RU2779673C1 - Liquid or gas flow rate suppressor (frs) - Google Patents

Abstract

FIELD: pipeline accessories.

SUBSTANCE: invention relates to auxiliary devices for the pipeline and duct network. The liquid or gas flow rate suppressor includes a quenching chamber made with the possibility of twisting oncoming flows in opposite directions. The chamber is made in the form of a toroidal structure consisting of a hollow open torus with screw-shaped corrugations and a gap in the form of a central hole. A pair of inlet pipes is coaxially connected to the toroidal structure, the axes of which intersect the axis of the central hole, and on the side of the latter in the wall of the toroidal structure there is a pair of coaxial outlet holes separated by a central hole, the axes of which intersect the axis of the central hole and are oriented perpendicular to the axes of the inlet pipes.

EFFECT: when implementing the invention, higher manufacturability and a simpler design are achieved while ensuring a high degree of quenching of the energy of the flow.

3 cl, 2 dwg

Description

The invention relates to auxiliary devices for pipeline and air duct networks and can be used in hydraulic engineering and water supply, as well as in ventilation and air conditioning systems as an air distributor or nozzle for air humidification chambers.

Known is a device for damping the energy of a jet in a pressure conduit, including a concrete plug mounted in it with pressure pipelines located inside it, having a rectangular cross section at the inlet, repair and working gates with a drive, and in the conduit, each of the pressure pipelines has a spiral shape with the outlet section in the form of a truncated sector, while the working gates are installed on the end wall of the plug in the outlet section of the pressure pipelines (USSR Author's certificate for the invention No. 600236, publ. 30.03.1978).

The disadvantage of the known technical solution is the low efficiency of damping the flow energy and complex design.

The prototype of the proposed liquid or gas flow rate damper can be a liquid or gas flow rate damper, including a damping chamber with an attached inlet and outlet, an additional inlet with the possibility of attachment, and the possibility of placing an additional outlet, and forming a gap between the outlets, and twisting the opposite flows in opposite directions (USSR author's certificate for the invention No. 723285, publ. 03.25.1980, Bull. No. 11).

The disadvantage of this absorber is a complex design and a rather low degree of damping of the flow energy.

The technical task is to create a variant of the design of the absorber, which has a higher manufacturability due to the simplification of the design, providing a higher efficiency of damping the flow energy.

The technical result of the design of the device is a simpler design that provides a higher efficiency of damping the flow energy.

An additional technical result also consists in improving manufacturability by reducing the overall size and increasing the degree of flow energy damping.

Improving manufacturability by simplifying the design while providing a higher efficiency of damping the energy of the flow is achieved by the fact that in the damper of the velocity of the flow of liquid or gas, including a damping chamber with an outlet and an attached inlet, an additional inlet with the possibility of attachment, and the possibility of placing an additional outlet with the formation of a gap between the outlet holes, and swirling of counter flows in opposite directions, while the chamber is made in the form of a toroidal structure, consisting of a hollow open torus with screw-shaped corrugations and a gap in the form of a central hole, and a pair of inlet pipes is coaxially attached to the toroidal structure, axes which intersect the axis of the central hole, and from the side of the latter, in the wall of the toroidal structure, there is a pair of coaxial outlet holes separated by a central hole, the axes of which intersect the axis of the central hole and oriented perpendicular to the axes of the inlet pipes.

To increase the degree of damping of the flow energy, the inlet pipes are connected to the toroidal structure from the outside, and in the central hole an additional pipe is installed to communicate the outlet holes with each other, the ends of which are fixed in the outlet holes, and a pair of coaxial through holes is made in the pipe wall, the axes of which cross the wall of the toroidal structure.

To increase the degree of damping the energy of the flow, the pipe is made cylindrical and with a round cross section, and an internal screw thread is made from the inside of the pipe to swirl counter flows in opposite directions.

The essence of the design variant of the proposed technical solution is illustrated by drawings: in Fig. 1 schematically shows the absorber (general view); in fig. 2 schematically shows the absorber (general view with the pipe).

The flow velocity damper contains a toroidal structure 1 formed by a hollow corrugated open torus with helical corrugations with a central hole 2, inlet pipes 3, outlet holes 4 and a pipe 5 with a pair of opposite coaxial through holes 6.

The absorber works as follows.

From the pipeline, water or from the air duct, air enters at high speed into the inlet pipes 3 and then into the toroidal structure 1, in which the flows are separated, twisted and flow towards each other with subsequent collision, due to which the kinetic energy of the flows is extinguished (in Fig. 1 ). Kinetic energy is also spent on collision and friction of oncoming flows. The resultant streams enter the central hole 2 through the outlet holes 4. In the central hole 2 the resultant flows collide with each other, further reducing the kinetic energy. The inlet pipes 3 are coaxially attached to the toroidal structure 1, and the axes of the inlet pipes 3 intersect the axis of the central hole 2, and from the side of the central hole 2, in the wall of the toroidal structure 1, there is a pair of coaxial outlet holes 4 separated by a central hole 2, the axes of which are oriented perpendicular to the axes inlet pipes 3. To increase the degree of damping of the flow energy, the inlet pipes 3 can be attached to the toroidal structure 1 from the outside (in Fig. 2), and in the central hole an additional pipe 6 is installed to communicate outlet holes 4 with each other, the ends of which are fixed in the outlet holes 4, and in the wall of the pipe 5 a pair of coaxial through holes 6 is made, the axes of which intersect the wall of the toroidal structure 1. To increase the degree of damping of the energy of the flow, the pipe 5 is cylindrical in shape and has a round cross section, and an internal screw thread is made from the inside of the pipe 5 and for spinning oncoming flows in opposite directions (not shown in the drawing). The device can be used as a nozzle for spraying water in the humidification chambers of air conditioners.

Claims (3)

1. A liquid or gas flow velocity damper, including a damping chamber configured to spin opposite flows in opposite directions, characterized in that the chamber is made in the form of a toroidal structure consisting of a hollow open torus with helical corrugations and a gap in the form of a central hole, moreover, a pair of inlet pipes is coaxially connected to the toroidal structure, the axes of which intersect the axis of the central hole, and on the side of the latter in the wall of the toroidal structure there is a pair of coaxial outlet holes separated by the central hole, the axes of which intersect the axis of the central hole and are oriented perpendicular to the axes of the inlet pipes. 2. The damper according to claim 1, characterized in that the inlet pipes are connected to the toroidal structure from the outside, and in the central hole there is an additional pipe for connecting the outlet holes with each other, the ends of which are fixed in the outlet holes, and a pair is made in the pipe wall coaxial through holes, the axes of which intersect the wall of the toroidal structure. 3. The damper according to claim 2, characterized in that the pipe is made cylindrical and with a round cross section, and an internal screw thread is made from the inside of the pipe to swirl counter flows in opposite directions.

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