KR20200144237A - Gas leak monitoring system comprising multi-sensing module capable of sensing fine gas leak - Google Patents

Abstract

The present invention relates to a gas leak monitoring system of a multi-sensing module capable of minute gas leak detection, capable of reliably monitoring a leak of gas through multiple detection factors, in particular, certainly detecting even a minute gas leak, and moreover, enhancing usability and safety by sounding an alarm along with a position in case of a gas leak. According to the present invention, the gas leak monitoring system, which is installed on a gas supply line receiving gas to monitor a leak of gas, includes: a first monitoring sensor module provided on the gas supply line to detect a temperature factor of the gas supply line; a second monitoring sensor module provided on the gas supply line to detect a pressure change of the gas supply line as an electric factor; a control part determining the probability of a gas leak and whether gas is leaked by receiving a detection signal from the first monitoring sensor module and a detection signal from the second monitoring sensor module; an alarm part generating a related alarm to a user based on a result determined by the control part; and a battery part for supplying necessary power to the first and second monitoring sensor modules, the control part and the alarm part.

Description

Gas leak monitoring system of multi-sensing module capable of detecting minute gas leaks {GAS LEAK MONITORING SYSTEM COMPRISING MULTI-SENSING MODULE CAPABLE OF SENSING FINE GAS LEAK}

The present invention relates to a gas leakage monitoring system of a multi-sensing module capable of detecting minute gas leakage, and more particularly, it is possible to reliably monitor gas leakage through multiple detection factors, and in particular, to reliably detect even minute gas leakage. In addition, it relates to a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak that can increase usability and safety by alarming the gas leak along with its location.

For welding of the hull of an enlarged ship or welding work required in the entire industrial site such as a large building, a device that supplies gas or oxygen to a welding machine/torch by connecting a flexible flexible hose from the gas and oxygen supply end should be provided. do.

For example, an arc welding apparatus supplies welding current from the welding body, connects one pole to the welding electrode, and connects the other pole to the base material to generate an arc between the two electrodes. Welding is performed by fusing them.

During such welding, when molten metal directly contacts air, oxygen and nitrogen in the air act to create oxides and nitrides on the weld, which severely deteriorates the material of the weld. Therefore, the arc and weld are completely deteriorated by neutral gas or inert gas It must be protected from the atmosphere. Moreover, the protection of the arc and the welding part not only metallurgically protects the welding part, but also has a close relationship with the protective gas, so it has a great effect on the stability of the arc. Improve.

The gas-protected arc welding device is a method of directly supplying such a protective gas to the vicinity of the arc, and an inert gas arc welder using an inert gas such as argon or helium, and mainly protected by carbon dioxide gas. There is a CO2 gas arc welder.

Specifically, in a general gas protection arc welding apparatus, a constant voltage current power from a power supply source is supplied to the welding body through a power cable, and a protective gas from a gas supply source is supplied to the welding body through a gas hose, which is a gas supply path. The gas hose and the device cable and welding cable are connected between the welding body and the wire feeder. After the wire feeder, the gas hose and the welding cable are integrated and connected to the torch, and the welding cable is connected from the welding body to the base material. . In such a gas-protected arc welding apparatus, the protective gas is supplied from a gas supply source to a torch through a gas hose through a welding body and a wire feeder.

However, most of the welding equipment is in poor working conditions, and the actual gas hose is very long enough to reach a maximum of 80m and has several connections. For this reason, the gas hose is highly likely to be damaged, so gas leakage. Concern is also very high, and it is difficult for workers to recognize it, and there is a problem that the protective gas is continuously leaked.

At work sites where sparks or flames are generated in this way, it is necessary to check whether gas or oxygen is leaked in real time and work.Therefore, check whether there is gas leakage between the supply end of gas and oxygen and the flexible hose. It is common to equip the measuring device or system.

Among the conventional patented technologies, "Gas Leak Safety Gauge (Registration No. 10-1845372) capable of checking gas leaks" proposes a device that measures whether a gas leaks through the elasticity of a spring.

In the case of Patent Registration No. 10-1845372, the visual detection of the presence of gas leakage according to the degree of contraction of the spring provided on the pipe through which the gas flows, and the part representing the contraction of the spring is visible through transparent plastic, etc. , There is a problem in that a flame or the like is damaged by splashing on the transparent plastic part, causing outflow of gas, resulting in a fire.

In addition, there was a hassle of having to check whether the spring contracted or not with the naked eye, and there was a problem in that it was not possible to detect gas leakage in real time until such an active action of the worker was accompanied.

Accordingly, research and development of technology that can prevent safety accidents by reliably and reliably checking whether gas or oxygen is leaked at work sites where sparks or flames are generated everywhere are required.

Republic of Korea Patent Publication 10-1845372 (2018.04.04. Announcement) Korean Registered Patent Publication 10-0466202 (announced on Jan. 13, 2005) Republic of Korea Patent Publication 10-2005-0113891 (published on May 12, 2005) Republic of Korea Patent Publication 10-2016-0068008 (published on June 15, 2016) Republic of Korea Patent Publication 10-2005-0079223 (published on Aug. 9, 2005)

Therefore, the present invention for solving the above-described conventional problem, it is possible to reliably monitor gas leakage through multiple detection factors, and in particular, it is possible to reliably detect even minute gas leakage. Its purpose is to provide a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak that can increase usability and safety by alarming together.

The problem of the present invention is not limited to those mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

According to one aspect of the present invention for achieving the objects and other features of the present invention, as a system installed in a gas supply line to monitor gas leakage, provided in the gas supply line to supply the gas A first monitoring sensor module configured to detect a temperature factor of a line; a second monitoring sensor module provided in the gas supply line and configured to detect a pressure change in the gas supply line as an electrical factor; A control unit configured to receive a detection signal from the first monitoring sensor module and a detection signal from the second monitoring sensor module to determine the possibility of gas leakage and whether the gas is leaked; An alarm unit for generating a related alarm to a user based on a result determined by the control unit; And a battery unit for supplying necessary power to the first and second monitoring sensor modules, the control unit, and the alarm unit. A gas leak monitoring system is provided.

In the present invention, the first monitoring sensor module includes a housing having a coupling port coupled to the gas supply line, a pair of temperature sensors configured in the housing to detect the temperature of the gas supply line, and the temperature And a transmission unit for transmitting a signal detected by a sensor to a first sensor module unit constituting the control unit, and the first sensor module unit receives temperature values respectively transmitted from temperature sensors of the pair of first monitoring sensor modules. The flow rate may be calculated, and pressure may be measured based on the calculated flow rate to determine whether gas leaks.

In the present invention, the first monitoring sensor module is configured by using a pair of monitoring sensor modules as one set and configured at a plurality of locations along the gas supply line, and each set is provided with a sensor ID, The transmission unit of the first monitoring sensor module is configured to transmit the ID information of the set together when transmitting the signal detected from one set, and the first module control unit calculates a wind speed value for the received temperature signal, and The wind speed value may be converted into a pressure value, and the converted pressure value may be compared with a preset value to determine whether gas leaks.

In the present invention, the second monitoring sensor module includes a valve body pipe connected to the gas supply line, and a head disposed in the valve body pipe and one end facing each other in a direction in which gas is applied and pressurized by the pressure of the gas. A part, a body part disposed in the valve body pipe, receiving a part of the other end of the head part, and measuring the pressure of gas when the head part is pressurized and flowing, and a body part disposed in the body part, partly outside the valve body pipe And a display unit that is exposed to and displays the pressure of the gas measured by the body unit, wherein a portion of the outer circumferential surface of the head unit and the body unit is spaced apart from the inner circumferential surface of the valve body tube to form a through path through which gas can flow. Can be formed.

In the present invention, the head portion is disposed in the head portion and one side faces in a direction in which gas is introduced and the other side faces in a direction in which gas flows, but the central portion is convexly formed, and the pressure portion contacts the other surface of the pressure portion. And a pressed portion that is pressed and whose electrical resistance value is changed by the pressure by the pressing portion, and a contact portion electrically connected to the pressed portion and applying a current to the pressed portion, and the pressing portion includes a conductive material. When made of a soft material, and the pressed portion is composed of the pair of conductors, the pair of conductors form a plurality of conduction branches that are spaced apart from each other, and the pressing unit presses the plurality of conduction branches , The electrical resistance value is configured to vary between the plurality of conduction branches, and the body portion constitutes the control unit, and is connected to the contact portion to measure the electrical resistance value of the pressed portion, and the measured pressure of the gas It may include a second module control unit represented by the display unit.

In the present invention, the display unit includes a command input unit disposed outside the valve body pipe to receive a preset command from an administrator, and the command input unit includes a power supply unit and a reference gas pressure or alarm setting from the administrator. And an instruction applying unit receiving a command, and the second module control unit compares the measured gas pressure and the reference gas pressure, and when the measured gas pressure is smaller than the reference pressure, the display unit displays or an alarm through the alarm unit. Can be made to do.

In the present invention, further comprising a third monitoring sensor module provided in the gas supply line and configured to detect a pressure change in the gas supply line as a pressure-temperature factor, the third monitoring sensor module, the gas supply A housing having a coupling port coupled to the line, a pressure sensor configured on one side of the housing to detect the pressure of the gas supply line, and a pressure sensor configured on the other side of the housing to detect the temperature of the gas supply line It may include a temperature sensor, and a transmitter for transmitting the signal detected by the pressure sensor and the temperature sensor to the control unit.

In the present invention, the third monitoring sensor module is configured at a plurality of locations along the gas supply line, and a sensor ID is assigned so that the transmitter transmits the sensor ID information when transmitting the signal detected by each sensor. It is transmitted to a third module control unit constituting the control unit, and the third module control unit receives a signal from the third monitoring sensor module and compares it with a preset value to determine whether gas leaks or not, and displays the alarm on the display unit. The third module control unit may be configured to an alarm through a unit, and the third module control unit may be configured together with the alarm unit and the display unit in at least one control panel of a work site and a remote central management unit.

According to the gas leak monitoring system of the multi-sensing module capable of detecting minute gas leaks according to the present invention, the following effects are provided.

First, the present invention has the effect of being able to reliably and reliably monitor and notify gas leakage through two or more detection factors.

Second, the present invention has the effect of reliably detecting even minute gas leaks through temperature-based pressure detection.

Third, according to the present invention, when a gas leaks, it is easy to identify an abnormal location by alarming it together with the location, and accordingly, there is an effect of increasing maintenance and safety.

Fourth, according to the present invention, the display unit and the alarm unit integrally provided with the monitoring sensor module allow the operator to easily check the gas leak even if the operator does not visually check separately during work such as welding.

Fifth, according to the present invention, according to the introduction of the pressure-sensitive sensor as a monitoring sensor module, it is possible to compensate for the occurrence of defects in the product due to the shortening of the life of the existing metallic spring.

Sixth, the present invention has the effect of preventing the risk of occurrence of a secondary fire due to flames by fundamentally reinforcing the externally displayed part.

The effects of the present invention are not limited to those mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a block diagram schematically showing the configuration of a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak according to the present invention.
2 is a perspective view showing the configuration of a second monitoring sensor module constituting a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak according to the present invention.
3 is a left sectional view showing a second monitoring sensor module constituting a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak according to the present invention.
4 is an exploded view showing a pressurized portion, a pressurized portion, and a contact portion of a second monitoring sensor module constituting a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak according to the present invention.
5 is a front view showing a state in which the second monitoring sensor module constituting the gas leak monitoring system of the multi-sensing module capable of detecting minute gas leakage according to the present invention is applied to the gas supply module.
6 is a front cross-sectional view of FIG. 4.
7 is a front cross-sectional view in a state in which a predetermined angle is rotated in an axial direction in FIG. 4.
8 is a block diagram showing the configuration of a third monitoring sensor module constituting a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak according to the present invention.

Additional objects, features, and advantages of the present invention may be more clearly understood from the following detailed description and accompanying drawings.

Prior to the detailed description of the present invention, the present invention is capable of various modifications and various embodiments, and the examples described below and shown in the drawings are intended to limit the present invention to specific embodiments. It should be understood as including all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

When a component is referred to as being "connected" or "connected" to another component, it is understood that it may be directly connected or connected to the other component, but other components may exist in the middle. Should be. On the other hand, when a component is referred to as being "directly connected" or "directly connected" to another component, it should be understood that there is no other component in the middle.

The terms used in the present specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof does not preclude in advance.

In addition, terms such as "... unit", "... unit", and "... module" described in the specification mean a unit that processes at least one function or operation, which is hardware, software, or hardware and It can be implemented as a combination of software.

In addition, in the description with reference to the accompanying drawings, the same reference numerals are assigned to the same components regardless of the reference numerals, and redundant descriptions thereof will be omitted. In describing the present invention, when it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Hereinafter, a gas leak monitoring system of a multi-sensing module capable of detecting a fine gas leak according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing the configuration of a gas leak monitoring system of a multi-sensing module capable of detecting a fine gas leak according to the present invention, and FIG. 2 is a multi-sensing module capable of detecting a fine gas leak according to the present invention. A perspective view showing the configuration of the second monitoring sensor module constituting the gas leak monitoring system, and FIG. 3 is a view showing a second monitoring sensor module constituting the gas leak monitoring system of the multi-sensing module capable of detecting a fine gas leak according to the present invention. It is a cross-sectional view on the left, and FIG. 4 is an exploded view showing a pressurized part, a pressured part, and a contact part of a second monitoring sensor module constituting a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak according to the present invention. A front view showing a state in which the second monitoring sensor module constituting the gas leak monitoring system of the multi-sensing module capable of detecting minute gas leakage according to the present invention is applied to the gas supply module, and FIG. 6 is a front cross-sectional view of FIG. 4 and FIG. 7 4 is a front cross-sectional view in a state in which a certain angle is rotated in an axial direction.

The gas leak monitoring system of the multi-sensing module capable of detecting minute gas leaks according to the present invention is installed in a gas supply line (for example, a rigid material line or a soft material line) to monitor gas leakage. As a system for performing, as shown in FIGS. 2 to 7, a first monitoring sensor module 700 provided in a gas supply line and configured to detect a temperature factor of the gas supply line; A second monitoring sensor module 200 provided in the gas supply line and configured to detect a pressure change in the gas supply line as an electrical factor; A control unit 300 that receives a detection signal from the first monitoring sensor module 700 and a detection signal from the second monitoring sensor module 200 to determine the possibility of gas leakage and whether the gas leaks; An alarm unit 400 for generating a related alarm to a user based on a result determined by the control unit 300; And a battery unit 500 for supplying necessary power to each of the sensor modules 100 and 200, the control unit 300, and the alarm unit 400.

In addition, the present invention is a display unit for displaying information (signals) received from the first monitoring sensor module 700, the second monitoring sensor module 200, and the third monitoring sensor module 100 (to be described later). 600) may be further included.

The first monitoring sensor module 700 includes a housing having a coupling port coupled to a gas supply line, and a pair of temperature sensors configured in the housing to detect the temperature of the gas supply line, and the temperature sensor It includes a transmission unit that transmits the detected signal to the first sensor module unit 310 constituting the control unit 300, and includes a pair of first monitoring sensor modules provided at a predetermined interval in the gas supply line.

Here, the first sensor module unit 310 receives temperature values transmitted from the temperature sensors of the pair of first monitoring sensor modules, calculates a flow rate, and measures a pressure based on the calculated flow rate It will determine if there is a leak.

As another example, the first monitoring sensor module 700 may be formed of a thermistor type wind speed sensor.

The first monitoring sensor module 700 and the first sensor module unit 310 may detect minute changes by measuring based on temperature, and may detect minute gas leakage.

The first monitoring sensor module 700 may include a pressure sensor and a battery unit 500 for providing necessary power to the transmission unit, and may be integrally built into the housing.

The first monitoring sensor module 700 may be configured at a plurality of locations along the gas supply line by using a pair of monitoring sensor modules as a set, and in this case, each first monitoring sensor module 100 The sensor ID is assigned to and configured.

At this time, when transmitting a signal detected by a set of temperature sensors, the transmitting unit of the first monitoring sensor module 700 transmits ID information of the set together.

In this way, the signal (information) transmitted from the first monitoring sensor module 700 is transmitted to the first module control unit 310 constituting the control unit 300, and the first module control unit 310 includes the first monitoring sensor module ( A wind speed value is calculated for the temperature detection signal of 100), the calculated wind speed value is converted back to a pressure value, and the converted pressure value is compared with a preset value to determine the possibility of gas leakage and whether or not gas leakage. In addition, the first module control unit 310 displays the signal (information) of the first monitoring sensor module 100 on the display unit 600.

When the first monitoring sensor module 700 is configured in a plurality of locations of the gas supply line, the first monitoring sensor module 700 includes a set ID included in the signal (information) from each set. It is possible to determine at which location the signal is being transmitted from the set, and accordingly, it is possible to easily identify the location of the potential leak and the location of the leak along with a notification notification to the user.

Here, the first module control unit 310 may be integrally formed in the housing of the first monitoring sensor module 700, while the first module control unit 310 is a separate control unit at a work site or a remote location. It may be configured with the alarm unit 400, the battery unit 500, and the display unit 600 in a box or control panel.

Next, the second monitoring sensor module 200 will be described.

The second monitoring sensor module 200 largely includes a head portion 210 and a body portion 220, and as will be described later, the second module controller 320 and the alarm unit are used as the controller 300. The 400, the battery unit 500, and the display unit 600 may be integrally configured. In the following description, a case where the second module control unit 320, the alarm unit 400, the battery unit 500, and the display unit 600 are integrally configured with the second monitoring sensor module 200 will be described.

In the second monitoring sensor module 200, the head part 210 and the body part 220 may be inserted into and fixed to the inside of the valve body tube 20, and the display part 600 may include the body part 220 and the body part 220. It is configured integrally with the valve body tube 20, but a part of the valve body tube 20 may be configured to be exposed to the outside.

In the case of the head part 210 and the body part 220, it is preferable to have a cylindrical shape corresponding to the inner pipe of the valve body pipe 20, but as will be described later, it is possible to naturally flow while the gas pressure is applied. It is made to have a shape.

In addition, in the case of the head portion 210, it is disposed inside the valve body tube 20, and one end thereof is disposed opposite to the direction in which the gas is applied, and is arranged to be pressurized by the pressure of the applied gas.

The head part 210 has a flow distance of about several millimeters (mm) of contraction and expansion due to the pressure of the gas, and such contraction and expansion is an action made by interaction between the pressure of the gas and its own elastic force. Corresponds to.

Subsequently, the head portion 210 may include a pressing portion 201, a pressed portion 202, and a contact portion 203.

As shown in FIG. 5, the pressurizing part 201 is disposed in the head part 210, and one side of the pressurizing part 201 faces the direction in which gas is introduced, and the other surface pressurizes the pressurized part 202 to be described later. Head towards

In addition, it is preferable that the other surface of the pressing portion 201 is formed so that its central portion protrudes toward the pressed portion 202 and the edge thereof is formed to be less protruding, that is, the center thereof is convex.

As an embodiment of the other surface of the pressing part 201, the protruding positive step between the center and the edge thereof is set in the range of 0.1 mm to 2 mm, and this step is an element corresponding to the flow distance of the head part 210 as described above. to be.

In addition, the pressurized portion 202 is configured to contact and press the other surface of the pressurizing portion 201.

As described above, the pressured portion 202 is configured such that a value of the current flowing through the contact portion 203, which will be described later while being pressed by the pressure portion 201, fluctuates, that is, the electrical resistance value fluctuates.

In addition, the contact portions 203 are configured to electrically connect to the pressed portion 202 in a pair, through which voltage and current are applied to the pressed portion 202.

Specifically, the pressing unit 201 is made of a soft material, that is, a soft material, and such a soft material preferably includes a conductive material.

In addition, the soft material constituting the pressing part 201 itself may be a material having electrical conductivity.

Referring to FIG. 5, when the pressing portion 201 of a soft material with a convex in the center slowly presses the pressed portion 202, the area in contact with the pressed portion 202 is widened, and the pressure of the pressed portion 202 is The electrical resistance changes.

To this end, more preferably, the pressed portion 202 may constitute a pair of conduction branches 202a and 202b, and these conduction branches 202a and 202b each form a plurality of branches, but these branches are As they are spaced apart from each other at equal intervals, the number of conductive branches 202a and 202b electrically connected to each other varies according to the pressing of the convex pressing portions 201 made of soft materials. Through this, the electrical resistance value of the pressurized unit 202 is changed according to the degree of pressurization of the pressurizing unit 201, and the gas pressure is ultimately measured through the changed electric resistance value.

Subsequently, in the case of the body portion 220, the valve body pipe 20 is disposed like the head portion 210, and the body portion 220 is a head portion that is not fixed in the valve body pipe 20 and flows. Unlike 210, it is fixed to the inner surface of the valve body tube 20.

It is preferable that the body part 220 has a cylindrical shape as a whole, and most of the outer circumferential surface thereof is preferably fixedly attached to the inner surface of the valve body tube 20.

Specifically, the body portion 220 is preferably made of a cylindrical shape corresponding to the inner conduit of the valve body tube 20, but as will be described later, a shape in which gas can flow naturally (Figs. 3 and 4 (See "H").

In other words, the head part 210 and the body part 220 are formed with a through path H through which the applied gas can flow by having a partial surface of the outer circumferential surface spaced apart from the inner circumferential surface of the valve body tube 20. As shown in Figs. 3 and 4, the through path H may have a cross section formed such that a part of a circle is cut to form a gas through path H.

As shown in Figs. 3 and 4, the body part 220 accommodates a part of the other end of the head part 210, and when the head part 210 is pressed and flows, such a flow distance can be accommodated. Have internal space.

Next, the control unit 300 receives a signal (information) from the first monitoring sensor module 100 and controls the first module control unit 310, and the signal from the second monitoring sensor module 200 ( Information) and a second module controller 320 that receives and controls it. As described above, each module control unit of the control unit 300 may be integrally configured with each monitoring sensor module, and may be configured in a separate control box or control panel.

The second module control unit 320 may be configured in the body unit 220.

The second module control unit 320 is connected to the contact unit 203 to measure the electrical resistance value of the pressurized unit 202, and ultimately measures the gas pressure, through which the measured pressure of the gas is displayed on the display unit. It should be expressed as (600).

The second module control unit 320 recognizes the value of the gas pressure according to the measured resistance value through the gas pressure value mapped to the measured electrical resistance value of the pressurized unit 202 through a previously stored data table. can do.

The second module controller 320 compares and analyzes the measured pressure of the gas and the reference gas pressure. If, after the second module control unit 320 analyzes, if the measured gas pressure is low compared to the reference gas pressure, it means that unexpected gas leakage has occurred in the flexible hose or other connection, so it is not normal. It is recognized that an abnormality has occurred.

Subsequently, the alarm unit 400 determines that there is a possibility of leakage or that leakage occurs according to the control signals of the control unit 300 (the first module control unit 310 and the second module control unit 320). In this case, it may be made of a speaker, a buzzer, and a warning light that can audibly and/or visually notify the operator and/or the manager.

In other words, in the first module control unit 310, the second module control unit 320, and the third module control unit 330 to be described later, the measured gas pressure is compared with the reference gas pressure based on a signal (information). When the pressure is less than the reference pressure, a control signal is transmitted to the alarm unit 400 to generate an alarm to the outside.

The alarm occurrence of the alarm unit 400 informs the outside of the occurrence of an abnormality through sound or vibration, through which the operator can recognize the occurrence of the abnormality through hearing or tactile sense even if there is no visual confirmation of the display unit 600. There will be.

The alarm unit 400 may generate a beep sound or motor vibration by having a binary speaker generating a beep sound or a small monitor for generating vibration.

Next, the battery unit 500 may be composed of a battery integrally configured with each of the monitoring sensor modules, or may be composed of a power supply unit through which external power may be input.

The display unit 600 performs a function of externally displaying the gas pressure measured by the first and second module controllers 310 and 320. In the case of the display unit 600, a solar cell used in an electronic calculator, for example, a display used for an electronic calculator, for example, a PMLCD (Passive Matrix LCD), or a STN (Super-Twisted Nematic) or TFT (Thin Film Transistor) method is used. It is desirable to be able to be driven even with ultra-low power of.

The display unit 600 may be configured in the housing of the first monitoring sensor module 100 and the valve body tube 20 of the second monitoring sensor module 200, and as described above, a separate control box or control panel Can be configured on

Here, for example, a case in which the display unit 600 is integrally formed in the second monitoring sensor module 200 will be described.

The display unit 600 may include first and second command input units 610 and 620.

The display unit 600 performs a function of exposing the pressure of the gas measured by the body unit 220 to the outside, and displaying and notifying the measured gas pressure to an operator or a manager at a work site of a torch/welding.

When the display unit 600 is integrally formed in the second monitoring sensor module 200, the first and second command input units 610 and 620 of the display unit 600 are external to the valve body tube 20. It is exposed and configured to receive various commands from the operator/manager.

Various commands through the first and second command input units 610 and 620 receive pre-determined commands from the administrator, and these commands are buttons to apply power or to determine whether gas is leaking. It is possible to perform such as receiving a reference value (reference) of the "reference gas pressure".

In the case of the first and second command input units 610 and 620, a power supply unit 610 and an instruction application unit 620 may be included.

In the case of the power applying unit 610, as to apply power, it performs a function of turning on or off the monitoring sensor module.

Further, the instruction applying unit 620 receives more various commands. As described above, the instruction applying unit 620 may receive a command for setting a reference gas pressure or an alarm.

Since the specific coating of the power supply unit 610 and the instruction application unit 620 and various UI/UX parts corresponding thereto will correspond to a specific embodiment for performing the functions as described above, a practical description will be omitted.

The first and second command input units 610 and 620 may be applied to the first monitoring sensor module 700 and the third monitoring sensor module 300 to be described later.

Meanwhile, FIG. 8 is a block diagram showing the configuration of a third monitoring sensor module constituting a gas leak monitoring system of a multi-sensing module capable of detecting a minute gas leak according to the present invention.

The gas leak monitoring system of the multi-sensing module capable of detecting a minute gas leak according to the present invention is provided in a gas supply line and detects a pressure change in the gas supply line as a pressure-temperature factor, as shown in FIGS. 1 and 8 A third monitoring sensor module 100 configured to be configured to be further included, and the control unit 300 may further include a third module control unit 330.

The third monitoring sensor module 100 includes a housing 110 having a coupling hole 111 coupled to a gas supply line, as shown in FIG. 8, and is configured on one side of the housing 110 to A pressure sensor 120 for detecting pressure, a temperature sensor 130 configured on the other side of the housing 110 to detect the temperature of the gas supply line, the pressure sensor 120 and the temperature sensor 130 It includes a transmitter (including an RF antenna) 140 for transmitting the signal detected in the control unit 300.

The third monitoring sensor module 100 includes a pressure sensor 120, a temperature sensor 130, and a battery unit 500 for providing necessary power to the transmission unit 140 are integrally built into the housing 110. Can be.

The third monitoring sensor module 100 may be configured at a plurality of locations along the gas supply line, and in this case, each second monitoring sensor module 300 is configured with a sensor ID assigned thereto.

At this time, the transmitter 140 transmits the sensor ID information together when transmitting the signal detected by each of the sensors 120 and 130.

In this way, the signal (information) transmitted from the third monitoring sensor module 100 is transmitted to the third module control unit 330 constituting the control unit 300, and the third monitoring sensor module ( 100) is compared with a preset value to determine the possibility of gas leakage and whether or not there is gas leakage. In addition, the third module control unit 330 displays the signal (information) of the third monitoring sensor module 100 on the display unit (the display unit for a third module) 600.

Here, the third monitoring sensor module 100 is configured at a plurality of locations of the gas supply line, and the position of the gas supply line through the sensor ID included in the signal (information) from the first monitoring sensor module 100 It is possible to grasp whether a signal is transmitted from the third monitoring sensor module 100 located at, and accordingly, it is possible to easily identify a location of a potential leak and a location of a leak along with a notification notification to the user.

Here, the third module control unit 330 may be integrally formed in the housing of the first monitoring sensor module 100, while the third module control unit 330 is a separate control unit at a work site or a remote location. It may be configured with an alarm unit (alarm unit for a third module) 400, a battery unit (battery unit for a third module) 500 and a display unit (display unit for a third module) 600 in a box or control panel. have.

According to the gas leak monitoring system of the multi-sensing module capable of detecting microscopic gas leaks according to the present invention as described above, gas leaks can be reliably and reliably monitored and notified through two or more detection factors, and temperature-based pressure Through detection, even minute gas leaks can be reliably detected, and when gas leaks occur, it is easy to identify abnormal locations by alarming them along with the location, thereby improving maintenance and safety.

In addition, the present invention increases usability by preventing the operator from separately visually checking during work such as welding by a display unit and an alarm unit integrally provided in the monitoring sensor module, and with the introduction of a pressure-sensitive sensor as a monitoring sensor module, It is possible to compensate for the occurrence of defects in the product due to the shortening of the life of the existing metallic elastic spring, and there is an advantage of preventing the risk of secondary fire occurrence due to sparks by fundamentally reinforcing the externally displayed part.

As described above, although the embodiments have been described by the limited drawings, those of ordinary skill in the art can apply various technical modifications and variations based on the above. For example, the described techniques are performed in a different order from the described method, and/or components such as a system, structure, device, circuit, etc. described are combined or combined in a form different from the described method, Alternatively, even if substituted or substituted by an equivalent, an appropriate result can be achieved.

The embodiments described in the present specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Accordingly, it is obvious that the embodiments disclosed in the present specification are not intended to limit the technical idea of the present disclosure, but to explain the technical idea, and thus the scope of the technical idea of the present disclosure is not limited by these embodiments. Modification examples and specific embodiments that can be easily inferred by those skilled in the art within the scope of the technical idea included in the specification and drawings of the present invention should be interpreted as being included in the scope of the present invention.

H: gas passage
10: valve connector
20: valve body pipe
100: third monitoring sensor module
110: housing
120: pressure sensor
130: temperature sensor
140: transmitter (including RF antenna)
200: second monitoring sensor module
210: head portion
220: body part
201: pressurization part
202: pressured part
203: contact
300: control unit
310: first module control unit
320: second module control unit
330: third module control unit
400: alarm unit
500: battery part
600: display unit
610: power supply
620: Is it an instruction
700: first monitoring sensor module

Claims (8)

As a system installed in the gas supply line where gas is supplied to monitor gas leakage,
A first monitoring sensor module provided in the gas supply line and configured to detect the temperature factor of the gas supply line
A second monitoring sensor module provided in the gas supply line and configured to detect a pressure change in the gas supply line as an electrical factor;
A control unit configured to receive a detection signal from the first monitoring sensor module and a detection signal from the second monitoring sensor module to determine the possibility of gas leakage and whether the gas is leaked;
An alarm unit that generates a related alarm to a user based on a result determined by the control unit; And
And a battery unit for supplying necessary power to the first and second monitoring sensor modules, the control unit, and the alarm unit.
Gas leak monitoring system.
The method of claim 1,
The first monitoring sensor module includes a housing having a coupling port coupled to the gas supply line, a pair of temperature sensors configured in the housing to detect the temperature of the gas supply line, and a signal detected by the temperature sensor And a transmission unit for transmitting to the first sensor module unit constituting the control unit,
The first sensor module unit receives temperature values transmitted from each of the temperature sensors of the pair of first monitoring sensor modules, calculates a flow rate, and measures a pressure based on the calculated flow rate to determine whether gas leaks. Characterized
Gas leak monitoring system.
The method of claim 2,
The first monitoring sensor module is configured by using a pair of monitoring sensor modules as one set, and is configured at a plurality of locations along the gas supply line, and a sensor ID is assigned to each set,
The transmitting unit of the first monitoring sensor module is configured to transmit ID information of the set together when transmitting the signal detected in one set,
Wherein the first module control unit calculates a wind speed value for the received temperature signal, converts the calculated wind speed value to a pressure value, and compares the converted pressure value with a preset value to determine whether gas leaks.
Gas leak monitoring system.
The method of claim 1,
The second monitoring sensor module includes a valve body pipe connected to a gas supply line, a head portion disposed in the valve body pipe and disposed opposite to one end in a direction in which gas is applied to be pressurized by a gas pressure, and the valve A body portion disposed in the body pipe, receiving a part of the other end of the head portion, and measuring the pressure of gas when the head portion is pressurized and flowing, and a body portion disposed in the body portion, but partially exposed to the outside of the valve body pipe, and the body It includes a display for displaying the pressure of the additionally measured gas,
The head portion and the body portion, characterized in that some of the outer peripheral surfaces are spaced apart from the inner peripheral surface of the valve body tube to form a through path through which gas can flow.
Gas leak monitoring system.
The method of claim 4,
The head portion is disposed in the head portion and one side faces in a direction in which gas is introduced, and the other side faces in a direction in which gas flows, but the central portion is convexly formed, and the pressurization portion is pressed in contact with the other surface of the pressure portion. A portion to be pressed whose electrical resistance value is varied by negative pressure, and a contact portion electrically connected to the portion to be pressed and applying a current to the portion to be pressed,
The pressing part is made of a soft material including a conductive material,
When the pressed portion is composed of the pair of conductors, the pair of conductors form a plurality of conduction branches that are spaced apart from each other, and the pressing portion presses the plurality of conduction branches, between the plurality of conduction branches Is configured such that the electrical resistance value fluctuates,
The body part comprises a second module control part which constitutes the control part, and is connected to the contact part to measure an electrical resistance value of the pressurized part, and then displays the measured pressure of the gas to the display part.
Gas leak monitoring system.
The method of claim 5,
The display unit includes a command input unit disposed outside the valve body pipe to receive a preset command from an administrator,
The command input unit includes a power supply unit and an instruction application unit receiving a command for setting whether to set a reference gas pressure or an alarm from an administrator,
The second module control unit is configured to compare the measured gas pressure and the reference gas pressure, and when the measured gas pressure is less than the reference pressure, display it on the display unit or to alarm through the alarm unit.
Gas leak monitoring system. The method according to any one of claims 1 to 6,
A third monitoring sensor module provided in the gas supply line and configured to detect a pressure change in the gas supply line as a pressure-temperature factor,
The third monitoring sensor module includes a housing having a coupling port coupled to the gas supply line, a pressure sensor configured on one side of the housing to detect pressure in the gas supply line, and configured on the other side of the housing And a temperature sensor for detecting the temperature of the gas supply line, and a transmitter for transmitting signals detected by the pressure sensor and the temperature sensor to the control unit.
Gas leak monitoring system.
The method of claim 7,
The third monitoring sensor module is configured at a plurality of locations along the gas supply line, and is configured with a sensor ID. When transmitting a signal detected by each sensor, the transmitting unit provides sensor ID information together with the control unit. 3 transferred to the module control unit,
The third module control unit is configured to receive a signal from the third monitoring sensor module and compare it with a preset value to determine whether gas is leaking and display it on the display unit, or to alarm through the alarm unit,
The third module control unit is configured with the alarm unit and the display unit in at least one control panel of a work site and a remote central management unit.
Gas leak monitoring system.

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