SU787807A1 - Radiation recuperator - Google Patents

Description

(54) RADIATION RECOVEROR

one

The invention relates to the preheating of air or gas in recuperators, specifically, to the design of metal radiation gap recuperators used for high-temperature heating heating furnaces of the rolling and forging industry.

The closest technical solution known to the present invention is a radiation recuperator containing coaxially mounted peripheral and central shells in the form of truncated circular cones, each of which is provided with manifolds for inlet and outlet of the heat transfer medium. In this recuperator, the ratio of the height of the recuperators is larger than the diameter of the inner cone less than unity 1.

With such a design of recuperators, the possibilities of thermal radiation of masonry or lining surrounding the inlet and outlet of the recuperator along the flue gases are far from being fully utilized. To increase thermal efficiency, increase dimensions.

(height) of the heat exchanger, which is spent on expensive heat-resistant alloy steel.

The purpose of the invention is to increase efficiency and reduce size.

This goal is achieved by the fact that the ratios of the smaller diameter of the base of the central shell and its height to the diameter of its larger base are respectively 1: 2 and 3: 1.

1 shows a radiation heat exchanger, top view; on fkg.2 section A-A in Fig .; Figures 1-1 and 4 If are an embodiment of a radiation recuperator using thermal radiation of a recuperator space with protection against overheating of a part of the recuperator from intensive radiation of the pre-recuperative space.

The recuperator contains coaxially mounted peripheral 1 and central

2 shell, each of which

25 is provided with collectors 3 and 4, respectively, for supplying and discharging the heat source. The collector 3 is provided with a supply pipe.5, and the collector 30 4 - with a discharge pipe 6..

Radiation heat exchanger works as follows

Heat emitting gas heated to a HIGH temperature flows from the furnace to the recuperator, to the rest of the recovery space, into the central shell 2 and transfers part of its heat to the heat-absorbing gas moving along the circumferential gap formed by peripheral 1 and central 2 shell.

In the case of using thermal radiation of the pre-recuperative space at a lower temperature of the incoming heat-transfer gas (up to 1100 ° C) into the recuperator, it is advisable to use countercurrent gas movement (Figures 1 and 2). At the same time, the cold heat-receiving gas flows through the nozzle 5, installed tangentially to the collector 3, the collector 3, an annular gap formed by the peripheral 1 and central 2 shells, the collector 4, and through the nozzle b to the heat-receiving devices.

  use of thermal radiation from the heat-recuperating space and protection of the latter from the heat radiation of the pre-recuperative space (at a temperature in the heat-recuperating heat-producing gas of more than 1100 ° C) it is advisable to use a continuous flow of gases.

The use of conical heating surfaces, taking into account the chosen ratios of structural dimensions, will allow increasing the efficiency by reducing heat loss of radiation.

Claims (1)

Invention Formula Radiation recuperator containing coaxially mounted peripheral and central shells in the form E truncated circular cones, each of which is provided with collectors for supplying and discharging coolant, characterized in that, in order to increase efficiency and 0 size reduction ratio the smaller diameter of the base of the central shell and its height to the diameter of its larger base are 1: 2 and 3: 1, respectively; Sources of information taken into account in the examination 1, USSR Author's Certificate No. 35895, cl. F23 C 7/06, 1967, A - A Phi1.1