RU173364U1 - Fluid leakage sensor - Google Patents

Abstract

The utility model relates to measuring equipment, in particular to indicator, recording and signaling devices driven by electric means, and can be used, in particular, as a sensor for determining the place of leakage of liquids mainly on extended objects. The required technical result, which consists in increasing accuracy and reliability, is achieved in a sensor containing two conductors, each of which is made in the form of a conductive core, connected to an electronic indicator made in the form of a resistance meter, each of the conductors being placed in a conductive shell of an electrically conductive polymer composition, and between the conductive shells and around them is a permeable shell in the form of a bundle of capillary-porous fibers, which is wound on conductors, placed in conductive shells of an electrically conductive polymer composition along a trajectory in the form of closed eights, and capillary-porous fibers impregnated with an 8-12% solution of sodium fluorescein are used as capillary-porous fibers in the bundle. 3 C.p. f-ls, 1 ill.

Description

The utility model relates to measuring equipment, in particular to indicator, recording and signaling devices, driven by electric means, and can be used, in particular, as a sensor for determining the place of leakage of liquids mainly on extended objects.

A device is known [RU 2312954, C1, E03C 1/00, F24D 19/10, 20.12.2007], including a horizontally perforated plate, a water level sensor and an open top container, the horizontal section of the container being smaller than the dimensions of the perforated plate, the container is attached to the bottom of the perforated plate with an offset toward the edge, there is a hole at the bottom of the container, and there is a water sensor and a siphon inside the container, while the bend of the siphon is higher than the water level sensor, the holes are located on the perforated plate so that at least one but of them is located above the container, on the upper part of the perforated plate there is a side having a closed circuit covering all openings, except those located above the container, or a groove having a closed circuit covering all openings except those located above the container and on one of which the groove closes.

The disadvantage of this device is the relatively narrow functionality that does not allow it to be used for extended objects, such as pipelines.

In addition, a device is known [RU 25222, U1, G01M 3/10, G01M 3/26, 09/20/2002], comprising a reservoir and a sensing element placed therein, which is made in the form of a rod on which a high-precision ultrasonic recorder for changing product level is mounted , temperature measuring sensors, bottom water level sensor and an electronic unit connected to a computer providing software testing of the dependence of the temperature layers of the liquid and its level.

The disadvantage of this device is its relatively narrow functionality, since it is designed to detect leaks from tanks and its use for extended objects, such as pipelines, mines, etc., is functionally limited.

Another well-known technical solution is a touch-sensitive, automatic, electronic water sensor [RU 99156, U1, G01M 3/10, G01M 3/26, 11/10/2010] containing a protective tube with a spark plate made of intrinsically safe metal with integrated end electrodes connected to it through wires with an electronic indicator containing an electronic circuit, an LED and an audible warning device connected to a power source and located on the dashboard.

The disadvantage of the device is its relatively narrow functionality, since it is intended to indicate the presence of water in the tank without the ability to determine the location of the water, which functionally limits its use for extended objects, such as pipelines.

The closest in technical essence and the achieved result is a liquid leak detector [RU 2545485, C1, G01F 23/18, 04/10/2015], containing two conductors, each of which is made in the form of a conductive core, connected to an electronic indicator made in the form of a meter resistance, moreover, each of the conductors is placed in a conductive sheath of an electrically conductive polymer composition, and between the conductive sheaths and around them is a permeable sheath in the form of a bundle of capillary-porous fibers, which motan on conductors placed in conductive shells of an electrically conductive polymer composition along a path in the form of closed eights.

In this sensor, when a drop of water enters the surface of a tow of capillary-porous fibers due to the capillary mechanism, water is absorbed by it and moves to an area closer to the conductors placed in the conductive shell of the electrically conductive polymer composition. Ultimately, water reaches the conductive shells and creates an electrically conductive bridge-contact between them. As a result, the continuously measured electrical resistance between the conductive wires changes and the fact of the appearance of water is detected. If the specific (linear) resistance of the conductors is known, then the place of occurrence of water (water leakage) or other conductive fluid can be approximately determined by the resistance value.

The disadvantage of this technical solution is the relatively low accuracy, since the linear resistance of the conductors can vary from various factors, in particular, temperature, with time, etc., and the resistance value at the point of contact is not exactly known, which introduces a significant error in determining the location leakage, so it cannot be determined accurately enough. In addition, the liquid dries out after short-term leaks and it is practically impossible to determine the place of leakage even after a relatively short time after fixing the fact of leakage. In addition to this, it can be indicated that the liquid may have low electrical conductivity, for example, deionized water, which significantly reduces the reliability of the sensor.

The problem that is solved in the utility model is the creation of a fluid leak detector, characterized by higher accuracy and reliability with respect to determining the location of fluid leakage.

The required technical result is to increase the accuracy and reliability of the sensor.

The problem is solved, and the required technical result is achieved by the fact that, in the liquid leak detector, containing two conductors, each of which is made in the form of a conductive core, connected to an electronic indicator made in the form of a resistance meter, and each of the conductors is placed in a conductive a sheath of an electrically conductive polymer composition, and between the conductive sheaths and around them is a permeable sheath in the form of a bundle of capillary-porous fibers, which is wound around rafters placed in the conductive shell of the conductive polymer composition of the trajectory in the form of closed eights, according to the utility model as a capillary-porous fibers in a bundle using a capillary-porous fibers impregnated with 8-12% sodium flourestseina.

In addition, the required technical result is achieved in that, as capillary-porous fibers impregnated with an 8-12% sodium fluorescein solution, cotton fibers are used, twisted into a single-strand yarn in 2 or 3 folds, which is introduced into a bundle of capillary-porous fibers .

In addition, the required technical result is achieved in that, as capillary-porous fibers impregnated with an 8-12% sodium fluorescein solution, cotton fibers are twisted into a two-strand yarn in 4 or 6 additions, which are introduced into a bundle of capillary-porous fibers .

In addition, the required technical result is achieved in that, the impregnation of capillary-porous fibers with 8-12% sodium fluorescein solution is carried out for 2 to 10 seconds, followed by drying.

The drawing shows the design of the sensor leakage of liquids.

The fluid leakage sensor contains two conductors 2, which are placed in a conductive shell 1 of an electrically conductive polymer composition, each of which is made in the form of a conductive core connected to an electronic indicator made in the form of a resistance meter (not shown in the drawing).

In the fluid leakage detector between the conductive shells 1 and around them there is a water-permeable shell 3 in the form of a bundle of capillary-porous fibers, which is wound on conductors 2 placed in conductive shells of an electrically conductive polymer composition along a path in the form of closed eights. At the same time, capillary-porous fibers impregnated with an 8-12% sodium fluorescein solution are used as capillary-porous fibers in the tow, and a lower concentration can significantly reduce the sensitivity of the sensor, and a higher concentration leads to unreasonably high consumption of the substance. The impregnation of capillary-porous fibers with 8-12% sodium fluorescein solution is carried out previously for 2 to 10 seconds, followed by drying. Less time can lead to poor-quality impregnation, and more is unnecessary.

The drawing also shows a conditional drop (jet) 4 of liquid or region 5 in a permeable shell 3 into which it penetrated.

As capillary-porous fibers impregnated with an 8-12% solution of fluorescein sodium, cotton fibers twisted into a single-strand thread in 2 or 3 additions can be used, which are introduced into a bundle of capillary-porous fibers or cotton fibers twisted into a double-strand thread 4 or 6 additions, which are introduced into a bundle of capillary-porous fibers.

A fluid leak detector is used as follows.

The sensor is placed mainly along extended objects (pipelines, wells, mines, tunnels, etc.). The ends of the conductors 2 on the one hand are connected to an electronic indicator made in the form of a resistance (or voltage) meter, and on the other hand, by electrical insulating plugs protecting the measuring circuit from short circuit.

Consider the example of a drop of liquid 4 on the surface of a capillary-porous material. Due to the capillary mechanism, the liquid is absorbed by it and moves to region 5 closer to the conductors 2 placed in the conductive sheath 1 from the electrically conductive polymer composition. Ultimately, the liquid reaches the conductive shells 1 and creates an electrically conductive bridge-contact between them. As a result of this, the continuously measured electrical resistance between the conductive cores 2 changes and the fact of the appearance of a liquid is detected. If the specific (linear) resistance of the conductors is known, then the location of the appearance of the liquid (liquid leakage) can be approximately determined by the value of the resistance. Due to various factors, the place where the liquid appears can be determined with a relatively large error, or the liquid appears briefly in the form of rare drops, or the liquid drops dry relatively quickly. All this does not allow to quickly and accurately determine the place of fluid leakage.

However, you can use the property of fluorescein sodium crystalline powder from red - brick to gray-green, readily soluble in water. It belongs to the class of xanthene dyes, and according to its technical properties it belongs to the group of acid dyes and is a disodium salt of fluorescein with extremely strong green fluorescence. Chemical formula: C ₂₀ H ₁₀ O ₅ Na ₂ . When interacting with a liquid, in particular with water, the fibers impregnated with a solution of fluorescein sodium are colored, and the contact area is clearly visible under ultraviolet radiation, which will make it possible to identify the leakage site even after a long time.

Thus, thanks to the introduced improvements, the required technical result is achieved, which consists in increasing the accuracy and reliability of the sensor. This eliminates the disadvantages of the known technical solution, such as relatively low accuracy, since the linear resistance of the conductors can vary from various factors, in particular, temperature, with time, etc., and the resistance value at the point of contact is not exactly known, which introduces a significant error in determining the location of the leak, so it cannot be determined accurately enough. In addition, the liquid dries out after short-term leaks and it is practically impossible to determine the place of leakage even after a relatively short time after fixing the fact of leakage. In addition to this, it can be pointed out that the liquid may have low electrical conductivity, for example, deionized water, which significantly reduces the reliability of the sensor, and the proposed sensor with higher accuracy creates a mark on the shell corresponding to the place of liquid leakage.

At the same time, without the presence of an electrical indication, it is impossible to quickly determine the fact of a leak. Therefore, only a joint electrical and color indication allows you to successfully (accurately and efficiently) solve the problem of identifying the fact and location of the leak.

Claims (4)

1. A fluid leak detector comprising two conductors, each of which is made in the form of a conductive core, connected to an electronic indicator made in the form of a resistance meter, each of the conductors being placed in a conductive shell of an electrically conductive polymer composition, and between and around the conductive shells a permeable sheath is located in the form of a capillary-porous fiber tow, which is wound on conductors placed in conductive sheaths of an electrically conductive polymer composition and, along a trajectory in the form of closed eights, characterized in that capillary-porous fibers impregnated with an 8-12% solution of sodium fluorescein are used as capillary-porous fibers in the tow. 2. The device according to p. 1, characterized in that as capillary-porous fibers impregnated with an 8-12% solution of sodium fluorescein, cotton fibers are used, twisted into a single-strand yarn in 2 or 3 additions, which are introduced into a bundle of capillary -porous fibers. 3. The device according to claim 1, characterized in that as a capillary-porous fiber impregnated with an 8-12% solution of sodium fluorescein, cotton fibers are used, twisted into a double-strand thread in 4 or 6 additions, which are introduced into a bundle of capillary -porous fibers. 4. The device according to claim 1, characterized in that the impregnation of capillary-porous fibers with an 8-12% solution of sodium fluorescein is carried out for 2 to 10 seconds, followed by drying.

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