JPH0413513Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) The present invention relates to a pressure regulating valve device for large tanks, etc., and in particular, it is used to control the pressure of seal gas that covers the liquid surface of chemical liquid etc. stored in the tank. The present invention relates to a valve device for carrying out the operation.

(Prior art) Conventionally, in storage tanks for petroleum products and chemical liquids, the liquid level inside the tank is covered with an inert gas.
This is to prevent deterioration of the liquid, but in this case, the pressure of the sealing gas, such as an inert gas, must be maintained at a constant level slightly higher than atmospheric pressure, taking into consideration the pressure resistance of the tank. Particularly in large tanks, the pressure resistance is low, so it is of course necessary to control the seal gas pressure with high precision, and it is desirable that the differential pressure between the seal gas pressure and the atmospheric pressure be as small as possible. In other words, tanks are generally equipped with a breather valve or the like to provide a breathing effect in order to cope with the increase or decrease in the air layer due to the intake or discharging of liquid, or the increase or decrease in air or steam due to increases or decreases in outside temperature. Under normal conditions, this breathing apparatus can be used, but a seal pot may be installed as a follow-up means for exhaust gas. In addition, in the event of a fire in an adjacent tank, etc., internal pressure will occur that exceeds the exhaust capacity of these normal exhaust systems, so emergency exhaust means of a higher class will be installed, and furthermore, these automatic control means will not be able to respond. In some cases, an alarm means is provided to notify of this, and a manual exhaust means or the like is installed in order to manually exhaust the air in response to this alarm.

In the control process when such a control means is provided, it is necessary to set it to respond at a pressure higher than the seal gas pressure in the tank, and when the control means are provided in an overlapping manner as described above, Since each control process must be set to operate at a higher pressure, it can be understood that it is more advantageous for the seal gas pressure in the tank to be closer to atmospheric pressure.

We first provided pressure regulating valve devices for tanks and other devices to meet the above requirements (Japanese Patent Application Laid-open No. 1983
In the seal gas pressure regulating valve device according to this proposal, the main valve for controlling the seal gas to be supplied to the tank has first and second pressure chambers separated by a diaphragm, and the main valve controls the seal gas to be supplied to the tank. The pressure gas supplied to the tank is regulated via a regulator, and equal pressure gas is introduced into both pressure chambers, and when the tank internal pressure drops, the seal gas in the tank is introduced. By operating the pilot valve, the gas in one of the pressure chambers is discharged and the main valve is opened, so that the pressure above the liquid level in the tank is maintained constant.

However, with the above equipment, the regulator must be removed for maintenance, inspection, disassembly, and adjustment, which necessitates removal of piping and other parts and readjustment of the control system.In addition, control via the regulator requires the pressure to be set. There was a point that needed to be improved in terms of response time, which required about 2 seconds when the value suddenly dropped below that value.

That is, in a breather valve, when the set pressure is 100% and the allowable amount for the set pressure is included, exhaust gas may continue to flow without stopping up to 72% of the set pressure. In such a case, if the sealing gas pressure is not quickly controlled relative to the atmospheric pressure, there is a risk that the sealing gas may be directly released or that air may come into contact with the liquid.

(Purpose of the invention) The purpose of the invention is to improve the pressure regulating valve device for tanks, etc. that we previously proposed, and to create a tank that can be disassembled, inspected, and adjusted without removing the piping, and has better responsiveness. An object of the present invention is to provide a seal gas pressure regulating valve device.

(Structure of the invention) The structure of the in-tank seal gas pressure regulating valve device according to the invention will be explained based on the drawings. The main valve 8 opens and closes the communication passage 7 between the seal gas inlet 5 side and the outlet 6 side. and first and second diaphragms 10 and 11 attached to the valve rod 9 of the main valve 8, and a bypass 13 formed between the first and second diaphragms 10 and 11, and a bypass 13 from the inlet 5 side. A first pressure chamber 12 is partitioned by the first diaphragm 10 and a first pressure chamber 12 is supplied with seal gas through the needle valve 15 from the inlet 5 side. a second pressure chamber 14, a gas passage 16 formed between the second pressure chamber 14 and the outlet 6 side, and a pilot arranged to open and close the gas passage 16. a third pressure chamber 18 defined by the valve 20 and the third diaphragm 17 and into which the seal gas in the tank flows through the pressure-sensitive tube 19;
diaphragm 17 and the pilot valve 20
The pilot valve 20, which closes the gas passage 16, is opened by actuation of the third diaphragm 17 as the pressure in the third pressure chamber 18 decreases. A connecting means 21 is provided.

In the above configuration, when the internal pressure P ₂ of the tank 1 is constant, the pressure gas P ₁ entering from the inlet 5 reaches the first pressure chamber 12 via the bypass 13; Pressure gas enters the pressure chamber 14 via the needle valve 15, so the first pressure chamber 12 and the second pressure chamber 14 are at the same pressure, but the outside of the second diaphragm 11 is exposed to the atmosphere. Because it is open, the second diaphragm 11
The main valve 8 is acting in the direction of closing by the output amount. The internal pressure of the third pressure chamber 18 is set to the same pressure as the internal pressure _P2 of the tank 1 by the pressure sensitive tube 19, and since this is constant, the pilot valve 20
The gas flow path 16 is closed by this.

In the above state, when the internal pressure P ₂ of the tank 1 drops, the third diaphragm 17 is pushed up and the pilot valve 20 is connected via the connecting means 21.
operates to open the gas passage 16, so that the gas in the second pressure chamber 14 is gradually discharged to the outlet 6 side and enters the tank 1. Pressure gas is supplied into the second pressure chamber 14 from the inlet 5, and the needle valve 15
The amount of supply is regulated because it is
Therefore, the pressure within the second pressure chamber 14 gradually decreases. Therefore, the first pressure chamber 12 and the second pressure chamber 1
4, the main valve 8 gradually moves to the right in FIG. 2, and the communication passage 7 is opened and the inlet 5 and outlet 6 communicate with each other, making it possible to supply a large amount of pressurized gas.

(Embodiment) An embodiment of the seal gas pressure regulating valve device in a tank according to the present invention will be described based on the drawings.The seal gas pressure regulating valve device 3 of the present invention, as shown in FIG. It is arranged in a conduit 2 that connects a tank 1 that stores a liquid or the like and a pressurized gas supply device (not shown) that is to supply sealing pressurized gas at a constant pressure P ₁ into the tank 1 . In addition, in FIG. 1, 1A is a breather valve (breathing valve) of the tank 1.

The seal gas pressure regulating valve device 3 has the following configuration. A main valve 8 is disposed in a valve chamber 81 in a valve housing 4 having an inlet 5 and an outlet 6 for seal gas, and opens and closes a communication passage 7 on the inlet 5 side and the outlet 6 side. Main valve 8 valve lever 9
A first diaphragm 10 and a second diaphragm 11 are attached at a predetermined interval, and the first
A first pressure chamber 12 is formed between the second diaphragms 10 and 11. Seal gas is supplied into the first pressure chamber 12 from the inlet 5 side through the common inflow path 31 and via the bypass 13.
The outside of the chamber 1 is an empty chamber 22 open to the atmosphere. A second pressure chamber 14 is defined by the first diaphragm 10, and a seal is inserted into the second pressure chamber 14 from the inlet 5 side through the common inflow path 31 via the needle valve 15. Gas is now being supplied. Second pressure chamber 14
A gas flow path 16 is formed in which gas flows out to the outlet 6 side, and a pilot valve 20 is provided to open and close this.

A third diaphragm 17 is located at the bottom of the valve housing 4.
A third pressure chamber 18 is provided, and the seal gas in the tank 1 flows into this via a pressure sensitive tube 19. The chamber 23 outside the third diaphragm 17 (lower part in the drawing) is open to the atmosphere, but the third diaphragm 17 maintains the steady state tank internal pressure P ₂ , that is,
It is always pushed up by a coil spring 24 whose spring load is weaker than the internal pressure P ₂ of the third pressure chamber 18 . This third diaphragm 1
7 and the pilot valve 20 are connected to a connecting means 21.
In the embodiment, a lever 25 having a fulcrum 26 is used.

Therefore, when the tank internal pressure is in a steady state, the third diaphragm 17 is pushed down and the pilot valve 20 closes the gas passage 16, but when the tank internal pressure drops, the third pressure chamber 1
As the internal pressure of 8 decreases, the third diaphragm 1
7 is pushed up, the pilot valve 20 is opened via the lever 24, and the gas passage 16 is opened.

Note that the pressure receiving area of the first diaphragm 10 is larger than that of the second diaphragm 11, and when the first pressure chamber 12 and the second pressure chamber 14 have the same pressure, the main valve 8 However, in order to more accurately close the main valve 8, the main valve 8 is biased in the closing direction by a coil spring 27. This coil spring 27
is a spring load that is weaker than the gas pressure P ₁ introduced into the first pressure chamber 12 . In addition, in the figure, 2
8 is a plug, 29 is a set screw, 30 is a valve lever guide, 32, 33 is a diaphragm plate, 34,
35 is a diaphragm cover, and 36 is an adjustment bolt for adjusting the spring load of the coil spring 24.

(Effect of the invention) According to the seal gas pressure regulating valve device in a tank according to the invention, when the internal pressure of the tank is constant, the first pressure chamber and the second pressure chamber are at the same pressure. The main valve is closed, and the internal pressure in the third pressure chamber is maintained at the same pressure as the tank internal pressure by the pressure-sensitive tube, so the gas flow path is closed by the pilot valve, but the internal pressure in the tank is When the pressure drops, the third diaphragm is actuated and the pilot valve is actuated via the connecting means to open the gas flow path, so the gas pressure in the second pressure chamber drops and the main valve is opened, allowing the pressure gas to flow out. A large amount of gas can be supplied to the tank, and the supply of seal gas is stopped when the pressure inside the tank reaches a constant level.

In this way, it can operate accurately and supply gas as the seal gas pressure in the tank decreases.
Moreover, the response time is extremely good, with the response time of the device of this embodiment being 0.5 seconds, compared to the pressure regulating valve device shown in Japanese Patent Application Laid-Open No. 55-43624, which we had proposed earlier. The response speed is significantly improved, and the tank internal pressure can be kept constant quickly. Furthermore, it is simple in structure and can be installed, disassembled, inspected, adjusted, etc. without removing piping, etc., and is most suitable as a valve device for adjusting seal gas pressure in a tank.

[Brief explanation of the drawing]

The drawings show an embodiment of the seal gas pressure regulating valve device in a tank according to the present invention, in which FIG. 1 is a layout diagram, FIG. 2 is a vertical cross-sectional side view, FIG. It is a side view of the whole. DESCRIPTION OF SYMBOLS 1...Tank, 2...Pipeline, 3...Seal gas pressure regulating valve device, 5...Inlet, 6...Outlet, 7...
...Communication path, 8...Main valve, 9...Valve rod, 1
0...First diaphragm, 11...Second diaphragm, 12...First pressure chamber, 13...Bypass, 14...Second pressure chamber, 15...Needle valve, 16...Gas flow 17... third diaphragm, 18... third pressure chamber, 19... pressure sensitive tube,
20... Pilot valve, 21... Connection means.

Claims (1)

[Scope of Claim for Utility Model Registration] A seal gas pressure regulating valve device for controlling seal gas to be supplied into a tank, comprising a main valve for opening and closing a communication passage between the inlet and outlet sides of the seal gas. , formed between first and second diaphragms attached to the valve rod of the main valve and the first and second diaphragms, and sealing gas is supplied from the inlet side via a bypass. a first pressure chamber,
a second pressure chamber partitioned by the first diaphragm and to which sealing gas is supplied from the inlet side via a needle valve; and a second pressure chamber between the second pressure chamber and the outlet side. The tank is defined by a gas flow path, a pilot valve arranged to open and close the gas flow path, and a third diaphragm, so that the seal gas in the tank flows through the pressure sensitive tube. A third pressure chamber connected to the third pressure chamber, the third diaphragm, and the pilot valve are connected, and the third diaphragm is operated as the pressure in the third pressure chamber decreases to close the gas flow path. and connecting means adapted to open the pilot valve.