KR101318916B1 - Duplex pipe line and apparatus for detecting the leakage of that - Google Patents

Abstract

The present invention improves the measurement accuracy of insulation resistance and defect location by simultaneously measuring bare copper wire and nickel chromium sensor wire, and the built-in detection line that can detect the leakage in the appearance of the double insulation tube is easy to install and leak Regarding the double insulation tube and the double insulation tube monitoring device that can accurately detect the, the double insulation tube according to the present invention, the inner tube through which the fluid flows and the outer tube wrapped in the spaced apart state and the filling between the inner tube and the exterior; Is a double insulation tube made of a heat insulating material, the fixed surface is installed so as to expose the surface on the inner surface of the exterior, the sensor wire made of nickel chromium wire; It is fixed to the exterior and installed, the return wire of the structure coated with an insulating material.

Description

DUPLEX PIPE LINE AND APPARATUS FOR DETECTING THE LEAKAGE OF THAT}

The present invention relates to a double insulation tube and a double insulation and monitoring device, and more specifically, to measure the copper wire and nickel chromium sensor wire in parallel to improve the measurement accuracy of insulation resistance and defect location, and to leak in the appearance of the double insulation tube The present invention relates to a double heat insulation tube and a double heat insulation tube monitoring device having a built-in detection line capable of detecting whether or not it is easy to install and accurately detect leaks.

In pipelines used for special purposes such as heat pipes or oil pipes, pipe lines consisting of double insulation pipes are generally used. The double insulation tube is made of an inner tube made of metal such as steel or stainless steel, an outer tube made of a plastic resin such as HDPE (High Density Poly Ethylene), and an insulating material filled between the inner tube and the outer tube. This double insulation tube is designed to easily identify the leak point and the degree of leakage if the pipe is exposed to the outside when the fluid flowing through the inside is leaked from the pipe due to damage, aging or other causes of the pipe. Repairs can proceed relatively quickly.

However, if the pipe is buried underground and blocked visually and externally, it is not economical because the pipe can be detected only after the leak is reached and the fluid has reached the advanced state. In addition to the large phosphorus loss, there was a problem that it takes a lot of time and expense in repairing the pipe because the leak point is not known accurately.

In order to solve this problem, various methods have been proposed in the Republic of Korea Patent Publication No. 2005-48328. Among them, as a way to accurately determine whether the double insulation tube leaks and the leaking point, the insulation resistance is indirectly measured by using the current flowing through the pipe and the sensing line embedded in the insulation region between the outer and inner diameter of the double insulation tube. Therefore, a method of determining whether or not leaks has been proposed.

In the conventional double heat insulation tube monitoring system, as shown in FIG. 1, the data transmission cable 1 embedded in the ground is connected to the central monitoring unit 2, and the data transmission cable 1 has a plurality of double thermal insulation. The pipe monitoring device 3 is connected in parallel, and the power supply device 4 and the signal amplification device 5 are connected in series to the data transmission cable 1 in order to provide a plurality of double thermal insulation pipe monitoring devices 3. It is subordinate to one central monitoring device (2).

As shown in FIG. 2, the double insulation tube monitoring device 3 includes a sensor wire 31 and a return wire 32 coated with an insulating material, and an inner tube 40 having the coating peeled off at regular intervals inside the double insulation tube. The wire 33 to be connected is connected, and the voltage applied to the three wires is measured to monitor the leakage.

Specifically, one end of the sensor wire 31 and the return wire 32 are connected to each other to form a loop, and the inner tube 40 is formed of a cast iron tube, thereby forming an independent line. One end of the sensor wire 31 and the return wire 32 and one end of the wire 33 connected to the inner tube 40 are connected to the double heat insulation tube monitoring device 3. The dual heat insulation tube monitoring device 3 supplies a constant voltage to the sensor wire 31, and if no leakage occurs, the same state of the voltage drop caused by the resistance of the sensor wire 31 and the return wire 32 has occurred. The current value is sensed by the double thermal insulation tube monitoring device 3. However, when leakage occurs, a current flows between the sensor wire 31 and the inner tube 40, and a current value different from the normal current value is sensed by the double insulation tube monitoring device 3. In this way, the double insulation tube monitoring device 3 monitors the leakage of the double insulation tube.

In this way, the insulation resistance of the double insulation tube insulation 60 is measured and transmitted to the central monitoring device 2 through the data transmission cable 1 embedded in the ground, and the data through the power supply device 4 The voltage drop in the transmission process is compensated for, and the signal attenuation phenomenon in the data transmission process is compensated for through the signal amplification device 5.

In addition, the signal transmission between the central monitoring unit 2 and the double thermal insulation tube monitoring device 3 sequentially transmits and receives data by the double thermal insulation tube monitoring device 3 according to the order of the double thermal insulation tube monitoring device 3.

As shown in FIG. 3 for monitoring the leakage of the double insulation tube, the sensor wire 31 and the return wire 32 are installed in the conventional double insulation tube. By the way, since the sensor wire 31 and the return wire 32 is installed separately from the inner tube 40 and the outer tube 50 of the double insulation tube, the manufacture of the double insulation tube is very difficult. That is, the inconvenience of using a separate bracket, etc. to fix the sensor wire and the return wire in the double complement tube.

In addition, after installing the sensor wire and the return wire, etc. in the double insulation tube, there is a problem that the position movement of the sensor wire or the return wire occurs in the process of filling the insulation. In this case, when the position shift of the sensor wire or the return wire occurs during the filling process of the thermal insulation material, a critical problem that is difficult to accurately measure the leakage occurs.

In addition, in the prior art, when a leak occurs only in a partial region of the double heat insulating tube, it is not possible to detect whether the water leaks.

The technical problem to be solved by the present invention is to measure the leakage line inside the double insulation tube is fixed to the correct position in the built-in double insulation tube and bare copper wire and nickel chrome sensor wire easy to manufacture and construction in parallel measurement It is to provide a double insulation tube monitoring device that improves the measurement accuracy for insulation resistance and defect location.

In the double heat insulating tube according to the present invention for achieving the above-described technical problem, the inner tube flowing through the fluid and the outer tube wrapped in the spaced apart state and the double heat insulating tube made of a heat insulating material filled between the inner tube and the exterior, A sensor wire fixedly installed to expose an inner surface of the exterior and made of nickel chromium wire; It is fixed to the exterior and installed, the return wire of the structure coated with an insulating material.

In the present invention, the inner surface of the external appearance of the sensor wire installation groove is further formed, it is preferable that the sensor wire is inserted and fixed to the sensor wire installation groove to expose a portion of the surface.

The sensor wire may have a structure in which the surface is coated with an insulating material, the insulating material coating is peeled off at regular intervals, or may have a non-coated structure in which no coating is formed on the surface.

The return wire may be fixedly installed on the inner surface of the exterior to expose a part of the surface similarly to the sensor wire, but may be installed to be completely buried in the interior of the exterior.

Meanwhile, a return wire installation groove is further formed on an inner surface of the exterior, and the return wire is inserted into and fixed in the return wire installation groove so that a part of the surface thereof is exposed.

And the inner surface of the exterior may be further provided with a bare copper wire fixedly installed so that a portion of the surface is exposed. At this time, the sensor wire is disposed on the upper side on the cross section of the double insulation tube, and the bare wire is disposed on the lower side on the cross section of the double insulation tube, it is preferable to monitor a wider area inside the double insulation tube.

In addition, the bare copper wire is composed of a first bare wire and a second bare wire arranged in a state spaced apart from each other, the sensor wire, the first bare wire and the second bare wire, the internal angle of 120 ° relative to the cross-sectional center of the double insulation tube It is preferred to be arranged to have.

In addition, the double insulation tube according to the present invention may be further provided with an external measuring wire made of a bare copper wire on the outer surface of the appearance.

The double heat insulation tube monitoring device according to the present invention monitors the leakage defect of the double heat insulation tube made of an inner tube through which a fluid flows and the inner tube spaced apart from each other, and a heat insulating material filled between the inner tube and the outer shell by an insulation resistance measurement method. A monitoring apparatus comprising: a sensor wire having a structure in which a coating is peeled off at a predetermined interval between the inner tube and an outer surface; A return wire having a structure coated with an insulating material; The bare copper wire having a structure completely peeled off; is disposed, the monitoring device is characterized by monitoring the leakage of the double insulation tube by indirectly measuring the insulation resistance between the sensor wire, the return wire and the bare copper wire.

In the present invention, the sensor wire and the return wire is disposed on the upper side on the cross section of the double insulation tube, the bare wire is disposed on the lower side on the cross section of the double insulation tube, the wire is arranged at various positions in the double insulation tube Therefore, even if a leak occurs in some areas of the double insulation tube it is desirable to detect the leak quickly.

The bare wires may include a first bare wire and a second bare wire which are spaced apart from each other, and may sense a wider area in the double insulation tube, and in particular, the sensor wire, the first bare wire and the second bare wire may be It is preferable to arrange | position so that it may have an internal angle of 120 degrees with respect to the cross-sectional center of a double heat insulating tube.

In the present invention, even if the inner tube is not used for sensing, it is possible to detect whether or not the inner tube is coated with an insulating material, and the inner tube is preferably coated because it can extend the life of the inner tube and prevent leakage due to corrosion of the inner tube. .

In addition, it is preferable that the external measurement wire made of a bare copper wire is further provided on the outside of the exterior, since it is possible to determine whether the leak in the double insulation tube is derived from the inner tube or the outside.

According to the present invention, since the sensing wire, the return wire and the bare wire are fixed in the double heat insulating tube, the manufacturing and construction work of the double heat insulating tube is facilitated, and unlike the conventional double heat insulating tube, the bare copper wire is further installed, so the inner pipe of the double heat insulating tube is Even when coated with an insulating material, there is an effect that can detect whether there is a leak.

In addition, since the sensor wire and two bare wires are disposed at an angle of 120 ° in the double insulation tube of the present invention, all areas inside the double insulation tube can be monitored, and the leaking process can be accurately understood, and further, signs of leakage before leakage can be observed. There is also a detectable effect.

According to the present invention, since leaks are detected using sensor wires and bare copper wires evenly disposed at various points in the double insulation tube, even if a leak occurs in a portion of the insulation region, the leak can be detected quickly and accurately. In particular, since the current flowing through the inner tube is not used for sensing, the outer surface of the inner tube may be coated with an insulating material to significantly extend the life of the inner tube.

In addition, according to the present invention there is an advantage that can determine whether the leak in the double insulation tube is derived from the outside or from the inside using an external measuring wire.

1 is a block diagram showing the configuration of a double heat insulation tube monitoring system.
2 is a view showing a pin connector connection structure of a conventional double heat insulation tube monitoring device.
3 is a cross-sectional view showing a conventional double heat insulation tube internal structure.
4 is a cross-sectional view showing the structure of a double heat insulation tube according to an embodiment of the present invention.
5 is a cross-sectional view showing the structure of a double heat insulation tube according to another embodiment of the present invention.
Figure 6 is a view showing a pin connector connection structure of the double thermal insulation tube monitoring apparatus according to an embodiment of the present invention.

Hereinafter, a specific embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, the double insulation tube according to the present embodiment will be described. As shown in FIG. 4, the double thermal insulation tube according to the present embodiment includes an inner tube 110, an exterior 120, an insulation material 180, a sensor wire 130, a return wire 140, and a bare wire 150, 160. It is configured to include). In the double insulation tube according to the present embodiment, the inner tube 110, the exterior 120, and the insulation material 180 are substantially the same as those of the conventional double insulation tube, and thus a detailed description thereof will be omitted.

However, the inner tube 110 of the double thermal insulation tube according to the present embodiment may be coated with an insulating material on the surface, unlike the conventional inner tube. Conventional inner tube could not be coated with an insulating material because it is electrically used to determine whether the double insulation tube is leaking, the double insulation tube according to the present embodiment can be used to check the bare wire (150, 160) without using the inner tube 110 It can be used to detect leaks inside the double insulation tube. In this embodiment, the inner tube 110 may be coated with an insulating material, and when the inner tube 110 is coated with an insulating material, the life of the inner tube 110 may be extended.

Next, as shown in FIG. 4, the sensor wire 130 is fixedly installed to expose a part of the surface of the outer surface 120. The sensor wire may have a non-coated structure in which an insulating material is not coated on the surface thereof, or may have a structure in which an outer surface thereof is coated with an insulating material, but the coating of the sensor wire may be peeled off at regular intervals. For example, it has a structure in which grooves are drilled at intervals of 1M on the coating formed on the outer surface of the sensor wire 130. In this way, when the grooves are drilled at intervals of 1M, the manufacturing cost is greatly reduced compared to the conventional structure in which grooves are drilled at intervals of 1.5 cm. have. Of course, the gap between the grooves may be changed in various ways, such as 15cm or 30cm.

The sensor wire 130 itself is preferably made of a metal material having excellent electrical conductivity, for example, may be made of nickel chromium wire. On the other hand, as shown in Figure 4, the sensor wire 130 is preferably disposed on the upper side on the cross-section of the double insulation tube. And the sensor wire 130 is supplied with a constant current from the monitoring device, the end of which is connected to the end of the return wire 140 to form a loop.

Meanwhile, in the present invention, as shown in FIG. 5, the sensor wire 130 may have a thin plate-like shape having a large surface area instead of a round shape. In the case of having a thin plate-like structure having such a large surface area, sensing is possible over a large area inside the double insulation tube, so that even if only a part of the inside of the insulation tube is leaked, it is possible to immediately sense the installed sensor wire. There is an advantage that the position movement does not occur 130. In this case, the sensor wire 130 may be formed of a curved surface in the same shape as a portion of the inner surface of the inner tube. Thus, when the sensor wire 130 is made of a curved surface is formed integrally with the inner surface of the inner tube does not interfere with the passage of the heat medium, there is an advantage that the manufacturing of the inner tube is easy. The return wire 140 and the bare wires 150 and 160 which will be described later may also be formed in the same curved surface as the sensor wire.

Next, the return wire 140 is a wire fixedly disposed inside or outside the exterior 120, and unlike the sensor wire 130, the return wire 140 is completely coated with an insulating material. The return wire 140 may be disposed anywhere inside the double insulation tube, and may be disposed adjacent to the sensor wire 130 for convenience of construction, for example. Since the return wire 140 has a completely insulated structure, the return wire 140 may be installed to be completely buried in the exterior 120, and similarly to the sensor wire 130, a part of the surface is exposed on the inner surface of the exterior 120. It may be fixed to be installed.

Next, the bare wires 150 and 160 are fixedly disposed to expose a part of the surface of the outer surface of the outer surface, and have a structure completely peeled off. The bare copper wires 150 and 160 are electrically connected to the sensor wires 130 when a leak occurs inside the double insulation tube, and detects the leak. In this embodiment, two or more of the bare wires may be arranged to more quickly and accurately detect leaks inside the double insulation tube. Although four bare wires 150 and 160 are illustrated in FIG. 4, the present invention is not limited thereto, and three or more bare wires 150 and 160 may be disposed. And since the sensor wire 130 is disposed on the upper side on the cross-section of the double insulation tube, it is preferable that these bare wires (150, 160) is disposed on the lower side on the cross-section of the double insulation tube.

More preferably, the sensor wire 130 in the first nadongseon 150, the angle (θ ¹⁾ and a sensor wire 130 and second nadongseon 160, the angle (θ ²⁾ forms shown in Figure 4 As described above, it is preferable to be arranged so as to be 120 degrees each so as to monitor the widest area.

Similar to the sensor wire 130 described above, the bare wires 150 and 160 may also have a thin plate-like structure having a large surface area.

Meanwhile, as illustrated in FIG. 4, the double insulation tube according to the present embodiment may further include an external measurement wire 170 formed of a bare wire on the outer surface of the exterior 120. Like the other wires, the external measurement wire 170 is mounted in a fixed state so that a part of the surface is exposed on the outer surface of the external appearance 120. The external measurement wire 170 may determine whether the leakage phenomenon inside the double insulation tube is due to internal tube rupture or external rupture.

This external measurement wire 170 may also have a thin plate-like structure with a large surface area, as shown in FIG. 5.

Hereinafter, a double heat insulation tube monitoring apparatus according to the present embodiment. As shown in FIG. 6, the double insulation tube monitoring apparatus according to the present embodiment includes a sensor wire 31, a return wire 32, a bare copper wire 1 131, a bare copper wire 2 132, which are inserted into the double thermal insulation pipe. It is connected to the monitoring device 130 by a 6-pin connector that can be electrically connected to the inner tube line 33 and the outer measurement wire 133 connected to the inner tube.

In the case where the inner tube 140 is coated with an insulator, the inner tube line 33 is not provided, and the outer measuring wire 133 may not be provided as necessary. In addition, although the bare copper wire is given as two examples, one or more than two may be evenly distributed in the double insulation tube.

On the other hand, in the conventional heat insulating tube, the sensor wire 31, the return wire 32, the pipe line 33 was electrically connected to the monitoring device (3) and measured.

The specific configuration of the dual thermal insulation tube monitoring apparatus 130 according to the present embodiment is substantially similar to that of the conventional 3 except that there are six incoming connectors, so the description thereof is omitted here.

Double insulation tube monitoring device 130 of the present embodiment is configured to configure each connection line under the control of the computing device in the switch block for measuring the above six electrical connection lines to each other, the sensor wire The measurement voltage is input to 31 and the return wire 32. Hereinafter, the process of measuring the leakage will be described briefly.

First, the measurement voltage is applied to the sensor wire 31 and the return wire 32 as described above.

1) The inner tube line 33 is input to the ADC block in the double insulation tube monitoring device 130 to measure and store the amount of current flowing therein.

2) Input bare copper wire 1 (131) to ADC block to measure and store the amount of current flowing in.

3) Input bare copper wire 2 133 to ADC block to measure and store the amount of current flowing in.

The number of cases that can occur at this time is as follows.

1) When the current flows only into the inner tube line 33,

2) When the current flows only to the bare wire 1 (131),

3) When the current flows only to the bare wire 2 (132),

4) When the current flows only in the inner tube line 33 and the bare copper wire 1 (131),

5) When the current flows only in the inner tube line 33 and the bare copper wire 2 (132)

6) When the current flows only to the bare copper wire 1 (131) and the bare copper wire 2 (132),

7) When current flows into all of the inner tube wire 33, the bare copper wire 1 131, and the bare copper wire 2 132

In any of the seven cases, the corresponding line is connected at the same time to measure and store the inflow of current. When the amount of current is measured, the voltage applied to the insulating material 160 can be known, so that the insulation resistance of each insulating material can be confirmed. By measuring the average value of the measured insulation resistance, it is possible to reliably classify and determine the progress distribution and degree of the insulation resistance defect of the pipe insulation 160. This information can be subdivided and stored and transmitted to the central monitoring system for wired and wireless monitoring.

In addition, the insulation resistance is continuously measured and monitored according to the degree of defects in the heat insulating material 160, and finally, the sensor wire 31, the return wire 32, the inner tube wire 33, the bare copper wire 1 131, and the bare copper wire 2 ( If the insulation resistance is detected in all of the 132), the entire pipe insulation 160 is in a bad state, and each of them is accumulated and detected in the middle thereof. Thus, as in the present embodiment, by dividing the progress of the leak in detail, the central monitoring device may issue a preliminary leak warning, there is an advantage that can minimize the damage by early response before the leak is completely proceeded.

Meanwhile, also in the method of disposing the sensor wire 31 and the bare copper wires 1, 2 (131, 132) in the double insulation tube, as shown in FIG. It is desirable to. That is, the leakage occurs in the region where the angle θ1 formed by the sensor wire 31 and the bare wire 1 131 and the angle θ2 formed by the sensor wire 31 and the bare wire 2 132 are all 120 °. It is preferable because it can sense whether or not.

Conventionally, since the sensor wire 31 and the return wire 32 are both disposed on the upper side on the cross-section of the double insulation tube for convenience of construction, there is a problem that cannot be detected when a leakage occurs in the lower side of the double insulation tube. . In particular, when a leak occurs, the leak area is likely to expand from the lower side of the double insulation tube due to the influence of gravity, so that the conventional monitoring device may not detect the leak early.

In addition, in the related art, since the leak position is detected only depending on the inner tube line 33, the leak position cannot be detected when a coating material having electrical insulation is applied to the outside of the inner tube 40. However, since the double insulation tube monitoring apparatus according to the present embodiment detects a leak position using separate bare wires 1 and 2 (131, 132) in addition to the inner tube line 33, even if the inner tube 140 is coated with an insulating material, the leak position is precisely determined. There is an advantage to detect.

In order to ensure the stability and lifespan of the double heat insulation pipe, the double heat insulation pipe coated with the inner pipe is mainly applied to oil pipes, etc., but it is known that it is worth applying to the district heating pipes as a trend. That is, there is a trend to be used for the purpose of extending the life by preventing corrosion of the double insulation tube. It is a global trend to apply double insulation pipes to externally coated pipes for oil pipelines. The double insulation tube monitoring device according to the present embodiment effectively monitors insulation insulation defects (leakage) of the insulation material inside the double insulation tube in the same manner except for the procedure of checking the current flowing into the pipe when applied to the coated pipe. It is a double insulation tube monitoring device.

Unlike in the case of identifying leak defect locations, the measurement error can be reduced by measuring and storing the incoming voltages for the seven cases, calculating the summed average value, and in each case, the measured measurement positions may be different. In this case, the movement (proliferation of defects) of the location where the defect occurs can be confirmed, so that it can be further subdivided and transmitted to the central monitoring system for monitoring.

As a method of transmitting the measured data to the central monitoring device can be transmitted by applying the existing wired and wireless communication methods.

Meanwhile, in the double heat insulation tube monitoring apparatus 130 according to the present embodiment, as shown in FIG. 5, the external measurement wire 133 made of a bare wire may be further provided outside the exterior 150. The external measurement wire 133 is disposed outside the double insulation tube, so that the leak inside the double insulation tube can be grasped whether it originates from the inside or the outside. If the leak in the heat insulation tube is derived from the inner due to the rupture of the inner tube 140, the correct follow-up should be made very quickly, but if it is derived from the outside can respond with a relatively gentle measure. As shown in FIG. 5, the external measurement wire 133 is fixedly installed outside the exterior 170 using a separate wire mounting device 135.

110: inner tube 120: appearance
130: sensor wire 140: return wire
150: bare copper wire 160: bare copper wire
180: thermal insulation

Claims (11)

In the double heat insulating tube consisting of an inner tube through which the fluid flows and the outer tube to be spaced apart from each other and a heat insulating material filled between the inner tube and the outer tube,
A sensor wire fixedly installed to expose a surface of the outer surface of the exterior and made of nickel chromium wire;
A return wire fixed to an inner surface of the exterior and coated with an insulating material; And
It is fixed to the inner surface of the exterior, the bare copper wire having a structure completely peeled off;
The sensor wire, the return wire or the bare wire is a double heat insulating tube, characterized in that the surface exposed in the inner tube direction is the same shape as a part of the cylindrical inner surface. delete The method of claim 1, wherein the sensor wire,
A double insulation tube, characterized in that the surface is coated with an insulating material, the insulating coating has a structure peeled off at intervals of 1M. The method of claim 1, wherein the sensor wire,
Double heat insulation tube characterized by having a uncoated structure. The method of claim 1, wherein the return wire,
Double insulation tube, characterized in that installed in the interior of the exterior. The method of claim 1,
The inner surface of the exterior is further formed with a return wire installation groove, the return wire is a double insulation tube, characterized in that inserted into the return wire installation groove is fixed so that a portion of the surface is exposed.
The method of claim 1,
The sensor wire is disposed on the upper side on the cross section of the double insulation tube,
The bare copper wire is a double insulation tube, characterized in that disposed on the lower side on the cross-section of the double insulation tube. The method of claim 7, wherein
The bare copper wire is a double insulation tube, characterized in that consisting of the first spiral wire and the second spiral wire which is disposed spaced apart from each other. 9. The method of claim 8,
The sensor wire, the first bare wire and the second bare wire, the double insulation tube, characterized in that arranged to have an internal angle of 120 ° with respect to the cross-sectional center of the double insulation tube. The method of claim 1,
Double insulation tube, characterized in that the outer surface of the appearance is further provided with an external measuring wire made of a bare copper wire. The double insulation tube monitoring device according to any one of claims 1 to 10, wherein the insulation insulation between the sensor wire, the return wire and the bare wire is indirectly measured to monitor the leakage insulation of the double insulation tube. .

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