OPTIMIZED CONTROL OF OILFIELD SEPARATOR LEVEL AND DUMP VALVES

Abstract

A dump valve system controls the level of a liquid inside a vessel that includes a liquid discharge. The dump valve system includes an automatic dump valve connected downstream from the liquid discharge and configured to adjust the flow rate of the liquid through the liquid discharge, a float inside the vessel, a float arm connected to the float, and an inclinometer attached to the float arm and configured to output an angular disposition signal representative of the angular disposition of the float arm. The dump valve system can also include a flow meter configured to measure the flow rate of liquids discharged from the automatic dump valve and output a flow rate signal representative of the measured flow rate. A control module is configured to adjust the operation of the automatic dump valve in response to the flow rate signal and the angular disposition signal.

Claims

1. A dump valve system for controlling the level of a liquid inside a vessel that includes a liquid discharge, the dump valve system comprising: an automatic dump valve connected downstream from the liquid discharge and configured to adjust the flow rate of the liquid through the liquid discharge; a float inside the vessel; a float arm connected to the float; an inclinometer attached to the float arm and configured to output an angular disposition signal representative of the angular disposition of the float arm; and a control module configured to adjust the operation of the automatic dump valve in response to the angular disposition signal.

2. The dump valve system of claim 1, further comprising a flow meter configured to measure the flow rate of liquids discharged from the automatic dump valve and output a flow rate signal representative of the measured flow rate.

3. The dump valve system of claim 2, wherein the control module is configured to adjust the operation of the automatic dump valve based on the flow rate signal.

4. The dump valve system of claim 1, wherein the control module is configured to adjust the automatic dump valve to change a dump rate of fluids passing through the automatic dump valve based on the angular disposition signal from the inclinometer.

5. The dump valve system of claim 1 further comprising a housing attached to the vessel, wherein the float arm extends through the vessel into the housing.

6. The dump valve system of claim 5 further comprising a pivot inside the housing.

7. The dump valve system of claim 6, wherein the float arm is connected to the pivot such that the float arm comprises: a proximal portion between the pivot and the float; and a distal portion outboard of the pivot.

8. The dump valve system of claim 7, wherein the inclinometer is located on the proximal portion of the float arm.

9. The dump valve system of claim 7, wherein the inclinometer is located on the distal portion of the float arm.

10. A dump valve system for controlling the level of a liquid inside a vessel that includes a liquid discharge, the dump valve system comprising: an automatic dump valve connected downstream from the liquid discharge and configured to adjust the flow rate of the liquid through the liquid discharge; a float inside the vessel; a float arm connected to the float; flow meter configured to measure the flow rate of liquids discharged from the automatic dump valve and output a flow rate signal representative of the measured flow rate; and a control module configured to adjust the operation of the automatic dump valve in response to the flow rate signal.

11. The dump valve system of claim 10, further comprising an inclinometer attached to the float arm and configured to output an angular disposition signal representative of the angular disposition of the float arm.

12. The dump valve system of claim 11, wherein the control module is configured to adjust the operation of the automatic dump valve based on the angular disposition signal.

13. The dump valve system of claim 11, wherein the control module is configured to adjust the automatic dump valve to change a dump rate of fluids passing through the automatic dump valve based on the angular disposition signal from the inclinometer.

14. A dump valve system for controlling the level of a liquid inside a vessel that includes a liquid discharge, the dump valve system comprising: an automatic dump valve connected downstream from the liquid discharge and configured to adjust the flow rate of the liquid through the liquid discharge; a float inside the vessel; a float arm connected to the float; an inclinometer attached to the float arm and configured to output an angular disposition signal representative of the angular disposition of the float arm; flow meter configured to measure the flow rate of liquids discharged from the automatic dump valve and output a flow rate signal representative of the measured flow rate; and a control module configured to adjust the operation of the automatic dump valve in response to the flow rate signal and the angular disposition signal.

15. The dump valve system of claim 14 further comprising a housing attached to the vessel, wherein the float arm extends through the vessel into the housing.

16. The dump valve system of claim 15 further comprising a pivot inside the housing.

17. The dump valve system of claim 16, wherein the float arm is connected to the pivot such that the float arm comprises: a proximal portion between the pivot and the float; and a distal portion outboard of the pivot.

18. The dump valve system of claim 17, wherein the inclinometer is located on the proximal portion of the float arm.

19. The dump valve system of claim 17, wherein the inclinometer is located on the distal portion of the float arm.

20. The dump valve system of claim 15, wherein the float arm comprises a plurality of interconnected segments.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0016] FIG. 1A is a cross-sectional depiction of a three phase separator with a dump valve system operating at a design dump rate.

[0017] FIG. 1B is a close-up view of the dump valve system from FIG. 1A.

[0018] FIG. 2A is a cross-sectional depiction of a three phase separator with the dump valve system decreasing the dump rate in response to a reduction in the level of crude oil in the separator.

[0019] FIG. 2B is a close-up view of the dump valve system from FIG. 2A.

[0020] FIG. 3A is a cross-sectional depiction of a three phase separator with the dump valve system increasing the dump rate in response to an increase in the level of crude oil in the separator.

[0021] FIG. 3B is a close-up view of the dump valve system from FIG. 3A.

DETAILED DESCRIPTION

[0022] Turning first to FIG. 1A, shown therein is a vessel 100 that is a three phase separator configured to separate a multiphase feed stream 102 from a well (not shown). The vessel 100 includes an inlet 104, a gas discharge 106, a water discharge 108 and an oil discharge 110. In accordance with well-established petroleum fluid separation mechanics, the multiphase feed stream 102 is injected into the separator 100 under pressure, where the constituent components separate according to their relative densities. The gas is discharged through the gas discharge 106, the water is discharged from the water discharge 108, and the liquid petroleum products (e.g., crude oil) are discharged through the oil discharge 110.

[0023] A dump valve system 112 is used to control the level of the liquid petroleum products in the vessel 100. The dump valve system 112 includes a float 114, a float arm 116, a housing 118, a pivot 120, an inclinometer 122, a control module 124 and an automatic dump valve 126. In some embodiments, the flow meter 128 is connected between the automatic dump valve 126 and the oil discharge 110. In this configuration, the dump valve 126 regulates the flow of petroleum liquids released through the oil discharge 110, while maintaining the pressure of the fluids as they pass through the flow meter 128. The flow meter 128 is configured to measure the flow rate of liquid petroleum products discharged through the oil discharge 110 and output a flow rate signal representative of the flow rate of fluids passing through the flow meter 128. The control module 124 can include electronic control systems that are adapted to adjust the operation of the automatic dump valve 126 according to a control scheme in response to one or more inputs from the inclinometer 122 and flow meter 128.

[0024] In exemplary embodiments, the float 114 is designed and weighted to rest at the interface of the liquid petroleum products and the gaseous petroleum products inside the vessel 100. As the level of the liquid petroleum products drops in the vessel 100, the float 114 also drops (as depicted in FIG. 2A). As the level of the liquid petroleum products rises inside the vessel 100, the float 114 also rises (as depicted in FIG. 3A).

[0025] The float 114 is connected to the float arm 116, which extends through the wall of the vessel 100 into the housing 118. The float arm 116 can be connected to and through the pivot 120 inside the housing 118. In this way, the float arm 116 includes a proximal portion 130 between the pivot 120 and the float 114 and a distal portion 132 outboard of the pivot 120. As the float 114 rises inside the vessel 100, the distal portion 132 of the float arm 116 drops beyond the pivot 120. Conversely, as the float 114 drops inside the vessel 110, the distal portion 132 of the float arm 116 raises beyond the pivot 120. In some embodiments, the float arm 116 is a unitary member that is configured to rock back and forth on the pivot 120. In other embodiments, the float arm 116 includes separated proximal and distal portions 130, 132 and the pivot 120 includes a shaft that transfers the rotation of the proximal portion 130 to the distal portion 132. In yet other embodiments, the float arm 116 includes multiple interconnected segments such that movement of the float arm segment attached to the float 114 causes the portion of the float arm with the inclinometer 122 to move in the same or opposite direction.

[0026] The inclinometer 122 can be attached to the proximal portion 130 or distal portion 132 of the float arm 116. The inclinometer 122 is configured to evaluate the angle of the float arm 116, e.g., with reference to a horizontal or other baseline reading and output an angular disposition signal. In exemplary embodiments, the angular disposition signal is an electric signal, which may be analog or digital. For example, in FIGS. 1A and 1B, the inclinometer 122 could be configured to output an angular disposition signal indicating that the float arm 116 is in a substantially horizontal position. In contrast, the inclinometer 122 might indicate that the float arm 116 is declined at an angle of about-20 degrees in FIGS. 2A and 2B, and inclined at an angle of about 45 degrees in FIGS. 3A and 3B.

[0027] The control module 124 can be located on the vessel 100, on the housing 118, on the float arm 116, on the automatic dump valve 126 (as shown), or elsewhere in an operative position to efficiently control the operation of the automatic dump valve 126. The control module 124 is programmed to process the angular disposition signal from the inclinometer 122 and the flow rate signal from the flow meter 128 and then output a control signal to adjust the adjust the position of the automatic dump valve 126 within a range of positions from fully open to fully closed to intelligently control the level of the petroleum fluids in the vessel 100. The automatic dump valve 126 can be an electrically or pneumatically actuated valve. If the automatic dump valve 126 is pneumatically actuated, an intervening pneumatic driver converts the electrical signals from the control module 124 to a pneumatic signal useable by the automatic dump valve 126. The pneumatic driver can be integrated into the control module 124.

[0028] For example, in FIGS. 1A and 1B, the inclinometer 122 indicates that the float arm 116 is relatively level or horizontal, which can be an indication that the level of the liquid petroleum products in the vessel is within an appropriate range. If the output from the flow meter 128 also indicates a flow rate within an appropriate range, the control module 124 is programmed to output a responsive control signal to maintain the automatic dump valve 126 in its current position, which is depicted as partially open in FIGS. 1A and 1B.

[0029] In contrast, if the level of the liquid petroleum products in the vessel 100 decreases as indicated in FIG. 2A, the inclinometer 122 outputs a corresponding angular disposition signal to the control module 124 based on the angular disposition of the float arm 116. Based on this input and the flow rate signal from the flow meter 128, the control module 124 is programmed to output a corrective control signal to partially or completely close the automatic dump valve 126. If the level of fluid inside the vessel 100 does not increase at a sufficient rate based on the feed stream 102, the control module 124 can be programmed to further close the automatic dump valve 126 to further reduce the dump rate through the automatic dump valve 126. Conversely, if the level of the liquid petroleum products in the vessel 100 increases as indicted in FIG. 3A, as reflected by a change in the angular disposition signal output by the inclinometer 122, the control module 124 completely or partially opens the automatic dump valve 126 based on the inputs received from the inclinometer 122 and flow meter 128. Again, if the initial dump rate measured by the flow meter 128 is insufficient given the flow rate of feed stream 102, the control module 124 can further open the automatic dump valve 126 to increase the dump rate to programmed rates or float level proportional rates to accommodate changing conditions in the vessel 100.

[0030] It will be noted that the control module 124 can be configured to adjust the automatic dump valve 126 based on one or both of the output signals generated by the inclinometer 122 and flow meter 128. If, for example, the inclinometer 122 outputs an angular disposition signal indicating that the level of the petroleum liquids in the vessel 100 is acceptable but the flow rate signal produced by the flow meter 128 is outside a desired range, the control module 124 can open or close the automatic dump valve 126 to bring the flow rate of the oil discharge 110 into the desired range. If increasing or decreasing the flow rate through the automatic dump valve 126 affects the level of the petroleum products in the vessel 100, the inclinometer 122 will detect the change in the angular position of the float arm 116 and the control module 124 can send a corrective control signal, as necessary, to the automatic dump valve 126. Thus, in exemplary embodiments, the dump valve system 112 is configured to adjust the operation of the automatic dump valve 126 in response to measurements from one or both of the inclinometer 122 and the flow meter 128.

[0031] Although the dump valve system 112 is depicted in use with a three phase separator, the dump valve system 112 can also be used to control the level of fluids in other vessels, including tank batteries, bulk storage tanks, water tanks, and other vessels in which fluid levels must be maintained by controlling the discharge of fluids from the vessel. Accordingly, the term vessel as used in this disclosure should be construed to cover any vessel in which the dump valve system 112 can be used to control the level of any liquid products inside the vessel 100. It will also be appreciated that a dump valve 126 can be connected to the water discharge 108 and configured for control by the control module 124 with inputs from a dedicated flow meter connected to the water discharge.

[0032] It is to be understood that even though numerous characteristics and advantages of various embodiments of the present invention have been set forth in the foregoing description, together with details of the structure and functions of various embodiments of the invention, this disclosure is illustrative only, and changes may be made in detail, especially in matters of structure and arrangement of parts within the principles of the present invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. It will be appreciated by those skilled in the art that the teachings of the present invention can be applied to other systems without departing from the scope and spirit of the present invention.