CS254927B1 - Steam muffler - Google Patents

Abstract

The device solves the problem of noise attenuation arising from steam blowing from the inlet and safety valves of steam boilers. The purpose of the solution is to increase the efficiency of noise attenuation in the low-frequency range, achieved by expansion silencers, while maintaining all their existing advantages. The effect is achieved by placing a reflection chamber in front of the expander. The reflection chamber is made of a cylindrical body closed with tin, while the internal volume of the chamber is divided into two sections by a partition, interconnected by a connector. The reflection chamber reflects part of the acoustic energy transported by low-frequency noise components back, towards the noise sources. In this way, the penetration of low-frequency noise into the vicinity of the steam exhaust is prevented, which has a positive effect on the overall noise level in the vicinity of the exhaust. The silencer can be used wherever pressurized gases and vapors are released into the air, with the primary source of noise having a significant impact on the noise level in the vicinity of the exhaust.

Description

BACKGROUND OF THE INVENTION The present invention relates to a steam silencer for use in the exhaust pipes of steam boiler start-up and safety valves.

When the steam is exhausted through the valve, a sudden, sudden change in the specific volume of steam occurs behind the valve seat, which, together with a velocity close to critical, results in the formation of pulsating pressure waves and areas with intense steam turbulence. Both of these phenomena are accompanied by the emission of noise, referred to as primary, which extends through the connected exhaust pipe to the mouth of the pipe into the atmosphere. As a result of the high velocities of the flowing steam it is created in the exhaust! ducts additional noise parts (secondary noise) and, together with primary noise, increase the noise level around the steam outlet into the atmosphere above the allowable limit.

So far known and used silencers are of the expansion or absorption type. Expansion attenuators include noise attenuators of pressure reducing and safety valves, designed in the form of a diffuser with a built-in cascade of throttling networks, in which the entire kinetic energy of the steam is gradually measured. The disadvantage of these dampers is the considerable construction length. The most widespread silencers include those consisting of an inlet pipe, an expander located at the end of the inlet pipe, and a sheath directing steam exiting the atmosphere. The connection of the damper sheath to the inlet pipe is converted into porn couplings. arched and flat diens. The damping effect is achieved by dividing the steam stream into a number of small streams. A common drawback of these silencers is the low noise attenuation efficiency in the low frequency range; Furthermore, absorbers are known in which the acoustic energy is converted to thermal by friction of the steam particles against the fibrous or porous structure of the absorbent material. To reduce low-frequency noise, it is necessary to apply to thick layers of absorbing material, which increases the dimensions and weights of these devices. Moreover, the same silencing efficiency cannot be guaranteed consistently with these silencers after several years of operation. Due to the change in the state of the absorbent materials, the noise attenuation efficiency decreases.

The essence of the steam silencer consisting of an inlet pipe, an expander, a cone passage and a baffle according to the invention is to place a reflective chamber in front of the expander on the inlet pipe of the silencer. The silencer inlet pipe is divided into two parts by the reflective chamber. One part of it forms the entrance to the reflective chamber, the other part from the reflective chamber. The reflective chamber is formed by a cylindrical body closed by a bottom. Inside the reflective chamber is a radial partition dividing the internal volume of the chamber into two shekels. A connector is passed through the partition through which steam can flow from one section to another. A connector is a pipe of a selected length.

An advantage of such an expansion-reflective noise silencer design is that reflectively the chamber reflects some of the acoustic energy transported by the low-frequency components of the noise from the valve to the atmosphere, to sleep, towards the noise sources. In this way, the low-noise noise is prevented from entering the vicinity of the exhaust, which has a positive effect on the overall noise level. By improving the acoustic properties of the expansion silencers in the low-frequency range, a higher noise attenuation efficiency is achieved.

The accompanying drawing shows schematically an embodiment of a vapor silencer according to the invention.

The steam noise timer consists of a reflective chamber 1, an inlet pipe 2, an expander 3, a conical transition 4 and a baffle 5.

The reflective chamber 1 consists of a cylindrical body 6 closed by the bottoms 7. The reflective chamber 1 is divided into two sections 9 by a radial partition 8. the holes of which are offset radially and axially relative to each other. A conical transition 4 with a baffle S is welded to the reflective chamber 1. Along with her from the saddle we vented the rom to exhaust steam into the atmosphere, spreading the primary noise. Sudden changes in the flow cross-section of the steam in the reflecting chamber 1 represent discontinuities in which a part of the acoustic energy of the bed reflects towards the noise sources. Upon exiting the reflective chamber 1, the steam flows through the annular interspaces of the expander 3, where, as a result of sudden changes in the flow direction, the kinetic energy of the steam is converted to thermal and thus the steam pressure drops to atmospheric pressure.

Expansion can occur under both critical and subcritical conditions. Upon exiting the last expansion stage, the steam flow through the conical passage 4 and the baffle 5 is rotated in the venting direction.

The invention can be used wherever there is a discharge of pressurized gases and vapors into the atmosphere with a primary source of noise (armature, technological process) having a significant effect on the noise level around the exhaust,

Claims (1)

OBJECT OF A Vapor Damper consisting of an inlet pipe, an expander, a conical transition, and a baffle, characterized in that a reflex chamber (1) is provided to the incoming pipe (2), formed by a cylindrical body (6) OUT of the closed bottom (7), wherein the inner volume of the chamber is a partition (8J divided by two axes (9), connected to each other by a knob (10).