RU2311584C2 - Pressure stabilizer - Google Patents

Abstract

FIELD: engine engineering.

SUBSTANCE: pressure stabilizer comprises hollow cylindrical housing (1) whose diameter is no less than the five diameters of the central pipeline, inlet branch pipe (2), and outlet branch pipe (3). Hollow cylindrical housing (1) receives baffles (4) that form air chambers (5). The chambers play a role of flexible pulsation damper. Perforated sleeve (6) are mounted at the center of baffle (4) coaxially to the hollow cylindrical housing. The diameter of the sleeves is equal to the diameter of the central pipeline. The spaces between the sleeves are equal to 10-20 mm. The section of supplying branch pipe (2) receives the main fluid flow, is set in the hollow cylindrical housing (1), and is made of perforated sleeve (7).

EFFECT: enhanced reliability.

3 cl, 1 dwg

Description

The stabilizer is designed to damp pressure and flow fluctuations during the passage of pulsating flows of the working medium through the flow meter, for example, when taking into account fuel consumption by diesel engines.

Pulsating flows differ from constant ones in that when passing through the flowmeter, the flow rate and pressure are constantly changing.

When measuring the average value of pulsating flows, in most cases there is an additional error, the magnitude and sign of which depend both on the type, nature and magnitude of the pulsations, and on the type of measuring instruments used.

Known devices designed to reduce forced pressure fluctuations, which use the principle of dissipative and elastically deforming effects on the pulsating flow when it is passed through perforation holes and interacts with the walls of the damping chambers, namely a pressure stabilizer containing a hollow cylindrical body with flanges, covering located in it the central perforated pipe communicated by the perforation holes with the damping chamber formed by the shell is set between the flanges in the housing coaxially to the central pipeline (RF Patent No. 213906, 07.27.1999, F16L 55/04).

A pressure stabilizer is also known, comprising a hollow cylindrical body with flanges, covering a cylindrical perforated spacer located in it, additional cylindrical bodies with perforated partitions and damping elements installed in them, and elastic damping inserts placed in the annular pre-chamber (Patent RF №2133905, 07.27.1999, F16L 55/04).

The disadvantages of the known devices is the design complexity due to the presence of damping (elasto-deforming) elements and the presence of complicating the construction of several additional hollow cylindrical bodies filled with perforation baffles and damping elements, in addition, most of the stabilizer volume is occupied by a central perforated pipe and damping elements, which makes it difficult to pass the main fluid flow.

The closest in technical essence to the proposed device is a pressure stabilizer selected as a prototype, comprising a hollow cylindrical body with flanges, enclosing a central perforated pipe located therein, communicated by perforation holes with a damping chamber formed by a shell with perforation holes installed coaxially between the flanges in the body the central pipeline (RF Patent No. 2249751, 10/13/2003, F16L 55/04).

The disadvantages of this device is the design complexity, since a significant part of the volume of the stabilizer is irrationally occupied by a central perforated pipe and shells with perforations that stabilize the flow in the transverse direction and prevent the passage of the main flow of the working medium. In addition, the known device only works in a horizontal position, when tilted and in a vertical position, air will be removed from the device, which can lead to a malfunction of both the engine and the flow meter, and the pressure stabilizer itself will not work.

The objective of the invention is to simplify the design of the pressure stabilizer while ensuring maximum smoothing of the amplitude of the pulsations of the flow regardless of the direction of flow of the medium, as well as regardless of the horizontal or vertical installation of the device, and to ensure the manufacturability of the design.

The task is achieved in that in a pressure stabilizer containing a hollow cylindrical body, covering with the formation of an annular precamera, a coaxially cylindrical perforated pipe installed inside it equal to the diameter d of the conditional passage of the central pipeline, the inlet and outlet pipes in the hollow cylindrical body are installed sequentially one after another along its longitudinal axis of the partition, forming at least two air chamber-sections, perforated it is filled in the form of cups perforated along the side surface with a blind bottom from the side of the outlet pipe, installed in the center of each partition coaxially to the hollow cylindrical body in the direction of the main flow of the working medium, so that gaps l are formed between them, located in the center of the air chamber sections and equal to 10-20 mm, and the portion of the inlet pipe at the inlet of the main flow of the working medium located in the hollow cylindrical body is made in the form of a perforated cup on the side surface, and Perforation holes on the side surface of the glasses are located near the bottom of the glass. The total area of the perforation holes on the side surface of the glass is 30-50% of the passage area of the central pipeline. The diameter D of the hollow cylindrical body is at least five diameters du of the conditional passage of the central pipeline. The distance L between the partitions is not less than five diameters dу of the conditional passage of the central pipeline.

The proposed pressure stabilizer greatly simplifies the design of the device and increases the throughput of the stabilizer, since there are no additional damping devices in the hollow cylindrical body, complicating the design of the device and preventing the flow of the working medium.

The drawing shows a structural diagram of a pressure stabilizer.

The pressure stabilizer comprises a hollow cylindrical body 1, the diameter of which is not less than five diameters du of the conditional passage of the central pipeline, with inlet 2 and outlet 3 nozzles. In the hollow cylindrical body 1, partitions 4 are installed, forming air-chamber sections 5, which act as an elastic ripple dampener. In the center of the partition 4, cups 6 perforated along the side surface are installed coaxially to the hollow cylindrical body 1, the diameter of which is equal to the diameter dу of the conditional passage of the central pipeline, so that between them gaps l equal to 10-20 mm are formed. The section of the supply pipe 2 at the inlet of the main flow of the working medium, located in the hollow cylindrical body 1, is made in the form of a perforated cup on the side surface 7. The distance L between the partitions 4 has been experimentally chosen with at least five diameters d for the conditional passage of the central pipeline.

The pressure stabilizer operates as follows. In the event of unstable flow conditions of the working medium, the pressure (flow) fluctuations in the stabilizer are damped due to multiple dissipation of the vibration energy on the distributed perforation of the perforated holes of the glasses 6, and also due to the air-chamber sections 5 formed by the partitions 4, which act as an elastic damper for the pulsations of the working flow Wednesday. Perforated glasses 6 and 7 divide the main jets of the working medium flow supplied through the inlet pipe 2 into smaller ones, thereby reducing the size and nature of the pulsations of the flow, the final smoothing of the pulsations of the working fluid flow occurs with the help of the air chamber sections 5 due to multiple reflection of the secondary waves from the walls of the partitions 4 and the hollow cylindrical body 1. Selected experimentally - the total area of the perforation holes on the side surface of the perforated glasses is 30-50% of the area and the bore of the central pipeline and the diameter of the hollow cylindrical body 1 in comparison with the diameter dу of the conditional bore of the central pipeline is made in a ratio of at least 5: 1 - provide maximum smoothing of the amplitude of the flow pulsations. Perforated on the side surface of the glasses 6 and 7 with gaps l between them equal to 10-20 mm and located in the center of the air chamber sections 5, allow you to use the flow stabilizer in any position (horizontally, vertically, obliquely at any angle). Moreover, the location of the perforation holes on the side surface of the glasses 6 and 7 near the bottom of the glasses prevents the removal of air from the device at any operating position of the stabilizer.

The presence in the device design of glasses 6 and 7 perforated along the side surface, as well as the possibility, depending on working conditions and the nature of the working medium, to install additional partitions 4 with glasses 6 perforated along the side surface, makes it possible to smooth out the pulsation amplitudes of the working medium flow, both high-frequency and low-frequency, which, in turn, will improve the accuracy of measuring the flow rate of the medium.

Stabilizer parts are made of carbon structural or corrosion-resistant steels, depending on the operating conditions of the work, which are determined by the properties of the working environment. The pressure stabilizer is installed in the Central pipeline using flanges or using a threaded connection of the inlet 2 and outlet 3 nozzles with the Central pipeline, as well as any other type of connection (welding, clamps, etc.).

A pressure stabilizer with such a design ensures maximum damping of pulsations of the flow of the working medium and at the same time differs in its simplicity of design and manufacturability. In addition, such a flow stabilizer is universal, it can be used both horizontally mounted, and vertically or obliquely.

It is advisable to use the proposed technical solution for measuring pulsating costs when taking into account fuel consumption on diesel engines of diesel locomotives, mining trucks, and ships.

Claims (4)

1. A pressure stabilizer comprising a hollow cylindrical body, covering, with the formation of an annular prechamber, a coaxial cylindrical perforated pipe installed inside it, equal to the diameter dy of the conditional passage of the central pipeline, inlet and outlet pipes, characterized in that the hollow cylindrical body is installed sequentially one after another along its longitudinal axis of the partition, forming at least two air chamber sections, the perforated pipeline is made in the form of perforation They are located along the side surface of glasses with a blind bottom from the side of the outlet pipe, installed in the center of each partition coaxially to the hollow cylindrical body in the direction of the main flow of the working medium, so that between them gaps l are formed, located in the center of the air chamber sections and equal to 10 20 mm, and the portion of the inlet pipe at the inlet of the main flow of the working medium located in the hollow cylindrical body is made in the form of a perforated cup on the side surface, and perforated holes The sides of the glasses are located near the bottom of the glass. 2. The stabilizer according to claim 1, characterized in that the total area of the perforation holes on the side surface of the glass is 30-50% of the passage area of the central pipeline. 3. The stabilizer according to claim 1, characterized in that the diameter D of the hollow cylindrical body is at least five diameters dy of the conditional passage of the central pipeline. 4. The stabilizer according to claim 1, characterized in that the distance L between the partitions is at least five diameters dy of the conditional passage of the central pipeline.