SU1654269A1 - Nozzle for glass melting furnace regenerator - Google Patents

Abstract

The invention relates to the glass industry and can be used in regenerative glassmaking and other melting of Hhix and H.ii, - |, - e-iax. The purpose of the invention is PP & chsh Effectiveness of the nods of the thermal deceleration and the consumption of refractories Nasa kz with productively symmetric and pairwise perpendicular ribs of cruciform refractory blocks The edge of the blocks are made in various lengths. The ratio of the length of the ribs is determined from the dependence q-K O.ZOZ / M) J, where K is 0, L75-0.9 is the coefficient of the air-force ratio, and h. ri - go is responsible for the distance from the in-c / u rsa; ki in the course of the air and pops high nozzles. Neighboring cells along the height are shifted relative to the other half of the transverse size of the cell. The cells are shaped by elongated ribs 1 part. F ly, 1 il. to

Description

The invention relates to the glass industry and can be used, for example, in regenerative glass and other melting and heating furnaces.

The purpose of the invention is to increase the efficiency of heat transfer and reduce the consumption of omevnopOB.

The drawing shows the proposed nozzle of the regenerator, top view.

The nozzle 1 of the regenerator contains cells 2 for the passage of combustion products and air, formed by elongated ribs 3 of block 4, Shorter edges 5 of block 4 are additional heating surfaces of blocks 4 in cells 2. The dashed lines show the contours of blocks 4 of the adjacent, underlying row cells 2.

The length ratio is determined from the dependency

q k | 1-0,33 (h / H) OJl,

where K - 0,575-0,9 - coefficient of proportionality;

h, H - respectively, the installation of the chip in the nozzle in the course of the process and full -i the height of the nozzle.

Neighboring cells are displaced one relative to the other by half the transverse size of the cell in the direction normal to one of the axes.

Combustion products and air cyclically and sequentially wash the surfaces of the fins 3 and 5 of the blocks 4, which flowed through the cells 2. These are the channels for the passage of gases and 1 liter of air. The temperature of the combustion products and air in the upper part of the nozzle 1 is higher than in the lower part. Therefore, the bottom of the NCA

ate

-N

Yu O

YU

In the set 1, the heat transfer of gases is minimal, and it is in this part of it that the intensification of heat exchange is most expedient, which is realized in the proposed solution.

The proposed nozzle of the regenerator in comparison with the prototype with the same linear dimensions of the cell has 32-75% more heating surface and increased turbulence of the gas flow. At the same time, the living section of the cell decreases accordingly by only 11-24%. Larger values of the increase in the heating surface refer to the lower part of the nozzle, and smaller to the upper part.

An even greater turbulization of the gas flow and an increase in its heat transfer is achieved by displacing the cells of adjacent horizontal rows. The most appropriate displacement of the cells of the adjacent FIRST in the lower quark of the nozzle of the regenerator is where the temperature and velocity of the gases are low.

The intensification of heat exchange is also facilitated by the execution of blocks 4 with a different ratio of the lengths of the ribs 5 and 3 - with longer long ribs 5 in the lower and shorter ribs 5 in the upper part of the nozzle 1. This embodiment of the nozzle 1 increases the velocity of gases in the cells 2 in the height of the nozzle and above all in its lower part, and, consequently, increases the heat transfer coefficient of the gas flow to the ribs 3 and 5 of the blocks 4.

The change in the living cross section of cell 2 in the height of the nozzle 1 due to the different ratio of the lengths of the ribs in accordance with the ratio given above is 25-40%, and the decrease in the volume of products

the burns and their rates are between 65 and 80%. Smaller limits of changes in the living cross section of cells compared to the volume of combustion products are due to the presence of entrainment

charge dust reducing the cross section of the cells and a significant increase in the hydraulic resistance of the nozzle with an even greater decrease in the living cross section of the cells in the event of a further increase in the length of the ribs5

It was experimentally established that the proposed nozzle allows to reduce the temperature of combustion products by 100-130 ° C with a lower consumption of refractories by 6%.

Claims (2)

1. The nozzle of a glass furnace furnace regenerator by cells formed in pairs of symmetrical and mutually perpendicular ribs of cruciform refractory blocks, which, in order to increase the efficiency of heat exchange and reduce the consumption of refractories, block edges are made of various lengths, the cells are formed by elongated ribs, the ratio of the lengths of the edges is determined from the dependence q , 33 (h / H) ° 7, where K 0.575-0.9 is the proportionality coefficient; h.H is, respectively, the distance from the entrance to the nozzle along the air and the height of the nozzle is full. 2. The nozzle according to claim 1, characterized in that the neighboring cells are displaced one relative to the other by half the transverse dimension of the cell in the direction normal to one of its axes,  "four / N -fc-lL .C   1 s X s four/ - rf