JP6327002B2 - Leak detection device for gate valve - Google Patents

Description

  The present invention is provided with a spare nozzle for equipment installation provided in a storage tank, and shuts off unused pipes with an inert gas in a gate valve that is closed until the start of use or a piping system connected to the storage tank. The present invention relates to a gate valve leak detection device that is used to detect the occurrence of leakage with respect to a gate valve that can be closed.

  Low temperature storage tanks that store low-temperature liquefied gases such as LNG and LPG are equipped with equipment such as a liquid level gauge, liquid density meter, thermometer, and submerged camera to detect the state (situation) inside the storage tank. .

  When installing these devices in a low-temperature storage tank, generally, a nozzle for device installation protruding outward (upward) is provided on the storage roof, and a flange is provided at the front end of the nozzle as a main valve. A configuration is adopted in which one flange of the gate valve is attached and the various devices are attached to the other flange of the gate valve (see, for example, Patent Document 1 (FIG. 17)).

  Conventionally, when installing or removing the various devices with respect to the other flange of the gate valve attached to the tip of the device installation nozzle, the gate valve is closed and the gas inside the storage tank is It is prevented from being discharged to the outside through the nozzle. On the other hand, in the state where the various devices are attached to the other flange of the gate valve, the gate valve is opened, and the sensor unit of the various devices is suspended through the nozzle and disposed inside the storage tank. It is.

  By the way, if the liquid level meter, liquid density meter, thermometer, submerged camera, etc. in the low temperature storage tank are damaged due to unforeseen circumstances such as an earthquake, they can no longer be used. It is desired to quickly restore the detection function of the internal state of the storage tank by the damaged device.

  Therefore, in the low-temperature storage tank, a spare nozzle for device installation having a structure including a gate valve on the tip side is provided on the storage tank roof in the same manner as the nozzle for device installation described above, and the device is attached. Until actual use, it is considered that the gate valve is closed and stored as a closed state with a closing plate attached to the other flange on the device mounting side of the gate valve.

  However, in general, even if the gate valve is closed, over time, the contact portion between the valve body and the valve seat may be distorted to cause valve seat leakage. Furthermore, in a gate valve used in an environment affected by rainwater, such as a gate valve attached to the nozzle of the storage tank of the low temperature storage tank, damage due to rust on the flange surface or deterioration of the packing over time. It is conceivable that gas leakage from the flange portion (hereinafter referred to as flange leakage) occurs due to the change.

  For this reason, in the low temperature storage tank, a gas detector is usually provided near the nozzle for installing various devices on the storage roof to detect gas leakage.

  Therefore, in the case where the auxiliary roof for equipment installation as described above is provided on the storage roof of the low temperature storage tank, the gate valve provided in the auxiliary nozzle causes the valve seat leakage, and the closing plate further When the other flange attached is in a state in which the flange leakage has occurred, and a gas leak has occurred from the inside of the low temperature storage tank to the outside through the spare nozzle and the gate valve, the gas leakage is detected by the gas detection. Detected by the instrument.

  However, since the gas detector detects gas leaking to the outside, either the valve seat leakage or the flange leakage at the other flange is added to the gate valve provided in the spare nozzle. When there is only a leak and no gas leaks to the outside, it cannot be detected.

  Therefore, when it is necessary to install equipment on the spare nozzle, the closing plate is removed from the other flange of the gate valve provided on the spare nozzle, and the equipment is attached to the other flange. However, at this time, if a valve seat leak has occurred in the gate valve, it becomes necessary to perform the installation work of the device in an environment where there is a gas leak due to the valve seat leak.

  On the other hand, if flange leakage is caused by damage due to rust or the like on the flange surface of the other flange of the gate valve provided in the spare nozzle, the device should be airtight against the other flange of the gate valve. Installation itself becomes difficult.

  Therefore, for the gate valve provided in the spare nozzle, even if only one of the valve seat leak and the flange leak at the other flange occurs during storage of the spare nozzle, the leak is detected. It is desirable to do.

  Moreover, in the piping system for gas circulation connected to the low temperature storage tank, when there are unused pipes, the unused pipes are connected to the upstream end and the downstream end in the gas circulation direction of the pipe. Close the gate valves provided respectively, and fill the pipes closed by the gate valves with nitrogen gas as an inert gas and store the pipes in a pressure-holding state. Is generally done.

  For each of the gate valves of the piping stored in this way, it is considered that valve seat leakage and flange leakage may occur due to changes over time. Conventionally, a means for detecting such leakage has been particularly employed. The fact is that there is no.

Patent No. 3964747

  Therefore, the present invention is a nozzle provided in a storage tank such as the low-temperature storage tank, and is a gate valve provided in a spare nozzle stored until installation of equipment, or a pipe connected to the storage tank, and is inactive when not in use. Providing a leak detection device for gate valves that can detect valve seat leaks and flange leaks when only one of the gate valves in a pipe that is stored in a gas pressure-carrying state. It is something to try.

  In order to solve the above-mentioned problem, the present invention is attached to the gate valve and one flange to be a flange leak detection target of the gate valve via a pipe that can be directly or hermetically sealed, corresponding to claim 1. A chamber, an inert gas sealing nozzle provided in the chamber, an in-chamber pressure gauge provided in the chamber, an inert gas supply line connected to the inert gas sealing nozzle of the chamber, and the inert gas supply A pressure control valve and a flow meter provided in the line, and the pressure control valve applies the chamber internal pressure detected by the chamber internal pressure gauge to the gate valve from the flange side opposite to the chamber mounting side. A leak detection device for a gate valve having a configuration in which the pressure is maintained higher than the pressure.

  According to claim 2, in the configuration corresponding to claim 1, the chamber is provided with a gas detector corresponding to the gas to be detected for leakage in the gate valve, and the pressure in the inert gas supply line. A pressure regulating valve is provided at a position downstream of the control valve, and the pressure regulating valve operates in the closing direction from the open state, thereby allowing the inert gas to be supplied to the chamber through the inert gas supply line. The supply pressure can be adjusted from the pressure controlled by the pressure control valve to a pressure lower than the pressure acting on the gate valve from the flange side opposite to the chamber mounting side.

  Further, in accordance with claim 3, in the configuration corresponding to claim 1 or 2, the gate valve is connected to the flange at the tip of the nozzle for equipment installation provided on the storage roof or the side wall of the storage tank, and one flange. And the chamber is configured to be attached to the other flange of the gate valve.

  Similarly, corresponding to claim 4, in the configuration corresponding to claim 1 or 2, the gate valve is a flange provided at the upstream end in the gas flow direction of the pipe stored in the pipe system when not in use. And a flange connected to the flange at the downstream end of the upstream pipe located upstream thereof, and the chamber is hermetically attached to the pipe wall in the middle of the pipe. The downstream end is configured to be closeable by another gate valve.

  According to the gate valve leak detection device of the present invention, the following excellent effects are exhibited.

  In the chamber attached to one flange which is a flange leakage detection target in the gate valve, the inert gas introduced through the inert gas supply line is injected through the inert gas sealing nozzle, and in this state, the pressure control valve Thus, the chamber internal pressure detected by the chamber internal pressure gauge can be maintained at a pressure higher than the pressure acting on the gate valve from the flange side opposite to the chamber mounting side. In this state, both the valve seat leakage occurring in the gate valve and the flange leakage in the one flange are phenomena in which the detected flow rate of the inert gas by the flow meter provided in the inert gas supply line changes. Can be detected on the basis.

It is a partial cutting schematic side view showing one embodiment of the leak detection device for gate valve of the present invention. It is a partially cut schematic side view which shows the other form of implementation of this invention. It is a partially cut away schematic side view which shows other form of implementation of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  FIG. 1 shows an embodiment of a leak detection device for a gate valve according to the present invention.

  In the present embodiment, the leakage detection target to which the present invention is applied is the gate valve 5 provided in the spare nozzle 3 for equipment installation provided on the storage tank roof 2 of the low temperature storage tank 1 as shown in FIG.

  The low temperature storage tank 1 is a storage tank for storing a low temperature liquefied gas (not shown) such as LNG or LPG. The preliminary nozzle 3 is provided on the storage tank roof 2 of the low temperature storage tank 1 so as to protrude upward by a certain dimension. In the flange 4 provided at the tip of the preliminary nozzle 3, one flange 6 of a sluice valve 5 serving as a main valve is illustrated as a bolt and a nut with a seal member such as packing (not shown) interposed therebetween. It is airtightly attached using non-fixing means. Thus, the preliminary nozzle 3 is stored in a closed state by closing the gate valve 5 until the device is installed and actually used.

  The gate valve leak detection device 8 of the present invention applied to the gate valve 5 provided in the spare nozzle 3 includes a container-shaped chamber 9 having one opening. The chamber 9 is configured to include a flange 10 on the periphery of the opening, and the flange 10 is in a state where a seal member such as packing (not shown) is interposed on the other flange 7 of the gate valve 5. It is attached airtightly and detachably using fixing means (not shown) such as bolts and nuts.

  Thereby, in the gate valve 5, the other flange 7 becomes a flange leak detection target by the gate valve leak detection device 8 of the present invention.

  The chamber 9 includes an inert gas sealing nozzle 11 with an on-off valve 12 that communicates with the internal space of the chamber 9 and a pressure in the internal space of the chamber 9 (hereinafter referred to as a chamber internal pressure). An in-chamber pressure gauge 13 is provided.

  As shown in FIG. 1, the chamber 9 is preferably further provided with a gas discharge nozzle 14 with an on-off valve 15 communicating with the internal space of the chamber 9. If this gas discharge nozzle 14 is provided, when nitrogen gas 17 as an inert gas is injected into the chamber 9 through the inert gas sealing nozzle 11 as described later, During this period, by opening the on-off valve 15 of the gas discharge nozzle 14, the atmosphere inside the chamber 9 can be easily replaced with the nitrogen gas 17 from air.

  A nitrogen gas supply line 16 as an inert gas supply line for guiding nitrogen gas 17 as an inert gas supplied from a gas supply source (not shown) is connected to the inert gas sealing nozzle 11 of the chamber 9.

  In the middle of the nitrogen gas supply line 16, a pressure control valve 18 and a flow meter 19 are provided in this order from the upstream side.

  A measured value of the pressure in the chamber by the pressure gauge 13 in the chamber is inputted to the controller 20 of the pressure control valve 18. Further, the controller 20 receives the pressure Pg of the gas acting from the inside of the low temperature storage tank 1 on the gate valve 5 provided to the reserve nozzle 3 from the internal pressure gauge 21 provided in the low temperature storage tank 1. The measured value of the pressure of the gas phase in 1 (hereinafter simply referred to as the internal pressure of the storage tank) is input. In the low-temperature storage tank 1 for storing low-temperature liquefied gas such as LNG and LPG, it is widely used to measure the internal pressure of the storage tank equipped with the internal pressure gauge 21 for management. Therefore, as the storage tank pressure gauge 21 for inputting the measured value of the storage tank pressure to the controller 20, the storage tank pressure gauge 21 generally equipped in the low temperature storage tank 1 may be used.

  The controller 20 compares the measured value X [Pa] of the chamber internal pressure input from the chamber pressure gauge 13 with the measured value Y [Pa] of the reservoir internal pressure input from the tank internal pressure gauge 21. Thus, the pressure control valve 18 is controlled so that the pressure in the chamber is always kept higher (X> Y) than the pressure in the storage tank. As will be described later, even if valve seat leakage occurs in the gate valve 5, the gas inside the low-temperature storage tank 1 is prevented from leaking into the internal space of the chamber 9, and this acts on the chamber 9. In view of preventing the chamber internal pressure from becoming excessive, the control target value of the chamber internal pressure by the controller 20 is preferably set to a pressure obtained by increasing the storage tank internal pressure by about 10% to 20%. .

  The flow meter 19 is configured to send a signal of a flow rate detection value of the nitrogen gas 17 flowing through the nitrogen gas supply line 16 to a central control device 24 that manages the low-temperature storage tank 1 and its associated facilities.

  Thereby, in the chamber 9 attached to the shut-off gate valve 5, when the on-off valve 12 of the inert gas sealing nozzle 11 is opened with the on-off valve 15 of the gas discharge nozzle 14 closed. The nitrogen gas 17 introduced through the nitrogen gas supply line 16 is injected into the internal space of the chamber 9 from the inert gas sealing nozzle 11. As the nitrogen gas 17 is injected, the pressure in the chamber increases in the chamber 9.

  Thereafter, in the chamber 9, when the detected value of the chamber pressure by the chamber pressure gauge 13 reaches the control target value set by the controller 20 of the pressure control valve 18, the pressure control valve 18 controls the chamber 9. The supply pressure of the nitrogen gas 17 is balanced with the pressure in the chamber. With the establishment of this balance, injection of new nitrogen gas 17 from the nitrogen gas supply line 16 stops in the chamber 9. For this reason, in the flow meter 19 provided in the nitrogen gas supply line 16, the flow rate detection value becomes zero.

  In this state, the spare nozzle 3 can be stored until the device is attached and used for actual use.

  When valve seat leakage occurs in the gate valve 5 in the state where the spare nozzle 3 is stored, the pressure in the chamber is kept higher than the pressure in the storage tank. 17 moves into the low temperature storage tank 1 through the valve seat leakage portion of the gate valve 5.

  When the nitrogen gas 17 moves from the inside of the chamber 9 into the low temperature storage tank 1 through the valve seat leakage portion of the gate valve 5, the pressure in the chamber is controlled by the pressure control valve 18 in the chamber 9. It drops below the supply pressure of 17. In such a state, in the chamber 9, the supply pressure of the nitrogen gas 17 is controlled by the pressure control valve 18 in order to recover the lowered pressure in the chamber, and the inert gas sealing nozzle 11 controls the chamber 9. 9 is replenished with new nitrogen gas 17. This replenishment of the nitrogen gas 17 into the chamber 9 is continuously performed while the valve seat leaks in the gate valve 5. For this reason, the flow meter 19 provided in the nitrogen gas supply line 16 detects the flow rate of the nitrogen gas 17 supplied into the chamber 9.

  On the other hand, when a flange leak occurs in the other flange 7 of the gate valve 5 to which the flange 10 of the chamber 9 is attached while the spare nozzle 3 is stored in the same manner as described above, Nitrogen gas 17 is discharged to the outside through the flange leakage point of the gate valve 5.

  When nitrogen gas 17 is released from the inside of the chamber 9 to the outside through the flange leakage portion of the gate valve 5, the supply pressure of the nitrogen gas 17 is controlled in the chamber 9 by the pressure control valve 18. Will be lower than. In such a state, in the chamber 9, the supply pressure of the nitrogen gas 17 is controlled by the pressure control valve 18 in order to recover the lowered pressure in the chamber, and the inert gas sealing nozzle 11 controls the chamber 9. 9 is replenished with new nitrogen gas 17. This replenishment of the nitrogen gas 17 into the chamber 9 is continuously performed while the flange leakage occurs at the other flange 7 of the gate valve 5. Therefore, also in this case, the flow meter 19 provided in the nitrogen gas supply line 16 detects the flow rate of the nitrogen gas 17 supplied into the chamber 9.

  Therefore, both the valve seat leakage occurring in the gate valve 5 provided in the spare nozzle 3 and the flange leakage in the other flange 7 are both detected by the flow meter 19 provided in the nitrogen gas supply line 16. The value can be detected based on a phenomenon in which the value fluctuates to the plus side from the normal flow rate zero state.

  Furthermore, the gate valve leak detection device 8 of the present invention is provided with a pressure regulating valve 22 at a position downstream of the flow meter 19 in the nitrogen gas supply line 16, and the low temperature in the chamber 9. It is preferable that a gas detector 23 corresponding to the low-temperature liquefied gas stored in the storage tank 1 is provided.

  The pressure regulating valve 22 is operated in the closing direction from the open state, whereby the supply pressure of the nitrogen gas 17 supplied to the chamber 9 through the nitrogen gas supply line 16 is controlled by the pressure control valve 18. Therefore, the pressure inside the storage tank, that is, a pressure lower than the pressure Pg of the gas acting on the gate valve 5 provided in the preliminary nozzle 3 from the inside of the low temperature storage tank 1 can be adjusted.

  The gas detector 23 provided in the chamber 9 is preferably configured to send a gas detection signal to the central controller 24 that manages the low-temperature storage tank 1 and its associated facilities.

  Thereby, in the chamber 9, when the pressure of the nitrogen gas 17 supplied from the nitrogen gas supply line 16 is adjusted to a pressure lower than the internal pressure of the low temperature storage tank 1 by operating the pressure adjusting valve 22. When a valve seat leak has occurred in the gate valve 5 of the spare nozzle 3, the gas inside the low temperature storage tank 1 flows into the chamber 9 through the valve seat leak point of the gate valve 5. Thus, the gas flowing into the chamber 9 is detected by the gas detector 23.

  On the other hand, when there is no valve seat leakage in the gate valve 5 of the spare nozzle 3, the supply pressure of the nitrogen gas 17 supplied to the chamber 9 from the nitrogen gas supply line 16 by operating the pressure adjustment valve 22 is reduced. Even if the pressure inside the storage tank of the low-temperature storage tank 1 is adjusted to a pressure lower than that inside, the gas inside the low-temperature storage tank 1 does not flow into the chamber 9. Therefore, in this case, the gas detector 23 does not operate.

  Therefore, as described above, the flow meter 19 provided in the nitrogen gas supply line 16 detects a phenomenon in which the flow rate detection value of the nitrogen gas 17 swings from the normal flow rate zero state to the plus side. In this case, when the operation of adjusting the supply pressure of the nitrogen gas 17 to the chamber 9 to a pressure lower than the internal pressure of the low-temperature storage tank 1 is performed using the pressure adjusting valve 22, the gas detector 23 Based on the presence or absence of gas detection, it is possible to determine which of the valve seat leak and the flange leak in the other flange 7 occurs in the gate valve 5.

  When using the leak detection device 8 for gate valve of the present invention having the above-described configuration, the gate 9 of the preliminary nozzle 3 provided on the storage tank roof 2 of the low temperature storage tank 1 is closed. The on-off valve 15 of the gas discharge nozzle 14 is closed, and the on-off valve 12 of the inert gas filling nozzle 11 is opened. At this time, the pressure regulating valve 22 provided in the nitrogen gas supply line 16 is in an open state so as not to change the supply pressure of the nitrogen gas 17 controlled by the upstream pressure control valve 18.

  As a result, the nitrogen gas 17 is injected into the chamber 9 and provided in the nitrogen gas supply line 16 when the pressure in the chamber becomes equal to the supply pressure of the nitrogen gas 17 controlled by the pressure control valve 18. Since the flow rate detected by the flow meter 19 is zero, the gate valve leak detection device 8 of the present invention maintains this state.

  Thereafter, in the leak detection device 8 for a gate valve of the present invention, the flow rate detection value of the nitrogen gas 17 in the flow meter 19 provided in the nitrogen gas supply line 16 swings from the normal flow rate zero state to the plus side. On the basis of the above, it is possible to detect that either the valve seat leak of the gate valve 5 of the spare nozzle 3 or the flange leak of the other flange 7 has occurred.

  At this time, in the gate valve leak detection device 8 of the present invention, nitrogen gas 17 is sealed in the chamber 9 and the pressure in the chamber is higher than the pressure in the storage tank. Even if the leak is a valve seat leak, it is possible to prevent the gas inside the low temperature storage tank 1 from leaking outside through the gate valve 5 and scattering.

  Furthermore, in the leak detection device 8 for a gate valve of the present invention, when the occurrence of leak in the gate valve 5 is detected based on the change in the flow rate detection value in the flow meter 19 as described above, the pressure regulating valve 22 is used to adjust the supply pressure of the nitrogen gas 17 to the chamber 9 to a pressure lower than the internal pressure of the low-temperature storage tank 1, based on the presence or absence of gas detection by the gas detector 23. As for the leakage at the gate valve 5, it can be determined whether it is a valve seat leakage or a flange leakage.

  Thus, according to the gate valve leak detection device 8 of the present invention, the valve valve provided in the spare nozzle 3 of the low temperature storage tank 1 causes the occurrence of valve seat leakage and the other flange 7 on the device mounting side. It is possible to quickly detect the occurrence of flange leakage.

  Therefore, with respect to the gate valve 5 in which these problems have occurred, the valve seat leakage and the flange leakage should be promptly eliminated by performing additional measures such as retightening a valve body (not shown), inspection, repair, etc. Can do. Therefore, when it becomes necessary to install equipment for the spare nozzle 3 that has been stored, this equipment should be installed in an environment in which gas leakage due to leakage of the valve seat of the gate valve 5 has occurred. Can be avoided, and airtight attachment of the device to the other flange 7 of the gate valve 5 can be performed.

  The gate valve leak detection device 8 according to the present invention detects a valve seat leak and a flange leak at the other flange 7 on the equipment mounting side, which is a flange leak detection target, for the gate valve 5. is there. Therefore, in the gate valve 5, the flange leak in one flange 6 attached to the flange 4 of the spare nozzle 3 cannot be detected by the gate valve leak detection device 8 of the present invention. However, when a flange leak occurs in one flange 6 of the gate valve 5, the gas inside the low temperature storage tank 1 leaks to the outside through the flange leak location and is scattered. The detection by the gas detector normally provided in the storage tank roof 2 of the low temperature storage tank 1 is possible.

  Next, FIG. 2 shows another embodiment of the present invention. A spare nozzle 3a for equipment installation in which a leak detection target to which the present invention is applied is provided on the side wall 25 of the low temperature storage tank 1 as shown in FIG. This is a gate valve 5 for closing the auxiliary nozzle 3a during storage.

  In addition, the said reserve nozzle 3a shall be provided in the position lower than the normal storage level (liquid level) of the low temperature liquefied gas (not shown) which is the liquid in the storage tank stored in the said low temperature storage tank 1. .

  For this reason, as for the said reserve nozzle 3, the opening part inside the low temperature storage tank 1 is immersed in the liquid of the said low temperature liquefied gas. Therefore, the gate valve 5 in a state in which the preliminary nozzle 3 is closed is supplied from the inside of the low-temperature storage tank 1 as the liquid phase pressure Pl of the low-temperature liquefied gas, as described above. The pressure obtained by adding the head pressure corresponding to the difference between the installation height of the preliminary nozzle 3 and the liquid level of the low-temperature liquefied gas acts on the phase pressure).

  In view of the above, the gate valve leak detection device 8 of the present embodiment applied to the gate valve 5 provided in the spare nozzle 3a has the same configuration as the gate valve leak detection device 8 shown in FIG. The control target value of the pressure in the chamber in the controller 20 of the pressure control valve 18 is changed.

  The controller 20 inputs the measured value of the chamber pressure from the chamber pressure gauge 13 and the measured value of the pressure in the storage tank from the pressure gauge 21 in addition to the liquid level gauge 26 provided in the low temperature storage tank 1. The measured value of the liquid level of the low-temperature liquefied gas is input.

  The controller 20 stores in advance data relating to the installation height of the spare nozzle 3 and data relating to the density of the low-temperature liquefied gas that is the liquid in the storage tank.

  Furthermore, when the measured value of the liquid level of the low-temperature liquefied gas is input from the liquid level gauge 26, the controller 20 firstly, the measured value, data regarding the installation height of the spare nozzle 3, and the Based on the data on the density of the low-temperature liquefied gas, the head pressure acting on the installation height position of the preliminary nozzle 3 is calculated.

  Next, the controller 20 obtains the sum of the calculation result of the head pressure and the measured value of the storage tank pressure, and the measured value of the chamber pressure by the chamber pressure gauge 13 is more than the sum value. The pressure control valve 18 is controlled so as to be held in a high state.

  Other configurations are the same as those shown in FIG. 1, and the same components are denoted by the same reference numerals.

  The same effect as the embodiment of FIG. 1 can be obtained also by the gate valve leak detection device 8 of the present embodiment having the above-described configuration.

  Next, FIG. 3 shows still another embodiment of the present invention. As shown in FIG. 3, the object of leakage detection to which the present invention is applied is for gas circulation connected to a low temperature storage tank (not shown). In this piping system, when a certain unused pipe 27 is stored, gate valves 28 and 29 for closing the upstream end and the downstream end of the pipe 27 in the gas flow direction are provided.

As shown in FIG. 3, the pipe 27 includes flanges 30 and 31 at an upstream end and a downstream end in the gas flow direction indicated by an arrow f, respectively.
In the piping system, piping (upstream piping) 32 positioned upstream in the gas flow direction with respect to the piping 27 is connected to a flange 33 provided at a downstream end thereof, and one flange 34 of the gate valve 28 is provided. In a state where a sealing member such as packing (not shown) is interposed, the fixing member (not shown) such as a bolt and a nut is attached in an airtight manner. The other flange 35 of the gate valve 28 is provided with a fixing means (not shown) such as a bolt and a nut with a flange 30 at the upstream end of the pipe 27 interposed with a sealing member such as packing (not shown). Used to be airtight.

  Furthermore, a pipe (downstream pipe) 36 located downstream in the gas flow direction with respect to the pipe 27 in the pipe system is connected to one flange of the gate valve 29 on a flange 37 provided at an upstream end thereof. 38 is airtightly attached using a fixing means (not shown) such as a bolt and a nut in a state where a sealing member (not shown) such as packing is interposed. The other flange 39 of the gate valve 29 is provided with a fixing means (not shown) such as a bolt and a nut with a flange 31 at the downstream end of the pipe 27 interposed with a sealing member such as packing (not shown). Used to be airtight.

  As a result, when the pipe 27 is not used, the gate valves 28 and 29 are closed together so that the communication with the upstream pipe 32 and the downstream pipe 36 can be stored in a sealed state. is there.

  The gate valve leakage detection device 8A of the present embodiment applied to the gate valves 28 and 29 attached to the upstream end and the downstream end of the pipe 27 is upstream in the gas flow direction in the pipe 27. A nozzle 40 that projects outwardly by a certain dimension is provided on the tube wall near the end, and a flange 41 of the chamber 9 similar to that shown in FIG. However, in a state in which a seal member such as packing (not shown) is interposed, it is airtightly attached via fixing means (not shown) such as bolts and nuts.

  As a result, in the gate valves 28 and 29, the other flanges 35 and 39 to which the pipe 27 is attached become flange leak detection targets by the gate valve leak detection device 8A of the present embodiment.

  The chamber 9 is provided with an inert gas-filled nozzle 11, a chamber pressure gauge 13, and a gas detector 23 as shown in FIG. Further, a nitrogen gas supply line 16 is connected to the inert gas sealing nozzle 11 in the same manner as shown in FIG. 1, and a pressure control valve 18, a flow meter 19, a pressure is connected to the nitrogen gas supply line 16. A regulating valve 22 is provided.

  By the way, the pressure Pg of the gas which distribute | circulates the said piping system is acting on the gate valve 28 which obstruct | occluded the upstream edge part of the said piping 27 from the upstream piping 32 side.

  In view of this point, the controller 20 of the pressure control valve 18 determines the measured value of the pressure in the chamber from the pressure gauge 13 in the chamber and the pressure in the upstream side pipe 32 by the pressure gauge 42 provided in the upstream side pipe 32. The measured value of the gas pressure Pg at is input.

  Further, the controller 20 compares the measured values when they are input, and the measured value of the chamber pressure is compared with the measured value of the gas pressure Pg in the upstream pipe 32. The control target value of the pressure in the chamber is set so as to be maintained in a high state, and the function of controlling the pressure control valve 18 based on the control target value is provided.

  Other configurations are the same as those shown in FIG. 1, and the same components are denoted by the same reference numerals.

  In the case of using the gate valve leak detection device 8A of the present embodiment having the above-described configuration, both the gate valves 28 and 29 provided on the upstream side and the downstream side of the pipe 27 are closed, and the pipe 27 , The communication with the upstream pipe 32 and the downstream pipe 36 is blocked and sealed, and then the on-off valve 12 of the inert gas sealing nozzle 11 of the chamber 9 is opened.

  Thereby, in the chamber 9, nitrogen gas 17 guided through the nitrogen gas supply line 16 is injected into the internal space of the chamber 9 from the inert gas sealing nozzle 11.

  Since the nitrogen gas 17 injected into the chamber 9 is supplied to the internal space of the pipe 27 through the nozzle 40, the pressure in the internal space of the pipe 27 rises together with the pressure in the chamber.

  Thereafter, when the chamber internal pressure detected by the chamber internal pressure gauge 13 reaches a control target value set by the controller 20 of the pressure control valve 18, the nitrogen gas 17 controlled by the pressure control valve 18 is increased. The supply pressure is balanced with the pressure in the chamber and the pressure in the internal space of the pipe 27. With the establishment of this balance, injection of new nitrogen gas 17 from the nitrogen gas supply line 16 stops in the chamber 9. For this reason, in the flow meter 19 provided in the nitrogen gas supply line 16, the flow rate detection value becomes zero.

  Accordingly, the pipe 27 is filled with the nitrogen gas 17 that is the inert gas in the internal space, and is held at an internal pressure that matches the supply pressure of the nitrogen gas 17 controlled by the pressure control valve 18. It becomes a state. The piping 27 in the pressure-holding state can be stored as in the conventional case.

  In the pipe 27 in the storage state, a valve seat leak in the gate valve 28 at the upstream end, a flange leak in the other flange 35, and a valve seat leak in the gate valve 29 at the downstream end, If any one of the flange leaks in the other flange 39 occurs, the flow rate detection value in the flow meter 19 provided in the nitrogen gas supply line 16 is normal, based on the same principle as shown in FIG. It will swing from the zero flow rate to the plus side.

  Therefore, also with the gate valve leak detection device 8A of the present embodiment, the flow rate detection value of the nitrogen gas 17 in the flow meter 19 provided in the nitrogen gas supply line 16 is positive from the normal flow rate zero state. On the basis of the phenomenon of swinging, it is possible to detect that either the valve seat leakage or the flange leakage at the other flange 35 or 39 has occurred in the gate valves 28 and 29.

  At this time, even if the generated leak is a valve seat leak in the gate valve 28 at the upstream end of the pipe 27, the gas existing in the upstream pipe 32 enters the internal space of the pipe 27. This can be prevented.

  Further, when a change in the flow rate detection value of the flow meter 19 as described above is detected, the pressure adjustment valve 22 provided in the nitrogen gas supply line 16 is operated, so that the piping 27 When an operation of adjusting the pressure in the internal space to a pressure lower than the gas pressure Pg in the upstream side pipe 32 is performed, if there is gas detection by the gas detector 23 in that state, the upstream side of the pipe 27 It can be determined that a valve seat leak has occurred in the gate valve 28 at the side end. On the other hand, when the gas detector 23 is not activated, the valve seat leaks at the gate valve 29 at the downstream end of the pipe 27 or the flanges at the other flanges 35 and 39 of the gate valves 28 and 29. It can be determined that any of the leaks have occurred.

  As described above, also by the leak detection device 8A for the gate valve according to the present embodiment, the valve seat leaks for the gate valves 28 and 29 that block the upstream end and the downstream end of the pipe 27 being stored. In addition, since the occurrence of flange leakage at the other flanges 35 and 39 can be detected promptly, the gate valves 28 and 29 can be dealt with according to need such as retightening, inspection, and repair. The valve seat leakage and the flange leakage can be quickly eliminated.

  Furthermore, the gate valve leak detection device 8A according to the present embodiment works on the downstream side of the pipe 27 in a state where the gate valve 28 at the upstream end of the pipe 27 is closed to block the gas flow. When a valve seat leak occurs at the gate valve 28 at the upstream end, the gas entering the pipe 27 due to the valve seat leak is disposed near the upstream end of the pipe 27. It can be detected by the gas detector 23 provided in the chamber 9.

  Therefore, the invasion of the gas into the pipe 27 can be detected before the gas reaches the construction site.

  Further, when the gas intrusion into the pipe 27 is detected, the nitrogen gas 17 introduced from the nitrogen gas supply line 16 is injected into the chamber 9 to enter the pipe 27. The concentration of the gas can be reduced by dilution with the nitrogen gas 17. Therefore, the construction on the downstream side of the pipe 27 can be performed in a state where the safe concentration condition of the gas is satisfied.

  The present invention is not limited to the above-described embodiment. In the embodiment of FIG. 1 and the embodiment of FIG. 2, the chamber 9 is accompanied by a temperature change due to the influence of the outside air temperature. When the inside nitrogen gas 17 contracts, in order to compensate for the pressure drop caused by the contraction, the nitrogen gas 17 is injected into the chamber 9, which is a flow meter 19 provided in the nitrogen gas supply line 16. It is conceivable that the flow rate detection value of the nitrogen gas 17 is detected as a phenomenon that swings positive. Therefore, when it is assumed that the nitrogen gas 17 in the chamber 9 is affected by the temperature change, the chamber 9 may be covered with a heat insulating material. Further, the chamber 9 is provided with a thermometer for measuring the temperature of the nitrogen gas 17 inside, and the volume change of the nitrogen gas 17 in the chamber 9 according to the detected temperature is predicted. Based on the prediction result, Corrections may be made to the flow rate detection value of the flow meter 19.

  Further, in the embodiment of FIG. 3, the flow rate meter similar to the above is obtained by contracting the nitrogen gas 17 in the chamber 27, the nozzle 40, and the stored piping 27 with the temperature change due to the influence of the outside air temperature or the like. It is considered that the flow rate detection value at 19 is affected. Therefore, in the embodiment of FIG. 3, the chamber 9, the nozzle 40, and the stored piping 27 may be covered with a heat insulating material. Further, a thermometer for measuring the temperature of the nitrogen gas 17 inside is provided in any one of the chamber 9 and the nozzle 40 and the pipe 27 to be stored, and the volume change of the nitrogen gas 17 corresponding to the detected temperature is predicted, On the basis of the prediction result, a correction may be made to the flow rate detection value of the flow meter 19.

  The low temperature storage tank 1 may store a low temperature liquefied gas other than LNG or LPG.

  Further, the present invention provides a gate valve for closing a reserve nozzle provided in a storage tank other than the low temperature storage tank 1 or a discharge to the outside as long as the storage tank stores gas or liquid that should be prevented from being released to the outside. You may apply when detecting the leak about the gate valve for obstruct | occluding piping which distribute | circulates the gas which should be prevented.

  Any type of valve may be used as long as it is a gate valve 5, 28, 29 used to block the flow of gas or liquid.

  Nitrogen gas 17 is exemplified as the inert gas injected into the chamber 9. However, if the gas is inert with respect to the gas to be prevented from leaking from the gate valves 5, 28, 29, the leakage is prevented. An inert gas other than the nitrogen gas 17 may be employed according to the composition and properties of the gas to be used, the usage environment of the gate valves 5, 28, and 29.

  Of course, various modifications can be made without departing from the scope of the present invention.

1 Low temperature storage tank (storage tank), 2 storage tank roof, 3, 3a Nozzle (spare nozzle), 4 flange, 5 gate valve, 6 flange (flange), 7 flange (flange), 8, 8A Gate valve leak Sensing device, 9 chamber, 11 inert gas sealing nozzle, 13 chamber pressure gauge, 16 nitrogen gas supply line (inert gas supply line), 17 nitrogen gas (inert gas), 18 pressure control valve, 19 flow meter, 22 Pressure regulating valve, 23 Gas detector, 25 Side wall, 27 Piping, 28 Gate valve, 29 Gate valve, 30 Flange, 32 Upstream piping, 33 Flange

Claims (4)

A gate valve;
A chamber attached to one flange to be a flange leakage detection target of the gate valve, directly or via a sealable pipe,
An inert gas sealing nozzle provided in the chamber;
An in-chamber pressure gauge provided in the chamber;
An inert gas supply line connected to an inert gas sealing nozzle of the chamber;
A pressure control valve and a flow meter provided in the inert gas supply line;
And the said pressure control valve hold | maintains the pressure in the chamber detected by the said pressure gauge in a chamber to the pressure higher than the pressure which acts on the said sluice valve from the flange side opposite to the chamber attachment side. A leak detection device for a gate valve, characterized by comprising: In the chamber, a gas detector corresponding to the gas to be detected for leakage in the gate valve is provided,
A pressure adjustment valve is provided at a position downstream of the pressure control valve in the inert gas supply line,
The pressure regulating valve performs an operation in the closing direction from the open state, thereby changing the supply pressure of the inert gas supplied to the chamber through the inert gas supply line from the pressure controlled by the pressure control valve. The leak detection device for a gate valve according to claim 1, wherein the gate valve can be adjusted to a pressure lower than a pressure acting on the gate valve from a flange side opposite to the chamber mounting side. The gate valve is formed by attaching one flange to the flange of the tip of the nozzle for equipment installation provided on the storage roof or side wall of the storage tank,
The leak detection device for a gate valve according to claim 1 or 2, wherein the chamber is attached to the other flange of the gate valve. The gate valve is flange-connected to the flange at the upstream end in the gas flow direction of the pipe stored in the piping system when not in use and the flange at the downstream end of the upstream pipe located upstream. To be installed
The chamber is hermetically attached to the pipe wall in the middle of the pipe,
The leak detection device for a gate valve according to claim 1 or 2, wherein the downstream end of the pipe can be closed by another gate valve.

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