KR100721932B1 - Apparatus for closing the gas valve - Google Patents

Abstract

An intermediate valve safety lock is disclosed that automatically closes an intermediate valve installed on a gas supply path of a gas using device. In the intermediate valve safety lock device according to the present invention, the sensor unit for detecting the amount of gas flow flowing in the gas supply path, using the input signal for the amount of gas flow transmitted from the sensor unit whether or not to stop using the gas and careless neglect and gas And a control unit for controlling the intermediate valve to be locked by judging leakage or the like, and an operation unit for blocking the intermediate valve according to the control signal of the control unit. The gas flow detection unit is installed around the intermediate valve on the gas supply path, Ducts having different cross-sectional areas; And a sensor unit connected to the control unit to enable signal exchange and having at least two pressure ports to measure pressures of different cross-sectional areas in the duct. According to the present invention, it is possible to prevent safety accidents by automatically locking the intermediate valve after gas use, careless neglect, and gas leakage while ensuring user convenience.

Gas use device, intermediate valve, pressure sensor, duct, solenoid, gas use detection

Description

Intermediate valve safety lock {Apparatus for closing the gas valve}

1 is a perspective view of an intermediate valve safety lock according to an embodiment of the present invention,

2 is an exploded perspective view of FIG. 1;

Figure 3 is a block diagram of the main components of the intermediate valve automatic locking device according to an embodiment of the present invention,

4 is a cross-sectional view taken from IV-IV of a duct to which the sensor unit of FIG. 2 is connected;

5 is a flowchart for explaining an operation of the controller of FIG. 3;

6 is a rear perspective view of the operating lever of FIG. 2;

7 to 10 is a front view of the engaged state for explaining the operation of the operating unit of the present invention,

FIG. 11 is a plan view of FIG. 1.

<Description of Major Symbols in Drawing>

110. Intermediate valve 120. Duct

130. Sensor unit 131. First pressure port

132. Second pressure port 140. Control unit

160. Fixed part 170. Power supply

172. Battery 200. Actuator

210. Main Unit Frame 220. Operating Lever

221. Lever spring 230. Locking lever

240. Lock release 250. Push block

260. Solenoid 270. Manual release pin

The present invention relates to an intermediate valve safety lock device, and more particularly, to an intermediate valve safety lock device that automatically shuts off the intermediate valve to prevent danger or accident.

In general homes and businesses, gas cooking apparatuses such as gas ranges, gas ovens, and gas boilers, which use gas such as LPG or LNG, are often used for cooking or heating.

Such a gas using device is connected to a gas tank such as an outdoor gas storage container or a city gas corporation through a gas pipe, and gas is supplied. An intermediate valve is installed between the gas using device and the outdoor gas storage container or gas tank. When gas leaks from a gas service device or piping, there is a risk of explosion, etc., so the gas requires a great care in use, and the use of an intermediate valve is regulated to prevent the danger. The user can shut off or open the gas by operating the intermediate valve to prevent the risk in advance.

When cooking or heating using a gas using device, the user opens the intermediate valve to supply gas to the gas using device, and turns on the ignition device installed in the gas using device to ignite the gas. When the use of the gas using device is completed, the user turns off and extinguish the ignition device installed in the gas using device, and closes the intermediate valve to cut off gas supply. As such, the original safety function is properly achieved by opening and closing the intermediate valve whenever the user uses the gas-operating device.However, due to the hassle, the user always keeps the intermediate valve open and uses only the ignition device of the gas-operating device. Often use the device. In particular, there is a risk of safety accidents are often left for a long time without forgetting the gas using the device is turned on. In other words, current mechanical fuse cocks have inherent limitations and inconveniences that depend on the user as a safety device.

Therefore, in order to prevent such a risk, a device for automatically shutting off the intermediate valve has been developed. For example, by installing a motor, a cam, a cam gear, etc. around the operation knob of the intermediate valve, and attaching a timer, when the user sets the time by the timer, the intermediate valve is automatically closed after the set time has passed.

However, such a device is also inconvenient to operate a time with a timer for every use. If the timer is set too short for cooking, it is inconvenient to frequently extend the timer or reopen the intermediate valve during cooking, and if it is set too long, the fire prevention effect is lowered. Thus, there is a need for an ideal safety intermediate valve that is not inconvenient in use but can only allow the minimum possible waiting time in negligible standing.

The present invention has been made in view of the above, it proposes the following technical problem.

First, by eliminating the timer setting by the user before using the gas and reducing the user's extension of the timer as much as possible during the period of use, the intermediate valve safety allows the user to conveniently use the gas using device without being aware of the intermediate valve locking device. It is an object to provide a locking device.

Second, it is an object of the present invention to provide an intermediate valve safety lock device that faithfully performs the role of the natural intermediate valve by closing the intermediate valve within a few seconds to several tens of seconds after using the gas.

Third, an intermediate valve safety lock is provided to close the intermediate valve after a period of safety, so as to prevent inadvertent neglect during use, except when the user can enter it when long-term use of the gas is required. For the purpose of

Fourth, an object of the present invention is to provide an intermediate valve safety lock that can detect gas leakage and temperature in addition to the function of automatically closing the intermediate valve.

Fifth, it is an object of the present invention to provide an intermediate valve safety lock that allows the power to be used only when the intermediate valve is open, thereby extending the life of the battery as much as possible, and allowing the intermediate valve to be closed using a low current consumption solenoid.

The intermediate valve safety lock device according to the present invention for achieving the above object, in the intermediate valve safety lock device for automatically blocking the intermediate valve installed on the gas supply path of the gas using device, the gas flow flowing in the gas supply path Sensor unit for detecting the amount; A controller configured to determine a closing timing of the intermediate valve by using an input signal corresponding to an amount of gas flow transmitted from the sensor unit to generate a signal for locking the intermediate valve; And an operation part for locking the intermediate valve according to a control signal of the controller. The gas flow detection part includes: a duct installed around the intermediate valve on the gas supply path and having a different cross-sectional area therein; And a sensor unit connected to the control unit so as to exchange signals, the sensor unit having at least two pressure ports to measure pressures of different cross-sectional areas within the duct.

The sensor unit is installed around the intermediate valve on the gas supply path, the duct having a different cross-sectional area therein; And a pressure sensor connected to the controller so as to exchange signals and having at least two pressure ports to measure pressures of different cross-sectional areas inside the duct.

The control unit transmits a control signal to the operation unit that locks the intermediate valve by determining that the gas flow inside the duct is unchanged for a predetermined safety idle time t1, and inadvertently neglects when there is no response. do.

The safety leaving time t1 is preferably set differently according to the use power of the gas using apparatus.

The control unit may determine that the gas stops when gas stops flowing in the duct, and transmits a control signal to the operation unit to block the intermediate valve after the set waiting time t2 elapses. .

In addition, the control unit detects a gas leakage by comparing the first gas flow signal value immediately after the intermediate valve is opened with a preset reference value when no gas flows, and when the gas leakage is detected, the intermediate part together with a warning signal. It is preferable to transmit a control signal for closing the valve to the operation unit.

In addition, the control unit detects whether the connection with the sensor unit is normal, and if the connection is not normal it is preferable to transmit a control signal for locking the intermediate valve to the operating unit.

On the other hand, the intermediate valve safety lock device according to the present invention, further connected to the control unit and the control unit further includes a long-term use setting unit that can be operated by the user, the control unit is set when the long-term use setting is input by the user, It is preferable to transmit a control signal for locking the intermediate valve after the long service time t4 has elapsed.

The apparatus may further include a temperature detector configured to exchange signals with the controller and detect an ambient temperature, wherein the controller sends a warning signal when the temperature sensed by the temperature detector is higher than a set reference temperature. It is preferable to transmit a control signal for locking the valve to the operation unit.

On the other hand, the control unit according to the present invention is to send a control signal for locking the intermediate valve to the operation unit is good to issue a warning signal so that the user can know when the intermediate valve is not normally closed.

The operation unit may include an operation lever installed at a key of the intermediate valve to be rotatable in a first position at which the intermediate valve is closed and at a second position at an open position of the intermediate valve; A lever spring for elastically biasing the actuating lever to the first position; A locking lever installed between rotational radius of the operation lever to restrain the operation lever from moving from the second position to the first position; A locking release unit including a solenoid and releasing the locking lever to rotate the operating lever from the second position to the first position when receiving the closing signal of the control unit; And a body frame accommodating the operation lever, the lever spring, the locking lever, and the unlocking part and including a cover.

The locking release unit pushes the locking lever out of the rotation radius of the operating lever, a push block having a plunger groove into which the plunger of the solenoid is inserted; And a push spring elastically biasing the push block, wherein the plunger of the solenoid is inserted into the plunger groove to fix the push block before the signal of the control unit is applied, and the plunger groove when the signal of the control unit is applied. Exit the release of the push block.

Further, when the push lever moves from the second position to the first position by the push block pushing the locking lever, one end of the push lever pushes the push block in the opposite direction to push the locking lever. It is preferable to return to the initial position before the signal is applied by the control unit.

In addition, the operation unit may further include a manual release pin, one end of which is connected to the locking lever and the other end of which is exposed out of the cover of the main body frame to enable a user operation.

On the other hand, the intermediate valve safety lock device according to the present invention, the fixing part for fixing the main frame of the operation unit to the intermediate valve, and is connected to enable the signal exchange with the control unit, the control unit, the sensor unit and the operation unit It is preferable to further include a power supply for supplying.

The power supply unit may be detachably coupled to the detachable groove of the fixing unit and include a case having a degree of freedom of movement in only one direction and a battery inserted into the case.

The above objects, features and other advantages of the present invention will become more apparent by describing the preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4, the intermediate valve safety locking device 100 according to the present invention includes a gas flow detecting unit 101, a control unit 140, an operation unit 200, and a fixing unit 160. And a power supply unit 170.

The intermediate valve safety lock device 100 according to the present embodiment is installed on a gas supply path of a gas using device such as a gas range or a gas oven, and may be installed by removing a handle lever from an existing gas intermediate valve 110. . Although not shown, a rubber hose or the like that provides a gas path is connected to the lower end of the intermediate valve 110.

The gas flow detecting unit 101 includes a duct 120 and a sensor unit 130. Referring to FIG. 2, the duct 120 is installed on a gas supply path between the gas using device and the intermediate valve 110. However, the present invention is not limited thereto, and it is sufficient if the duct 120 is installed around the intermediate valve 110 on the gas supply path. According to this embodiment, the duct 120 is coupled to the lower end of the intermediate valve 110 by the connecting member 113, but the present invention is not limited to this, the duct 120 is the intermediate valve 110 and It is also possible to install integrally. In addition, the duct may have a structure for the pressure sensor or may have a structure for another flow sensor.

Referring to FIG. 4, according to the present embodiment, the inside of the pressure sensor duct 120 has an unequal cross-sectional area. The inside of the duct 120 has a throat portion 121 having the smallest cross-sectional area, an extension portion 122 having the widest cross-sectional area, and a reduction portion 123 connecting the throat portion 121 and the extension portion 122. ). If the cross-sectional area of the throat part 121 is too small, it affects the thermal power of the gas using apparatus. If the throat area 121 is too large, the pressure difference is insignificant. It is preferable to appropriately determine the cross-sectional area of

The sensor unit 130 of the example using the pressure sensor detects the gas flow by measuring the pressure of two places having different cross-sectional areas inside the duct 120. The sensor unit 130 is connected to the control unit 140 to enable signal exchange. According to the present embodiment, the sensor unit 130 uses a differential pressure sensor of a MEMS type having two pressure ports. The first pressure port 131 of the sensor 130 is connected to the throat portion 121, the second pressure port 132 is connected to the expansion portion 132, respectively, after measuring the pressure, the signal for the pressure difference The value is sent to the control unit 140. When the first and second pressure ports 131 and 132 are combined with the duct 120, the gas leakage is prevented by treating the gas so as not to leak, such as filling or molding the entire sensor with epoxy or an O-ring or rubber seal. It is good.

Since the throat portion 121, the expansion portion 122, and the reduction portion 123 in the duct 120 have different cross-sectional areas, the velocity of the gas passing through each of them is different even under the same gas supply pressure, and thus the throat portion. The pressures measured at each of the 121, the extended part 122, and the reduced part 123 are different from each other. As a result, when the gas flows inside the duct 120, a minute pressure difference is generated between the first pressure port 131 and the second pressure port 132. Since the pressure difference is linearly proportional to the amount of gas flow, a change signal of the gas flow can be transmitted to the controller. On the other hand, when the gas does not flow in the duct 120, a pressure difference does not occur between the first pressure port 131 and the second pressure port 132 regardless of the gas supply pressure.

The control unit 140 is connected to the sensor unit 130, the operation unit 200, the power supply unit 170, the temperature sensing unit 180 and the long-term use setting unit 190 to enable a signal exchange. The control unit 140 determines the closing timing of the intermediate valve 110 by determining whether to stop using gas, inadvertently neglecting or leaking gas, by using an input signal for the gas flow transmitted from the sensor unit 130. The valve 110 is controlled to lock. The controller 140 is installed inside the main frame 210 and is implemented in the form of a printed circuit board (PCB). When the intermediate valve 110 is opened, the control unit 140 receives power from the power supply unit 170 by a non-electrical switch such as a reed switch and starts the control, and the control unit 140 starts the intermediate valve from this time. As the 110 is closed, the gas flow is periodically monitored until the supply of power is stopped. When the operation unit 200 is operated to close the intermediate valve 110, the switch is turned off, and the power supplied to the controller 140 is cut off so that battery consumption of the power supply unit 170 is not generated.

An operation of the controller 140 will be described in detail with reference to FIG. 5.

First, when the intermediate valve 110 is switched on by being opened by the user and is supplied with power, the controller 140 detects that the gas leaks from the gas using device or the lower end of the intermediate valve 110. Immediately after the intermediate valve 110 is opened, it is normal that the gas using device is not yet in an ignition state and therefore no gas flows. However, when the gas leaks, the gas flows even if the gas using device is not in an ignition state, and thus the sensor unit 130 detects the gas flow. That is, the controller 140 compares the signal value of the initial gas flow of the sensor unit 130 which is first detected immediately after the intermediate valve 110 is opened with a preset reference value (signal value sent by the sensor unit when no gas flows). To determine whether the gas leaks. That is, since the signal value sent by the sensor unit 130 when the gas does not leak is the same as the reference value, the control unit 140 determines that the gas is not counted, and the signal sent by the sensor unit 130 when the gas leaks. Since the value is different from the reference value, it is determined that the gas is leaking. If it is determined that the gas leaks, the control unit 140 issues a warning signal so that the user knows it, and controls the intermediate valve 110 to be closed.

In addition, the control unit 140 determines that the gas stops when the gas stops, that is, when the waiting time t2 is set to the state in which there is no pressure difference measured in the sensor unit 130, so that the intermediate valve 110 is closed. To control. That is, when the gas stops flowing, the control unit 140 does not immediately close the intermediate valve 110 and transmits a signal for closing the intermediate valve 110 only after the set waiting time t2 has elapsed. Preferably, the waiting time t2 is set to approximately 10 seconds to 30 seconds. When the user re-ignites within the waiting time t2 after extinguishing the gas using apparatus, the user may immediately ignite without opening the intermediate valve 110, thereby improving user convenience. In addition, by reducing the number of closing of the intermediate valve 110, the power consumption of the operating unit 200 is lowered, thereby improving the battery life of the power supply unit 170.

On the other hand, when maintained for a set safe idle time (t1) without changing the gas flow, the control unit 140 first sends a user warning signal such as a warning sound or LED (151, Fig. 2) for a while. During this warning period t3, if there is no gas change response by the user, the control unit 140 determines that it is inadvertently left and sends a signal to lock the intermediate valve 110. The warning period is preferably set to about several tens of seconds.

If the user changes the gas flow (for example, when controlling a fire or igniting another heating device) during the safety leaving time t1 and the warning period t3, the control unit 140 is an intermediate valve. It does not send a signal to lock (110). The controller 140 determines that the gas is in use at every instant of change when there is a response of the gas flow change, and resets the start reference time point of the safety leaving time t1 with the unchanged flow time as "0".

In this way, even if the user forgets to ignite and accidentally leaves the seat for a long time, the intermediate valve 110 is closed after the safety leaving time t1 has elapsed, and the gas is safely shut off, and the user continues to operate the gas using device. In this case, the gas flow change is detected and the intermediate valve 110 is kept open.

The safe leaving time t1 means the maximum leaving time without fear of a fire accident, and a short time as much as possible to prevent a risk is preferable. However, if it is too short, it may cause inconvenience that the user frequently responds to the user warning signal to check whether the neglect is neglected. On the contrary, if it is too long, the effect on fire prevention is lost. Therefore, it is appropriate to set the safety leaving time t1 to approximately 10 to 30 minutes.

The stable standing time t1 is preferably set differently according to the use power of the gas using apparatus. The greater the thermal power of a gas-operated device, the shorter the time. The weaker the thermal power, the longer the time. For example, in the case of a gas range, the safety leaving time (t1) is about 20-30 minutes in the case of single-stage use, about 15 minutes in the case of two-stage use, three or more stages, or two or more craters of the gas range. In this case, it is recommended to set it in about 10 minutes. As described above, since the sensor unit 130 transmits a signal differently according to the amount of gas flowing in the duct 120, the controller 140 may determine the thermal power used, and the automatic valve according to the thermal power used. The closing time of the 110 is determined.

On the other hand, there is a need for the user to use the gas use device for a long time there is a case where the user intentionally to leave the gas use for 2 to 3 hours. In this case, when the safety leaving time (t1) has passed after the intermediate valve 110 is automatically closed, the user may experience the inconvenience of opening the intermediate valve 110 again. In order to solve this problem, the intermediate valve safety locking device according to the present invention preferably includes a long-term use setting unit 190. According to the present embodiment, the long life setting unit 190 is implemented as a button type. 2 and 3, the long-term use setting unit 190 has one end protruding out of the cover 211 to allow user manipulation, and the other end of the long-term setting unit 190 to exchange signals with the controller 140 implemented as a PCB. Connected. Therefore, when the user operates the long-term use setting unit 190 to set the long-term use, the control unit 140 does not close the intermediate valve 110 until the set long-term use time t4 has elapsed. Only after the intermediate valve 110 is controlled to close. On the other hand, when the intermediate valve 110 is closed, the long-term use function is released, and when the intermediate valve 110 is opened again, it is preferable to return to the original safety idle time t1 method.

On the other hand, the intermediate valve safety lock device according to the present invention, the control unit 140 is connected to enable a signal exchange and includes a temperature sensing unit 180 for sensing the ambient temperature. According to this embodiment, the temperature sensing unit 180 is preferably installed directly in the control unit 140. In general, the temperature sensor 180 is a temperature sensor such as a thermistor. If the temperature detected by the temperature sensing unit 180 is greater than the set reference temperature, the controller 140 controls to close the intermediate valve 110 after the warning signal is issued. As such, the intermediate valve safety lock according to the present invention also functions as a fire alarm and a breaker.

The control unit 140 detects whether the connection between the control unit 140 and the sensor unit 130 is normal by using a method of checking whether the signal of the sensor unit 130 is above or below the normal output range. If it is determined that the controller 140 is not connected to the sensor unit 130, the controller 140 issues a warning signal so that the user knows this and controls to close the intermediate valve 110.

In addition, the control unit 140 also detects whether the closing of the intermediate valve 110 by the operation unit 200 is normal. That is, the control unit 140 transmits a control signal for locking the intermediate valve 110 to the operating unit 200 to automatically generate a warning signal. As described above, when the intermediate valve 110 is normally closed, the switch is turned off and the power is cut off, so that no warning signal is generated. However, when the intermediate valve 110 is not normally closed, the warning signal is generated and the user can take appropriate measures.

In addition, the controller 140 monitors the battery voltage of the power supply unit 170 to determine the life of the battery 172. The controller 140 determines that the battery life is near the end of the set value when the battery voltage is less than the set value, and issues a warning signal for the user to replace.

Referring back to FIG. 2, the operation unit 200 cuts off the intermediate valve 110 according to the signal of the operation unit control unit 142. The operation unit 200 includes a main body frame 210, an operation lever 220, a lever spring 221, a locking lever 230, and a unlocking unit 240.

The main frame 210 is installed to support the components of the operation unit 200, and the cover 211 is coupled to the front of the main frame 210 by screws or the like. Passing holes 212 and 213 through which the lower end and the upper end of the operation lever 220 pass are formed in the body frame 210 and the cover 211, respectively.

2 and 6, the operation lever 220 is fitted to the key 111 of the intermediate valve 110, the intermediate valve 110 is opened and closed by the operation of the operating lever 220. Therefore, the operation lever 220 is operated to rotate as shown by arrow C in the first position (A, FIG. 7), which is the position at which the intermediate valve 110 is closed, and the second position (B, FIG. 8), which is the open position. do. The operation lever 220 includes a center spring receiving portion 223, a rotary knob 222 formed on the upper surface, and a cylindrical fixing portion 224 formed on the lower surface. Rotating knob 222 is exposed to the outside through the through hole 213 of the cover 211, the user can be manipulated, the fixing portion 224 through the through hole 212 of the body frame 210 through the intermediate valve ( It fits into the key 111 of 110. In the center of the fixing part 224, a fitting groove 225 for fitting to the key 111 of the intermediate valve 110 is formed. Some sections of the fixing part 224 are tapered so that the operation lever 220 does not interfere with the push block 250 during rotation. Constraints 224a are formed at the ends of the fixing portion 224.

The lever spring 221 is inserted into the spring receiving portion 223 of the operating lever 220 and is installed to be supported by the body frame 210. The lever spring 221 elastically biases the operation lever 220 to the first position (A, FIG. 7). Therefore, the intermediate valve 110 is always kept closed by the lever spring 221.

Locking lever 230 is installed between the rotation radius of the operating lever 220, so that the operating lever 220 does not move from the second position (B, Fig. 8) to the first position (A, Fig. 7). It plays a role. One end of the locking lever 230 is coupled to the lower end of the hinge shaft 231 to the main frame 210 and the other end 232 is a free end. A hinge spring 232 is installed on the hinge shaft 231 so as to be supported by the body frame 210 to elastically bias the other end 234 of the locking lever 230 in an inner direction of a rotation radius of the operating lever 220. Referring to FIG. 8, when the operating lever 220 is in the second position B by the user's operation, that is, the intermediate valve 110 is opened, the other end 234 of the locking lever 230 is hinged. The spring 232 is moved in the direction of the arrow D is caught by the restraining end 224a of the operating lever 220. Therefore, the operation lever 220 is fixed to the second position (B) and can not move to the first position (A, Fig. 7). On the other hand, when the locking lever 230 is moved in the opposite direction of the arrow D direction by the external force, the operating lever 220 is no restraining force, so moving to the first position (A) by the elastic force of the lever spring 221 Done. The other end 234 of the locking lever 230 has a tapered shape so that the locking lever 230 is not subjected to resistance by the operation lever 220 when the locking is released.

The unlocking unit 240 operates to close the intermediate valve 110 by releasing the restraining of the locking lever 230 by the closing signal of the controller 140. That is, when the locking release unit 240 receives the closing signal of the control unit 140, the locking lever 230 is operated by moving the locking lever 230 in the direction opposite to the rotation radius of the operation lever 220, that is, the direction opposite to the arrow D direction. The lever 220 is moved from the second position (B) to the first position (A). According to the present embodiment, the unlocking unit 240 includes a push block 250 and a solenoid 260.

One end of the push block 250 is provided with a push spring 251 which is installed to be supported by the body frame 210. The push spring 251 elastically biases the push block 250 in the direction of the arrow E (see FIG. 8). The pressing portion 253, which is the other end of the push block 250, is installed to face the protrusion 233 formed at the side of the locking lever 230. A fixing groove 252 into which the plunger 261 of the solenoid 260 is inserted is formed at the lower end of the central portion of the push block 250. When the plunger 261 is inserted into the fixing groove 252, the push block 250 is suppressed in the direction of the arrow E.

The plunger 261 of the solenoid 260 is provided with a plunger spring 262. The plunger spring 262 elastically biases the plunger 261 in the upward direction, that is, the arrow F direction (see Fig. 8). Upon receiving the signal from the controller 140, the solenoid 260 operates to lower the plunger 261, and thus the push block 250 having no external force moves in the direction of the arrow E. FIG.

The manual release pin 270 is exposed to the outside of the cover 211, the lower end 271 is inserted and fixed to the release pin insertion groove 235 formed in the locking lever 230. The user may manually close the intermediate valve 110 by manipulating the manual release pin 270 to the right. Thus, by installing the manual release pin 270 in the intermediate valve safety lock device 100 according to the present embodiment, when the intermediate valve 110 is not automatically locked because the device is abnormal, the user manually The valve 110 can be locked, which is more effective for risk prevention. You can also use your manual lock after every gas use.

Hereinafter, the operation of the operation unit 200 according to the embodiment of the present invention will be described with reference to FIGS. 7 to 10. 7 to 10 except for the cover 211 and the control unit 140 of the body frame 210 for convenience of explanation, and also except for the operation knob 222 and the lever spring 221 of the operating lever 220. The combined front view of the state is shown.

7 illustrates a state in which the intermediate valve 110 is closed, that is, the operating lever 220 is in the first position A, and FIG. 8 illustrates a state in which the intermediate valve 110 is opened, that is, the operating lever 220 The state in 2 position (B) is shown.

Referring to FIG. 7, the operation lever 220 is always kept closed by the lever spring 221 (see FIG. 2). At this time, the other end portion 234 side of the locking lever 230 is in contact with the outer circumferential surface of the fixing portion 224 (see FIG. 6) of the operating lever 220. When the user turns the operating lever 220 counterclockwise by more than 90 degrees to move to the second position (B), the other end of the locking lever 230 as shown in FIG. 234 faces the cutout of fixing part 224 (see FIG. 6). At this time, the locking lever 230 is moved into the rotation radius of the operating lever 220 by the elastic force of the hinge spring 232, the other end 234 of the locking lever 230 of the operating lever 220 It is caught by the restraint end 224a. Therefore, the operation lever 220 is fixed in the second position (B) to maintain the intermediate valve 110 in the open state. In addition, since the plunger 261 of the solenoid 260 is inserted into the fixing groove 252 of the push block 250, the push block 250 may not move in the direction of the arrow E.

On the other hand, when receiving the closing signal of the control unit 140, as shown in Figure 9, the solenoid 260 is operated so that the plunger 261 is lowered, so that the upper end of the plunger 261 fixed groove ( 252). Then, the push block 250 is moved in the direction of the arrow E by the elastic force of the push spring 251, the pressing portion 253 of the push block 250 to the protrusion 233 which is the side of the locking lever 230. Pushed.

As shown in FIG. 10, the locking lever 230 is pushed out of the rotation radius of the operation lever 220 by the continuous pressing of the push block 250. Therefore, the operation lever 220 is rotated clockwise, that is, the arrow G direction by the lever spring 221 (see Fig. 2) and eventually the intermediate valve 110 is locked. On the other hand, while the operating lever 220 is rotated, the restraint end 224a pushes the pressure end 254 of the push block 250, and when the push block 250 is fully retracted, the plunger 261 of the solenoid 260 is Ascending in the direction of the arrow F by the plunger spring 262 is inserted into the fixing groove 252 of the push block 250.

After the intermediate valve 110 is opened, that is, even if the operating lever 220 is rotated to the second position (B, see Fig. 8) until the plunger 261 of the solenoid 260 until the push block 250 is lowered You will not move forward.

As a result, the locking release unit 240 converts and stores the rotational torque of the operating lever 220 into the elastic force in the push spring 251 and releases the locking lever 230 by using the force, so that the solenoid 260 is pushed. Since only the force to overcome the friction of the fixing groove 252 of the block 250 is required, it is possible to use a solenoid having a low current consumption and a small size. Therefore, the plunger 261 of the solenoid 260 is more efficient than the role of the push block 250, that is, the plunger 261 of the solenoid 260 pushes the locking lever 230 to release the restraint. .

2 and 11, the fixing unit 160 fixes the operating unit 200 to the intermediate valve 110. The fixing part 160 is screwed or bolted to the body frame 210 of the operating part 200 with the intermediate valve 110 interposed therebetween. The fixing part 160 and the main frame 210 are provided with receiving grooves 162 and 214 for accommodating the hexagonal circumference 112 of the intermediate valve 110, and the receiving grooves 162 and 214 are formed of the intermediate valve 110. By closely coupling to the hexagonal circumferential portion 112, the shaft alignment assembly of the fixing portion 224 (see FIG. 6) of the operating lever 220 and the key 111 of the intermediate valve 110 is performed. The rear portion of the fixing unit 160 is formed with a rectangular removable groove 163 is coupled to the power case 171 of the power supply unit 170. Therefore, detachment is easier than screwing and can be fixed at any inclination angle.

The power supply unit 170 supplies power to the components of the apparatus. The power supply unit 170 is detachably coupled to the detachable groove 163 of the fixing unit 160 and has a power case 171 having a degree of freedom of movement in only one direction and a battery 172 installed inside the power case 171. Include. In this way, since the power case 171 is detachably coupled to the fixing unit 160, the user may easily replace the battery when the battery life is over.

According to the intermediate valve safety locking device according to the present invention as described above, by detecting the flow of the gas, using the detected gas flow whether the gas stop using the device and careless neglect or long time use, and gas By determining whether there is a leak and closing the intermediate valve automatically automatically, there is an effect of preventing safety accidents and improving user convenience.

In addition, gas leak detection and temperature detection are more effective in preventing accidents.

In addition, the power is used only when the intermediate valve is open, thereby extending the life of the battery as much as possible, and the user convenience is improved by closing the intermediate valve using a low current consumption solenoid.

Although preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described specific embodiments. That is, a person having ordinary skill in the art to which the present invention pertains can make many changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications are possible. Equivalents should be considered to be within the scope of the present invention.

Claims (19)

In the intermediate valve safety lock to automatically shut off the intermediate valve installed on the gas supply path of the gas using device, A gas flow detector configured to detect an amount of gas flow flowing in the gas supply path; A controller configured to determine a closing timing of the intermediate valve by using an input signal corresponding to an amount of gas flow transmitted from the gas flow detector to generate a signal for locking the intermediate valve; And, And an operation unit for locking the intermediate valve in accordance with a control signal of the controller. The gas flow detector, A duct installed around the intermediate valve on the gas supply path and having a different cross-sectional area therein; And, And a sensor unit connected to the control unit so as to exchange signals, the sensor unit having at least two pressure ports to measure pressures of different cross-sectional areas in the duct. delete The method of claim 1, wherein the control unit, And a control signal for locking the intermediate valve when the gas flow inside the duct is unchanged for a predetermined safety idle time t1. The method of claim 3, wherein the safety leaving time (t1), Safety lock device for the intermediate valve, characterized in that differently set according to the fire power of the gas using device. The method of claim 3, wherein the control unit, It sends a warning signal for a certain time so that the user can know before transmitting the control signal to the operating unit, and if there is no response to the gas change from the user during the warning signal is transmitted to the control signal for locking the intermediate valve Intermediate valve safety lock. The method of claim 1, wherein the control unit, And a control signal for shutting off the intermediate valve after the set waiting time (t2) has elapsed when the gas stops flowing in the duct. The method of claim 1, wherein the control unit, Immediately after the intermediate valve is opened, the first gas flow signal value is compared with a preset reference value when no gas flows, and gas leakage is detected. When gas leakage is detected, a control signal for locking the intermediate valve with a warning signal Safety lock device for the intermediate valve, characterized in that for transmitting to the operating unit. The method of claim 1, wherein the control unit, Detecting whether the connection with the sensor unit is normal, and when the connection is not normal, the intermediate valve safety lock device, characterized in that to transmit a control signal for locking the intermediate valve to the operation unit. The method of claim 1, It is further connected to the control unit and a signal exchange, and further comprising a long-term use setting unit for the user operation, And the control unit transmits a control signal for locking the intermediate valve to the operation unit when the long-term use setting is input by the user, after the set long-term use time t4 elapses. The method of claim 1, It is connected to enable the signal exchange with the control unit and further comprises a temperature sensing unit for sensing the ambient temperature, The control unit is an intermediate valve safety lock device, characterized in that for transmitting the control signal for locking the intermediate valve after sending a warning signal when the temperature sensed by the temperature sensing unit is higher than the set reference temperature. The method according to any one of claims 3 to 10, wherein the control unit, And a warning signal for transmitting a control signal for locking the intermediate valve to the operating unit to issue a warning signal to the user when the intermediate valve is not normally closed. The method of claim 1, wherein the operating unit, An actuating lever installed on a key of the intermediate valve so as to be rotatable in a first position in which the intermediate valve is closed and in a second position in which the intermediate valve is opened; A lever spring for elastically biasing the actuating lever to the first position; A locking lever installed between rotational radius of the operation lever to restrain the operation lever from moving from the second position to the first position; A locking release unit including a solenoid and releasing the locking lever to rotate the operating lever from the second position to the first position when receiving the closing signal of the control unit; And, And an operating frame, a lever spring, a locking lever, and a locking release part, and a body frame including a cover. The method of claim 12, wherein the unlocking unit, A push block for pushing the locking lever out of the rotation radius of the operating lever and having a plunger groove into which the plunger of the solenoid is inserted; And a push spring elastically biasing the push block. The plunger of the solenoid is inserted into the plunger groove to fix the push block before the signal is applied by the controller, and when the signal is applied by the controller, the plunger is released from the plunger groove to release the restraint of the push block. Valve safety lock. The method of claim 13, When the operating lever moves from the second position to the first position by the push block pushing the locking lever, one end of the operating lever pushes the push block in the opposite direction to push the locking lever to push the locking lever. The safety valve of the intermediate valve, characterized in that for returning to the initial position before the signal applied by the control unit. The method of claim 12, wherein the operating unit, One end connected to the locking lever is installed, the other end of the intermediate valve safety lock device characterized in that it further comprises a manual release pin exposed to the outside of the cover of the main body frame to enable the user operation. The method of claim 12, Safety lock device for the intermediate valve characterized in that it further comprises a fixing portion for fixing the body frame of the operating unit to the intermediate valve. The method of claim 16, Is connected to the control unit and the signal exchange, the intermediate valve safety lock device, characterized in that further comprising a power supply for supplying power to the control unit, the sensor unit and the operation unit. The method of claim 17, wherein the power supply unit, Removably coupled to the removable groove of the fixing portion and the intermediate valve safety lock device, characterized in that it comprises a case having a degree of freedom to move in only one direction and the battery is inserted into the case. The method of claim 18, wherein the control unit, Detecting the battery voltage to determine the life of the battery, and if the battery voltage is less than the set value, the intermediate valve safety lock device characterized in that it is determined that the end of life.

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