SU1060572A1 - Vacuum dearation apparatus - Google Patents

Abstract

1. A VACUUM DEAERATOR INSTALLATION containing a water jet ejector in series with deaerated water with a mixing chamber of active and passive streams, a gas separator tank, a pump, a heater, a heated water nozzle connected to an aerial cylindrical deaerator reported through a steam ejector mixing chamber. distinguished by the fact that, in order to reduce metal consumption and. dimensions, the mixing chamber of the ejector is placed in the upper part of the deaerator, the superheated water nozzle is connected to the deaerator tangentially at the location of the mixing chamber, and the output part of the superheated water nozzle is expanded to the horizontal upper boundary plane. 2, Installation according to claim 1, wherein the height in the slot of the nozzle at the entrance to the deaerator, the angle about {between the axis of the nozzle and the horizontal and the diameter D of the deaerator are related by the equation ",

Description

The invention relates to water treatment devices for heat supply and hot water supply systems, mainly in industrial and heating boiler houses and central heat points of heat: networks A vacuum deaerator installation is known, comprising a water jet ejector with a jet-forming perforated mixing chamber and a diffuser, as well as a tank gas separator, pump and evaporator cooler (YJ. The water in the circuit is heated by the heat of the vapor, a significant hour of which is not caught in the cooling l and steam and for The efficient operation of the vacuum system requires that some of the water in the circuit be discharged and replaced with fresh cold water, which leads to loss of heat and water; as well as complication of operation. A vacuum deaerator installation is known that contains a water-jet ejector with a mixing chamber sequentially connected to the water being deaerated. active and passive flow tank separator, pump, heater, superheated water nozzle connected to a vertical cylindrical deaerator communicated through a vapor with an ezek mixing chamber torus 2. The drawback of the device is the large dimensions of the jet columns, which leads to an unnecessary complexity of the design and increased metal consumption in the apparatus. The purpose of the invention is to reduce the metal and installation dimensions. The goal is achieved by the fact that in a vacuum deaerator installation containing a water-jet ejector with successively connected in deaerated water with a mixing chamber of active and passive flow, the tank-gas outlet: a litter, a pump, a heater, conj:; o heated superheater connected to a vertical cylindrical deaerator . reported through the evaporator with the ejector mixing chamber, the ejector mixing chamber is located in the upper part of the deaerator, the superheated water nozzle is connected to the deaerator torus tangentially at the location of the mixing chamber, and the outlet to the horizontal upper boundary plane is reached. In this case, the height of the nozzle slit at the entrance to the deagfator, the angle between the axis of the nozzle and the horizontal and the diameter of the deaerator are related by the equation b-TT.Dtgf Under this condition, a uniform filling of the inner surface of the pipe - water separator flowing down the helix is achieved. Fig, 1 shows a diagram of a vacuum deaerator installation in Fig, 2 is a section of a vertical cylindrical deaerator. The vacuum deaerator installation contains a water jet ejector 1 with a mixing chamber 2 of active and passive streams in series through deaerated water, a gas separator 3, a pump 4, a heater 5, a superheated water nozzle b connected to a vertical cylindrical deaerator 7 connected to the ejector blending chamber 2 1, Mixing chamber 2 is placed in the upper part of deaerator 7 ,, the superheated water nozzle 6 is connected to the deaerator 7 at the location of the mixing chamber 2, with the outlet part of the superheated water nozzle 6 The extension of the horizontal upper boundary plane 8, the height of the slit of the nozzle C at the entrance to the deaerator 7, the angle between the axis of the nozzle 6 and the horizontal and the diameter of the deaerator 7 are related by the equation b-IV-Di l where b is the height of the slit of the nozzle at the entrance to the deaerator ; D is the diameter of the deaerator; oL- is the angle between the axis of the nozzle and the horizontal. The installation also contains a raw water inlet 9, a collection tank 10 and a pump 11 for pumping de-aerated water. The installation works as follows. Cheese water through the pipe 9 is fed into the ejector 1 and creates in its mixing chamber 2 the necessary vacuum. Water overheated in the preheater 5, having a temperature higher than the saturation temperature under pressure (vacuum) in the upper deaerator 7, enters the nozzle b. Here, water boils up and water is released from it along with the vapor of dissolved gases. From the nozzle b the vapor-air mixture enters tangentially ( tangential) inside the deaerator 7, and the centrifugal force arising due to the tangential entry throws water onto the walls, and the lighter vapor-gas CMect. is collected in the center of the deaerator 7 and is sucked into the mixing chamber 2 of the ejector 1, the vapor entering the lubrication chamber 2 condenses in cold water and heats it, and the water with trapped gases goes to the gas separator tank 3, where the water flows to the non-condensable gases that discharge in atmosphere. Water

The gas separator tank 3 is pumped into the heater 5, where it is heated to a predetermined temperature and is fed to the deaeration in the nozzle 6. The deaerated water is discharged into the collection tank 10, from where it is supplied to the consumer by pump 11.

The placement of the working chamber 2 of the mixing ejector 1 inside the upper part of the deaerator 7 and the use of the latter as a centrifugal separator provide a purely radial movement of the expired vapor-gas phase within chamber 2

mixing the ejector 1, which eliminates the need to increase the flow area (i.e., the annular channel between chamber 2 and deaerator 7 for the vapor-gas phase to pass in the axial direction. In addition, water reabsorption of gases that might occur during axial movement is minimized gases along the film, the proposed technical solution will reduce the intensity and size of the vacuum deaerating installation.

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Fi & 1

Claims (2)

(57 ') 1. VACUUM DEAERATOR PLANT containing a water-jet ejector with a mixture of active and passive flows, a gas separator tank, a pump, a heater, a superheated water nozzle connected to a vertical cylindrical deaerator, connected via a vapor to the mixing chamber, in series with a deaerated water ejector, characterized in that, in order to reduce metal consumption and. dimensions, the ejector mixing chamber is located in the upper part of the deaerator, the superheated water nozzle is connected to the deaerator tangentially at the location of the mixing chamber, and the outlet part of the superheated water nozzle is made expanding with a horizontal upper boundary plane. 2. Installation according to π. 1, the fact that the height in the slot of the nozzle at the inlet of the deaerator, the angle o £ between the axis of the nozzle and the horizontal, and the diameter D of the deaerator are related by the equation