RO113869B1 - Heat exchange for air preheaters - Google Patents

Abstract

The invention relates to a heat exchanger for preheaters of the air used in steel furnace extractive, as well as any plant industrial processes that work with the development of large amounts of heat at high temperatures. The switch is consisting of superimposed rows of bricks (1), the structure of the masonry having some vertical channels (d). some vertical semicanas outer (ej and some central channels (d0) which extend in vertical and vertical directions horizontal, integrating the entire perimeter of the the bricks (1) in the thermal transfer, the bearing the bricks (1) of a row being made those in the row adjacent to the bottom, through by means of flat faces (b) being secured against relative displacement with the ribs of stabilization (c) on flat faces (a) of of the bricks (1) in said lower row.

Description

The invention relates to a heat exchanger, for air preheaters, used in furnaces, in the extractive steel industry as well as to any other industrial installations, in which work processes are carried out with the development of large quantities of heat, at high temperatures. It is applied for the recovery of thermal energy, residual energy, and its use in the same technological process or in related technological processes, which take place at lower temperatures, for example, in processes of drying and conditioning of some products and materials, for heating domestic water. , heating of production and living spaces.

It is known a heat exchanger for air preheaters, consisting of bricks placed side by side, in horizontal rows, superimposed from the base to the top so that in the masonry structure, a network of vertical and horizontal channels is formed. The vertical channels are formed of central channels, of the bricks and of partial channels, from their corners, and the horizontal channels are formed between each two rows of superimposed bricks, they being determined by the existence of legs at the base of each brick, which rests on the upper face of the brick from the bottom row. To these are added other partial, vertical channels, which are limited to each row of overlapping bricks, these being determined by practicing V-shaped grooves on the side faces of the bricks, these grooves having different widths and being in different numbers, on two opposite sides of the brick (US 2,833,532)

This heat exchanger has the disadvantage that it lacks its own means for positioning each brick in the masonry and therefore has no stability in case of partial deterioration of the bricks. Another disadvantage is that the support legs, between two rows of bricks, generate areas of concentrated efforts in the bricks on which they rest, the intensity of these efforts increasing from the top to the bottom rows. The negative effect produced by these concentrated efforts can lead either to the crushing of the support legs and, thus, to the cancellation of the corresponding horizontal channel and to the reduction of the heat transfer, or to the deterioration of one or more corners of the bricks, thus affecting the stability of the masonry of the heat exchanger. , as mentioned above. The measure of vertical and horizontal reinforcement of the bricks does not completely eliminate these risks. At the same time, it complicates the manufacturing technology and increases the cost price. To the above, there is also the presence of decreasing conications, downstream, of the central channels of bricks, which cause accumulations of material particles on the walls of the channels, due to their circulation on the downward trajectories, the slipping and fixation on these walls that intersect the respective paths. .

Another heat exchanger is also known, in which the masonry consists of rows of overlapping bricks and is crossed only by vertical, cylindrical channels. In this case, the stability of the masonry is ensured by a joint of nut type and fence present at the bottom, respectively, at the top of each brick. At this structure, each brick in a row rests on three bricks in the lower adjacent row, the groove of the one above joining with the groove of the one below.

This heat exchanger has the disadvantage that the nut and groove joint shrinks the support surface and also involves high compression efforts in the respective areas. Also, limiting the flow of gas flows only to vertical channels greatly reduces the efficiency of the heat transfer of each brick and of the heat exchanger as a whole.

The problem to be solved by the invention consists in the realization of a heat exchanger, for air preheaters, to be designed in such a way as to increase the stability of the masonry, by simple means of positioning and fixing the bricks, capable of evenly distributing the load load of the structure. , without

RO 113869 Bl creates areas of concentrated effort. It is also required that the masonry of the heat exchanger has such a structure, so as to increase the contact surface with the gas flows, to intensify the thermal transfer and at the same time reduce the deposition of material particles on the channel walls.

The heat exchanger for preheating of air, according to the invention, solves. this problem and removes the mentioned disadvantages, in that all the bricks in a row rest on the bricks in the adjacent row, inferior, by means of flat faces, they are fixed against the relative displacement with some stabilizing ribs on the upper faces of the bricks from the lower line, mentioned, the masonry structure comprising vertical rectilinear channels and horizontal channels, integrating the entire perimeter of the bricks in the thermal transfer. Said stabilization nerves define, in the plurality of coplanar faces, from each row of bricks, a network of polygonal configurations, each of these configurations having the inner perimeter equal to the outer perimeter of a supporting face. The aforementioned vertical channels result from the combination of the central channels and the inner channels, from the odd rows of bricks, with pairs of outer semichannels from the rows appearing of bricks which, together, define a channel with the same geometrical configuration in the horizontal plane, and the horizontal channels in the form of a triangle. vertical isosceles, have the section defined by the hypotenuses, rectangular triangles in the radial faces of the outer semichannels and follow a circular path in a horizontal plane, surrounding the lateral surface of each brick.

The assembly of said channels communicates with each other vertically and horizontally, through the inside and outside of the bricks.

The heat exchanger for air preheaters according to the invention has the following advantages:

- has high stability;

- intensifies the heat exchange and increases the efficiency of the heat transfer;

- decreases the deposition of material particles.

The following is an example of an embodiment of the heat exchanger, for air preheaters, according to the invention, in connection with FIGS. 1 and 2, which represents:

FIG. 1, partial perspective view of the masonry structure of the exchanger;

FIG. 2 is a schematic representation of an air preheater, equipped with a heat exchanger.

The heat exchanger according to the invention is made up of bricks 1 having two flat faces a and b hexagonal and parallel with different areas S _a and S _b . The flat face has stabilizing ribs c, joined to the center and forming an angle of 120 °. The bricks are provided with six vertical channels, inner d and vertical semichannel, external e having, for example, hexagonal section. The inner vertical channels d are grouped symmetrically around a central channel d ₀ , and the vertical, outer semichannels e are positioned at the middle of each side. These channels also have different areas, the small area being positioned on the front with large area of the brick, and the large area being positioned on the one with the small area. The radial faces of the vertical semichannels, exterior e, have the form of a rectangular triangle, with the base in area S _a , with the height parallel to the axis of the brick and the hypotenuse, joining the two sides in a direction inclined to the axis.

The process of assembling the heat exchanger and its geometrical and functional characteristics are described in relation to fig. 1 in which a fragment from its masonry is presented in perspective. The assembly starts with placing the first row of bricks 1 on the bottom plate of the heat exchanger chamber so that all the bricks are oriented with the flat face b down, all being placed side by side, and one stabilizing rib c on the three adjacent bricks 1 to meet at one point

RO 113869 Common Bl. In this way, the entire area of the flat faces b of all the bricks 1 is in contact with the bottom plate of the heat exchanger chamber, and the stabilizing ribs c on the flat faces form hexagonal configurations of limiting ribs, having the inner perimeter equal to outer perimeter of the flat face a.

secondly, the bricks Π are also placed with the plane face down so that the perimeter of these faces is included within the inner perimeter of the mentioned hexagonal configurations, formed by the association of the stabilizing ribs c · of the plane faces a and orienting these ribs from the second row of bricks, to meet at common points like those of the first bricks. In this way, the stabilizing ribs c on the flat faces of the second row of bricks also form limiting hexagonal configurations.

At the third row and then until the last row of bricks, repeat the way of placing the bricks from the second row.

In this way, a heat exchanger is obtained whose masonry is crossed by a plurality of rectilinear channels, circular and their combinations, vertically and horizontally, namely:

- vertical channels resulting from the combination of the central channels d ₀ and the inner vertical channels d from the odd rows of bricks, with pairs of external vertical semichannels e from the rows appearing of bricks, which together define a channel with the same geometrical shape in the horizontal plane;

- horizontal channels that have an isosceles triangle shape, vertically defined by the hypotenuses of the rectangular triangles, from the radial faces of the vertical, external semichannels e, and follow a labyrinthine path in the horizontal plane, surrounding the lateral surface of each brick;

- combinations of channels, following labyrinthine paths in horizontal and vertical plane through the inside and outside of the bricks.

Since all the brick channels have the area S _a in front of the large area, smaller than the area S _b in the small front, it turns out that in fact, the vertical channels of the heat exchanger are not uniform on its height, but gradually widen in size. down and repeatedly from brick to overlapping rows. This fact has beneficial effects by reducing the deposition of material particles in the gas flows, on the walls of the so-called channels, thus extending the working life of the heat exchanger and at the same time maintaining the intensity of the heat transfer. These favorable effects are explained by the fact that the variation of the gas passage sections on the height of the heat exchanger results in a continuous variation of their circulation speed, at a rapid rate of about one tenth to two tenths of a second, in flow function, producing molecular shocks and energetic gas turbulence and thus favoring the thermal transfer through convection. On this basis, a considerable increase in the efficiency of the heat exchanger according to the invention is obtained, compared to the heat exchangers existing in the known state of the art.

The heat exchanger A is mounted in the heat recovery chamber 2 of an air preheater (fig.2). In the process of working the gases resulting from the combustion gases of the furnace (1200 ... 1600 ° C) or other gases enter the air preheater, through a socket 3, go through the room 4, pass through the masonry channels, give part of them from the heat, heating and exiting to the basket (150 ... 350 ° C) through a socket 5. After the preheater's masonry has been sufficiently heated, cold air is introduced through a socket G from some non-figured blowers and along the route In the opposite direction, it takes the heat from the masonry of the recuperator and exits through a socket 7 towards the blast furnaces at a temperature of 11001350 ° C. Basically, for heating the masonry of the heat exchanger it takes about 2 hours and for cooling it about one hour. For this reason, for

EN 113869 With a blast furnace, several air preheaters may be required, which are switched on and off automatically. By introducing the preheated air in the furnace, there is a significant fuel economy, of about 4% for every 1 ° C of preheating.

Claims (5)

1. Heat exchanger, for air preheaters, consisting of superimposed rows of bricks (1), characterized in that the masonry structure of the exchanger has some interior vertical channels (d), external vertical semichannels (e) and some central channels (d ₀ ) that extend in vertical and horizontal directions integrating the entire perimeter of the bricks (1) in the heat transfer, the bricks (1) being supported in a row making those in the adjacent lower row by means of flat faces (b), being secured against displacement relative to the stabilizing ribs (c) on the sides (a) of the bricks (1) in the lower row. Heat exchanger, for air preheaters, according to claim 1, characterized in that the stabilizing ribs (c) define in the plurality of flat faces (a), from each row of bricks (D, a network of polygonal configurations, each from these configurations having the inner perimeter equal to the outer perimeter of a planar face (b), we rest. 5 Heat exchanger for air heaters according to claim 1, characterized in that, from the combination of the central channels (d ₀ ) and the internal vertical channels (d) of the rows ¹⁰ odd bricks (1) with pairs of vertical vertical semichannels. (e) from the rows of bricks (1), it follows, vertical channels, which together define a channel with the same geometric shape, ¹⁵ in a horizontal plane. 4. The heat exchanger of the air heater, according to claim 1, characterized in that the horizontal channels in the shape of an isosceles triangle in a vertical plane ²⁰ defined by the right triangles ipotenuzele semicanalelor radial outer vertical faces (e) and follows a path labyrinth in a horizontal plane, surrounding the lateral surface 25 of each brick. 5. Heat exchanger for air heaters according to claims 1, 3 and 4, characterized in that the channel assembly (d ₀ , d, e) communicates 30 horizontally and vertically, through the inside and outside of the bricks (1).