SU998810A1 - Apparatus for suppressing pressure and flowrate fluctuations in forging pipeline - Google Patents

Description

The invention relates to mechanical engineering, in particular to hydraulic structures, where pumping and injection units are used for transporting liquid through long pipelines.

A device for damping pressure and flow fluctuations in an injection pipeline is known, including a sealed damping shell located on a perforated section of the pipeline so that its internal cavity is connected to the internal cavity of the pipeline (£ 1).

A disadvantage of the known device is the implementation of a damping shell made of an elastic material and the presence of a chamber with compressed air around it, which requires technological pressurization of the chamber in the device body for its normal functioning, reduces the range of operating temperatures and frequencies of the damping device, and also tightens its performance, thereby reducing The very efficiency of damping pressure fluctuations in a pipeline. .

The aim of the invention is to increase the efficiency of the damping device.

The goal is achieved due to the fact that the device for damping pressure and flow fluctuations in the discharge pipe containing a sealed damping shell located on the perforated section of the pipeline so that its internal cavity is connected to the internal cavity of the pipeline, the damping shell is made in the form of autonomous chambers, evenly spaced along the perimeter of the pipeline and made of a material with a high modulus of elasticity;

As a material for damping chambers, spring steel is used.

In FIG. 1 shows the proposed device, a longitudinal section; in FIG. 2 - the same, transverse section; in the initial, inoperative state, in FIG. 3 - the same cross-section, in working condition · (B - pressure in the pipeline is normal *, C - increased pressure).

The device comprises a pipeline 1 with perforated sections 2 and autonomous damping chambers 3 uniformly distributed along the perimeter of the pipeline and hermetically fixed on it so that their internal cavities are connected through perforation to the internal cavity of pipeline 1. The number of chambers can be different * and is determined based on from the specific requirements for the dynamics of the line and the discharge unit.

The device operates as follows. at once.

In the initial state, in the absence of a working medium in the pipeline 1 and chambers 3, the latter have the form A, Yu shown in FIG. 2. When the transported medium is supplied to the discharge pipe 1 in a steady quasistatic mode, the liquid enters the cavities of the damping chambers 3 through the perforation in the sections 15 of the pipeline 2, which at the same time take the working form B shown in FIG. 3. If pressure fluctuations occur in the pipe-20 wire? Under the action of pressure and flow waves, an instantaneous linear movement of the chambers 3 takes place, which are stretched and take the form B, also shown in FIG. 3. The maximum 25 maximum linear displacements of chambers 3 occur at the time of the impact of the water hammer, when the maximum amplitude of oscillations in the line occurs.

When the pressure in the pipeline 1 decreases, part of the liquid from the chambers 3 passes through the perforation back into the pipeline, while the chambers shine take the form B in the case of normal pressure, or the form A in the case of reduced pressure.

Due to the great flexibility of the damping chambers, the pressure and splitting oscillations are suppressed, while choosing the geometric parameters of the chambers and the total area, perforation, we can achieve the maximum reduction in the amplitude of pressure oscillations and the removal of the natural frequency of the oscillations of the line from the resonance region.

The proposed device is universal, as it can work effectively with any previously set mode of dynamic effects.

Claims (2)

The invention relates to mechanical engineering, in particular to hydraulic structures, where pumping and injection installations are used for transporting fluid through long-distance pipelines. A device for damping pressure and flow fluctuations in an injection pipeline is known, which includes a hermetic damping casing located in the perforated section of the pipeline. that its internal cavity is connected to the internal cavity of the pipeline Cl. A disadvantage of the known device is the implementation of a damping shell made of elastic material and the presence of chambers with compressed air around it, which requires technological pressurization of the chamber in the body of the device for its normal operation reduces the operating temperature and frequency of the damping device and reduces its performance, reducing This is the effect of damping pressure fluctuations in the pipeline. The aim of the invention is to increase the efficiency of the damping device, the goal is achieved due to the device for damping pressure fluctuations and flow in the discharge pipe containing a sealed damping sheath placed in the perforated section of the pipeline so that its internal cavity is connected to the internal cavity of the pipeline damping casing is made in the form of autonomous chambers evenly spaced along the perimeter of the pipeline and made of material from -y OKIMO modulet elasticity; In Ka4ecTBJe, spring steel is used for damping materials. FIG. 1 shows the proposed device, a longitudinal section I in FIG. 2 - the same, cross cut | in the initial, inoperative state in Fig. 3 - the same, cross section, in the operating state (B - pressure in the pipeline is normal; C - increased pressure). The device contains a pipeline 1 with perforated sections 2 and independent damping chambers 3, uniformly distributed around the perimeter of the pipeline and hermetically fixed on it so that their internal cavities are connected through perforation to the internal cavity of the pipeline. The number of chambers can be different requirements for the dynamics of the line and injection installation. The device operates as follows. In the initial state, when there is no working medium in the pipeline 1 and the privateers 3, the latter have the form A shown in FIG. 2. When the transported medium is supplied to the injection pipe 1 in a steady-state quasi-static mode, liquid through perforations in pipeline sections 2 water enters the cavities of the damping chambers 3, which then take the working form B shown in FIG. 3. When pressure oscillations occur in the pipeline under the action of pressure and flow waves, an instantaneous linear movement of the chambers 3 occurs, which expand to take the form B, also shown in FIG. 3. The maximum linear displacements of the chambers 3 occur at the time of the impact of the water hammer, when the maximum amplitudes of oscillations in the main line occur. When the pressure in the pipeline 1 decreases, part of the liquid from the chambers 3 goes through the perforations back into the pipeline, and the chambers sit down to form B in the case of normal pressure, or form L in the case of reduced pressure. Due to the great flexibility of the degreasing chambers, pressure oscillations and the splitting are quenched. With this choice of the geometrical parameters of the chambers and the total area of perforations, the amplitude of pressure fluctuations can be maximized and the natural frequency of oscillations from the resonance region can be removed. The proposed device is universal, since it can effectively work under any pre-specified dynamic action mode. Claim 1. A device for damping a kibble of the pressure and flow rate in the injection pipeline, containing a sealed damping sheath placed in the perforation section of the pipeline so that its internal cavity is connected to the internal cavity of the pipeline, so that In order to improve the efficiency of the operation, the damping casing is manufactured in the form of autonomous chambers evenly spaced around the perimeter of the pipeline and made of a material with a high modulus of elasticity. 2. The device according to claim 1, clause 1 and -, so that spring steel is used as the material for the damping chambers. Sources of infurmation, taken into account during the examination 1. German patent 1096694, cl. 47 1/10, published. 1961 (prototype). / L bm 3