RU2684296C1 - Angular anti-vibration isolation pipe with vibrating masses - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to pipeline systems and can be used as a vibration isolating and compensating connection in vibroactive pipeline hydraulic systems. Angular vibroisolating compensating branch pipe consists of external and internal U-shaped bodies, internal knee-shaped housing connected to each other through annular thin-layer rubber-metal elements with vibro-retaining masses. There is no metal contact between the housings.EFFECT: high vibration-insulating properties of branch pipe in wide frequency range in all directions are ensured by installation of vibro-retaining masses between thin-layer rubber-metal elements located perpendicular to each other.1 cl, 1 dwg

Description

(The technical field to which the invention relates)

The invention relates to mechanical engineering, namely to pipeline systems and can be used as a vibration-isolating and compensating connection in vibroactive hydraulic piping systems, for example, for connecting equipment and pipelines of circulating routes of power plants of ships and ships, in main oil pipelines.

(Prior art)

Known for the prototype is the angular compensation nozzle with thin-layer elastomeric elements (Kiryukhin A.V., Tikhonov V.A., Chistyakov A.G. Vibration characteristics of the angular compensation nozzle with thin-layer elastomeric elements // Problems of Mechanical Engineering and Machine Reliability. 2007, No. 1 , Pp. 103-108), used in ship pipelines of circulating seawater routes.

The pipe consists of an outer and inner U-shaped cases, an internal L-shaped case, interconnected through thin-layer rubber-metal elements so that there is no metal contact between the cases. The thin-layer rubber-metal element (RF patent 2538500 C2, class F16F 1/40, F16F 3/08) contains alternating layers of elastomer and metal reinforcing plates placed between the metal support rings. Thin-layer rubber-metal elements in the pipe are perpendicular to each other, which ensures relative movements of the bodies in all directions.

The effectiveness of the specified compensation pipe in the frequency range of 10-200 Hz is 20 dB (Tikhonov V.A., Chistyakov A.G. Development of vibration isolation systems for high-pressure pipes and vehicles. - Proceedings of the international conference: "Machines, technologies and materials for modern Engineering ”, dedicated to the 75th anniversary of the A. A. Blagonravov Institute of Mechanical Engineering of the Russian Academy of Sciences. Moscow. 2013. P. 107). However, in some cases, an additional increase in the vibration-isolating efficiency of the nozzles is required.

(Disclosure of invention)

The problem solved by the invention is to increase the vibration isolation efficiency in a wide frequency range in all directions.

This problem is solved due to the fact that the claimed angular vibration-isolating compensation pipe with vibration-holding masses consists of an external and internal U-shaped housing, an internal elbow-shaped housing interconnected through ring thin-layer rubber-metal elements with vibration-retaining masses so that there is no metal contact between the housings, and characterized in that the vibration-holding masses installed in the nozzle between the thin-layer rubber-metal elements provide ayut high vibration insulation properties over a wide frequency range in all directions. Thin-layer rubber-metal elements consist of thin alternating layers of rubber and metal.

(Brief Description of Drawings)

The invention is illustrated by the drawing: in FIG. 1 shows a longitudinal section of an angular vibration-isolating compensation pipe with vibration-holding masses.

(Implementation of the invention)

An angular vibration-isolating compensation pipe with vibration-holding masses consists of an external (1) and internal (2) U-shaped body, an internal knee-shaped body (3), interconnected via ring thin-layer rubber-metal elements (4) with ring vibration-holding masses (5) so that there is no metal contact between the cases. Thin-layer rubber-metal elements (4) have low stiffness in the transverse direction and high in the axial. The housing (1) is rigidly attached to the inlet flange (6), and the housing (2) is rigidly attached to the output flange (7). Ring vibration-holding masses (5) are installed between ring thin-layer rubber-metal elements (4) to increase vibration-isolating efficiency. Ring thin-layer rubber-metal elements (4) with vibration-holding masses (5) are located perpendicular to each other to move the bodies in all directions. The inlet (6) and outlet (7) flanges are designed to unfasten the pipe to the pipeline and vibroactive equipment.

Angular vibration-compensating pipe with vibration-holding masses works as follows. Vibroactive equipment is attached to the inlet flange (6) of the nozzle. The vibrational energy transmitted from the vibratory equipment is absorbed by thin-layer rubber-metal elements (4) with a vibration-holding mass installed between them (5): vertical elements in the Y and Z directions, horizontal in the X and Z directions. In the nozzle, vibration-holding masses (5) with thin-layer rubber-metal elements (4) are located perpendicular to each other, which provides relative movements of the housings in all three directions. On the output flange (7) connected to the hydraulic system pipeline, the value of vibrational energy is significantly reduced in a wide frequency range.

The proposed design of an angular vibration-isolating compensation pipe with vibration-holding masses allows to increase the vibration-isolating efficiency in a wide frequency range in all directions. Conducted bench tests of ring-shaped thin-layer rubber-metal elements with vibration-holding mass confirm the effectiveness of the proposed technical solution. The fabricated samples of ring thin-layer rubber-metal elements are a package of duralumin rings 1.5 mm thick (17 pcs.) With interlayers of rubber grade IRP-2025 1 mm thick (18 pcs.) Glued with 88-Metal waterproof adhesive. The geometric dimensions of the ring-shaped thin-layer rubber-metal element: inner diameter 100 mm, outer diameter 180 mm, height 48 mm. The value of the installed vibration-holding mass is 23 kg. The effectiveness in the frequency range of 20-1600 Hz of the tested thin-layer rubber-metal elements with a vibration-holding mass installed between them exceeds the efficiency of one thin-layer rubber-metal element by up to 50 dB, two thin-layer rubber-metal elements bonded to each other by up to 40 dB.

The achieved technical effect is ensured by the installation of a vibration-holding mass between thin-layer rubber-metal elements.

Claims (1)

An angular vibration-isolating compensation pipe with vibration-holding masses consists of an external and internal U-shaped bodies, an internal knee-shaped body, interconnected via thin-layer annular rubber-metal elements with vibration-holding masses so that there is no metal contact between the bodies, and characterized in that the vibration-holding in the pipe masses between thin-layer rubber-metal elements provide high vibration-isolating properties in a wide range frequency range in all directions.

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