SU577510A1 - Device for controlling inhibitor flow - Google Patents

Description

a rod 8 connected to the contacts of the first and second switches 9 and 10. The switch 9 has a normally closed contact 11 and a normally open contact 12.

The driver cavity / is connected to the master valve 13 installed on the outlet 14 of the pulse lines 3. In the LINE of the supply of the inhibitor 15, an electric control valve 16 is installed with control inputs 17 and 18. The control input 17 is connected via the first time relay 19 to the first switch 9 and through time relay contact 20 with control valve 13. Control input 18 is connected through contact 21 to a second time relay 22, to the electrical control circuit of which contact 1 of the first switch 9 connected via a rod 8 from the actuator is connected Tiu 6. The rod 8 of the driver cavity 7 is connected via the second switch 10 to the driver valve 13.

The device works as follows.

In the normal process mode, when the gas flow rate corresponds to 34 (the output of the flow sensor 1.aza 1 is connected to the executive cavity 6 directly, and to the reference cavity 7 through the open positive short-time pulse, the soaking valve 13. At the same time, the diaphragm 5 is in balance, and the switches 9 and 10. Disconnected. Contact switch 10 and contact 12 of first switch 9 are open, and contact 11 of switch 9 is closed. Second time relay 22 is turned on. By switch 15, the inhibitor is applied to line 2, the number of which is the degree of opening zlektroupravl emogo valve 16. In the initial position it maximally open.

If the gas flow through line 2 has not changed (i.e. there is no hydrate formation) for a predetermined time, time relay 22 closes contact 21, as a result of which a signal is sent to control input 18 of valve 16. The supply of inhibitor decreases in this case until hydrate formation is detected / as indicated by the output signal of gas flow sensor 1. A decrease in gas flow leads to a decrease in pressure in the executive cavity 6, the equilibrium of the diaphragm 5 is disturbed, deflected, it moves the stem B, the output the end of which closes the contact 12 and opens the contact 11 of the switch 9. As a result, the second time relay 22 is turned off and the first time relay l is turned on to the control input 17 of the valve 16 is also given a signal that the inhibition is applied torus through valve 16 is increased to

until the hydrating situation is resolved and the equilibrium of the diaphragm 5 is reestablished. After this, contact 12 is opened, the first time relay 19 and control input 17 of valve 16 are turned off, contact 11 is closed and the second time relay 22 is turned on, repeat the operation cycle described above. .

Usually gas transportation

10 is associated with the necessity of forcibly regulating the gas supply in connection with a variable gas consumption value. As a result, the gas flow rate and, consequently, the output signal of the gas flow sensor 1 may vary both upwards and downwards, regardless of the process of hydrate formation.

As the gas flow rate increases, the pressure in the executive cavity 6 increases, the diaphragm 5 with the rod 8 moves to the right. The stem end of the valve B. closes the contact of the switch 10 and turns on the valve 16. A pressure equal to the output signal of the gas flow sensor 1 is supplied to the driver 5 of the mechanical converter 4 by the outlet 14, the equilibrium of the diaphragm 5 is restored, the contact of the first

0 switch 9 opens.

With a forced decrease in gas flow, the pressure in the executive cavity 6 decreases, the diaphragm 5, deflection, moves the rod 8, the end

5 which closes contact 12 and opens contact 11 of the first switch 9. The first time relay 19 is turned on, adjusted for a time delay exceeding the time of hydrate destruction. But in this case there are no hydrates, so the first time relay 19 will be turned on until the moment when the contact 20 trips. At that, the valve 13 is turned on and pressure equal to the new output signal of the gas flow sensor 1 is supplied to the master cavity 7 of the mechanical transducer 5 of pressure bodies 4 As a result, the equilibrium of the diaphragm 5 is restored, leading to the switching of the contacts 11 and 12 of the first switch 9 and the restoration of the initial operation cycle of the device.

Thus, the device reacts to the hydrate formation process and acts on it in the early stage of hydrate formation, thereby distinguishing the situations in which gas consumption decreases as a result of forced reutilization and due to hydrate formation. This makes it possible to increase the economic efficiency of the process by reducing the costly consumption of the inhibitory-hydrate formation mountain.

Claims (2)

1. Patent number 3644107, cl.48-190 1970. 2.Kiiko E.K. et al. Hydrate Formation and Corrosion Inhibitor Input System, Gas Industry, K 7, 1973.