RU2137975C1 - Pressure fluctuation damper for pneumohydraulic systems - Google Patents

Abstract

FIELD: dampening pressure fluctuations in pipe lines. SUBSTANCE: pressure fluctuation damper includes cylindrical housing closed on two sides by means of covers with inlet and outlet branch pipes; perforated tube and dampening members are arranged inside housing. Branch pipes are provided with perforated tubular inserts for forming circular blind passages between inserts and inner walls of branch pipes. Blind circular passages are oriented to inlet by their open part. perforated passages in tubular inserts are made at engine relative to their axis. EFFECT: enhanced efficiency of dampening pressure fluctuations and flow rate of working medium; enhanced operational reliability; reduced resistance; reduced power requirements; extended operational capabilities. 3 cl, 2 dwg

Description

 The invention relates to mechanical engineering and can be used in the oil, gas, chemical industry and heat supply, and is designed to dampen pressure and flow pulsations in pipeline systems.

 The well-known "damper for pressure fluctuations for hydraulic lines" (see av. St. N 1006850, MKI F 16 L 55/04, 10.21.81), containing a cylindrical body closed on both sides with caps with inlet and outlet pipes, with perforated pipe placed in it.

 Closer in its technical essence is the “Damper of pressure and flow fluctuations in pneumohydraulic systems” (see av. St. N 1681126, MKI F 16 L 55/04, 07/14/89.), Containing a cylindrical body, closed on both sides by covers with inlet and outlet nozzles, with a perforated tube placed in it and elastic damping elements.

 The disadvantage of these dampers is the incomplete use of the useful volume for damping pressure pulsations, and the inability to reduce hydraulic resistance when a fluid flows through it.

 The objective of the invention is the full use of the useful volume for damping pressure pulsations and the possibility of reducing the hydraulic resistance of the damper.

The problem is solved by the described damper of pressure fluctuations in pneumohydraulic systems, containing a cylindrical body closed on both sides with caps with inlet and outlet pipes, with a perforated pipe and elastic damping elements placed in it, the new one is that the pipes are equipped with perforated pipe inserts placed with the possibility of formation annular deadlock channels between the liners and the inner walls of the nozzles. In addition, the new fact is that the dead end ring channels are oriented towards the entrance with the open part and that the perforated channels in the tube inserts are made at an angle to their axis (it is advisable that the diameter of the tube inserts is 0.8-0.95 of the pipe diameter, length the tube liner was 10-25 gaps between the liner and the pipe, the degree of perforation of the pipe insert was 10-20%, the size of the holes of the perforation of the insert was 0.02-0.001 diameter of the pipe, and the angle of inclination of the beta perforated channels was in the range of 45-60 ^o to the axis insertion).

 Studies of patent and scientific and technical literature have shown that such a combination of essential features is new and has not been used before, and this, in turn, allows us to conclude that the technical solution meets the criterion of "novelty."

 This increases the efficiency of damping the pulsations of the pressure of the working medium, the reliability of the damper and decreases the hydraulic resistance of the damper, which leads to lower energy consumption for the passage of the working medium.

 The supply of the damper with perforated tube inserts allows to increase the throughput (productivity) of the damper and the efficiency of damping pressure and flow pulsations.

 When comparing the essential features of the invention, it was found that the perforated tube liners are installed in the suction and discharge nozzles, with the possibility of deadlock ring channels with the open part oriented to the input of the working flow and that the perforated channels in the tube liners are made at an angle to their axis, while change the direction of fluid movement in the annular channel and at the outlet of the perforation channels to the opposite, which leads to a decrease in the hydraulic resistance of the entire damper and allows you to partially suppress the pressure pulsation due to energy dissipation on the perforation of the insert.

 Since the proposed damper device can improve the efficiency of damping pressure pulsations, the reliability of the damper and reduce its hydraulic resistance, this leads to a reduction in energy consumption for the passage of the working medium, which is impossible to implement with any similar known device, this indicates the "inventive step" of the proposed devices.

 In FIG. 1, which shows a pressure pulsation dampener; in FIG. 2 - placement of a perforated tube insert.

 The damper for pressure and flow fluctuations in pneumohydraulic systems comprises a cylindrical housing 1, closed on both sides by caps 2 and 3 with inlet and outlet nozzles 4 and 5, respectively, a perforated pipe 6 coaxially mounted inside the housing 1 and elastic damping elements evenly placed around the perforated pipe 7 , pulled together in a bag, and perforated liners 8 and 9, coaxially installed in the nozzles 4 and 5, respectively.

 The proposed technical solution meets the criterion of "industrial applicability", since the possibility of its implementation is confirmed by a description of its work.

During the operation of the damper, the working medium flowing through the main pipeline enters the suction pipe. Figure 2 shows a schematic diagram of the flow of the working medium when passing through the suction (discharge) pipe. As can be seen from the drawing, a low-speed wall zone is formed between the pipe of the nozzle and the perforated insert. Entering the nozzle, the flow of the working medium is divided into the main, moving in the center, and auxiliary, moving near the inner surface of the nozzle. The central stream performs the main task of transporting the working medium, the auxiliary stream helps the main stream to move with greater speed, reducing the surface friction resistance of the main stream against the pipe surface and partially damping the pressure fluctuations of the main stream. The speed of the main stream (U) is much higher than the speed of the auxiliary stream (V), and therefore, the pressure in the main stream (P _v ) will be lower than the pressure in the auxiliary stream (Pv) in each section of the nozzle. Under the influence of the pressure difference between the main and auxiliary flow, the direction of movement of the auxiliary flow changes and is directed at an angle to the direction opposite to the main flow through the perforations of the liner, which leads to a decrease in friction losses and at the same time there is a partial damping of pressure pulsation due to energy dissipation on the perforation of the insert .

 The high-speed main stream is pushed away from the walls. Further, the flow through the perforation holes of the pipe 6 fills the cavity of the housing 1 and acts on the damping elements 7. The resulting pressure fluctuations lead to deformation of the damping elements 7. The damping of pressure fluctuations occurs due to deformation of the damping elements 7 and energy dissipation on the perforation of the pipe 6 and inserts 8 and 9.

 The design features of the pressure and flow pulsation dampers disclosed above make it possible to increase the efficiency of damping pressure pulsations and the flow rate of the working medium, increase the reliability of the damper, reduce the resistance of the damper, which will lead to reduced energy consumption for the passage of the working fluid and will significantly expand its operational capabilities.

References
1. Analogue: “Damping of pressure fluctuations for hydraulic lines,” ed. N 1006850, MKI F 16 L 55/04, dated 10.21.81.

 2. Prototype: "A damper for pressure and flow fluctuations in pneumohydraulic systems," autos N 1681126, MKI F 16 L 55/04, dated 14.07.89.).

Claims (3)

 1. The damper of pressure fluctuations in pneumohydraulic systems, comprising a cylindrical body, closed on both sides with caps with inlet and outlet pipes, with a perforated pipe and elastic damping elements placed in it, characterized in that the pipes are provided with perforated pipe inserts arranged to form annular deadlock channels between the liners and the inner walls of the nozzles.  2. The vibration damper according to claim 1, characterized in that the dead end ring channels with the open part are oriented to the input.  3. The vibration damper according to claim 1, characterized in that the perforated channels in the tube inserts are made at an angle to their axis.

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