RU2234118C2 - Universal pressure controller - Google Patents

Abstract

FIELD: apparatuses for controlling and stabilizing pressure and flow rate of any gaseous medium except aggressive one, particularly flow rate of natural gas fed to user.

SUBSTANCE: pressure controller includes mounted on pipeline axial valve with elastic shutter adjoined with distributing system; two pilot regulators and flow rate indicator mounted into pipeline. Each regulator includes spring mechanism and regulating unit. Pilot regulator setting target flow rate is provided with comparison chamber arranged between spring mechanism and regulating unit. Said chamber is divided by means of additional membranes by two cavities. Each cavity is communicated with outlet flow rate indicator.

EFFECT: enlarged functional possibilities, maximum degree of unification with known types of articles.

1 dwg

Description

The claimed invention relates to gas distribution and can be used to regulate (stabilize) pressure, regulate (stabilize) and limit the flow of any gaseous medium, except aggressive, in gas, oil and other industries. For example, to regulate, stabilize pressure and flow, as well as to limit the flow of natural gas supplied to the consumer from gas distribution stations, gas control points, gas reduction plants.

A known flow control system (US patent 6152162 A, IPC G 05 D 7/06) containing a flow limiter installed in a pipeline with a fluid medium, pressure sensors installed above and below the flow limiter, a pressure regulator. The pressure regulator, depending on the magnitude of the pressure drop generated by the flow limiter, maintains a pressure in the pipeline corresponding to a given flow rate. The system can regulate and limit the flow, regulate the pressure.

The disadvantage of this technical solution is the need to select a flow limiter corresponding to the throughput of the pipeline. This will limit the use of the system at gas distribution facilities with a very wide range of flow rates.

According to its functional purpose, the well-known “Real-time control and correction method for a wide-range gas flow control system” can be considered as an analogue (US patent 6119710 A, IPC G 05 D 7/06).

The gas flow control system comprises a gas pipeline that sequentially connects an inlet valve, a calibration chamber, a flow restrictor, and an outlet valve. The calibration chamber contains pressure and temperature sensors. Pressure sensors are also located before and after the flow restrictor. The system also contains a mass flow calculator, a master and regulating device. In the process, according to the readings of the sensors and the pressure drop at the flow limiter, the mass flow rate is periodically measured, which is then controlled by changing the pressure until the desired value of the corresponding setting is reached.

This method allows you to accurately maintain a given flow rate, allows you to adjust (if necessary) the pressure, but is unreasonably complex and expensive. This is its main drawback, which limits its application. The disadvantages should also include the presence of a flow limiter, which should be selected for each pipeline.

The closest analogue (prototype) of the claimed invention is an axial type pressure regulator RDO-1 (Operation manual RDO-1, approved 12.11.97, ZI.2 501.000 RE. Developer and manufacturer of products LLC Gazpriboravtomatika LLC). RDO-1 contains an axial valve mounted on the pipeline with an elastic shutter coupled to the distributor, and a pilot regulator that includes a spring mechanism and a control unit, the first inlet of which is connected to the outlet of the distributor, and the second inlet is connected to the pipeline from the low pressure side.

The RDO-1 regulator provides only maintaining at a given level the value of the outlet pressure. In cases where not only pressure maintenance is required, but also the regulation and limitation of the gas flow supplied to the consumer, this regulator is not applicable.

The technical task of the invention is to expand the functionality of the regulator, namely improving the accuracy of regulation and pressure stabilization, as well as regulation (stabilization) and limiting the flow of gas supplied to the consumer.

The stated technical problem is achieved due to the fact that the pressure regulator is universal (hereinafter referred to as the Regulator), contains an axial valve mounted on the pipeline with an elastic valve, coupled to the distributor, and a pilot regulator, including a spring mechanism and a control unit. In this case, the first inlet of the pilot regulator is in communication with the outlet of the distributor, and the second inlet - with the pipeline from the low pressure side. An additional flow indicator is installed in the regulator, mounted in the pipeline behind the axial valve with an elastic shutter on the low pressure side of the pipeline, and a second pilot regulator, in which a comparison chamber is made between the spring mechanism and the regulating unit, divided by additional membranes into two cavities, from of which the cavity adjacent to the control unit is in communication with the output of the flow indicator closest to the axial valve with an elastic shutter, and the cavity adjacent to the spring mechanism, with another their output flow indicator. The output of the second pilot controller is connected to the input of the distributor, and the first input is connected to the output of the first pilot controller.

Comparative analysis with the prototype shows that the inventive regulator is characterized by the presence of an additionally introduced flow indicator and a second pilot regulator, in which a comparison chamber is made between the spring mechanism and the regulating unit, divided by additional membranes into two cavities, each of which is connected with the corresponding output of the flow indicator.

Thus, the set of essential features of the claimed technical solution, due to the presence of new features, provides a technical result, expressed in expanding the functionality of the regulator. The constructive solution of the regulator makes it possible, while maintaining the pressure control function, to increase the accuracy of pressure stabilization and to provide regulation (stabilization) and limit the flow of gas supplied to the consumer, while ensuring maximum unification with commercially available regulators.

These essential features in the aggregate, characterizing the essence of the claimed technical solution, are not currently known for regulatory devices. The analogue, characterized by the identity of all the essential features of the claimed invention, was not found during the studies, which allows us to conclude that the claimed technical solution meets the criterion of “Novelty”.

The essential features of the claimed invention cannot be represented as a combination identified from known solutions with the implementation in the form of distinctive features to achieve a technical result, from which we can conclude that the criterion of “Inventive step” is met.

Due to the fact that the constructive solution of the claimed regulator is intended for use within the real gas distribution system and has been tested to achieve the claimed technical result, the alleged invention meets the criterion of "Industrial applicability".

The drawing shows a structural diagram of a universal pressure regulator.

The regulator contains an axial valve mounted on the pipeline 1 with an elastic shutter 2, hermetically connected to the distributor 3, pilot regulators 4 and 5, each of which includes a spring mechanism 6 and a control unit 7. The first input “BX1” of the pilot regulator 4 is communicated via communication line 8 with the output “OUT” of the distributor 3. The second input “BX2” of the pilot regulator 4 through the communication line 9 through the throttle 10 with a pressure gauge 11 is connected via valve 12 to the pipeline 1 from the low pressure side. The “EXIT” output of the pilot controller 4 via a communication line 13 is connected to the first input “BX1” of the pilot controller 5, in which a comparison chamber 14 is made between the spring mechanism 6 and the control unit 7, which is divided into two cavities using membranes 15, 16, 17 A and B. The cavity A adjacent through the membrane 15 to the control unit 5 is communicated via a communication line 18 through a valve 19 with a flow indicator 20 located in the pipeline 1 behind the axial valve with an elastic shutter 2 from the low pressure side. The cavity B in contact through the membrane 17 with the spring mechanism 6 is communicated via a communication line 21 through a valve 22 with a second output “OUT2” of the flow indicator 20. The output “OUT” of the pilot regulator 5 is connected via input 23 to the input “IN” of the distributor 3. The control unit 7 in the pilot controllers 4 and 5 includes a nozzle 24 in contact with the valve 25 suspended on the membranes 15 and 26. Moreover, in the pilot controller 5, the membranes 15, 16 and 17 are rigidly interconnected.

The controller has three operating modes:

- regulation (stabilization) of pressure;

- regulation (stabilization) of the flow;

- flow restriction.

1. Work in the mode "Regulation (stabilization) of pressure".

The reducing gas from the pipeline 1 enters the axial valve with an elastic shutter 2. Through the distributor 3, part of this gas is transmitted via the communication line 8 to the first input “BX1” of the control unit 7 of the pilot controller 4 and then through the communication line 13 to the input “BX1” of the pilot controller 5 and further from the “EXIT” output of the latter via the communication line 23 to the “ВХ” input of the distributor 3. This gas passes sequentially through the nozzle 24 in contact with the valve 25 of the pilot regulators 4 and 5.

The output pressure setting is set by the spring mechanism 6 of the pilot regulator 4. Stabilization of the output pressure is achieved by the fact that the pressure deviation is transmitted through the valve 12 via a communication line 9 with a throttle 10 to the second input “BX2” of the control unit 7 of the pilot regulator 4, which causes a change in the gap between the valve 25, suspended on the membranes 15 and 26, and the nozzle 24. This leads to a change in flow rate through the pilot regulator 4 and, accordingly, through the axial valve with an elastic shutter 2. Moreover, a decrease in output pressure increases the flow through an axial valve with elastic shutter 2 and vice versa, which leads to the downstream pressure recovery. In this mode, the pilot regulator 4 sets the maximum allowable outlet pressure.

2. Work in the mode “Regulation (stabilization) of the flow”.

The required flow rate is set according to the flowmeter device of the object of operation (not shown in the drawing) by the spring mechanism 6 of the pilot regulator 5. The stabilization of the flow rate is achieved by the fact that the flow deviation is converted by the flow rate indicator 20 to the pressure drop, which is transmitted through the valves 19 and 22 through the communication lines 18, respectively and 21 in the cavity A and B of the comparison chamber 14 of the pilot regulator 5, as a result of which, on the membrane 16, which is rigidly connected with the membranes 15 and 17, a force appears that counteracts the force of the spring fur nizma 6 of this pilot regulator.

3. Work in the "Limitation of flow" mode.

In this mode, the gas flows in the same way as in the two previous cases. Pilot regulator 4 sets the required output pressure, which is recorded by pressure gauge 11. In the event of unstable operation of the regulator, fluctuations in the output pressure are eliminated by the throttle 10. The value of the limited flow rate is set by the spring mechanism 6 of the pilot regulator 5. The regulator acts as a gas pressure regulator to the specified flow rate. With increasing gas sampling by the consumer, the pressure drop on the flow indicator 20 increases. This line is transmitted through the communication lines 18 and 21 to the cavities A and B of the comparison chamber 14 of the pilot regulator 5, as a result, a force is created on the membrane 16 that counteracts the force of the spring mechanism 6. The gap between the valve 25 and the nozzle 24 of the pilot regulator 5 is reduced. This leads to an increase in pressure in the communication lines 13 and 8 and ultimately to the closure of an axial valve with an elastic shutter 2, the pressure of the reduced gas behind which decreases.

Thus, the claimed invention provides a technical result, expressed in expanding the functionality of the regulator, namely the fulfillment of the functions of regulation (stabilization) of pressure, regulation (stabilization) and limitation of gas flow. At the same time, the design solution incorporated in the regulator provides maximum unification with commercially available regulators.

Claims (1)

A universal pressure regulator containing an axial valve mounted on the pipeline with an elastic shutter docked with a distributor, and a pilot regulator including a spring mechanism and a control unit, the first inlet of which is connected to the outlet of the distributor, and the second inlet to the pipeline from the low pressure side, characterized in that a flow indicator is additionally introduced into the regulator, mounted in the pipeline behind the axial valve with an elastic shutter on the low pressure side, and a second pilot regulator, ne the output of which is connected to the output of the first pilot regulator, and the output is communicated with the input of the distributor, and in the second pilot regulator, a comparison chamber is made between the spring mechanism and the regulating unit, divided by additional membranes into two cavities, of which the cavity adjacent to the regulating unit, communicated with the output of the flow indicator closest to the axial valve with an elastic shutter, and the cavity adjacent to the spring mechanism, with another output of the flow indicator.