RU2178579C2 - System and process for regulating pressure - Google Patents

Abstract

FIELD: pressure control equipment and processes. SUBSTANCE: system includes underground module for controlling pressure inside cartridge receiving flow of high-pressure gas for discharging controlled low pressure gas. Cartridge includes main valve with joined check valves. Check valve has variable setting point changed by instruction from control unit for repeating preliminarily tested consumption curves. EFFECT: combination of modified apparatus with improved control unit arranged in underground modular cartridge. 13 cl, 5 dwg

Description

 The invention relates to a fluid pressure control system using an underground modular cartridge for a fluid pressure regulator (for example, for fuel gas) inside a pipeline.

 In known underground systems, the entire module 110 of the pressure regulator is located inside the underground chamber (see Fig. 1) with the main control devices located inside the module’s housing, so the module can be easily replaced for maintenance and other purposes. The module is accessed through the hatch cover 111. In practice, an underground system piping typically includes an inlet valve, an outlet valve, and a casement type non-return valve outside the module.

 The inlet has a flange 113 (e.g., 150 mm) for connecting to the inlet pipe and the outlet has a flange 115 (e.g., 200 mm) for connecting to the exhaust pipe.

 The underground module includes a filter 116, through which gas passes into the chamber and, therefore, into the replaceable cartridge 112. A pop-up valve 117 is connected in series with the valve 118 of the pressure regulator. In addition, a number of additional elements are provided, including several control valves. The cartridge is pre-assembled, therefore, it is easy to replace, which reduces downtime.

Such a pressure regulator module can usually operate at an inlet pressure of up to 400 kPa and an outlet pressure between 2 and 7.5 kPa with a throughput of up to 8500 m ³ / h. Ventilation pipe 130 provides an appropriate atmospheric pressure point for cartridge 112 and other lines (shown schematically as pipe 131). Box 133 of measuring instruments contains a chart recorder for recording pressures at the inlet and outlet and various control points (for example, to check a pop-up valve).

 To improve the operational efficiency of the system, a timer-controlled actuator can be included in it so that during the night, when consumption is low, various pressures can be set.

 In FIG. 2, such a device is shown with a flap valve 117 not shown for simplicity. The pressure regulator controls the flow pressure of the main valve 118, and the control valve 120 (K1) provides the mounting point for the valve 118. The control is carried out by receiving a pre-regulated gas supply through the regulator 121 (J) before passing through the restrictor pipe 122 and then through the control valve 120 (K1) before passing to the output line (neglecting the additional control regulator 123 (K2)). The gas flows into the control line of the main valve 118 of the regulator near the outlet of the restrictor 122. Any pressure changes perceived by the control valve during its operation lead to high-speed changes in the limiter, creating a Venturi effect, which leads to suction of gas back from the line from the main valve 118 of the regulator pressure. This causes a change in the applied pressure, which counteracts the spring regulating the membrane in the main valve 118 of the regulator, bringing the pressure at the outlet in accordance with a preset value through the control valve 120.

 When using the timer, the additional control regulator 123 (K2) is equipped with a different set point in order to have a different set level of consumption, for example the level during the night. In this case, it is required to provide a timer device 135 with a cooperating valve, which is connected to an additional control regulator 123 through a fluid line.

 The present invention is the creation of a modified device with more advanced control that meets the requirements, but located in an underground modular cartridge.

 The technical result is achieved by means of a fluid pressure control system comprising a replaceable underground modular pressure regulator cartridge designed to be inserted into an underground chamber with a pressure regulator main valve and a pop-up safety valve connected in series with the pressure regulator, as well as a control means providing a plurality of settings for a predetermined period of time for the repetition of consumer spending, and control means inside the modular cartridge, designed to respond to settings to make changes to the operation of the main valve of the pressure regulator inside the modular cartridge to provide a variable output pressure.

 The tool inside the modular cartridge, designed to respond to settings, includes a double membrane that provides differential control.

 The control unit inside the modular cartridge, designed to respond to settings, is located in the modular cartridge, but separately from the main valve of the pressure regulator.

 The management tool can be additionally used to control fluid consumption over a set period of time and determine future consumer spending.

 Preferably, in the fluid pressure control system, means are provided for remotely receiving the recorded information, means for calculating settings based on them, and means for transmitting settings for controlling the remote control system.

 A ventilation pipe may be provided in the system on which a recording means is placed above the surface of the earth.

 In addition, an adjustable pressure source may be provided in the control system for a control means providing a plurality of settings, wherein the collapsing safety valve is configured to open in the event of a malfunction.

 Advantageously, a needle valve may be provided in the system, which is installed to provide a stable controlled pressure at the outlet with a predetermined set level in the event of a failure of the control means intended to respond to the installation parameters.

 The technical result according to the invention is achieved by creating a pressure control method in a fluid pressure control system comprising a replaceable underground modular pressure regulator cartridge with a main pressure regulator valve and a pop-up safety valve, according to which the flow rate of the fluid is monitored for a certain period of time in the recording device, provide many settings for a pre-set period time based on the control data and control the main valve of the pressure regulator using control means inside the modular cartridge, providing response to the settings for changing the output under the action of the setting parameters to provide a variable required pressure at the outlet, while providing remote reception of the recorded information, calculate settings on its basis and transmit the settings back to the control system to ensure Iya her management.

 It is preferable to simulate the installation of the main valve of the pressure regulator, providing a variety of settings, by means of a two-membrane control means.

 In the method according to the invention, a shut-off safety valve is opened in the event of a malfunction to ensure that the pressure rises to a predetermined value.

 It is advisable to use a needle valve to obtain a stable controlled pressure at the outlet with a predetermined set level in case of failure of the control means designed to respond to the installation parameters.

The invention will now be described by way of example with reference to the accompanying drawings, in which:
in FIG. 1 shows an underground pressure regulator module,
in FIG. 2 shows an outlet pressure control device with a timer mechanism enabled,
in FIG. 3 shows a graph of consumer spending and output pressure over time,
in FIG. 4 shows a modified device with variable pressure control,
in FIG. 5 shows in more detail the recording / control device.

 In FIG. 3 shows pressure plots for gas supply. Therefore, the requirement is to supply consumers with a gas stream at a steady pressure of at least 2 kPa (see graph (a)). In practice, it is possible to reduce the set pressure at the outlet of the regulator from 4 kPa to about 3 kPa during the night using the timer device described above (see graph (b)), and at the same time ensure the needs of users. The present invention provides, using a modified underground module, a continuously varying pressure set depending on the previously monitored use at this particular station in the gas supply network. The consumer spending profile (see graph (c)) maintains the pressure at the outlet (a) in order to meet demand requirements, while at the same time ensuring a reduction in the selected pressure and, consequently, reducing consumed volumes, the likelihood of leakage, etc. Although changes graph (c) is shown as relatively static over a given short period of time (for example, one hour), in practice, if necessary, a large number of changes can be included.

 To perform the required function, the modular cartridge 112 is modified as shown in FIG. 4.

The control knob 123 shown in FIG. 2, is replaced by a double diaphragm valve 168 (K _DP ), which receives control signals from the recording / control device 153. Another control valve 120 (K1) can be stored if required for safety reasons. The regulator 157 supply provides an adjustable supply of gas to the control device for its use. The needle valve 170 provides a limitation of the path, which, in the event of a malfunction of the recording / control device 153, acts as a reliable means to ensure stable controlled pressure at the outlet with a predetermined set level.

 In operation, the recording / control device 153 is programmed with information to provide pulses for the upper membrane D1 of valve 168, causing a variable setting of this valve depending on pre-stored information to provide a continuously changing pressure setting corresponding to the profile of FIG. 3 (s).

 In practice, in order to accommodate the recording / control device, an additional control box 150 is mounted on the ventilation pipe 130 below the existing box 133 of measuring instruments (see FIG. 5). Lines for operational control pass from the box 133 of the measuring devices through the pipe 151. The main element of the control device is a control / recording device 153, which may include a microprocessor, memory, timer and display. The modem 154 provides the ability to remotely receive registered information and control information received in the recording / control device 153 from a remote area. Depending on operational and safety requirements, a low pressure shut-off valve 156 and a feed pressure regulator 157 may be included.

 The control / recording device controls the pressure / flow rate and thus receives the gas supplied through the small pipe in the inlet 160. It also uses gas to drive the elements, while the gas receives through the supply pressure regulator 157. The exhaust channel 161 passes to the box 133 measuring instruments. The control outlet 163 controls the pressure of the underground regulator through a flexible pipe 164, which is the control line also led to the pop-up valve 156. In the event of damage, when the pop-up valve receives a low outlet flow, it relieves the control pressure into the outlet and allows pressure to increase to the preset value of the underground regulator. Line 65 provides a path for gas discharge during plant changes.

 A recording / control device 153 monitors and logs flow / pressure information to provide a profile that should be known for a given station, and it is usually transmitted once every 24 hours after a fast signal over the telephone line to modem 154. This information is used on a remote computer (not shown) to calculate the expected flow rate and select the various pressure flow settings for use over the next 24 hours (with a margin for handling slightly higher than the load) and transmit it over the telephone line to the controller, which uses its internal timer to raise and lower the pressure according to preliminary instructions for the whole day to provide variable pressure control for the cartridge 112 to obtain the results shown, for example, in the graph in FIG. 3 (s).

 The recording device can also generate emergency and other signals for transmission through a modem to a remote site. Although a telephone line can be used, a radio or other transmission methods can also be used.

 The cartridge can be easily interchanged with that shown in FIG. 1 cartridge, and no earthwork is needed, since it is pushed into an existing chamber and closed using the same bulk bulkhead.

Claims (13)

 1. A fluid pressure control system comprising an interchangeable underground modular pressure regulator cartridge designed to be inserted into an underground chamber with a pressure regulator main valve and a pop-up safety valve connected in series with the pressure regulator, as well as a control means providing a variety of settings for a predetermined period of time for the repetition of consumer spending, and the control inside the modular cartridge Adapted to respond to the settings to make changes in the operation of the main pressure regulator valve within the module cartridge for alternating the required outlet pressure.  2. The system according to claim 1, in which the means inside the modular cartridge, designed to respond to settings, includes a double membrane that provides differential control.  3. The system according to claim 2, in which the control means inside the modular cartridge, designed to respond to settings, is located in the modular cartridge, but separately from the main valve of the pressure regulator.  4. The system according to any one of paragraphs. 1-3, in which the control tool is additionally used to control fluid consumption over a specified period of time and determine future consumer spending.  5. The system according to claim 4, which provides means for remote reception of the recorded information, means for calculating settings based on it, and means for transmitting settings to provide control of the remote control system.  6. The system of claim 4 or 5, wherein a ventilation pipe is provided on which a recording means is located above the surface of the earth.  7. The system according to any one of the preceding paragraphs, in which an adjustable pressure source is provided for a control means providing a plurality of settings, and a collapsing safety valve is configured to open in the event of a malfunction.  8. The system according to any one of the preceding paragraphs, which provides a needle valve installed to provide stable controlled pressure at the outlet with a predetermined set level in the event of a failure of the control means designed to respond to the installation parameters.  9. A method for controlling pressure in a fluid pressure control system comprising a replaceable underground modular pressure regulator cartridge with a main pressure regulator valve and a slam-shut safety valve, according to which the flow rate of the fluid is monitored for a certain period of time in the recording device, provides many settings in during a predetermined period of time based on the control data and control the main a pressure regulator valve using a control tool inside a modular cartridge, which provides a response to the settings for changing the output under the action of the settings to provide a variable output pressure.  10. The method according to p. 9, in which provide remote reception of the recorded information, calculate the settings on its basis and transmit the settings back to the regulation system to ensure its management.  11. The method according to p. 9 or 10, in which the simulation of the installation of the main valve of the pressure regulator, providing many settings, is carried out by means of a two-membrane control means.  12. The method according to any one of paragraphs. 9-11, in which the shut-off safety valve is opened in the event of a malfunction to ensure that the pressure rises to a predetermined value.  13. The method according to any one of paragraphs. 9-12, in which the use of a needle valve is used to obtain a stable controlled pressure at the outlet with a predetermined set level in case of failure of the control means designed to respond to the setting parameters.

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