RU2744530C1 - Interferential compensating disk - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to a device for reducing pulsations of liquids and gases in pressure pipelines of large cross-sections. The interference disk includes the main channel 1 in the central part, made in the form of an opening with a cross-section corresponding to the section of the pressure pipeline, a bypass channel 2 extending from the inlet end side of the disk, the cross-section of which is less than the cross-section of the main channel, the main 1 and bypass 2 channels have inlet and outlet parts. According to the proposed invention, the bypass channel 2 is made in such a way that it twists around the main channel 1 and passes from the inlet end side (side A) of the interference disk to the opposite outlet side (side B) along the through channel 3. On the inner inlet end side behind the inlet part the bypass channel is made at least one curved protrusion 5, 6, smoothly decreasing along the inner wall of the main channel 1 in the direction of the outlet end face of the disk.

EFFECT: reduced pulsations of liquids in pipelines.

5 cl, 8 dwg

Description

The proposed invention relates to a device for reducing pulsations of liquids and gases in pressure pipelines of large cross-sections.

It is known that the internal pressure of the working medium in the pressure pipeline is one of the main force effects that determine its stress state. It seems dangerous here that the flow of the transported product carries the pulsation of this pressure, caused by the peculiarity of the design of pumps and compressor stations. Therefore, pipelines of hydraulic and gas systems, being constantly under cyclic force, can be subject to fatigue failure of the material of both the pipeline itself and the structures of control units. Such influences, as a rule, cause a breach of the tightness of pipelines, failures of units, emergency destruction and loss of operability of the system as a whole.

To eliminate the dangerous level of product flow pulsation in pipelines and reduce their vibration in hydraulic pneumatic systems, special pulsation dampers are used.

The most promising dampers that meet the modern requirements of such industries as aviation, mechanical engineering, chemical, oil, are interference (acoustic) pulsation dampers. These dampers use a method to reduce ripple by means of negative interference of superimposed oscillation waves. The priority of such devices is the absence of moving parts in the design, which ensures their reliable operation in conditions of harsh operation at high pressures and temperatures.

The main feature of pulsation dampers close to the claimed invention is the use of the direct negative interference method in them to reduce fluctuations in the pressure of the working medium (patent RU No. 626304, and applications for patents US 20030155026, 20030155027).

The main design element of these absorbers is a hard interference disk with two channels, where the first channel, the main (central) one, has a minimum length. The section of this channel is equal to the section of the diameter of the pressure pipeline. The second, bypass channel is made in the form of a spiral around the central channel on the flat sides of the disk. The bypass channel has a length equal to the half-wave length of the main frequency of the suppressed flow pulsation in the pressure pipeline.

With small sections of the main channel of the disc, the bypass channel, as a rule, has a section equal to the diameter of the central channel. With large diameters of the pressure pipeline, in order to create small-sized, compact absorbers, the cross-section of the disc bypass channel is significantly reduced. At the same time, the design features of the new interference discs created make it possible not to reduce their high operating efficiency in the pulsation dampers.

In addition, special requirements are imposed on the design of interference discs today, associated with the emergence of new pump designs. Modern high-performance pumps can have several stages in the discharge lines, as well as operate at different engine speeds. As a result, at the outlet of such pumps, the pulsation of the working medium can simultaneously carry several active frequencies. Therefore, the design of the interference disk should provide the ability to suppress such complex pulsations by the absorbers.

The closest prototype to the disc of the damper of the present invention is the interference disc given in the application for invention No. 2016121321 with priority dated May 30, 2016; Rospatent. Here, on both sides of the disk, bypass channels of various lengths formed in the sectors divide the flow of the working medium of the main channel into several streams. Before entering the central channel, the flows of the bypass channels, evenly distributed over its diameter, are again connected to the working medium, where the pulsation of this medium is suppressed.

Dampers with such discs allow suppressing the pulsation of the flow of the working medium in pipelines of large diameters and simultaneously at several frequencies.

However, the disadvantages of these discs are the complexity of their designs and the loss of energy of the working medium in the bypass channels at their numerous bends.

The task (technical result) of the proposed invention is to create an interference disk free from the above disadvantages.

The problem is solved by the fact that the interference disk includes a main channel in the central part, made in the form of a hole with a cross-section corresponding to the section of the pressure pipeline, a bypass channel extending from the inlet end side of the disk, the cross-section of which is less than the cross-section of the main channel, the main and bypass channels have inlet and output part. According to the proposed invention, the through channel connects the inlet and outlet end sides in the interference disk, the bypass channel is made in such a way that it twists around the main channel and passes through the through channel from the inlet end side of the interference disk to the opposite outlet side, on the inner inlet end side behind the inlet part of the bypass channel is made at least one curved protrusion, smoothly decreasing along the inner wall of the main channel in the direction of the outlet end face of the disk.

On the inner inlet end side, behind the inlet part of the bypass channel, several curved protrusions with different curvature can be made, smoothly decreasing along the inner wall of the main channel in the direction of the outlet end side of the disk.

The outlet part of the bypass channel can be made in the form of at least two outlet openings.

The section of each subsequent outlet can be made larger than the section of the previous outlet.

The bypass channel at the transition to the outlet end side of the disk can branch out into at least two channels of the same or different section and length.

The curved protrusion in the bypass channel provides suppression of the pulsation of the medium flow at low frequencies. And the implementation in the bypass channel of several protrusions with different curvatures provides the ability to suppress pulsations of the flow of the medium in a wider frequency range.

Execution of one bypass channel allows to increase its volume to damp the pulsation of the air flow at medium and high frequencies.

Thus, the proposed design of the interference disk makes it possible to increase the efficiency of its operation and expand the spectrum of suppressed frequencies. In this case, the very design of the disc is simplified.

The invention is illustrated by drawings, where in FIG. 1 and 2 show the inventive interference disk with two curved projections and several outlets in the bypass channel. FIG. 3 and 4 show perspective views of the disc of FIG. 1 and 2.

FIG. 5 and 6 show an interference disk, in which the bypass channel branches into two channels at the transition to the output end side of the disk.

FIG. 7 and 8 show perspective views of the disc of FIG. 5 and 6.

The proposed interference disk (Fig. 1, 2) includes the main channel 1 in the central part. The cross-section of the main channel 1 corresponds to the cross-section of the pressure pipeline into which the pulsation damper with this disc is cut. The bypass channel 2 is twisted around the main channel 1 and through the through channel 3 from the inlet side of the disk A passes to its opposite outlet side B. On the inner inlet end side, behind the inlet 4 of the bypass channel 2, curved projections 5 and 6 are made, smoothly decreasing along the inner wall the main channel in the direction of the output end face of the disc. FIG. 1 shows that the projections 5,6 have different curvatures. On the end side B of the disc, the bypass channel 2 ends in a continuous ring around the main channel 1. On this ring there are outlet openings 7, 8, 9, 10, evenly distributed over the diameter of the main channel. Moreover, of these holes, each subsequent hole has a larger cross-section in relation to the previous one.

Such an arrangement of holes 7, 8, 9, 10 and their successively increasing cross-sections allow suppressing adjacent frequencies relative to the main suppressed frequency and evenly distributing the flow energy of the bypass channel 2 over these holes.

This design of the interference disc provides aerodynamic compensation and broadband tuning.

FIG. 5, 6 shows the inventive interference disk, in which the bypass channel 2 on side A, when passing to the end side B, forks into two branches 11, 12. These branches end with outlet openings 7, 8, 9, 10, evenly distributed along the diameter of the main channel 1 The lengths of each of the branches 11, 12 are equal to each other. Therefore, the disc under consideration provides for a precise adjustment of the damper to suppress one frequency.

However, if the lengths of the branches 11, 12 are changed relative to each other (not shown in the figure), then through such a disk the damper can be adjusted to suppress several frequencies. For example, by decreasing the length of leg 11, the damper can be tuned to suppress the higher frequency of the spectrum. At the same time, with an increase in the length of branch 12, the damper will be able to suppress the pressure pulsation in the pressure pipeline at a lower frequency.

Thus, the disc structure in FIG. 3, which assumes precise tuning of the ripple damper to one frequency, also makes it possible to tune the damper to reduce several frequencies in a wider frequency range.

This design of the interference disk provides high volume compensation and tuning to various frequencies.

The proposed interference disk works as follows.

FIG. 14.

The flow of the working medium through the inlet part 4 enters the bypass channel 2, passing along the projections 5, 6, the flow of the working medium accelerates its flow. In this case, according to the aerodynamic laws of flow around curved surfaces, the pressure of the working medium decreases, and in the region of the projections 5, 6 a rarefied space is created, where a pulsating flow of the medium in a volume exceeding its usual filling actively rushes through the inlet part 4 of the bypass channel 2.

Now the increased volume of the working flow through one bypass channel 2 with a minimum loss of energy passes to the outlets 7-10. Further, through these holes, the flow of the medium of the bypass channel 2 is superimposed on the flow of the working medium of the main channel 1 and, due to direct negative interference, the pulsation of this medium is effectively suppressed. In the pulsation damper, the flow of the medium, freed from dangerous vibrations, flows into the pressure pipeline.

Thus, one bypass channel of the proposed disc, due to aerodynamic compensation and its continuous looping around the central channel, provides effective suppression of pulsations of the flow of the working medium. In this case, the power of the overwhelming flow increases due to the additional conservation of energy.

FIG. 7 - 8.

The flow of the working medium through the inlet part 4 enters the bypass channel 2, passing along the projection 5, the flow of the working medium accelerates its flow. In this case, according to the aerodynamic laws of the flow around curved surfaces, the pressure of the working medium decreases, and a rarefied space is created in the region of the protrusion 5, where a pulsating flow of the medium in a volume exceeding its usual filling actively rushes through the inlet part 4 of the bypass channel 2. When passing to the end side B, the working stream is divided into two parts and then passes along the branches 11 and 12 of the bypass channel 2 to the outlet openings 7-10. Further, through these holes, the flow of the medium of the bypass channel 2 is superimposed on the flow of the working medium of the main channel 1, and due to direct negative interference, the pulsation of this medium is effectively suppressed. In the pulsation damper, the flow of the medium, freed from dangerous vibrations, flows into the pressure pipeline. The spectrum of the suppressed frequencies of the pulsation of the working flow is determined by the choice of the lengths of the branches 11 and 12.

The accompanying explanatory figures confirm the industrial applicability of the claimed device.

Thus, the proposed technical solution, while simplifying the design of the interference disk, simultaneously increases the efficiency of the pulsation damper.

Claims (5)

1. An interference disk, including a main channel in the central part, made in the form of a hole with a cross-section corresponding to the section of the pressure pipeline, a bypass channel extending from the inlet end side of the disk, the cross-section of which is less than the cross-section of the main channel, the main and bypass channels have inlet and outlet parts, characterized in that it is equipped with a through channel connecting the input and output end sides in the interference disk, the bypass channel is designed so that it twists around the main channel and passes through the through channel from the input end face of the interference disk to the opposite output side, on the inner input at the end side behind the inlet part of the bypass channel, at least one curved protrusion is made, smoothly decreasing along the inner wall of the main channel towards the outlet end side of the disk. 2. An interference disk according to claim 1, characterized in that at least two curved protrusions with different curvature are made on the inner inlet end side behind the inlet part of the bypass channel, smoothly decreasing along the inner wall of the main channel towards the outlet end side of the disk. 3. An interference disk according to claim 1, characterized in that the outlet part of the bypass channel is made in the form of at least two outlet openings, evenly distributed along the diameter of the main channel. 4. An interference disk according to claim 2, characterized in that the cross section of each subsequent outlet of the bypass channel is greater than the cross section of the previous outlet. 5. Interference disk according to any one of paragraphs. 1, or 2, or 3, characterized in that the bypass channel branches out into at least two channels of the same or different length when passing to the outlet end side of the disk.

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