SU1719862A2 - Contact heat exchanger - Google Patents

Abstract

The invention relates to heat exchange technology and can be used to heat a liquid by a contact method. The aim of the invention is to increase the efficiency of heat and mass transfer by increasing the contact surface. The nozzles (F) 12, 13, 14 and 15 are located respectively: F 12 and 13 in the heating heat supply pipes 3 and 2, F 14 in the guide channel 7, F 15 at the top. 2 parts of the chamber 1 in the gap between the walls of the latter and the cylindrical nozzle 9. The installation of F 12,13,14 and 15 in the specified places of the heat exchanger contributes to the additional irrigation of the gas flow with liquid. 1 il. Water

Description

The invention relates to heat exchange technology, can be used to heat a liquid by a contact method for recovering heat from the heat engineering equipment of the flue gases and is an improvement of the known device according to the author. M 1638517.

Heat exchangers are known for the interaction of a gas with a liquid, comprising a housing with tangential nozzles for supplying contacting media.

Also known is a contact heat exchanger containing a working chamber with tangential nozzles for supplying heating medium in its upper and lower parts, installed along the body axis, respectively, a cylindrical nozzle in its upper part and two coaxial cylinders in the lower part. The latter form guide channels for the passage of the heating medium. The liquid distributor is located along the axis of the chamber between the inlets of the heating medium.

The disadvantage of the heat exchanger is relatively low heat transfer.

Zlju invention is to increase the efficiency of heat transfer by increasing the contact surface.

This goal is achieved by the fact that a contact heat exchanger containing a vertical chamber with a branch pipe, equipped with a cylindrical nozzle and tangential branch pipes for supplying a heating medium, a water distributor with at least one spraying device, and two coaxial outer and inner shell bodies are installed in the chamber to form channels, provided with additional nozzles placed in the heating coolant inlet pipes, in the upper part of the chamber, in the gap between the walls of the latter s and the cylindrical nozzle and the guide channel.

The use of additional irrigation of the heating medium flows through the above-mentioned nozzles allows organizing contact between the media in the entire volume of the heat exchanger, which, in turn, makes it possible to fully utilize the heat of gases.

The drawing shows a contact heat exchanger, a general view.

The heat exchanger contains a vertical chamber 1, tangential nozzles 2 and 3 for the supply of a gaseous medium. In this case, the nozzle 2 is located in the lower part of the chamber 1, and the nozzle 3 is located in the upper part, the nozzle 4 serves to drain the gaseous medium.

The outer and inner shells 5 and 6 coaxially located along the axis of the chamber form guide channels 7 and 8, the outer shell 5 being connected to the lower nozzle 2 for supplying a gaseous medium, and the cylindrical nozzle 9 is connected to the discharge nozzle 4.

The water distributor 10 is located along the axis of the camera 1 and has or sections 11

0 perforated holes, or nozzles, located all the way between the tangential nozzles 2 and 3 for supplying a gaseous medium.

nozzles 12-15 are designed for additional irrigation of heat flux entering the heat exchanger. The nozzles 12 and 13 are located in the tangential nozzles for supplying the gaseous medium, the nozzle 14 is located in the 0 guide channel 7, and the nozzle 15 is located in the upper part of the chamber 1 between the casing and the cylindrical nozzle 9. The gaseous medium is simultaneously fed through the upper 3 and lower 2 tangent 5 social nozzles, due to which it acquires a helical motion.

Due to the presence of nozzles 12 and 13 in the tangential nozzles 2 and 3, the gaseous mixture is irrigated, which provides a coherent heat exchange between the gaseous medium and the liquid. Further, the heat flows move along closed trajectories, directed towards each other. The size of the upper stream is limited.

5 with a diameter of chamber 1 and a cylindrical nozzle 9. Here the upper stream is again irrigated with liquid from the nozzle 15.

The dimensions of the underflow are limited by the guide channel 7 formed by

0 two shells 5 and 6 coaxially located along the axis of the chamber, where it is again irrigated with liquid from the nozzle 14. In addition, the lower swirling flow is covered by the upper gaseous flow

Claims (1)

5 Wednesday. In the lower part of the chamber, the flow is sucked into the guide channel 8 due to the negative pressure created by the internal flow of the gaseous medium and is connected to it. Water supplied for irrigation into the cavity of chamber 1, through distributor 10, contacts two twisted gaseous medium flows and moves along a complex spiral path, thereby increasing the contact time of the gaseous medium and the liquid. Claims of the invention Contact heat exchanger according to auth.St. No. 1638517, about tl and h ayusch and with the fact that, in order to increase the efficiency of heat exchange by increasing the surface of contact 517198626 one, it additionally contains nozzles, in the gap between the walls of the latter and cy- placed in the inlets for supplying a heating nozzle and in the guide heat carrier, in the upper part of the chamber, the channel.