SU807010A1 - Rotary furnace cellular heat exchanger - Google Patents

Description

one

This invention relates to a heat exchange technique in rotary kilns and can be used in the building materials industry.

Cell, cycloid and other types of heat exchangers are known that serve to intensify heat exchange between hot gases and material. .

Closest to the present invention is a cell heat exchanger of a rotary lined furnace, containing sections of cells arranged in series along the axis of the furnace with a displacement around the circumference of one section relative to the other and formed by partitions made parallel to each other and the axis of the furnace by interlocking separate hinge6 connected parts ,

Overheatings are arranged evenly over the cross section of the furnace, dividing the material into individual portions that rise upward into the gas stream, and then pouring down the bulkheads, taking heat away from them. The execution of each partition from the individual links interconnected pivotally, ensures, with the exception of glossing over

sections of material due to relative humidity 2.

A disadvantage of the known heat exchangers is their low efficiency, since the presence of complex elements in the form of hinges that can be performed. TCJbKO from metal, does not allow to arrange them in high-temperature zones.

The purpose of the invention is to increase the efficiency of heat transfer.

This goal is achieved by the fact that in a cell heat exchanger of a rotating lined furnace, there are sections of cells arranged successively along the axis of the furnace, offset along the circumference of one section relative to the other and formed by partitions made of overlapping separate pivotally connected links parallel to each other and the axis of the furnace , the latter are interconnected and the furnace body with the help of the t. At the same time, the rods are made in the form of flexible elements, and the ends of the tg in the place of their attachment to the furnace body odpruzhineny. In addition, the extreme links of the partitions are recessed into the furnace lining, and the links at the extreme end of the furnace adjacent to the furnace body are made with windows. The link is made of heat-resistant material.

FIG. 1 shows one section consisting of several successively arranged along the axis of the furnace and adjacent partitions, the general view in FIG. 2 is a section A-A in FIG. in FIG. 3 section bb in fig. one; in fig. 4 shows a section B-B in FIG. one.

Inside the furnace 1 with lining 2, there are partitions 3, consisting of links 4, which are strung on ropes. On one side, rods 5 can rest on the furnace body 1 through springs b, rods 5 can be made in the form of flexible elements, for example cables .

In the lining 2 and the furnace 1, in the place of junction of the extreme links 4 of the partitions 3 there are depressions 7. The edges of the links 4 in the place of joining to each other are made with overlapping 8 and 9.

Link 4, adjacent to the furnace body 1 at the extreme end of the hot end of the partition 3, is provided with windows 10, and the outer surfaces of the outermost ones at the hot end of the furnace 1 of the limiting racks are made with fairings 11 directed the larger side along the material flow

The dimensions of the windows 10 are (0.050, 25) Dx0.05-0.25) 0, where D is the internal diameter of the furnace 1 (the size of the window 10 is taken more radially, the larger the material layer in the furnace 1, and the dimension along the axis of the furnace 1 the greater, the greater the fluidity of the material and the slope of the furnace 1). Link 4 is made up of reinforcement 12, on which a refractory brick or heat-resistant concrete 13 is applied. There are holes 14 in passage 12 for passageways 5. The next section of the heat exchanger (not shown) is rotated at an angle.

The heat exchanger operates as follows.

When the furnace 1 rotates, the material twice in Ks1, each turn enters each cell formed by the adjacent partitions 3, and moves in it with lifting and pouring, which ensures high efficiency. The absence of hinges that come into contact with hot gases and can only be made of metal increases reliability and, therefore, efficiency, since links 4 can be made of refractory bricks or heat-resistant concrete, therefore, the heat exchanger can be shifted further to the hot end furnace 1.

The ropes 5 can be made in the form of flexible elements, for example, tro (Sov, which provides greater flexibility of the work, as compared to rigid rods 5, which are quickly destroyed by fatigue.

The ends of tg 5 for: are fixed on the furnace body 1 through the springs b, which provides constant tension and, therefore, independence of the sagging of the partitions 3 during rotation (with a larger sagging there will be a big turn; links 4, which may cause damage to the edges of the links four). In liner 2, there are depressions 7, into which the extreme links 4 are pinched. This provides protection of the grams 6 from the influence of hot gases. The edges of the links 4 in the place adjoining each other are repaired with ceilings 8 and 9, which eliminates spilling of the material, and hence dusting.

In the extreme links x 4, there are windows 10 at the hot end, which prevent material from falling into the gas stream along the edges from the hot end of the furnace, since when the extreme partition 3 is raised from the lower position, the material does not rise up due to the window 10. The material lifted by the adjacent section of the partition 3 without a window 10, due to the inclination of the furnace 1 and the flowability of the material moves along the section of the partition 3 with the windows 10, it does not have time to reach its edge, since the length of this section is determined by the absence of material scattering; The streamlined shape 11 is made to avoid material lifting. Link 4 is made of composite, with the outer surface of the links 4 lined with refractory bricks or heat-resistant concrete.

The sections of the cells are rotated relative to each other from 180 to so that on the partitions 3, at any position of the furnace 1, there is material and hot gases are in contact with it.

The use of the proposed heat exchanger increases efficiency, since the absence of hinged joints in contact with hot gases, which can only be made from me-. tall, makes it possible to move the part of 4 partitions 3 made of heat-resistant concrete or refractory brick to a zone of higher temperatures.

We offer the proposed design more reliable in operation.

the invention

Formula

1. A cell heat exchanger of a rotary kiln, containing cell sections, arranged in series along the axis of the kiln, with the circumferential displacement of one section relative to another and formed by partitions parallel to each other and the kiln axis made of overlapping

Claims (6)

Claim 1. Cellular heat exchanger of a rotary kiln, containing sections of cells arranged sequentially along the axis of the kiln with offset along the circumference of one section relative to the other and formed by partitions parallel to each other and the kiln axis, made of separate joints pivotally connected to each other, characterized in that , in order to increase the efficiency of heat transfer, the links are interconnected and the furnace body using rods. 2. Heat exchanger according to π. 1, characterized in that the yen traction in the form of flexible elements. 3. The heat exchanger according to paragraphs. 1 and characterized by the fact that the ends ₍ rods in the place of their attachment to the furnace body are spring-loaded. 4. The heat exchanger according to paragraphs. 1-3, characterized in that the extreme links of the partitions are recessed into the lining of the furnace 2 about t. 10 (0.05 t 0.25) V 5. The heat exchanger according to paragraphs. 1-4, characterized in that the partitions adjacent to the furnace body of the outermost part of the furnace from the hot end of the furnace are made with windows. 6. The heat exchanger according to paragraphs. 1-5, characterized in that the links are made of heat-resistant material.