RU86491U1 - LIQUID ADSORBENT REGENERATION DEVICE - Google Patents

Abstract

1. A liquid adsorbent regeneration device comprising a cylindrical working chamber, spray nozzles and a microwave radiation source, characterized in that the cylindrical chamber is mounted vertically and passes into the gas duct at the top and into the drain port of the dehydrated absorbent, the microwave source includes magnetrons and waveguides attached to them, supplying radiation to communication windows located in the central part of the working chamber, closed by radio-transparent sealing inserts , The nozzles are fixed on the wall of the working chamber below the communication window and directed at an acute angle to its axis upwards. ! 2. The device according to claim 1, characterized in that the magnetrons are protected by gates or circulators installed in the waveguides. ! 3. The device according to claim 1, characterized in that the sealing inserts are made of fluoroplastic. ! 4. The device according to claim 1, characterized in that the gas duct is fixed to the working chamber by means of a flange connection.

Description

The utility model relates to a technique for drying gases, namely, to devices for regenerating a liquid adsorbent and can be used to dry aqueous glycol solutions.

A known device for the regeneration of a liquid adsorbent containing a cylindrical working chamber, spray nozzles and a microwave source (see patent CN 1935324, CL. B01D 53/74, publ. 28.03.2007). A disadvantage of the known device is the inefficient heating of the aerosol of a liquid adsorbent and, as a result, the inefficient operation of the device.

The objective of the utility model is to eliminate these drawbacks. The technical result consists in increasing the uniformity of filling the chamber with an aerosol and increasing the reliability of the microwave source. The problem is solved, and the technical result is achieved by the fact that in the device for the regeneration of liquid adsorbent containing a cylindrical working chamber, spray nozzles and a microwave radiation source, the cylindrical chamber is mounted vertically and passes into the upper part of the duct, and in the lower part into the drain port of the dehydrated absorbent the microwave radiation source includes magnetrons and waveguides attached to them, supplying radiation to communication windows located in the central part of the working chamber, Closing the radiotransparent sealing inserts, the nozzles mounted on the wall of the working chamber below the communication window and directed at an acute angle to its axis upwards. It is advisable to protect magnetrons with gates or circulators installed in waveguides. Sealing inserts can be made of fluoroplastic. The flue can be fixed to the working chamber by means of a flange connection.

The drawing shows the proposed device in cross section.

The liquid adsorbent regeneration device is a vertically mounted cylindrical working chamber 1, which in the lower part passes into the drain pipe 2 of the dehydrated absorbent. A gas duct 4 is fastened to the upper part of the chamber 1 by means of a flange connection 3. Communication windows 5 are located in the central part of the chamber, which are closed by fluoroplastic seals 6. The waveguides 7, coming from the magnetrons and equipped with gates or circulators (not shown in the drawing), are connected to the communication windows 5. Below the communication windows 5 there are nozzles 8 directed at an acute angle to the axis of the chamber 1 upward, in which aerodynamic, piezoceramic or magnetostrictive spraying devices are used.

The device operates as follows.

Through the spray nozzles 8, an adsorbent in the form of an aerosol is supplied to the chamber 1. Microwave radiation generated continuously by magnetrons at frequencies of 2450 MHz or 915 MHz and a power of 1 kW propagates through waveguides 7 and through communication windows 5 enters camera 1, where it excites multimode microwave oscillations. An aerosol cloud having a developed surface is effectively heated by absorption of microwave energy. Since the nozzles 8 are directed upward and located below the communication windows 5, aerosol particles fly past the windows 5 twice: upward and then under the influence of gravity downward. Moreover, they are longer in a free state inside the chamber 1, which allows to increase the uniformity of filling the chamber with aerosol, as well as to increase the efficiency of absorption of microwave energy. The resulting water vapor leaves through the gas duct 4, and the dehydrated adsorbent flows down the walls of the chamber 1 through the pipe 2 into the receiving tank (not shown in the drawing). From there, it can, if necessary, be again fed to the nozzles, forming a closed processing cycle. In the case of a large amplitude of the electromagnetic wave reflected from the communication windows 5, the magnetrons protect the valves or circulators located in the waveguides 7. Removing the microwave generators (magnetrons) from the working chamber through the use of waveguides, as well as isolating the waveguides from the volume of the chamber 1 with sealing inserts 6 allows increasing the efficiency of the microwave source.

Using the proposed device can increase the final concentration of glycol to 99.5%.

Claims (4)

1. A liquid adsorbent regeneration device comprising a cylindrical working chamber, spray nozzles and a microwave radiation source, characterized in that the cylindrical chamber is mounted vertically and passes into the gas duct at the top and into the drain port of the dehydrated absorbent, the microwave source includes magnetrons and waveguides attached to them, supplying radiation to communication windows located in the central part of the working chamber, closed by radio-transparent sealing inserts , The nozzles are fixed on the wall of the working chamber below the communication window and directed at an acute angle to its axis upwards. 2. The device according to claim 1, characterized in that the magnetrons are protected by gates or circulators installed in the waveguides. 3. The device according to claim 1, characterized in that the sealing inserts are made of fluoroplastic. 4. The device according to claim 1, characterized in that the gas duct is fixed to the working chamber by means of a flange connection.