RU119062U1 - DEVICE FOR EXTINGUISHING THE PRESSURE PULSATION - Google Patents

Abstract

1. A device for damping pressure pulsations containing a pipeline, a plate with holes installed in a cylindrical chamber, coaxial with the inner cylindrical surface of the pipeline and the hydraulic diameter of the chamber exceeding the hydraulic diameter of the pipeline, characterized in that the plate contains holes with a total flow area of at least an area the flow area of the pipeline is located in the chamber orthogonal to the axis of the pipeline, while the length of the cylindrical chamber is in the range of 0.5 ÷ 1.5 of the hydraulic diameters of the chamber. ! 2. Device for damping pressure pulsation according to claim 1, characterized in that cylindrical holes are made in the plate. ! 3. A device for damping pressure pulsations according to claim 1, characterized in that holes in the form of slits are made in the plate. ! 4. A device for damping pressure pulsations according to claim 2, characterized in that there are conical chamfers at the inlet and outlet of the holes in the plate with cylindrical holes.

Description

The proposed utility model relates to auxiliary devices for the pipeline network, and more specifically, to devices for damping the pulsation of parameters of liquid or gaseous media and reducing vibration of the elements of the pipeline network and can be used to dampen the pressure pulsation of the pumped working fluid (gas) in piping systems.

There is a device for damping pressure pulsations, taken as a prototype (US 2011/0061757 A1), consisting of a pipeline, a plate with holes installed at an acute angle to the axis of the pipeline in a cylindrical chamber, coaxial with the inner cylindrical surface of the pipeline with an inner diameter of the chamber larger than the inner diameter of the pipeline. The angle between the axis of the pipeline and the plane of the camera is in the range of 5 ° ÷ 20 °. The transition from the inner diameter of the chamber to the inner diameter of the pipeline is carried out by means of conical inserts. A perforated plate divides the camera into two parts: inlet and outlet. The rigidity of the structure is ensured by installing a stiffener in the output chamber between the perforated plate and the inner contour of the chamber. The ratio of the length of the chamber to its diameter is in the range of 3 ÷ 10. The work of the prototype is based on dividing large vortex formations generated by a pressure pulsation source into many small vortex formations, the dissipation rate of which is greater than that of the initial vortex, and the amplitude of the pulsation of flow parameters (velocity and pressure) is less. Therefore, the presence of such a device in the piping system reduces the risk of pipeline vibration caused by the presence of unsteady hydrodynamic vortex flows that occur in individual elements of the pipeline and the equipment connected to them, and mitigates the consequences of the occurrence of water hammer in the piping system. The design of the device (namely, the installation of a plate with holes at an acute angle to the axis of the pipeline in the chamber, the inner diameter of which is larger than the internal diameter of the pipeline) makes it possible in principle to reduce the hydraulic resistance of the device.

The prototype has the following disadvantages:

1) The complexity of the design, since it is rather difficult to provide a given angle of inclination of the plate mounted in a cylindrical chamber. In addition, to ensure the rigidity of such a structure, it is necessary to further complicate it by installing a stiffener between the perforated plate and the inner contour of the chamber. The complexity of the design leads to its cost increase and a decrease in reliability.

2) Large hydraulic losses in the specified device are caused by large angles of leakage of the flow of the working fluid onto the plate (the dependence of the hydraulic resistance of the grating on the angle of flow of the flow onto the spatial lattice is shown in the minutes of the workshop for reviewing the results of studies on the thermohydraulics of fuel assemblies with sector-type mixing gratings made in NRNU MEPhI topic No. 00-3-013-1460), and the presence of a stiffener, which introduces additional disturbance into the flow transported through the pipeline water working fluid (gas).

3) Calculation and experimental studies (the main research results are reflected in the work: A.V. Nikolayev, A.P. Skibin, O.V. Belova "Calculation and experimental study of unsteady flow in vortex suppressors of various designs", theses of the conference "The future of mechanical engineering Russia ”, Moscow: MSTU named after NE Bauman, September 28 – October 1, 2011) show that with an increase in the ratio of the total length of the chamber to its diameter (L / D) from 0.25 to 2.5 rms pulsations pressure downstream of the damping device of pressure pulsation in the pipe wires increases 4 times. Moreover, the rms pressure pulsations in a system with a pulsation damping device exceed the same indicator in a system without a pulsation damping device by more than 3 times. Thus, the damping device of pressure pulsations with L / D = 3 ÷ 10, as recommended in the prototype, can lead to increased rms pressure pulsations.

4) The calculation and experimental studies cited above show that the presence of a conical transition from the diameter of the chamber to the diameter of the pipeline does not introduce a tangible economic effect, since this complication of the design leads to an equivalent decrease in the hydraulic resistance of the system and an increase in the amplitude of pressure pulsation.

5) The prototype proposes to produce perforated lattices with elliptical holes, which are difficult to manufacture and provide a small relative passage area of the lattice, which leads to an increase in hydraulic losses in such a lattice and an increase in the cost of its manufacture.

The objective of the proposed utility model is to reduce the level of pressure pulsation of the pumped working fluid in the piping systems, reduce the vibration level of pipelines, reduce the impact of water hammer on pipelines and equipment connected to them, increase the reliability, economy and service life of piping systems and equipment connected to them.

The problem is solved in that the device for damping pressure pulsation includes a pipeline and a plate with holes installed in a cylindrical chamber, coaxial with the inner cylindrical surface of the pipeline and a hydraulic diameter of the chamber exceeding the hydraulic diameter of the pipeline.

A distinctive feature of the device is that the plate contains openings with a total passage area of at least the area of the passage section of the pipeline and is located in the chamber orthogonal to the axis of the pipeline, while the length of the cylindrical chamber is in the range of 0.5-1.5 hydraulic diameters of the chamber.

In addition, a distinctive feature is that the plate has cylindrical holes or holes in the form of slots.

In addition, a distinctive feature is that at the entrance and exit from the holes in the plate with cylindrical holes there are conical bevels.

In addition, a distinctive feature is that the device is installed at a distance of at least two hydraulic diameters of the pipeline from the source of pressure pulsation.

The proposed utility model is illustrated by the drawings presented in Fig.1-3.

Figure 1 presents a General view of the proposed device.

Figure 2 shows the dependence of the rms pressure pulsation ΔP and the relative hydraulic resistance coefficient ζ of the pipeline section with the device for damping the pressure pulsation from the relative chamber length L / D (here L is the chamber length, D is the chamber diameter).

Figure 3 shows the dependence of the rms pressure pulsation ΔР and the relative hydraulic resistance coefficient ζ of the pipeline section with the device for damping the pressure pulsation from the relative distance L / D between the pressure pulsation source and the device for damping the pressure pulsation (here L is the absolute value of the distance, D - pipe diameter).

The proposed device includes:

Pipeline 1 (Fig. 1), a plate with holes 3 (Fig. 1), mounted orthogonally to the axis of the pipeline in a cylindrical chamber 2 (Fig. 1), coaxial with the inner cylindrical surface of the pipeline and an inner diameter of the chamber larger than the inner diameter of the pipeline.

The device operates as follows:

Pressure pulsations in pipelines, as a rule, are caused by the presence of large vortex formations in the pipelines generated during the passage of the working fluid (gas) through valves, turbine units, various local resistances, etc. A device for damping pressure pulsations (Figure 1) is installed behind the source of pressure pulsations in the pipeline at a distance of at least 2 hydraulic diameters of the pipeline 1 (Figure 3). The working fluid with large vortex formations through the pipeline 1 (Figure 1) enters the inlet of the chamber 2 (Figure 1), the hydraulic diameter of which is larger than the hydraulic diameter of the pipe 1 (Figure 1). When switching to a larger hydraulic diameter, a sudden expansion of the flow and a decrease in the axial flow velocity occur. Further, the inhibited working fluid enters the holes of the plate 3 (Figure 1), the total passage area of which is not less than the area of the passage section of the pipeline. In plate 3, large vortex formations are divided into many small vortex formations, the amplitude of pressure pulsation in which is less than the amplitude of pressure pulsation in the initial large vortex formations, and the frequency, on the contrary, is greater. From the holes of the plate 3 (Figure 1), the working fluid (gas) enters the outlet of the chamber 2 (Figure 1). From the outlet of the chamber 2 (FIG. 1), the working fluid (gas) is sent to the pipeline 1 (FIG. 1), where the flow rate of the working fluid again increases to the initial level.

Small vortex cords formed after the outlet part of the chamber can no longer harm the pipeline and the equipment connected to it, and due to the fact that the pressure pulsation frequency in these cords is high, the kinetic energy of the cords dissipates quite quickly and they decay at a much smaller distance than large vortex formations. Therefore, the presence of such a device in the pipeline system reduces the risk of pipeline vibration caused by the presence of unsteady hydrodynamic vortex flows that occur in individual elements of the pipeline and the equipment connected to them, and mitigates the effects of the occurrence of water hammer in the pipeline system.

Since the total area of the holes in the plate 3 (Figure 1) is not less than the passage area of the pipe 1 (Figure 1), and the speed in the chamber 2 (Figure 1) is less than the speed in the pipe 1 (Figure 1), a significant reduction in hydraulic losses in pressure damping damping devices.

The prototype proposes to install a plate with holes in the chamber at an angle of 5 ° ÷ 20 ° with respect to the axis of the pipeline. As noted above, this leads not only to the complication and cost of the design of the device for damping pressure pulsations, but also to an increase in the hydraulic resistance introduced by the device for damping pressure pulsations to the total resistance of the piping system. To eliminate these drawbacks, it is proposed to install a plate with holes 3 (Figure 1) in the chamber 2 (Figure 1) orthogonal to the axis of the pipeline 1 (Figure 1), which simplifies the design of the device and increases its reliability and efficiency.

The prototype proposes to produce perforated lattices with elliptical holes, which are difficult to manufacture and provide a small relative passage area of the lattice, which leads to an increase in hydraulic losses in such a lattice. In a utility model, it is proposed to produce plates with cylindrical holes or openings in the form of slots with a total passage area of the holes of at least the passage area of the pipeline in which the device for damping pressure pulsation is installed, which reduces hydraulic losses in such a grate and simplifies the task of manufacturing a device for damping pressure pulsations. It should be borne in mind that devices for damping pressure pulsations with cylindrical holes in the plate have a greater hydraulic resistance, but better characteristics for reducing pressure pulsations than devices for damping pressure pulsations with slotted holes in the plate with the same passage area of the holes in the plate. This happens because the holes in the form of gaps break the initial large vortex into a smaller number of small vortex formations than a plate with cylindrical holes in the same passage area. Moreover, the amplitude of pressure fluctuations in large eddy formations is greater than in small ones, and the frequency on the contrary is less. Therefore, it is recommended that devices for damping pressure pulsations with holes in the form of slots in the plate be installed mainly in cases where it is necessary to tune the natural frequencies of the oscillations of pipelines from the frequencies of oscillations of disturbing forces, i.e. from the frequency of pressure pulsation in the flow of the pumped working fluid (gas).

To reduce the hydraulic resistance of the device for damping pressure pulsations with cylindrical holes, it is recommended that the bevel bevels be made at the inlet and outlet of the holes.

Calculation and experimental studies cited above show (Figure 2) that the greatest economic effect is achieved by a device for damping pressure pulsations with a chamber, the length of which is in the range of 0.5 ÷ 1.5 hydraulic diameters of the chamber (L / D = 0, 5 ÷ 1.5).

Calculation and experimental studies cited above show that the distance from the source of pressure pulsation in the pipeline to the damping device of pressure pulsation is of great importance (Figure 3). Based on this, it is proposed to install devices for damping pressure pulsation at a distance of at least two hydraulic diameters of the pipeline from the source of pressure pulsation, which can significantly reduce the amplitude of pressure pulsation and hydraulic resistance in the pipeline with a device for damping pressure pulsation.

Thus, the tasks set for the proposed utility model are achieved, namely, reducing the level of pressure pulsation of the pumped working fluid in the piping systems, reducing the vibration level of pipelines, reducing the impact of water hammer on pipelines and equipment connected to them, increasing the reliability, efficiency and durability of piping systems and equipment attached to them.

Currently, manufacturing is being carried out with subsequent testing of the proposed device to prepare for its introduction at nuclear power plants.

Claims (4)

1. A device for damping pressure pulsations, containing a pipeline, a plate with holes installed in a cylindrical chamber, coaxial with the inner cylindrical surface of the pipeline and a hydraulic diameter of the chamber exceeding the hydraulic diameter of the pipeline, characterized in that the plate contains holes with a total passage area of at least the area the cross section of the pipeline, located in the chamber orthogonal to the axis of the pipeline, while the length of the cylindrical chamber is in the range of 0.5 ÷ 1.5 hyd vlicheskih diameter chamber. 2. The device for damping pressure pulsations according to claim 1, characterized in that the plate has cylindrical holes. 3. The device for damping pressure pulsations according to claim 1, characterized in that the holes in the form of slots are made in the plate. 4. The device for damping pressure pulsations according to claim 2, characterized in that there are conical bevels at the inlet and outlet of the holes in the plate with cylindrical holes.