SU1368332A1 - Air heater - Google Patents

Abstract

The invention relates primarily to high-temperature heating and other gaseous heat transfer fluids used in metallurgy and power engineering. The aim of the invention is to increase the resistance of the walls of the combustion chambers and the nozzle. The presence of a gap 4 between the chambers and between them and wedges contributes to the comprehensive washing of the walls of the chamber 3 of the nozzles and chamber 9 of burning with gaseous coolants and, thus, a more uniform temperature distribution along the perimeter of these walls. The application of the invention allows to increase the heating temperature by blowing 40-50 0. 2 Il. from (L from from 05 00 with from to

Description

. The invention relates to the advantage of high temperature heating and other gaseous heat carriers that are used in metallurgy and power engineering.

The aim of the invention is to increase the resistance of the walls of the combustion chambers and the nozzle.

FIG. 1 shows the air heater after its heating, operating condition; in fig. 2 shows section A-A in FIG. one.

An air heater contains a cold-blowing nipple 1 connected to and a sub-nozzle 2. A subunit 2 located in the lower part of the air heater connects chamber 3 of the nozzles and the gap 4 with the cold-blowing nipple 1 and 20 nozzles of smoke. The nozzle chamber 3 is connected at the top with the dome 6. A gap 4 located between the wall 7 of the chamber 3 of the nozzle and the wall 8 of the combustion chamber 9, as well as between them and the wedges 10 25, serves to move gaseous heat transfer media therein. The locking protrusions 11 located in the gap 4 serve to ensure the stability of the width of the gap 4 and contribute to the stability of the combustion chamber 9 and the wedges 10.

The heater works as follows.

During the heating period of the nozzle, gas and air flow into the combustion chamber 9 and burn. The products of combustion enter the chamber 3 of the nozzles and the gap 4, moving along which they cool and exit into the sub-nozzle 2 and out of it through fittings 5 are diverted into a common chimney.

During the cooling period of the nozzle, the cold blast through, the nozzle 1 is fed into the sub-nozzle 2, from which it enters the nozzle chamber 3 and the gap 4, and, due to the heat of the nozzle and walls, heats up

40

50

five

0

measure 9 of burning, from where it enters the general pipeline and blows hot.

The presence of the gap 4 contributes to the comprehensive washing of the walls of the chamber 3 of the nozzle and the chamber 9 of combustion with gaseous coolants and thereby a more uniform distribution of temperature around the perimeter of these walls.

On the basis of the calculated research, it was found that the optimum for the conditions of uniform temperature distribution along the perimeter of the walls and, accordingly, their durability, the width of the gap (gap) between the walls in the working condition of the air heater is (2.5-5.5) 10 of the inner diameter of the chamber wall nozzles This gap width for the passage of gaseous coolants reduces the unevenness of the temperature distribution by more than. 2 times around the perimeter of the wall of the combustion chamber and 5-6 times around the perimeter of the wall of the nozzle chamber, which increases the resistance of these walls and the degree of heat utilization of the combustion products.

The application of the invention allows to increase the heating temperature by 40-50 ° C.

Claims (1)

Formula invented, shadow An air heater containing a dome, a nozzle chamber, a side combustion chamber, the outer surface of which is located with a gap in relation to the inner surface of the nozzle chamber, which is made in order to increase the resistance of the walls of the nozzle chambers and the combustion chambers a lining in the form of wedges with protrusions fixing the gap between the combustion chambers and the nozzle and between them and the wedges, while the size of the aazor between the combustion chambers and the nozzle is (2.5-5.5) -10 internal diameter of the nozzle chamber. ten. LA FI.2