KR20230103075A - Liquid leak detecting sensor - Google Patents

Abstract

The present invention relates to a liquid leakage detection sensor which can simply manufacture a liquid leakage detection part by using a protective cap (tube) instead of a complex design, and arrange a partition dividing a light transmitting part and a light receiving part in the liquid leakage detection part to minimize the direct entry of reflected light into the light receiving part in the protective cap to maximize sensing performance. To this end, the liquid leakage detection sensor comprises: a liquid leakage detection part transmitting and receiving an optical signal, and detecting leakage of liquid by connecting two optical cables thereto; a light transmitting part installed on an end of one of the optical cables to project light onto the bottom; a light receiving part installed on an end of the other one of the optical cables to transfer external reflected light to the inside; and a protective cap separately injection-molded on the liquid leakage detection part to surround and cover the liquid leakage detection part.

Description

Liquid leak detection sensor {LIQUID LEAK DETECTING SENSOR}

The present invention relates to a leak detection sensor for detecting leaked liquid.

In general, a leak detection sensor using an optical fiber forms transparent media having different refractive indices in the core area and the cladding area, and uses light guided through the transparent medium formed in the core area to light the gas or liquid filled in the hole in the cladding area. Absorption, refractive index, concentration, density, etc. are detected to detect leakage.

Signals are transmitted through light reflected from a center made of a transparent dielectric, and since the state of light passing through the center is changed by external factors, the optical fiber is also used as a sensor.

In addition, the leak detection sensor using the optical fiber uses a photoelectric sensor at the detection end as its operating mechanism, and is manufactured by covering the outside of the detection end with a case made of a transparent material. and to detect the presence of leaked fluid by specially designing the structure so that the optical properties are distinguished between the presence and absence of liquid outside. The optical characteristic signal, which has been changed due to the contact of the leaked liquid, is converted into an electrical signal at the detection end and transmitted to the controller through the wire.

In the case of adopting the photoelectric sensor as an operating mechanism, since the photoelectric sensor is an electrical component, a separate shielding structure is required to use it in an explosion-proof environment, and expensive explosion-proof certification is also required to secure this safety. .

In addition, in order to use the photoelectric sensor in a high-temperature environment, special measures are required to operate the internal electric circuit even in a high-temperature environment.

Therefore, it is manufactured to be hardly affected by the environment in the work space by detecting liquid leakage using an optical fiber sensor so that an optical signal flows not only to the area to be sensed but also to the control unit outside the work space.

Since general fiber optic sensors corrode and lose their function when exposed to liquid, the sensing head is covered with a chemically resistant transparent material to protect it, and the optical cable is also covered with a chemically resistant material if necessary.

Republic of Korea Patent Publication No. 10-2018-0065530 (title of invention: leak detection sensor, published on June 18, 2018) Republic of Korea Patent Publication No. 10-2019-0070716 (Title of Invention: Liquid Leak Detector Using Optical Fiber Sensor and Method for Manufacturing The Same, published on June 21, 2019)

The present invention was devised in view of the above points, and the leakage detection unit is simply manufactured using a protective cap (tube) rather than a complicated design, and a barrier rib partitioning the light transmitting unit and the light receiving unit is disposed inside the leakage detection unit. The object of the present invention is to provide a leak detection sensor capable of maximizing sensing performance by minimizing direct incident of reflected light to a light receiving unit from inside a protective cap.

According to a preferred embodiment for achieving the above object of the present invention, the leak detection sensor according to the present invention transmits and receives light signals, respectively, and two optical cables are connected to detect leak of liquid. A light emitting unit installed at one end of the optical cable and projecting light to the floor, a light receiving unit installed at the other end of the optical cable and transmitting the reflected light from the outside to the inside, and a separate injection into the leak detection unit, A protective cap covering the leakage detection unit may be included.

A fixing pin protrudes from the outer circumferential surface of the protective cap along the longitudinal direction and is fixed through a fixing bracket to hold the set optical axis of the light transmitting/receiving unit.

The light transmitting unit and the light receiving unit face the bottom at 6 o'clock with the leak detection unit at the center, and the fixing pin of the protective cap protrudes in the opposite direction of the light transmitting unit and the light receiving unit at 12 o'clock and is inserted into the slot of the fixing bracket. Insertion can be fixed.

An inclined mirror may be installed inside the light transmitting unit, and light introduced along the core of the optical cable may be reflected by the mirror to transmit light to the floor of the light transmitting unit.

An inclined mirror is installed inside the light receiving unit, and external light is reflected by the mirror to receive light along the core of the optical cable.

A barrier rib may be installed between the light transmitting unit and the light receiving unit to block light reflected inside the protective cap and received by the light receiving unit.

According to the leak detection sensor according to the present invention, the barrier rib dividing the light emitter and the light receiver is placed inside the leak detection unit to minimize the reflected light reflected inside the protective cap from entering the light receiver, thereby maximizing the sensing performance of the leak detection sensor. can

In addition, the leak detection sensor can be simply manufactured using a protective cap.

In addition, by assembling the leak detection unit of the leak detection sensor and the protective cap in the same direction, the operation direction of the leak detection unit can be accurately set and it can be easily fastened to equipment with a risk of liquid leakage.

1 is a diagram illustrating a leak detection sensor according to an embodiment of the present invention.
2 is a diagram showing the structure of a leak detection sensor according to an embodiment of the present invention.
3 is a diagram illustrating a light transmitting unit and a light receiving unit of a leak detection sensor according to an embodiment of the present invention.
4 is a diagram illustrating an operating state of a light emitting unit according to an embodiment of the present invention.
5 is a diagram illustrating a dry state and a wet state of a leak detection sensor according to an embodiment of the present invention.

Hereinafter, an embodiment of a leak detection sensor according to the present invention will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to clarify the gist of the present invention.

1 is a diagram illustrating a leak detection sensor according to an embodiment of the present invention. 2 is a diagram showing the structure of a leak detection sensor according to an embodiment of the present invention.

1 and 2, the leak detection sensor 1 according to the present invention includes a leak detection unit 10, a light transmitter 20, a light receiver 30, and a protective cap 40, and the leak detection sensor The leakage of the liquid can be detected through the leakage detection unit 10 of (1) and notified by projecting light to the outside.

In the present embodiment, the leak detection unit 10 of the leak detection sensor 1 transmits and receives light signals, respectively, and detects leakage of liquid by connecting two optical cables 11, and the light emitter ( 20) is installed at one end of the optical cable 11 to project light onto the floor, and the light receiving unit 30 is installed at the other end of the optical cable 11 to transmit external reflected light to the inside. , and the protective cap 40 may be separately injected into the leak detection unit 10 and covered while surrounding the leak detection unit 10 .

That is, since the optical cable 11 is used as an operating mechanism of the leak detection sensor 1, not only the leak detector 10 that senses the signal sensed by the leak detector 10 but also an amplifier located outside the process Only the optical signal flows through the optical cable 11 flowing to the controller, and the amplifier that receives the optical signal and converts it into an electrical signal is installed outside the explosion-proof facility, that is, in a control room in a safe area, so that no electricity is operated inside the explosion-proof facility. It is the leak detection sensor (1) without it.

In addition, the leak detection sensor 1 can be used even in a high-temperature environment because the leak detection unit 10 and the optical cable 11 are made of materials that can be used at high temperatures even when the sensing environment is a high-temperature environment.

In addition, even when the leak detection sensor 1 is used at high temperature, since the optical signal is amplified and the amplifier is installed in the control room, which is a room temperature environment outside the process, the amplifier can be sufficiently applied for room temperature even if the process requiring sensing is a high temperature environment. can

In this embodiment, the protective cap 40 of the leak detection sensor 1 has a fixing pin 41 protruding along the longitudinal direction on the outer circumferential surface and fixed through a fixing bracket 50 to catch the optical axis of the set light-transmitting part. can give The light transmitting unit 20 and the light receiving unit 30 face the bottom at 6 o'clock with the leakage detection unit 10 as the center, and the fixing pin 41 of the protective cap 40 connects the light transmitting unit 20 and the light receiving unit. It protrudes in the 12 o'clock direction opposite to the direction of (30) and can be inserted and fixed into the slot 51 of the fixing bracket 50.

The fixing bracket 50 is formed integrally with the protective cap 40 so that the fixing bracket 50 and the leak detection unit 10 are integrally formed to hold the optical axis by installing and mounting the leak detection sensor 1. It can be held through the pin 41.

Since it is important for the leak detection unit 10 to align the optical axes of light transmission and light reception, the optical axis can be more easily adjusted by stably installing the leak detection unit 10 through the fixing bracket 50 .

That is, by setting the sensing direction of the leak detection sensor 1 toward the bottom, which is the side direction of the optical cable 11, the internal operating direction of the leak detection unit 10 faces the 6 o'clock direction, and the protective cap 40 The fixing pin 41 integrally molded in the 12 o'clock direction is fixed to the slot 51 of the fixing bracket 50. Through this, since the leak detection unit 10 is laid down and fastened to the floor, the direction of the light transmitting unit 20 and the light receiving unit 30 inside the leakage detection unit 10 can be disposed toward the floor.

3 is a diagram illustrating a light transmitting unit and a light receiving unit of a leak detection sensor according to an embodiment of the present invention. 4 is a diagram illustrating an operating state of a light emitting unit according to an embodiment of the present invention.

3 and 4, in the leak detection sensor 1, an inclined mirror 60 is installed inside the light transmitting unit 20, and the light transmitting unit 20 is the core of the optical cable 11. The light introduced along (11a) is reflected by the mirror 60 to transmit light to the floor.

In addition, an inclined mirror 60 is installed inside the light receiving unit 30, and the light receiving unit 30 reflects external light to the mirror 60 along the core 11a of the optical cable 11. light can be received.

That is, the leak detection sensor 1 senses the leaked liquid through the light transmitting unit 20 and the light receiving unit 30 installed at the ends of the optical cable 11, and the leaked liquid is transferred from the light transmitting unit 20 to the mirror ( 60) transmits light to the floor, and when the leaked liquid is located at the bottom, the amount of light reflected from the floor is reduced and received. Light can be received inside along the core 11a of (11).

5 is a diagram illustrating a dry state and a wet state of a leak detection sensor according to an embodiment of the present invention.

Referring to FIG. 5 , the leak detection sensor 1 is in a dry state (a) in non-contact with the liquid (L) and in a wet state (b) in which the leak detection sensor 1 is in contact with the liquid (L). The operating structure of the detection sensor 1 is changed.

That is, a barrier 12 is installed between the light transmitter 20 and the light receiver 30 to block light reflected inside the protective cap 40 and received by the light receiver 30 .

Here, when the leak detection sensor 1 is in a dry state (a), the projected light is reflected from the outer surface or bottom of the protective cap 40 so that the light enters the optical cable 11 through the light receiver 30. do.

In addition, when the leak detection sensor 1 is in the Wet state (b), the outer surface of the protective cap 40 is optically recognized as the same medium as the tear liquid, and reflection does not occur on the outer surface, and the tear liquid and less reflection occurs on the floor surface, so light enters the light receiving unit 30. In this way, the leakage is detected by the difference in the amount of light received between the dry state and the wet state, so as not to minimize the light reflected inside the protective cap 40 Otherwise, the difference in light reception amount between the dry state and the wet state compared to the dry state is not large.

Therefore, in the leak detection sensor 1, since the barrier 12 is formed in the leak detection unit 10 inside the protective cap 40 to partition the light transmitting unit 20 and the light receiving unit 30, the projected light is transmitted through the protective cap. Even if it is reflected from the inside of (40), the amount of light received can be minimized.

When the floor is dry, a large portion of the projected light is reflected and received from the outer surface of the protective cap 40 of the leak detection unit 10, and when the liquid L flows on the floor and contacts the leak detection unit 10, it is detected. The liquid L is filled by the surface tension of the lower part. In this case, the material of the protective cap 40 and the liquid L are optically recognized as the same medium, and light is not reflected from the outer surface of the protective cap 40. Since the light is spread into the liquid L and is reflected from the floor, the light entering the light receiving unit 30 is reduced and can be received.

In order to minimize the amount of light entering the light receiver 30, the position of the light receiver 30 is adjusted and the thickness of the barrier 12 is adjusted to minimize the portion that is directly reflected from the floor and receives light. Depending on (a) and the lath state (b), the light reflection characteristics can be changed, and the difference in received light amount between the dry state and the wet state can be maximized compared to the dry state.

Therefore, in the leak detection sensor 1, the barrier 12 partitioning the light transmitting unit 20 and the light receiving unit 30 is disposed inside the leak detection unit 10 so that the reflected light reflected from the inside of the protective cap 40 is transmitted to the light receiving unit. The sensing performance of the leak detection sensor 1 can be maximized by minimizing the incident incident on the leak detection sensor 1 .

In addition, the leak detection sensor 1 can be simply manufactured using the protective cap 40 .

In addition, by assembling the leak detection unit 10 of the leak detection sensor 1 and the protective cap 40 in the same direction, the operating direction of the leak detection unit 10 can be accurately set and easily fastened to equipment with a risk of liquid leakage. can do.

In the above, the present invention has been shown and described in relation to preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described. Rather, it will be appreciated by those skilled in the art that many changes and modifications may be made to the present invention without departing from the spirit and scope of the appended claims.

1: leak detection sensor
10: leak detection unit
11: optical cable
11a: core
12: bulkhead
20: emitter
30: light receiving unit
40: protective cap
41: fixing pin
50: fixed bracket
51: slot
60: mirror
L: liquid

Claims (6)

a leak detection unit configured to transmit and receive light signals and to detect leakage of liquid by connecting two optical cables;
a light emitting unit installed at one end of the optical cable to project light onto the floor;
a light receiving unit installed at an end of another one of the optical cables to transfer externally reflected light to the inside; and
a protective cap that is separately injected into the leak detection unit and is covered while surrounding the leak detection unit; A leak detection sensor comprising a. According to claim 1,
The leak detection sensor, characterized in that the protective cap has a fixing pin protruding along the longitudinal direction on the outer circumferential surface and holding the optical axis of the set light-transmitting and receiving part while being fixed through a fixing bracket. According to claim 1,
The light transmitting unit and the light receiving unit face the bottom at 6 o'clock with the leak detection unit at the center, and the fixing pin of the protective cap protrudes in the opposite direction of the light transmitting unit and the light receiving unit at 12 o'clock and is inserted into the slot of the fixing bracket. A leak detection sensor characterized in that it is inserted and fixed. According to claim 1,
An inclined mirror is installed inside the light transmitting unit, and the light transmitting unit transmits light to the floor by reflecting light introduced along the core of the optical cable by the mirror. According to claim 1,
An inclined mirror is installed inside the light receiving unit, and the light receiving unit receives light along the core of the optical cable by reflecting external light to the mirror. According to claim 1,
The leak detection sensor, characterized in that a barrier rib is installed between the light transmitter and the light receiver to block light reflected inside the protective cap and received by the light receiver.

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