WO2021261661A1 - Self-power generating system monitoring opening/closing of gas valve in wireless and remote manner - Google Patents

Abstract

The present invention relates to a self-power generating system monitoring opening/closing of a gas valve in a wireless and remote manner, which performs self-power generation in accordance with opening and closing operations of the gas valve so as to immediately monitor the opening and closing states of the gas valve in a wireless manner, thereby improving safety by means of a rapid response. The system comprises: a self-power generating gas valve opening and closing detector which is capable of self-power generation, and which is connected to a gas pipe and is operated through self-power generation in accordance with the opening and closing of the gas valve; a receiving unit which receives the opening and closing states of the gas valve in accordance with the operation of the self-power generating gas valve opening and closing detector through wireless communication and monitors the states; and an application unit which enables real-time notification of a signal transferred through the receiving unit. The self-power generating gas valve opening and closing detector comprises: a body holder unit connected to the gas pipe; a body unit connected to a valve lever on the top of the body holder unit; a valve opening and closing unit which is connected to the body holder unit through the body unit so as to allow the gas pipe to be opened and closed by means of rotation; a rotator mounted in the body unit and operating in accordance with the opening and closing operations of the valve opening and closing unit; and a dustproof/waterproof self-power generating detection unit mounted in the body unit and performing self-power generation in accordance with the rotation of the rotator.

Description

Self-powered gas valve wireless remote open/close monitoring system

The present invention relates to a wireless remote open/close monitoring system for a self-powered gas valve, and more particularly, to generate self-generation according to the opening/closing operation of the gas valve to wirelessly monitor the opening/closing state of the gas valve immediately, thereby improving safety through rapid response. It relates to a wireless remote open/close monitoring system for self-powered gas valves.

SF6 Gas is used by filling the inside of GIS (Gas Insulator Switchgear) operating in the power system due to its excellent insulation performance and excellent extinguishing ability when the circuit breaker operates.

GIS is a core device that receives power from substations and connects the grid as well as supplies power converted to an appropriate voltage through a large transformer.

Due to the nature of the substation’s power supply, only a part of the facility (the device) needs to cease operation, and the sulfur hexafluoride gas (SF6 Gas) that is being filled inside the device is recovered by opening the valve of the device. It has the specificity of the work that needs to be done after work.

Generally, there are about 12 SF6 Gas valves per GIS unit. When recovering SF6 Gas, only the relevant valve should be opened to recover only the gas of the device. This is complicated, and the valve of the device is installed on the LCP (Local Control Panel) separately from the gas tank, and due to the misunderstanding of the valve for the truce device (work object) and the live line device, not only a large blackout failure but also a safety accident for workers occur. is currently doing.

Such accidents cause power supply disruption due to total power outage of substations and delay in recovery time, resulting in loss of electricity sales as well as disruption to the production activities of the national economy.

In addition, many valves such as gas insulated switchgear, ambient pressure, and air pressure are used for instantaneous inspection of substations. In addition, there have been many cases of gas leakage and equipment failure due to inaccurate detection of valve opening/closing status during instantaneous, but there is no countermeasure to date.

In addition, at the present time, a system that can operate and check the opening and closing of valves electronically, such as a limit connected by wiring, is being developed. It is necessary to minimize the application of the system, and even if the application of the electronic system is possible, there is a problem in that it takes considerable time and cost to construct it.

Accordingly, the present invention has been devised to solve the above problems, and its purpose is to connect a self-powered gas valve opening/closing sensor capable of self-generation to the gas valve to generate self-generation according to the opening/closing operation of the gas valve to transmit a signal to the wireless receiver. We provide a wireless remote open/close monitoring system for self-powered gas valves that monitors the opening and closing status of gas valves and notifies them immediately to prevent malfunctions of gas valves in advance and to respond quickly to maximize productivity and work efficiency. is in

A self-powered gas valve wireless remote open/close monitoring system according to an embodiment of the present invention for achieving the above object is connected to a gas pipe to open and close a self-powered gas valve capable of self-generation operated through self-generation according to the opening and closing of the gas valve It may include a detector, a receiver for receiving and monitoring the opening/closing status of the gas valve through wireless communication according to the operation of the self-generated gas valve opening/closing detector, and an application unit for notifying the signal transmitted through the receiver in real time. .

The self-generated gas valve opening/closing sensor includes a body holder connected to a gas pipe, a body connected to a valve lever on an upper portion of the body holder, and a body holder connected to the body through the body to rotate the gas pipe. A valve opening/closing unit for opening and closing, a rotator installed inside the body unit and operated according to the opening/closing operation of the valve opening/closing unit; It may include a sensing unit.

The body holder part may include a base lever connected to a gas pipe, and a body holder provided outside the base lever.

The body portion is provided on the upper portion of the body holder portion to allow the installation of the dustproof/waterproof self-generation detection unit and the rotator, and the cover is connected to the upper portion of the body to seal the inside of the body and has an insertion groove for connecting the valve opening and closing portion. may include

The valve opening and closing part may include a valve shaft inserted through the body part and connected to the body holder part, and a valve lever coupled to the upper part of the valve shaft to rotate the valve shaft to open and close the gas pipe.

A bearing is fixed to the outside of the valve shaft by an E-ring, and a sliding holder that is connected to the rotator and rotates the rotator while moving up and down according to the operation of the valve lever may be attached to the outside of the bearing.

The rotator is connected to the inside of the body by a hinge and rotates around the hinge according to the operation of the valve opening and closing part, one side is in contact with the valve opening and closing part, and the other side can be in contact with the dustproof/waterproof self-generation sensor.

The lower portion of the rotator is in contact with the upper portion of the operation member of the dustproof/waterproof self-generation detection unit, and a concave groove may be formed to limit the operation of the operation member when the rotator is rotated according to the operation of the valve opening and closing portion so that it can be operated smoothly. .

The rotator may have a plurality of left and right hinge connection grooves to which a hinge is connected so that the rotator can be extended and applied to various types of valves according to a stroke moving up and down of the valve opening and closing part.

The dustproof/waterproof self-generation detection unit includes a bottom member provided on the inner bottom of the body, a first dustproof member provided on the bottom member to prevent moisture or dust from penetrating through the floor member, and the first dustproof A self-generation module that is provided on the upper part of the member for self-generation, a transmission module that is provided on the top of the self-generation module and sends a wireless signal to the receiver for output generated from the self-generation module, and is provided on the first anti-vibration member A housing enclosing the self-power generation module and the transmission module, an operation member passing through the housing and positioned in the self-generation module to control the operation of the self-generation module according to the pressing operation of the rotator, is provided between the housing and the operation member It may include a second anti-vibration member that elastically supports the operation member and seals the inside of the housing so that moisture or dust does not penetrate.

A convex surface may be formed around the upper periphery of the first anti-vibration member, and a concave surface may be formed around the lower end of the housing so that the convex surface is in close contact with the first anti-vibration member to increase sealing efficiency inside the housing.

The second anti-vibration member is closely attached to the outer surface of the operating member on the upper portion and provided with a contact portion to increase sealing efficiency inside the housing without falling out from the operation member, and the housing is fitted with a fitting groove formed in the upper portion at the lower portion and fixed with a fixing ring A fitting part may be provided so that it can be.

The operation member may be provided with a contact portion for controlling the operation of the self-generation module according to the operation of the rotator in a state in which the upper end of the operation member is formed in a curved shape and is in contact with the rotator, and is supported by the pressing protrusion of the self-generation module at the lower portion.

As described above, according to the wireless remote open/close monitoring system for a self-powered gas valve according to the present invention, the body part is installed between the gas pipe and the valve opening/closing part so as to detect the opening/closing status of the gas valve in the gas pipe, and the body part is self-contained inside the body part. By installing a self-generated gas valve opening/closing detector that can generate electricity and has excellent dust and water resistance, the opening and closing status of the gas valve can be immediately detected, transmitted, and monitored, so that a safety accident can be prevented with a quick response. And waterproofing efficiency can be increased, so installation is easy, and by blocking the inflow of dust and water, it is possible to maximize the convenience of work and the performance of the product.

1 is a block diagram illustrating a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention.

2 is a perspective view illustrating a self-generation gas valve opening/closing sensor of a wireless remote opening and closing monitoring system for a self-generation gas valve according to the present invention.

3 is a front view showing a self-generated gas valve opening/closing sensor of a wireless remote open/closed monitoring system for a self-powered gas valve according to the present invention.

4 is an exploded perspective view illustrating a self-generation gas valve opening/closing sensor of a wireless remote opening and closing monitoring system for a self-generation gas valve according to the present invention.

5 is a cross-sectional view illustrating a self-generation gas valve opening/closing sensor of a wireless remote opening and closing monitoring system for a self-powered gas valve according to the present invention.

6 is a cross-sectional view showing an example of a self-powered gas valve wireless remote open/close monitoring system according to the present invention.

7 is a cross-sectional view showing another example of a self-powered gas valve wireless remote open/close monitoring system according to the present invention.

8 is a perspective view illustrating a dustproof/waterproof self-generation detection unit of a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention.

9 is a front view illustrating a dustproof/waterproof self-generation detection unit of a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention.

10 is an exploded perspective view illustrating a dustproof/waterproof self-generation detection unit of a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention.

11 is a cross-sectional view illustrating a dustproof/waterproof self-generation detection unit of a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention.

<Explanation of symbols for main parts of the drawing>

1: gas pipe 10: self-generated gas valve opening/closing detector

20: receiving unit 30: application unit

100: body holder 110: base lever

120: body holder 200: body part

210: body 220: cover

221: insertion groove 300: valve opening and closing part

310: valve shaft 320: valve lever

330: bearing 340: E-ring

350: sliding holder 400: rotator

410: concave groove 420: hinge connection groove

500: dustproof / waterproof self-generation detection unit 510: floor member

511: bulkhead 520: first anti-vibration member

521: convex surface 530: self-generation module

531: pusher 540: transmission module

550: housing 551: through hole

552: concave surface 553: fitting groove

560: operation member 561: contact part

570: second anti-vibration member 571: close contact

572: fitting portion 580: fixing ring

h: hinge

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

In the drawings, embodiments of the present invention are not limited to the specific form shown and are exaggerated for clarity. Although specific terms have been used herein, they are used for the purpose of describing the present invention, and are not used to limit the meaning or scope of the present invention described in the claims.

In the present specification, the expression 'and/or' is used to mean including at least one of the elements listed before and after. In addition, the expression 'connected/coupled' is used in a sense including being directly connected to another element or indirectly connected through another element. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. Also, as used herein, a component, step, operation, and element referred to as 'comprises' or 'comprising' refers to the presence or addition of one or more other components, steps, operation and element.

In addition, expressions such as 'first, second', etc. are used only for the purpose of distinguishing a plurality of components, and do not limit the order or other characteristics between the components.

In the description of the embodiments, each layer (film), region, pattern or structure is “on” or “under/under” the substrate, each side (film), region, pad or patterns. The description of "formed on" includes all those formed directly or through another layer. The standards for the upper/above or lower/lower layers of each layer will be described with reference to the drawings.

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

1 is a block diagram illustrating a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention, and FIG. 2 is a perspective view illustrating a self-generated gas valve open/close sensor of the wireless remote open/close monitoring system for a self-powered gas valve according to the present invention. 3 is a front view showing a self-generated gas valve opening/closing sensor of the self-powered gas valve wireless remote opening/closing monitoring system according to the present invention, and FIG. It is an exploded perspective view showing a gas valve opening/closing detector, and FIG. 5 is a cross-sectional view showing a self-powered gas valve opening/closing sensor of a wireless remote opening/closing monitoring system for a self-powered gas valve according to the present invention, and FIG. 6 is a self-generation according to the present invention. A cross-sectional view showing an example of a gas valve wireless remote open/close monitoring system, FIG. 7 is a cross-sectional view showing another example of a self-powered gas valve wireless remote open/close monitoring system according to the present invention, and FIG. A perspective view showing a dustproof/waterproof self-generation detection unit of a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention, and FIG. It is a front view, and FIG. 10 is an exploded perspective view showing a dustproof/waterproof type self-generation detection unit of a wireless remote open/close monitoring system for a self-powered gas valve according to the present invention, and FIG. 11 is a wireless remote open/close monitoring of a self-powered gas valve according to the present invention. It is a cross-sectional view showing the dustproof/waterproof self-generation detection unit of the system.

1 to 11, the self-powered gas valve wireless remote open/close monitoring system according to the present invention includes a self-powered gas valve open/close detector 10, a receiver 20, and an application unit 30 do.

The self-generated gas valve opening/closing detector 10 is connected to the gas pipe 1 and is operated through self-generation according to the opening and closing of the gas valve to detect whether the gas valve is opened or closed.

In addition, the self-generation gas valve opening/closing sensor 10 is capable of self-generation, so wiring is not required, so it can be easily connected to the gas pipe 1, and it is easy to attach and detach, so that replacement is convenient.

In addition, the self-generated gas valve opening/closing detector 10 may up-convert a radio frequency (RF) signal to wirelessly communicate with the receiver 20 .

2 to 5, the self-generated gas valve opening/closing sensor 10 has a body holder part 100, a body part 200, a valve opening/closing part 300, a rotator 400 and a dustproof / It may include a waterproof self-generation sensor 500 .

The body holder unit 100 includes a base lever 110 connected to the upper portion of the gas pipe 1 and a body holder 120 provided outside the base lever 110 to surround the base lever 110 . may include

The body part 200 may be connected to the upper part of the body holder part 100 to connect the valve opening/closing part 300 .

The body part 200 is provided on the upper part of the body holder part 100 to install the dustproof/waterproof self-generation detection part 500 and the rotator 400 , and the body 210 of the body 210 . It may include a cover 220 connected to the upper portion to seal the inside of the body 210 and connect the valve opening and closing unit 300 .

The body 210 may be bolted to an upper portion of the body holder 120 .

An insertion groove 221 may be formed in the upper portion of the cover 220 to connect the valve opening and closing unit 300 .

The valve opening/closing part 300 may pass through the body part 200 and be connected to the base lever 110 of the body holder part 100 to open and close the gas pipe 1 through rotation.

In addition, the valve opening and closing part 300 is inserted into the insertion groove 221 of the cover 220 and coupled to the valve shaft 310 connected to the base lever 110 and the upper part of the valve shaft 310 to provide a gas pipe. (1) may include a valve lever 320 for rotating the valve shaft 310 to open and close.

As shown in FIG. 6 , a bearing 330 is fixed to the outside of the valve shaft 310 by an E-ring 340 , and is connected to the rotator 400 on the outside of the bearing 330 and the valve lever 320 . A sliding holder 350 capable of rotating the rotator 400 may be attached while moving up and down according to the operation.

That is, the bearing 330 is fixed in the middle of the valve shaft 310 with an E-ring 340 to hold the rotation of the valve shaft 310 , and the sliding holder 350 attached to the bearing 330 is the valve lever. By the operation of 320, it is moved up and down to rotate the rotator 400 at a predetermined angle to operate the dustproof/waterproof self-generation sensor 500 .

The rotator 400 is installed inside the body part 200 and is operated according to the operation of the valve opening and closing part 300 to operate the dustproof/waterproof self-generation sensor 500 .

In addition, the rotator 400 is connected to the inside of the body part 200 by a hinge (h) and rotates about the hinge (h) according to the operation of the valve opening and closing part 300, and one side of the valve opening and closing part 300 and The other side may be in contact with the dustproof/waterproof self-generation sensor 500 .

That is, when the valve opening and closing part 300 is operated, the rotator 400 in contact with the valve shaft 310 is rotated about the hinge h, and the rotator 400 comes into contact with the rotator 400 according to the rotation of the rotator 400 . The dustproof/waterproof self-generation detection unit 500 that is used may be operated.

In addition, the upper portion of the operation member 560 of the dustproof/waterproof self-generation detection unit 500 described below is in contact with the lower portion of the rotator 400 , and the rotator 400 rotates according to the operation of the valve opening and closing unit 300 . The concave groove 410 may be formed to limit the operation of the operation member 560 when it becomes available so that it can be operated smoothly.

At the same time, as shown in FIG. 7 , the rotator 400 has a hinge connection groove 420 to which the hinge h is connected so that it can be extended and applied to various types of valves according to the stroke moving up and down of the valve opening and closing part 300 . may be formed into a plurality of left and right sides.

That is, as an example, it is applicable to a valve having a valve stroke of 2 mm or less as in FIG. It is possible to sufficiently operate the self-generation detection unit 500 to generate a self-generation output.

In addition, it is applicable to a valve having a valve stroke of 2 mm as shown in FIG. The unit 500 can be sufficiently operated to generate self-generation output.

And, as shown in (c) of FIG. 7, it is applicable to a valve having a valve stroke of 2 mm or more, and when the valve moves to 2 mm or more, the self-generation pressing part of the rotator 400 moves at the same rate, so that the dust-proof / waterproof self It is possible to sufficiently operate the power generation detection unit 500 to generate a self-generated output.

The dustproof/waterproof self-generation detection unit 500 is installed inside the body unit 200 and transmits a wireless communication signal to the receiving unit 20 while self-generating according to the rotational operation of the rotator 400 .

8 to 11 , the vibration/waterproof self-generation detection unit 500 includes a floor member 510 , a first vibration-proof member 520 , a self-generation module 530 , and a transmission module 540 . ), a housing 550 , an operation member 560 , and a second anti-vibration member 570 .

The bottom member 510 is provided on the inner bottom of the body 210 of the body 200, and a partition wall 511 may be formed vertically around the outer rim.

The first anti-vibration member 520 is provided on the bottom member 510 , and may prevent penetration of moisture or dust through the bottom member 510 .

In addition, a convex surface 521 may be formed on the upper periphery of the first anti-vibration member 520 .

The first anti-vibration member 520 may be made of a rubber material.

The self-generation module 530 is provided on the first anti-vibration member 520 to convert mechanical displacement into electric power and self-power generation is possible.

In addition, the self-generation module 530 is made in a way that generates an induced current by the movement of a magnet and a coil according to Faraday's law to generate self-generation, and since this method is already widely used and used, the technical configuration and operation of this method The principle is omitted.

The transmission module 540 is electrically connected to the self-generation module 530 on the upper portion of the self-generation module 530 , and receives the output generated from the self-generation module 530 to transmit a wireless signal to the receiver 20 . .

The housing 550 may be seated on the upper portion of the first anti-vibration member 520 to enclose the self-generation module 530 and the transmission module 540 and seal the inside.

A through hole 551 may be formed in the upper portion of the housing 550 so that the operation member 560 may be fitted thereinto.

In addition, the convex surface 521 of the first anti-vibration member 520 is fitted in the lower portion of the housing 550 to increase the sealing efficiency inside the housing 550 so that a concave surface 552 may be formed concavely inward. have.

In this case, the concave surface 552 may be formed on the entire lower circumference of the housing 550 .

That is, the convex surface 521 of the first anti-vibration member 520 is fitted in close contact with the concave surface 552 to increase the sealing efficiency of the first anti-vibration member 520 and the housing 550 inside the housing 550 ) The inside is tightly sealed to prevent the inflow of moisture or foreign substances as much as possible.

In addition, a fitting groove 553 may be formed in the upper outer surface of the housing 550 in which the through hole 551 is formed so that the second anti-vibration member 570 can be fitted therein.

The operation member 560 passes through the through hole 551 of the housing 550 and is positioned on the pressing protrusion 531 of the self-power generation module 530 and operates according to the pressing operation of the rotator 400 to operate the self-power generation module 530 . ) can be controlled.

In addition, the operating member 560 is formed in a curved shape at the upper portion to make line contact with the concave groove 410 of the rotator 400 to minimize resistance when the rotator 400 operates.

In addition, the lower portion of the operation member 560 is a contact portion to control the operation of the self-generation module 530 according to the operation of the rotator 400 in a state that supports the pressing protrusion 531 of the self-generation module 530 . 561 may be provided.

The second anti-vibration member 570 is provided on the outside of the operation member 560 in close contact with the housing 550 to elastically support the operation member 560 and block the through hole 551 of the housing 550 to prevent the housing 550 . (550) can be tightly sealed inside.

The second anti-vibration member 570 is made in the form of a bellows in the shape of a flying saucer, and is in close contact with the outer surface of the operation member 560 on the upper portion to prevent it from falling out from the operation member 560 to improve the sealing efficiency of the inside of the housing 550 . A contact portion 571 may be provided to increase the height.

In addition, a fitting portion 572 may be provided at a lower portion of the second anti-vibration member 570 to prevent separation by being fitted into a fitting groove 553 formed on the upper portion of the housing 550 .

In addition, a fixing ring 580 may be fitted to the outside of the fitting portion 572 to fix the second anti-vibration member 570 fitted in the fitting groove 553 .

The second anti-vibration member 570 may be made of a rubber material.

The receiver 20 receives and monitors the opening/closing status of the gas valve by wireless communication from the transmission module 540 according to the operation of the self-generated gas valve opening/closing detector 10 .

That is, the receiver 20 receives the detection signal of the self-generated gas valve opening/closing detector 10 as a radio frequency (RF) signal and transmits the received signal to the application unit 30 .

In addition, the receiver 20 displays the location number of the area where the fire occurred on the monitor when the self-generation gas valve open/close detector 10 operates, and utilizes a communication module (eg, 485 communication or RF communication relay module) to A signal is sent to the application unit 30 .

The application unit 30 informs the fire occurrence reception signal through the reception unit 20 in real time.

In addition, the application unit 30 receives the signal from the receiver 20 to notify the occurrence of a fire by using a speaker and a warning light, and is connected to the server to check the registered signal to quickly replace the fire situation.

In addition, the wireless signal of the self-generation gas valve opening/closing sensor 10 is the self-generation module when the pressing protrusion 531 attached to the self-generation module 530 operates at a certain angle according to the pressing operation of the operation member 560 . At 530, self-generation is generated and power is supplied to the transmission module 540 to wirelessly transmit an RF signal.

In addition, the registration of the self-generation gas valve opening/closing detector 10 rotates the valve lever 320 to open and close the gas valve, the self-generation module 530 operates and sends a wireless signal to the receiver 20, respectively. of self-generated gas valve opening/closing detector 10 is registered.

On the other hand, as an embodiment of the self-generated gas valve wireless remote open/close monitoring system according to the present invention as shown in FIG. 1 , first, when the self-powered gas valve open/close detector 10 operates, the opening/closing status of the gas valve in the monitor of the receiver 20 It is a system that can display and notify when a problem occurs by using the speaker and warning light of the application unit 30 .

Second, when the self-generated gas valve open/close detector 10 operates, the monitor of the receiver 20 displays the open/close status of the gas valve and at the same time utilizes 485 communication to connect to the server and mobile phone app of the application unit 30, gas It is a system that can manage the valve opening/closing status by extending it to a server and mobile phone app.

Third, when the self-generated gas valve opening/closing detector 10 operates, the RF communication relay module of the receiving unit 20 receives the signal and transmits it to the server of the application unit 30, and the server checks the received signal to transmit the mobile phone app, etc. gas valve It is a system that quickly transmits the opening/closing status.

Looking at the operating state according to the wireless remote open/close monitoring system of the self-powered gas valve of the present invention consisting of the system as described above, the following is trapped.

In a state in which the valve opening and closing part 300 is disassembled on the upper part of the gas pipe (1), the self-generation gas valve opening/closing sensor 10 is aligned with the base lever 110, and then fixed with the body holder 120 and again the valve opening and closing part 300 ), the self-generated gas valve opening/closing sensor 10 can be easily assembled and disassembled without additional construction, making the installation work convenient.

And, since the self-generated gas valve opening/closing detector 10 is installed, it is possible to wirelessly immediately monitor and quickly respond to the fact that it was previously impossible to check whether the gas valve is opened or closed with the naked eye or a monitor.

When the valve lever 320 is rotated, the valve shaft 310 moves or rotates up and down, and according to the operation of the valve shaft 310 , the rotator 400 rotates at a predetermined angle with respect to the hinge h. It moves, and presses the operation member 560 of the dustproof/waterproof self-generation detection unit 500 that is in contact with the lower right side of the rotator 400 .

At the same time, as the operation member 560 is pressed, the pressing protrusion 531 in contact with the operation member 560 operates at a predetermined angle to generate instantaneous self-generation in the self-generation module 530 and transmit. Power is supplied to the module 540 and an RF signal is transmitted to the receiver 20 in a short time.

Accordingly, according to the operation of the self-generated gas valve opening/closing detector 10, the opening/closing status of the gas valve is immediately sensed, and a signal is sent to the receiver 20, and the opening/closing status of a large number of gas valves is performed through the application unit 30. can be seen with the naked eye.

And, by supplying power to the self-generation gas valve opening/closing sensor 10 by embedding a self-generation module 530 capable of self-generation inside the dust-proof/waterproof self-generation detection unit 500 , it is semi-permanent without a separate wired connection. can be used as

In addition, the housing 550 is seated on the upper portion of the first anti-vibration member 520 in which the self-generation module 530 and the transmission module 540 are embedded, and the operation member 560 inserted into the housing 550 is removed. By being wrapped with two anti-vibration members 570, the inside of the housing 550 is tightly sealed to prevent dust or water from flowing into the housing 550 from the outside, so that the self-power generation module 530 and the transmission module 540 ) to prevent failure.

In addition, when the housing 550 is seated on the upper portion of the first vibration-proof member 520 , the convex surface 521 of the first vibration-proof member 520 is firmly on the concave surface 552 of the housing 550 . The sealing efficiency inside the housing 550 may be maximized by being in close contact with the housing 550 .

In addition, the second anti-vibration member 570 for sealing the through hole 551 while enclosing the operation member 560 fitted into the through hole 551 of the housing 550 is formed in a bellows type, thereby pressing the rotator 400 . When the operation member 560 presses the pressing protrusion 531 of the self-generation module 530 by operation, the entire second anti-vibration member 570 is not deformed, and only the portion in contact with the operation member 560 is deformed. Even when the air inside the housing 550 expands, it is possible to secure a space for the expanded air by the bellows type, so that the pressing operation of the operation member 560 is not limited, so that it operates smoothly without errors even in multiple operations. Durability and abrasion resistance can be improved.

Accordingly, the housing 550 in which the self-generation module 530 and the transmission module 540 are accommodated is tightly sealed with the first vibration-proof member 520 and the second vibration-proof member 570 made of rubber to form the housing 550 ) The performance of the product can be maximized because dust or water does not enter the inside.

In addition, since the inside of the dustproof/waterproof self-generation detection unit 500 can be maximally dustproofed and waterproofed, the self-generation gas valve opening/closing detector 100 can be mounted and used indoors and outdoors without distinction, thereby maximizing product efficiency. can do.

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person with ordinary skill in the art to which the invention pertains can variously Of course, modifications are possible, and such modifications are intended to be within the scope of the claims.

Claims (12)

1. a self-generation gas valve opening/closing sensor 10 connected to the gas pipe 1 and capable of self-generation operated through self-generation according to the opening and closing of the gas valve;

   a receiver 20 for receiving and monitoring the opening/closing status of the gas valve through wireless communication according to the operation of the self-generated gas valve opening/closing detector 10; and

   and an application unit 30 that notifies the signal transmitted through the receiving unit 20 in real time;

   The self-generated gas valve opening/closing detector 10,

   Body holder unit 110 connected to the gas pipe (1);

   a body part 200 connected to a valve lever 320 on an upper portion of the body holder part 110;

   a valve opening/closing unit 300 penetrating through the body unit 200 and connected to the body holder unit 100 to open and close the gas pipe 1 through rotation;

   a rotator 400 installed inside the body 200 and operated according to the opening and closing operation of the valve opening and closing part 300; and

   A self-powered gas valve wireless remote open/close monitoring system comprising a; a dustproof/waterproof type self-generation detection unit 500 that is installed inside the body 200 and is self-generated according to the rotational operation of the rotator 400 .
2. The method of claim 1,

   The body holder part 100,

   a base lever 110 connected to the gas pipe 1; and

   Self-powered gas valve wireless remote open/close monitoring system including; body holder 120 provided on the outside of the base lever 110
3. The method of claim 1,

   The body part 200,

   a body 210 provided on the body holder unit 100 so as to install the dustproof/waterproof self-generation detection unit 500 and the rotator 400; and

   Self-generation gas valve wireless remote open/close monitoring system including; a cover 220 connected to the upper portion of the body 210 to seal the inside of the body 210 and having an insertion groove 221 for connecting the valve opening and closing unit 300 .
4. The method of claim 1,

   The valve opening and closing unit 300,

   a valve shaft 310 inserted through the body 200 and connected to the body holder 100; and

   A self-powered gas valve wireless remote open/close monitoring system comprising a; a valve lever 320 coupled to the upper portion of the valve shaft 310 to rotate the valve shaft 310 to open and close the gas pipe 1 .
5. 5. The method of claim 4,

   A bearing 330 is fixed to the outside of the valve shaft 310 by an E-ring 340, and is connected to the rotator 400 on the outside of the bearing 330 so that the A self-powered gas valve wireless remote open/close monitoring system, characterized in that a sliding holder 350 capable of rotating the rotator 400 is attached while moving downward.
6. The method of claim 1,

   The rotator 400 is connected to the inside of the body part 200 by a hinge (h) and rotates around the hinge (h) according to the operation of the valve opening and closing part 300, and one side is in contact with the valve opening and closing part 300. The self-generation gas valve wireless remote open/close monitoring system, characterized in that the other side is in contact with the dust-proof/waterproof self-generation detection unit 500 .
7. The method of claim 1,

   The upper portion of the operation member 560 of the dustproof/waterproof self-generation detection unit 500 is in contact with the lower portion of the rotator 400 , and the operation member 560 when the rotator 400 is rotated according to the operation of the valve opening and closing unit 300 . ), a self-powered gas valve wireless remote open/close monitoring system, characterized in that the concave groove 410 is formed so that it can be operated smoothly by limiting the operation.
8. The method of claim 1,

   The rotator 400 has a plurality of hinge connection grooves 420 to which the hinges are connected, left and right, so that the rotator 400 can be extended and applied to various types of valves according to the upward and downward strokes of the valve opening and closing part 300. Self-generated gas valve wireless remote open/close monitoring system, characterized in that.
9. The method of claim 1,

   The dustproof / waterproof self-generation detection unit 500,

   a bottom member 510 provided on the inner bottom of the body 200;

   a first anti-vibration member 520 provided on the bottom member 510 to prevent moisture or dust from penetrating through the bottom member 510;

   a self-power generation module 530 provided on the first anti-vibration member 520 and capable of self-generation;

   a transmission module 540 provided on the self-generation module 530 and transmitting a wireless signal to the receiving unit 20 for output generated from the self-generation module 530 ;

   a housing 550 provided on the first anti-vibration member 520 to surround the self-power generation module 530 and the transmission module 540;

   an operation member 560 positioned in the self-generation module 530 through the housing 550 to control the operation of the self-generation module 530 according to the pressing operation of the rotator 400; and

   A second anti-vibration member 570 provided between the housing 550 and the operation member 560 to elastically support the operation member 560 and seal the inside of the housing 550 so that moisture or dust does not penetrate; Self-generated gas valve wireless remote open/close monitoring system including.
10. 10. The method of claim 9,

    A convex surface 521 is formed on the upper periphery of the first anti-vibration member 520 , and the convex surface 521 is in close contact with the lower periphery of the housing 550 to form the first anti-vibration member 520 and the housing 550 . A self-powered gas valve wireless remote open/close monitoring system, characterized in that a concave surface (552) is formed to increase the sealing efficiency of the interior.
11. 10. The method of claim 9,

    The second anti-vibration member 570 is closely attached to the outer surface of the operating member 560 on the upper portion, so that the sealing efficiency inside the housing 550 can be increased without falling out from the operating member 560, a contact portion 571 is provided. , A self-powered gas valve wireless remote open/close monitoring system, characterized in that the housing 550 is provided with a fitting portion 572 at the lower portion so that the housing 550 is fitted into the fitting groove 553 formed on the upper portion and fixed with the fixing ring 580.
12. 10. The method of claim 9,

    The operation member 560 is formed in a curved shape with an upper end in contact with the rotator 400 , and in a state where the pressing protrusion 531 of the self-generation module 530 is supported at the lower portion, according to the operation of the rotator 400 . A self-powered gas valve wireless remote open/close monitoring system, characterized in that a contact portion 561 for controlling the operation of the power generation module 530 is provided.

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