RU123887U1 - PRESSURE WAVE SMOOTHING SYSTEM - Google Patents

Abstract

1. The pressure wave smoothing system (SSVD), which has a modular design and includes three SSVD valves, which discharge oil from the receiving line of the pumping pumping station (LPS) in the event of a rapid increase in pressure, an SSVD backup valve, a separation tank for separating oil transported through the pipeline and antifreeze used to transfer oil pressure from the receiving line of the NPS to the elements of the SSVD, pneumohydraulic accumulators (PGA), a control valve to maintain a preset value of the slew rate in the receiving line of the NPS, a block of manometers for filling with PGA technical nitrogen, monitoring the gas pressure in the PGA and the antifreeze pressure in the SSVD and the means of refueling with antifreeze SSVD for filling with antifreeze the working volumes of SSVD elements and checking the tightness of hydraulic lines. 2. The pressure wave smoothing system according to claim 1, characterized in that to control the increase in pressure in the receiving line of the NPS control valve is made with the possibility of changing its flow area. The pressure wave smoothing system according to claim 2, characterized in that the pressure rise rate is regulated in the range from 0.01 to 0.06 MPa / s. The pressure wave smoothing system according to claim 3, characterized in that the SSVD valves are capable of being triggered by a pressure jump in the range from 0.1 to 0.4 MPa at a pressure rise rate exceeding the tuning value. The pressure wave smoothing system according to claim 4, characterized in that the SSVD valves are capable of being triggered when the pressure jump differs from the tuning value by no more than 0.02 MPa. 6. The pressure wave smoothing system according to claim 1, I distinguish

Description

The utility model relates to the field of oil transportation through oil pipelines, in particular, pressure wave smoothing systems for oil pipelines.

The pressure wave smoothing system (SSVD) is designed to protect the linear section of the main oil pipeline located in front of the pumping pumping station (LPS) from increasing pressure caused by spontaneous or unauthorized closing of the shut-off and control valves elements of the LPS or stopping of pumping units at the LPS during oil transportation.

A known system for smoothing pressure waves of the group of companies "IMS" (IMS) (http://www.imsholding.ru/sistemy_sglazhivanija_voln_davlenija). The equipment includes control valves, a valve control system and an SSVD condition monitoring system installed on a single frame. A set of equipment may also include a block box (building) with all the necessary life support systems, monitoring and signaling. The principle of operation of the system is based on the timely discharge of the working fluid through the control (waste) valves, the flow rate through which is controlled and adjusted by the control system.

SSVD is equipped with a valve actuation control system with a signal output to the dispatcher's control panel and is made on the basis of a control valve developed by the IMS group of companies (RF patent No. 69955).

In addition, pneumatic-hydraulic accumulators (PGA) can be installed in the SSVD, designed to damp fluid pressure pulsations in pipelines. Alternatively, you can use a pneumatic-hydraulic membrane battery, disclosed in the patent of the Russian Federation No. 2270370 (published on 02.20.2006; IPC F15B 1/24, F16L 55/04).

As the closest analogue of the considered technical solution, a device for absorbing hydraulic shocks in a pipeline according to the RF patent No. 2193134 (published on November 20, 2002; IPC F16L 55/045) can be selected. The device includes a pumping unit, suction, discharge and bypass pipelines, starting and shut-off valves. It is also equipped with an automatic flow switch installed after the pump, connecting the discharge pipe and the bypass pipes. The automatic flow switch is made in the form of a tee, along the main axis of which are saddles mirrored to each other, the passage channels of which are respectively connected with the cavities of the bypass pipe and the pump discharge pipe. In addition, shut-off elements are placed in the automatic flow switch, mirrored to each other on a rod with a degree of freedom along the main axis. The locking element on the pump side is spring loaded. The bypass pipe is inclined to the suction pipe at an acute angle diverging towards the automatic flow switch.

The objective of this utility model is to simplify the design of known SSDS with a simultaneous increase in reliability.

The problem is solved in that the pressure wave smoothing system, which has a modular design, includes three SSVD valves that discharge oil from the receiving line of the pumping pumping station (LPS) in the event of a rapid increase in pressure, and one backup SSVD valve. The system also includes a separation tank for separating oil and antifreeze transported through the pipeline, used to transfer oil pressure from the receiving line of the LPS to the elements of the SSVD; PGA; a control valve to maintain the set value of the pressure rise rate in the receiving line of the NPS; a block of manometers for refueling with PGA technical nitrogen, monitoring the gas pressure in the PHA and the antifreeze pressure in the SSVD; means of refueling with antifreeze SSVD for filling with antifreeze the working volumes of elements of SSVD and checking the tightness of hydraulic lines.

The pressure gauge block may consist of pressure gauges for measuring gas pressure in a PHA, a pressure gauge for measuring antifreeze pressure and a safety valve.

To control the increase in pressure in the receiving line of the NPS control valve can be made with the possibility of changing its flow area, providing a rate of increase in pressure in the desired range.

SSVD valves can be made with the possibility of actuation during a pressure jump in a given range at a pressure rise rate exceeding a predetermined value. Moreover, it is preferable if the SSVD valves are triggered by a pressure jump that differs from the tuning value by no more than a predetermined value.

Next, the device is explained in more detail with reference to figure 1, which shows an embodiment of a system for smoothing pressure waves according to a utility model. The upper figure shows the side view of the SSDS, the lower figure shows the top view of the SSDS.

SSDS has a modular design. Its main functional element is the SSVD valve (1), which discharges oil from the receiving line of the LPS in the event of a rapid increase in pressure characteristic of a hydraulic shock in the main oil pipeline. The system is designed to work when connecting three valves (1) SSVD. In addition, one backup valve (1) of the SSVD is installed, which is connected to work if one of the standard valves (1) of the SSVD fails.

The increase in pressure in the receiving line of the NPS is accompanied by the flow of antifreeze from the separation tank (2) into the fluid cavities of the PHA (3) through the variable passage section of the control valve (4), which leads to an increase in pressure in the control line of the SSVD.

The separation tank (2) is designed to separate the oil transported through the pipeline, and the antifreeze used to transfer oil pressure from the receiving line of the LPS to the elements of the SSVD.

PHA (3) are intended for accumulation and release of antifreeze energy by compression of technical nitrogen. The media separator is an elastic separator, such as a rubber balloon. During operation of the PHA (3), a change in the antifreeze pressure leads to a corresponding change in the internal volume of the elastic separator in it. In the case when the oil pressure in the pipeline is lower than the pressure in the PHA fluid cavity (3), the elastic separator expands and squeezes the antifreeze from the fluid cavity into the SSVD control line. With the complete displacement of antifreeze from the PHA (3), the rubber balloon is adjacent to its cylindrical body.

Setting the SSVD to maintain the set value of the pressure rise rate is carried out using the control valve (4) by changing the size of its flow area. The position of the shut-off element of the control valve (4) is set in accordance with the required adjustment rate of pressure increase in the oil pipeline.

With a rather slow increase in pressure in the intake line of the NPS, the resulting slight pressure drop between the pressure in the oil supply line to the SSVD valve (1) and the antifreeze pressure is insufficient to open the SSVD valve (1).

With a rapid increase in oil pressure, the valves (1) of the SSVD open almost instantly. The magnitude of this growth rate of pressure increase is determined by the design of the valve and the parameters of the water hammer in the receiving line of the NPS. The process is accompanied by the discharge of oil in the tank capacity of the pumping station and the triggering of flow sensors installed in the oil discharge pipelines behind the valves (1) of the SSVD.

To ensure reliable protection of the linear section of the main oil pipeline located in front of the pumping pumping station (LPS) from pressure increase, it is preferable if the pressure rise rate is regulated in the range from 0.01 to 0.06 MPa / s. In this case, the valves (1) SSVD are configured in such a way that they are triggered by a pressure jump in the range from 0.1 to 0.4 MPa, if the pressure rise rate exceeds the tuning value. In the best embodiment, the specified excess is not more than 0.02 MPa from the tuning value.

Closing the valves (1) SSVD is carried out at a speed necessary to ensure the maintenance of a given rate of increase in pressure in the receiving line of the NPS.

In addition, the SSVD contains a block (5) of pressure gauges intended for refueling the PHA (3) with technical nitrogen, monitoring the gas pressure in the PHA (3) and the antifreeze pressure in the SSVD block. The pressure gauges block (5) includes 11 gauges for measuring gas pressure in a PHA (3), a manometer for measuring antifreeze pressure and a safety valve.

The inventive system has a simpler and more reliable design in comparison with the closest analogue. The technical result is to increase reliability, simplify the design, provide reliable protection of the linear section of the main pipeline from increasing pressure.

Claims (6)

1. The pressure wave smoothing system (SSVD), which has a modular design and includes three SSVD valves, which discharge oil from the receiving line of the pumping pumping station (LPS) in the event of a rapid increase in pressure, an SSVD backup valve, a separation tank for separating oil transported through the pipeline and antifreeze used to transfer oil pressure from the receiving line of the NPS to the elements of the SSVD, pneumohydraulic accumulators (PGA), a control valve to maintain a preset value of the slew rate in the receiving line of the NPS, a block of manometers for refueling with technical nitrogen of the PHA, monitoring the gas pressure in the PHA and the pressure of the antifreeze in the SSVD and the means of refueling with the antifreeze SSVD to fill the antifreeze with the working volumes of the SSVD elements and checking the tightness of the hydraulic lines. 2. The system of smoothing pressure waves according to claim 1, characterized in that to control the increase in pressure in the receiving line of the NPS control valve made with the possibility of changing its bore. 3. The pressure wave smoothing system according to claim 2, characterized in that the pressure rise rate is regulated in the range from 0.01 to 0.06 MPa / s. 4. The pressure wave smoothing system according to claim 3, characterized in that the SSVD valves are operable to act upon a pressure jump in the range from 0.1 to 0.4 MPa at a pressure rise rate exceeding the tuning value. 5. The pressure wave smoothing system according to claim 4, characterized in that the SSVD valves are capable of actuation when the pressure jump differs from the tuning value by no more than 0.02 MPa. 6. The pressure wave smoothing system according to claim 1, characterized in that the pressure gauge block includes manometers for measuring gas pressure in a PHA, a manometer for measuring antifreeze pressure and a safety valve.

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