnel is excavated deeper than the oil storage tanks or delivery pipes buried underground. The tunnel is excavated in the direction that the groundwater flows out through the oil storage tank or the delivery pipe.

Tubes can be buried inside the tunnel to prevent the wall from falling down. The pipe body includes a hollow pipe-shaped pipe 11, a tip portion 12 having a sharp end at the end of the pipe 11, and a fine hole 13 formed at the lower end of the pipe 11 into which groundwater or oil flows do.

When the oil and groundwater permeate along the fine holes 13, the oil flows to the top of the groundwater as shown in FIG. In the oil above the ground water, harmful gas is generated and it rises to the top of the tunnel along the tunnel.

The noxious gas measuring unit 20 includes a body portion including a fastening means for fastening to the upper end of the tube.

A plurality of gas inflow holes 21 may be formed in the body portion to penetrate the body portion and allow the noxious gas rising along the tube to pass therethrough. A noxious gas measuring sensor (22) is disposed at the end or side of the gas inlet hole (21) to detect the presence of noxious gas passing through the gas inlet hole (21). In a preferred embodiment, the noxious gas measurement sensor 22 may be a Volatile Organic Compounds (VOCs) detection sensor. A communication line (23) is installed in the noxious gas measurement sensor (22) and is connected to the leakage determination portion.

In addition, the leak detector (10) may further include a communication part to be fastened to the upper end of the noxious gas measuring part, and a communication fan to be fastened to the upper end of the communication part. The communication portion is in the form of a pipe extending to a predetermined length along the ground. The communicating part prevents impurities and the like from flowing into the canal. In addition, the communicating portion blocks the noxious gas flowing on the ground from flowing into the noxious gas measuring sensor 22. Further, the communication part facilitates the discharge of the noxious gas raised from the tube to the ground along the communication part. A communication fan can be installed at the end of the communication part. The communication fan promotes air circulation to the outside of the communication part to prevent the noxious gas flowing on the ground from flowing into the communication part, Speeding up the discharge to the outside.

3 is a view showing another embodiment of the noxious gas measuring unit of the present invention

3, the noxious gas measuring unit 20 may include a plurality of gas inflow holes 21 through which the noxious gas that has risen along the tube is passed through the body. At this time, the gas inlet hole 21 may be a spiral shape and a rising shape. A noxious gas measurement sensor (22) is disposed at the distal end and / or the side surface of the gas inlet hole (21) to detect the presence of noxious gas passing through the gas inlet hole (21). When the gas inlet hole 21 is formed so as to be spirally rotated, the noxious gas can be extended within the noxious gas measuring unit 20. If the noxious gas measurement sensor 22 is disposed along the movement path, the time for which the noxious gas comes into contact with the gas measurement sensor 22 can be extended, so that it is possible to more accurately detect the leakage of the gas.

Meanwhile, in another embodiment, the noxious gas measuring unit 20 may further include a backflow preventing fan 24. The counterflow preventing fan 24 may be disposed at the upper end of the noxious gas measuring unit 20, preferably at the upper end of the noxious gas measuring sensor 22. The backflow prevention fan 24 prevents the noxious gas flowing on the ground from flowing into the noxious gas measurement sensor 22. In the vicinity of the oil storage facility, facilities such as a lube oil purifier are present, and when oil is supplied from a lube oil purifier, harmful gas is generated on the ground. Therefore, the noxious gas that evaporated from the oil floats on the ground near the oil storage facility. The backflow prevention fan 24 has the effect of preventing the noxious gas measurement sensor 22 from malfunctioning due to the noxious gas present on the ground.

The lower end extension 25 for coupling with the tubular body may be formed at the lower end of the noxious gas measuring unit 20. [ An upper end extension 26 may be formed at the upper end of the noxious gas measuring part 20 for coupling with the communication part.

≪ Embodiment of leakage detection algorithm >

An embodiment of a leakage determination algorithm of the leakage detection apparatus of the present invention will be described.

The present invention can simultaneously perform leakage monitoring of the oil supply pipe and inventory monitoring of the oil storage tank.

The leakage monitoring of the oil supply pipe is started when the change of the flow rate is stabilized for a predetermined time (for example, 10 minutes), monitoring the leakage at a predetermined interval (for example, 1 hour) Can be output.

Inventory monitoring of oil storage tanks precisely measures flow, moisture, and temperature. On the other hand, if oil supply amount of the lubricator is matched with oil change amount of the oil storage tank, it is possible to detect whether the oil storage tank is leaking or not, and it is also possible to detect the inflow of ground water by measuring the water amount.

Hereinafter, a specific leak detection method will be described by way of example.

First, the flow rate of the oil storage tank is monitored at a predetermined cycle (for example, one minute), and the flow rate, water content, and temperature are displayed on the controller display screen in real time.

Next, when the amount of change in flow rate is equal to or less than a predetermined criterion (5 liters per 10 minutes), leakage is detected. Such a condition is necessary, for example, in order to confirm whether or not the oil supply has stopped because oil leakage can not be detected in the case of oil supply in the oil supply apparatus.

Next, the flow rate change amount is measured at a predetermined interval (for example, one hour), and if there is a change in flow rate over a predetermined reference (0.8 liters), it is detected that there is a leak. When a leak is detected, a notification screen and an alarm sound can be automatically output.

Next, when it is detected that there is a leak, the genuine leak is determined by comprehensively analyzing the vibration, the temperature, and the normal operation of the check valve.

Next, the position of the ultrasonic sensor is matched with the position of the pipe to compare the leaked portion on the display screen or output to the printer.

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

Claims (6)

Gwanjeong, which was excavated from the surface to the basement and collected leaking oil from the oil storage facility;
A noxious gas measuring unit coupled to the upper end of the well and detecting a noxious gas generated from the oil;
A communicating part which is connected to the upper end of the noxious gas measuring part and formed in a pipe shape extending to a predetermined length toward the ground and discharges the noxious gas rising along the pipe to the ground; And
And a communication fan coupled to an upper end of the communication part to prevent a noxious gas flowing on the ground from flowing into the communication part,
The duct is drilled to a depth deeper than the oil storage tank or the delivery pipe embedded in the underground, and the duct is installed in a direction in which the ground water flows out through the oil storage tank or the delivery pipe, A tip portion formed to be sharp at the end of the pipe, and a tubular body formed at the lower end of the pipe and including a fine hole into which the ground water or the oil flows, are buried, and the noxious gas measuring portion has a fastening means A body portion including; A gas inflow hole formed through the body and through which a noxious gas rising along the tube is passed; And a noxious gas measuring sensor connected to the gas inlet hole, wherein the noxious gas measuring sensor is a Volatile Organic Compounds (VOCs) detecting sensor.
A leakage detection apparatus for detecting leakage of a fuel oil storage facility by using harmful gas generated from oil collected in a canister. delete delete delete delete delete

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