SU992916A1 - Regenerative air preheater - Google Patents

Description

The invention relates to heat engineering and can be used in thermal installations.

Known regenerative air heaters containing a rotor with a radially divided lamellar nozzle

The disadvantage of this air heater is a relatively low heat exchange performance due to insufficiently developed heat exchange surface.

Closest to the proposed. The heater is a regenerative heater containing coaxially arranged perforated shells, which form a rotating annular chamber filled with a dispersed heat exchange nozzle and divided into sections by radial shades, the cavity of the inner shell being divided by a partition into gas and air parts connected respectively to the side panels and the side and to the side walls of the inner shell. inlet and exhaust air and gases pipesS23.

A disadvantage of the known air preheater is the leak between the gas and air parts.

resulting in heat transfer fluids.

The purpose of the invention is to reduce the flow between air and gases.

This goal is achieved by the fact that in a regenerative air heater containing coaxially arranged perforated shells forming a rotating ring 10, a chamber filled with a dispersed heat exchange nozzle and divided into compartments by radial walls, and the cavity of the inner shell is divided by a partition wall

15 and the air parts, connected respectively to the side and tsertsov inlet and exhaust air and gases nozzles, the inner shell is fixed, and the side nozzles have a height less than the height of the annular chamber, and their edges are offset from the ends of the latter.

FIG. 1 shows the proposed regenerative heat exchanger, a longitudinal section; in fig. 2 - the same cross section.

The regenerative heat exchanger contains coaxially arranged perforated shells 1 and 2, obzv disassembling a rotating annular chamber 3 filled with a dispersed heat exchange nozzle and divided into compartments 4 by radial walls 5. The cavity of the inner shell 2 is divided by a partition 6 into gas and water parts 7 and 8 connected respectively to side and end inlet and exhaust air and gases connections 9-12. The inner shell 2 is fixed, and the height of the side nozzles 9 and 10 is less than the height of the annular chamber 3, and their edges are offset from the ends of the latter. The annular chamber 3 rests on the drive rollers 13. The working heat exchange zones in the nozzle over the area correspond to the cross-sectional area of the pipes 9 and 10. Those parts of the nozzle which are located along the section between the working areas act as sealing cavities. The same role is played by those parts of the nozzle which are located along the height of the chamber 3 above and below the working zones. The minimum distance between the working zones over the cross section and the distance from the ends of the chamber 3 to the edges of the pipes 9 and 10 can be equal to or greater than the thickness of the nozzle along the gases. At the upper end of the chamber 3, there are hatches 14 for loading the dispersed nozzle, and in the lower part of the shell 1 - hatches 15 for unloading the nozzle.

The device works as follows.

Hot flue gases through the pipe 12 enter the gas part 7, from where they are sent to the working area of the nozzle, heated and removed through the pipe 10. The nozzle is heated during rotation of the annular chamber 3 enters the cooling zone, where cold air flows through the pipe 9. The last passage through the nozzle layer is heated, enters the air part 8 and is discharged through pipe 11 to the consumer.

Those parts of the nozzle, which are located along the nozzle section between the edges of the pipes 9 and 10, perform the role of seals, preventing the flow of heat exchanging media. Walls 5 located between the edges of the pipes 9 and 10 serve as an additional seal. Nozzle zones located above and below the working zones, namely, between the ends of the chamber 3 and the edges of pipes 9 and 10, impede external air.

The use of the proposed heat exchanger allows to reduce the flow between air and gases and to increase 5 operational efficiency.

Claims (2)

1. Dobro kov. and others. Air heaters boiler installations. L., Energie, 1971, p. 6-2-87. 2. USSR author's certificate 5 No. 200702, cl. F 23 L 15/02, 1966.