RU113381U1 - GAS PRESSURE AND FLOW REGULATOR - Google Patents

Abstract

1. A regulator of pressure and gas flow, containing a hollow body with flanges at its ends, a metering element installed in the body cavity, having the possibility of axial reciprocating movement and containing a stem with a plate that forms a gap with a seat made in the body, which determines the pressure and gas flow characterized in that the regulator is equipped with a drive for adjusting the position of the metering element, located on the body and made in the form of a screw pair, the nut of which is kinematically connected to the drive motor, and the screw is fastened to the rod of the metering element. ! 2. The regulator of pressure and gas flow rate according to claim 1, characterized in that the actuator for adjusting the position of the metering element is closed with a glass attached to the body of the regulator. ! 3. The regulator of pressure and gas flow rate according to claim 1, characterized in that a valve motor is used as an electric motor for adjusting the position of the metering element. ! 4. The regulator of pressure and gas flow rate according to claim 1, characterized in that the metering element is equipped with a second plate mounted on the rod coaxially with the first, and a second seat is made in the body coaxially with the first, with each plate mounted above the seat with which it forms a gap for gas passage or has the ability to contact when the gas supply is shut off. ! 5. The gas pressure and flow regulator according to claim 1, characterized in that the nut of the drive for adjusting the position of the metering element is equipped with a shank fastened to it, at the free end of which there is a wrench space for manual rotation of the nut. ! 6. The gas pressure and flow regulator according to claim 1, characterized in that it is

Description

The utility model relates to equipment for gas transportation and can be used in gas distribution systems (GDS) designed to supply consumers with gas from main and field pipelines with automatic maintenance of a given pressure and gas flow, regulating them over a wide range, and also shutting off gas supply to emergency situations and in cases of unauthorized selection.

Known gas pressure regulator, consisting of a hollow body with flanges at its ends for mounting the regulator in a gas pipeline, made in the cavity of the body two seats, with which there are two valves, mounted on a common rod. In the case, under a removable cover, several tared loads are placed one above the other with a gap, with the rod fastened to the bottom of them.

In the process of operation of the regulator built into the gas pipeline, with the pressure of the transported gas increasing, the force from its impact on the valve stem will mix the latter up. At the same time, the lower load comes into contact with the load located above it and the force of gravity of the two loads will already act on the rod, which exceeds the counter-directed force from pressure on the rod and its upward movement stops.

With a further increase in gas pressure, the stem, overcoming the gravity of two loads, will be mixed upward on the working stroke until it contacts the upper load, and in this case, the gravity of the three loads will be affected by the rod and the upward movement of the rod will stop.

When the rod moves up, the gaps between the valves and seats are gradually reduced and the pressure of the gas leaving the body decreases.

With an excess gas pressure increase at the inlet of the device, the stem will continue to move upward until the valves come in contact with the seats, which leads to a complete cessation of gas supply.

(see RF patent for utility model No. 73094, class G05B 16/02, 2008).

As a result of the analysis of the implementation of the known regulator, it should be noted that it provides only discrete adjustment of the gas supply, the accuracy of which depends on the difference in mass of calibrated goods, which significantly reduces the accuracy and range of regulation of pressure and gas flow.

Known gas pressure regulator, consisting of a hollow body with inlet and outlet cavities, with flanges at its ends and a lid attached on top and a gas pressure adjustment mechanism located therein, made in the form of a screw screwed into the lid, to the lower end of which there is a stop in contact with a spring resting on a membrane sandwiched between the disks and dividing the volume of the cover into a submembrane and submembrane cavity, a rod is fastened to the membrane with a valve, which has the ability to contact with a seat made in the cavity to Orpusa. The submembrane cavity by means of a tube mounted behind (relative to the direction of gas movement) the metering element is connected to the gas pipeline.

In the process of operation of the regulator, gas is supplied to the inlet cavity of the housing and, through the gap formed by the valve and the seat, enters the outlet cavity and then to the consumer.

As the consumer increases the gas flow rate, the pressure in the outlet cavity of the housing decreases and the gas pressure of this magnitude through the feedback tube enters the submembrane cavity, acts on the membrane, which, bending, moves the valve stem and the valve moves away from the seat and the flow rate set by the tuning mechanism increases.

(see RF patent No. 2391695, class G05D 16/06, 2010) - the closest analogue.

As a result of the analysis of this solution, it should be noted that the valve is adjusted by adjusting the compression force of the spring, which reduces the accuracy and range of regulation of pressure and gas flow, and also makes it practically impossible to control the pressure and gas flow in the wide range during gas supply to the consumer.

The technical result of this utility model is the development of a pressure and gas flow regulator that allows controlling the flow of the working medium in automatic mode, with high accuracy and within wide limits, including remotely, from the control panel located far from the regulator.

The specified technical result is ensured by the fact that in the pressure and gas flow regulator containing a hollow body with flanges at its ends, a metering element installed in the body cavity having axial reciprocating movement and containing a rod with a plate forming a gap with a saddle made in the body , which determines the pressure and gas flow rate, it is new that the regulator is equipped with a metering element position control actuator placed on the housing and made in the form of a screw pair, nut which is kinematically connected to the drive motor, and the screw is fastened to the rod of the metering element, while the drive for controlling the position of the metering element is closed by a glass mounted on the regulator body, and a valve motor is used as the drive motor for controlling the position of the metering element, while the metering element can be equipped with a second plate mounted on the stem coaxially with the first, and a second saddle is made coaxially with the first in the housing, with each plate mounted above the saddle, with torym they form a gap for the passage of gas or has a possibility of contact with the overlapping feed gas, and adjusting the position of the nut drive of the metering member equipped with a shank, on the free end of which holds a key location intended for manual rotation of the nut.

The regulator can be equipped with a mechanism for manually moving the metering element, made in the form of a roller installed in the bottom of the glass, which can be rotated and axially displaced, at one end of which a gear is fixed that can engage with the gear drive of the metering element, and channels can be made in the flanges for installing sensors that monitor gas flow parameters.

The essence of the utility model is illustrated by graphic materials, in which figure 1 and figure 2 show in axial section different versions of the pressure regulator and gas flow.

The pressure and gas flow regulator contains a hollow body 1, flanges 2 (inlet) and 3 (outlet) are docked to the ends of the body, through which the regulator is mounted in the gas pipeline. In the cavity of the housing 1 with the possibility of reciprocating movement, a metering element 4 is installed, made in the form of a two-seat valve, which is a rod with two coaxial plates "a", which have the ability to contact with the coaxially made saddles "b" in the body, and the gap between plates "a" and seats "b" determines the throughput (flow) of the valve. When the valves are in contact with the seats, the regulator cuts off the gas supply.

The metering element 4 is equipped with a drive for adjusting the position of the metering element mounted on the housing. The drive can be made in various ways, for example, in the form of a helical gear, the screw 5 of which is fastened to the rod of the metering element, and the nut 6 is connected to the gear 7 (in Fig. 1, this gear is not indicated kinematically associated with the electric motor 8.

The drive for adjusting the position of the metering element is placed in a glass 9 mounted on the housing 1. As a motor in the design of the controller, it is most advisable to use a valve (torque) motor, which has a higher efficiency and lower mass compared to traditionally used stepper motors.

The regulator can be equipped with a manual movement of the metering element located in the glass 9, made in the form of a roller 10 (Fig.2), mounted in the end of the glass with the possibility of rotation and axial movement and spring-loaded relative to the housing. At one end of the roller, a turnkey place is made (for example, a hexagon), and gear 11 is fixed at the other end, but the upper end of which has a disk 12 of the same diameter with this gear.

The mechanism for manual movement of the metering element can be performed in another way (figure 1). For the manual movement of the metering element, the nut 6 can be equipped with a shank 10 fastened with it (analogue of the roller in FIG. 1).

Manual movement of the metering element 4 is necessary in emergency situations or for technological purposes.

The controller is equipped with a sensor 13 for the position of the metering element 4 mounted on the cantilever arm 14, mounted on the rod of the metering element 4.

Visual control of the position of the metering element is carried out through a window 15 closed by a transparent material.

In flanges 2 and 3, channels 16 and 17 can be made for installing sensors (not shown) of temperature and pressure in front of the metering element, gas pressure behind the metering element and pressure at the outlet of the gas distribution system.

The controller is equipped with a unit 18 for controlling the position of the metering element, which can be located in the glass 9.

Naturally, the shank 10 of the nut (Fig. 2) must be elongated to such an extent that its free end extends out through the hole in the cover 19 of the glass 9. At the free end of the shank, a turnkey place is made, for example, a hexagon is milled, which is inoperative position is closed by a removable plug 20 mounted on the lid 19 of the glass 9.

All elements of the regulator, the design of which is not disclosed in this application, are known and their implementation is not subject to patent protection.

The pressure regulator and gas flow rate is as follows.

Before starting work, the regulator is mounted in the gas pipeline, for which flanges 2 and 3 are connected to the gas pipeline flanges. Install the necessary sensors for monitoring gas parameters in channels 16 and 17. The sensors are connected to an autonomous valve operation control unit or to a control room control panel. The circuit for connecting the valve to the gas supply pipe and to the control devices is similar to that used in RF patent No. 2294555.

The gas stream enters through the gas pipe through the inlet flange 2 opening into the cavity of the housing 1 to the metering element 4. The gap between the plates “a” and the seats “b” sets the flow rate of gas sent through the regulator to the consumer. In this case, the position of the metering element and the gas flow parameters in front of the metering element and behind the metering element are measured by the respective sensors and their values are supplied to the control unit 18, where they are compared with the set ones and, based on the comparison results, the control unit generates a control signal to the electric motor 8 to adjust the position of the metering element 4 The control unit can be performed similarly to that described in patent No. 2294555).

The electric motor 8 of the drive for adjusting the position of the metering element 4 in accordance with the value of the control signal rotates the nut 6, which informs the axial movement of the screw 5, and therefore the rod of the metering element 4, the movement of which accordingly changes the passage section between the plates “a” and the seats "B", thereby providing a predetermined value of gas flow.

If it is necessary to manually move the metering element, for example, for emergency shutdown of the gas supply, move the roller 10 (Fig. 2) until the disk 12 and gear 7 contact (while the roller gear 11 engages with the gear 7 and rotate the roller leading to operation a screw mechanism that moves the metering element 4 until its plates come in contact with the seats, which stops the gas supply.Manual movement of the metering element can also be carried out (figure 1) by rotating the nut 6 through an elongated shank 10.

From the foregoing, it is quite clear that the principle of operation of the regulator is based on the fact that the gas flow passing through the gap formed by the plates “a” of the metering element and the saddles “b” of the body is reduced to obtain the specified parameters. When moving the metering element, the flow area changes, and, consequently, the amount of gas passing through. This ensures that the outlet pressure is maintained at a given value when the gas flow rate or outlet pressure changes. The movement of the metering element occurs through mechanical transmission during rotation of the rotor of the electric motor (that is, a rigid kinematic connection is implemented that increases the accuracy of regulation). The deviation of the output pressure resulting from a change in gas consumption or inlet pressure is sensed by a pressure sensor, the output signal from which is fed to a control unit, which compares it with a software set value, when the signals are mismatched, the control unit generates a corresponding digital signal through the channel to the control unit, which gives the command to the electric motor 8 to set the metering element 4 in a position corresponding to the equality of the control and reference signals.

To ensure the regulation function when the gas consumption mode exceeds a preset flow rate, the regulator switches to the consumer pressure reduction mode until the specified preset value for flow restriction is reached up to the pressure value determined by the minimum permissible pressure at the outlet of the gas distribution system. In case of exceeding the actual gas flow rate with a given setpoint, the control unit issues a command to cover the dosing element. As a result, the gas flow through the regulator decreases. Closing continues until the actual and set flow rates are equal if the outlet pressure has not dropped below the set minimum flow setpoint. The cover is terminated when the output pressure is equal to the minimum acceptable, safe for the consumer.

The implementation of the metering element with two plates "a" allows us to provide, compared to its single-pocket version, ceteris paribus, greater throughput due to the larger total flow area. The design of the metering element is made in such a way that the excess pressure of the gas provides an additional compression of the plates "a" to the saddles "b", which ensures reliable shut-off of the gas supply, if necessary.

The implementation of the channels for the installation of sensors for monitoring the parameters of the gas flow in the flanges 2 and 3 eliminates the holes in the gas pipeline.

The regulator allows gas supply to consumers with maintaining the specified parameters of the medium supply based on a comparison of its input and output parameters and automatic maintenance of the set parameters during operation.

Claims (7)

1. A pressure and gas flow regulator comprising a hollow body with flanges at its ends, a metering element mounted in the body cavity having axial reciprocating movement and comprising a rod with a plate forming a gap with a saddle in the body that determines the pressure and gas flow characterized in that the controller is equipped with a drive for controlling the position of the metering element, placed on the housing and made in the form of a screw pair, the nut of which is kinematically connected with the electric motor of the drive, a screw fastened to a rod metering element. 2. The pressure and gas flow regulator according to claim 1, characterized in that the actuator for regulating the position of the metering element is closed by a glass mounted on the regulator body. 3. The pressure and gas flow regulator according to claim 1, characterized in that a valve motor is used as an electric drive for controlling the position of the metering element. 4. The pressure and gas flow regulator according to claim 1, characterized in that the metering element is equipped with a second plate mounted on the stem coaxially with the first, and a second seat is made coaxially with the first in the housing, with each plate mounted above the saddle with which it forms a gap for gas passage or has the ability to contact when the gas supply is shut off. 5. The pressure and gas flow regulator according to claim 1, characterized in that the nut of the drive for regulating the position of the metering element is equipped with a shank attached to it, at the free end of which a turnkey place is made for manual rotation of the nut. 6. The pressure and gas flow regulator according to claim 1, characterized in that it is equipped with a mechanism for manually moving the metering element, made in the form of a roller installed in the bottom of the glass, which can be rotated and axially moved, a gear having a clutch is fixed at one end of it with gear wheel for moving the metering element. 7. The pressure and gas flow regulator according to claim 1, characterized in that the flanges are made channels for installing sensors that control the parameters of the gas stream.