EA022595B1 - Chain having different links for chain curtain of a rotating roasting furnace - Google Patents

Abstract

The invention relates to chain curtains for rotating furnaces. The technical result is increased intensity of hear transfer, heat conduction, heat accumulating properties; reduced resistance to gas flow; higher strength. The different-links chain for the chain curtain of a rotating roasting furnace comprises connected links, each having an oval-shaped cross-section, maximum and minimum diameters of which are in mutually perpendicular directions. The chain is made of two types of alternating links, the longitudinal chain axis of one type of links coinciding with the maximum diameter of the oval-shape cross-section, and the longitudinal chain axis of the other link type coinciding with the minimum diameter of the oval-shape cross-section. The minimum diameter of the oval-shaped form is equal to the diameter of a hypothetical circle with an area equal to at least 40% of the area of the link cross section. The external part of the contour of the oval-shaped form is formed by a convex curve or a jogged line, while the internal part, at the links contact place, is formed as a convex arc of a circle with a radius equal to the radius of the curvilinear part of an internal ring of the chain link adjacent thereto.

Description

The invention relates to the field of heat exchange devices, in particular to chain curtains for rotary kilns of the building materials industry.

The most common structural elements used in the manufacture of chain heat exchangers are either round-link or oval chains made of a bar of cylindrical shape. In the furnaces of the building materials industry, at present, mainly round-link chains are used, both welded and cast (Valberg G.S., Griner I.K., Mefodovsky V.Ya. Intensification of cement production. - M.: Stroyizdat, 1971, p. 145).

The disadvantages of the known chain are the low amount of heat transferred to the material due to the small surface of the chain; the difficulty of heating the chain links in the gas flow through the thickness due to the low thermal conductivity of the chain links;

high wear of the chain links at their interfaces due to the small contact area; low self-cleaning of chain links from sticking material.

Closest to the claimed technical solution is the chain for a chain curtain of a rotary kiln known by the patent for utility model KI 112377, consisting of interconnected links of any geometric shape with a cross section of each link, the contour of which is made with ribbing except at the point of contact of the chain links contour, which is made in the form of an arc of a circle with a radius equal to half the chain pitch or the radius of the curved part of the chain pitch, characterized in that the cross section of each link is made It is related with the ratio of its vertical overall dimension to the horizontal overall dimension equal to 0.3-0.9, and all the edges of each chain link have a contour in the form of a circular arc or a triangular section. At the same time, a circle having an area of at least 60% of the entire cross section of the link is inscribed inside the cross section of each chain link.

The disadvantages of the known chain are the decrease in the total amount of heat transferred to the material due to the deterioration of the heat-accumulating properties of the chain links during its operation;

increasing the thermal conductivity of each chain link using concave surfaces that accelerate chain wear;

increased resistance to gas flow due to poor flow around each second chain link with gas flow;

a decrease in the intensity of the process of heat transfer from the gas stream to the material due to an increase in the chain resistance to the gas stream;

a decrease in the productivity of a rotary kiln due to a decrease in the intensity of the process of heat transfer from the gas stream to the material;

increased chain wear due to chemical corrosion (high temperature oxidation) due to the presence of concave surfaces on the chain links;

a decrease in the safety margin of the chain and its service life, a decrease in the heat-accumulating properties of the chain links due to the acceleration of the penetration of corrosion into the body of each chain link in places of concave surfaces;

the inability to accumulate a large amount of heat in the links throughout the operation of the chain due to a decrease in the heat-accumulating properties of the links during their wear;

lack of self-cleaning of chain links on concave surfaces of chain links from sticking material.

The technical result of the claimed invention is the elimination of these disadvantages, namely an increase in the total amount of heat transferred to the material during operation of the circuit; increase in thermal conductivity of each chain link without using concave surfaces; decrease in chain resistance to gas flow;

increasing the intensity of the process of heat transfer from the gas stream to the material; increasing the productivity of a rotary kiln;

reduction in chain wear due to chemical corrosion (high temperature oxidation); increasing the margin of safety of the chain and its life;

increasing the heat-accumulating properties of the chain links, allowing to accumulate a greater amount of heat in the links throughout the entire operation of the chain;

increased self-cleaning of links in the absence of concave surfaces in the chain links.

According to the claimed invention, the technical result is achieved by the fact that the chain is manifold for a chain curtain of a rotary kiln, consisting of interconnected links, each of which has a cross section, the profile of which is an oval-shaped figure, the largest and smallest diameters of which are in mutually perpendicular directions, made of two types of links with alternating through the link, while the longitudinal axis of the chain in one type of links coincides with the largest diameter oval th figure, and the other type of units coincides with the smallest diameter oval-shaped figure.

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In this case, the smallest diameter of the oval-shaped figure representing the cross-sectional profile of each chain link is made equal to the diameter of the conditional circle with an area equal to at least 40% of the cross-sectional area of the link.

The outer part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link is made by a convex curve, and the inner part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, at the point of contact of the links is made by a convex circular arc with a radius equal to the radius of a curvilinear parts of the inner ring of the chain link mating with it.

The outer part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link is made by a broken line, and the inner part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, at the point of contact of the links is made by a convex circular arc with a radius equal to the radius of the curved part the inner ring of the chain link mating with it.

According to the claimed invention, the implementation of the cross section of each chain link in the form of an oval-shaped figure, the largest and smallest diameters of which are in mutually perpendicular directions, allows you to increase the surface area of each link, i.e. heat transfer surface, which leads to an increase in the total amount of heat transferred to the material.

The surface area of a torus having a cross-sectional profile of the body in the form of an oval-shaped figure is larger than the surface area of a torus having a cross-sectional profile of the body in the form of a circle.

During the operation of the chain curtains, the surface of the chain is either constantly covered with material directly in contact with the gases, or works as a regenerator, absorbing heat from the gases and transferring it to the material. Thus, chains are involved in two types of heat transfer - convection from gases to material adhering to the chains and during regenerative heat transfer between gases, chains and material.

It can be assumed that under steady-state conditions, heat is perceived by the chains from gases due to convective heat transfer, and then it completely passes into the material.

The process of heat transfer due to the interaction of heat carriers during the movement of flows, when more heated particles, in contact with less heated ones, transfer heat to them, is a convective heat transfer. The rate of heat transfer by convection is formulated by Newton’s law <3 = α · P ΔΙ · τ, formula (1) where α is the heat transfer coefficient;

P is the heat transfer surface;

Δΐ is the temperature difference between a more heated body and a less heated body (the so-called temperature head);

τ is the duration of the heat transfer time.

From formula (1) it follows that the amount of transferred heat O is directly proportional to the heat transfer surface R.

When considering the process of heat transfer within one body (thermal conductivity of a chain link), when the heat passes from more heated parts of the body to less heated ones. The rate of heat transfer due to thermal conductivity (conduction) is formulated by Fourier law

C = λ / s Ρ ΔΙ τ, formula (2) where λ is the coefficient of thermal conductivity;

- the length of the heat transfer path (chain link thickness).

The ratio λ / 8 from formula (2) characterizes the thermal conductivity of the chain link. By reducing the thickness of the cross section of the chain link, it becomes possible to more quickly warm the chain links in thickness and to accumulate more heat in the central part of the link. Therefore, according to the claimed invention, the cross section of each chain link in the form of an oval-shaped figure, the largest and smallest diameters of which are in mutually perpendicular directions, makes it possible to better warm up the chain links in the gas stream in thickness and give more fully the accumulated heat to the material, as a result of which the heat transfer between chain links is intensified and material, as well as between the gas stream and chain links, leading to increased furnace productivity.

According to the claimed invention, the execution of a chain for a chain curtain of a rotary kiln of two types of links alternating through a link, the difference of which is that the longitudinal axis of the chain in one type of links coincides with the largest diameter of the oval-shaped figure, and in the other type of links coincides with the smallest diameter oval-shaped figure, allows you to reduce the resistance of the circuit to the gas flow, to increase the intensity of the heat transfer from the gas flow to the material, to increase the performance of the rotary firing th furnace.

The constructive solution of the links of the claimed chain allows the developed side surfaces of each chain link during operation of the chain curtain in the furnace to be located along the gas stream, without reducing its speed. The design solution of the inventive chain improves the conditions of gas flow around the chains in the chain curtain in comparison with the prototype, where the specific heat attributed to the surface unit of the chain of the chain of the curtain (heat transfer coefficient) is reduced, since each second link of the prototype chain increases the local resistance to gas flow.

The specific amount of heat transferred from gases to the material in the chain zone (c | _c in kcal / kg clinker) is determined (Deshko Yu.I., Kreimer MB, Ogarkova TA. Adjustment and heat engineering tests of rotary kilns on cement factories. - 2nd ed., revised and additional - Moscow: Stroyizdat, 1966, p. 40)

Cs = <Cc Hz D1 _C / C, formula (3) where a _c is the heat transfer coefficient, kcal / m ² -h- ° C;

t-2

B _c - total heat transfer surface, m;

D1 _c - average logarithmic temperature difference of the material and gases in the chain zone in ° C;

О - furnace productivity, kg / h.

The heat transfer coefficient from formula (3) depends on the relative residence time of the chains in gases and material and the heat transfer coefficients from the gas flow to the chains and from chains to the material.

The value of the heat transfer coefficient is a measure of the intensity of the heat transfer process.

Due to the fact that the heat transfer coefficient from the gas flow to the chains is less than from the chains to the material, then to intensify the heat transfer in the furnace, the first of them should be increased.

The value of the heat transfer coefficient by convection depends on the physical properties and flow regimes of the heating stream flowing around the heat-receiving surface. This parameter is usually found experimentally for specific heat transfer conditions and the obtained dependencies are expressed in a criterial form.

Based on the similarity equations, one can determine the values of the Nusselt number and, consequently, the corresponding values of the heat transfer coefficient.

With convective heat transfer, the similarity equation in the general case has the following form:

Νυ = / (Ke, Og, Pr), formula (4) where Νυ is the Nusselt criterion, which is a dimensionless heat transfer coefficient;

Ke - Reynolds criterion characterizing the regime of gas movement;

Og is the Grashof criterion characterizing the lifting force arising due to the difference in the density of gases;

Pr is the Prandtl criterion that determines the physical properties of gases.

When calculating chain curtains, the following types of the similarity equation are used to determine the Nusselt criterion:

PM = / (Ke, Pr), formula (5) (Mazurov D.Ya. Heat engineering equipment of cementing factories: textbook for technical schools. - 2nd ed., Revised and additional - M .: Stroyizdat, 1982, p. 160.)

Pi = / (Ke), formula (6) (Deshko Yu.I., Kreimer MB, Ogarkova TA Adjustment and heat engineering tests of rotary kilns in cement plants. - 2nd ed., Revised and extended . - M.: Stroyizdat, 1966, p. 40, 41.)

The Nusselt criterion is determined by No. ”- a-s1, _q / λ _Γ , formula (7) where α is the heat transfer coefficient in kcal / m ² -h- ° C;

bzhv - the equivalent diameter of the chain, m, which can be considered as the diameter of the conditional cylinder;

λ, is the coefficient of thermal conductivity of gases, kcal / m-h- ° C.

From the formula (7), the heat transfer coefficient α is determined by a ~ Pi 'λ _Γ / s1., _К1 „formula (8)

It follows from formulas (4) - (6) and (8) that the convective heat transfer coefficient of a moving gas stream is a function of the Reynolds criterion, which characterizes the flow flow regime.

Reynolds criterion is determined

Ке = и ' _г б ,, _: „/ ν _Γ , formula (9) where № _g is the gas velocity during the flow around the chains in m / s; _g - kinematic viscosity of gases in m ² / s.

From formula (9) it follows that the intensity of heat transfer will be determined by the relative velocity of the gas stream. Thus, it is possible to intensify the process of heat transfer in a rotary kiln by increasing the relative velocity of the gas flow, which will lead to an increase in the productivity of the rotary kiln.

According to the claimed invention, the implementation of the smallest diameter of an oval-shaped figure, representing a cross-sectional profile of each chain link, equal to the diameter of the conditional circle with an area equal to at least 40% of the cross-sectional area of the link, allows you to increase the margin of safety of the chain and increase the heat storage properties of the chain links.

The smallest diameter of an oval-shaped figure, representing the cross-sectional profile of each chain link, cannot be determined by the diameter of the conditional circle with an area equal to the area of the cross-section of the link, since the cross-sectional profile according to the claimed invention must have a deviation from roundness - ovality. Therefore, the conditional circle should always have an area smaller than the cross-sectional area of the link.

During operation, the working surfaces of the chain experience constant or cyclic exposure to an aggressive environment with simultaneous external mechanical loading, which leads to the destruction of the metal surface with a constant change in the size of the shape of the chain links. Thus, simultaneously with the corrosive effects of the medium, the surfaces of the chain links are subjected to local mechanical stresses arising from friction and other types of interaction of the mating surfaces, wear by solid abrasive particles, etc. All this leads to premature failure of the chain due to the intensive development of corrosion processes and wear of working surfaces.

The ratio of ultimate stress to maximum operating voltage is called the safety factor. For reliable operation of the circuit, it is impossible to allow the working (calculated) voltages during operation to become close to the limit, i.e. need to provide a margin of safety. The life of the chain depends on how quickly the chain loses its margin of safety.

The cross-sectional area of each link of the claimed chain should not be more or less than the circular cross-sectional area of the links of the already known and most common chain. An increase in cross-sectional area increases the mass of the chain, and a decrease in cross-sectional area reduces the strength of the chain. An increase in the mass of the chain negatively affects both the cost of the chain itself and the operation of the chain curtain and the entire rotary kiln, leading to an increase in the dust content of the gas flow, to destruction of the granules of the material, to an increase in the weight of the rotating part of the kiln, and an increase in the load on the rollers, bandages and gear gearboxes. Therefore, the optimal cross-sectional area of each link of the claimed chain should be equivalent to the circular area of the body of the link of the known chain. The experience of operating well-known chains with circular links shows that chains with a cross-sectional area of the link body of less than 40% of the initial cross-sectional area rapidly wear out, losing strength. In this case, the ratio of the surface to the volume (mass) changes, which leads to the loss of energy storage properties of the circuit. In this regard, the claimed invention provides for the protection of the critical cross-sectional area of the body of each chain link in the form of an increase in the area around it and the separation of the section boundaries from it, thereby increasing the chain safety margin and the chain life.

In the operation of the chain, such a parameter as the ratio of the surface of the chain link to its mass is important. It characterizes the heat storage properties of the circuit. The amount of heat accumulated (then given to the material) by the chain links depends on their mass, since there is a direct proportional relationship between the mass of the body and the amount of heat necessary for its heating. According to the claimed invention, the concentration of mass in the center of the body of the chain link allows you to accumulate a greater amount of heat in the links throughout the work of the chain. In the process of wear of the inventive chain, the ratio of the surface of the chain link to its mass will change slowly due to the concentration of the bulk in the central part of the body section of each chain link, remote from the boundaries of the cross section.

According to the claimed invention, the execution of the outer part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, a curved line, and the inner part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, at the junction of the links, a convex circular arc with a radius, equal to the radius of the curved part of the inner ring of the chain link mating with it, allows to increase the safety margin by increasing the period of allowable wear of the chain links and the mind by wearing at the contact point of the chain links.

The chain wear is simultaneously affected by many different factors leading to premature failure of the chain due to the intensive development of corrosion processes and wear of working surfaces, which are very difficult to deal with. Therefore, one of the directions for increasing the operability of chains for chain curtains of a rotary kiln operating under conditions of corrosion and abrasive wear is the rational design of a chain link of such shape and dimensions that would ensure the appearance on the working surfaces of minimal mechanical stresses during operation and would extend allowable wear period.

Corrosion-mechanical wear occurs as a result of mechanical stresses, accompanied by chemical interaction of the metal with the medium (high-temperature oxidation of the metal by gases).

According to the claimed invention, the use of curved surfaces at the links allows to reduce the wear of the chain, since in case of uneven corrosion its maximum penetration is estimated, and to increase the life of the chain to the maximum wear as a result of mechanical and corrosion-mechanical wear, i.e. increase the period of allowable wear. The greater the curvature of the convex surface of the chain link, the higher the period of allowable chain wear.

The contour of the cross section of the chain links in the form of a convex curved line allows you to further develop the surface of the chain link and to intensify heat transfer, since the length of the circular arc is always greater than the length of the chord that tightens it.

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The conjugation conditions, the nature of the contact of the internal end surfaces of the chain links also affect the wear rate. Therefore, according to the claimed invention, the inner part of the contour of an oval-shaped figure, which is a cross-sectional profile of each chain link, at the point of contact of the links is made of a convex circular arc with a radius equal to the radius of the curved part of the inner ring of the chain link that is mated to it, which allows to increase the contact surface between the chain links , and, due to the reduction of the load on the inner surface of the link, reduce its wear.

According to the claimed invention, the execution of the outer part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, a broken line, and the inner part of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, at the contact point of the links, with a convex circular arc with a radius equal to the radius of the curvilinear part of the inner ring of the chain link mating with it, makes it possible to increase the self-cleaning of the links in the absence of concave surfaces and the mind of the chain links shit wear of the chain links at their point of contact.

According to the claimed invention, the presence in the cross-sectional contour of each link of a chain of fractures or kinks formed by segments of a broken line allows the sludge adhering to the chain to more easily separate from the surface of the links, since in the relief of the film, repeating the relief of the links, multidirectional forces of its breaking and separation from the links , which contributes to the quick self-cleaning of chains in front of the decarbonization zone and the preservation of the particle size distribution of the material received from the chain zone, and does not increase dusty whith the gas stream. In order to ensure that the ribs at the points of fracture or kink of the cross-sectional contour of each chain link are not quickly worn out and burned during operation in the hot zone, they can be rounded off in the claimed chain.

The essence of the claimed invention is illustrated by drawings:

in FIG. 1 shows a general view of a chain with oval and round links;

in FIG. 2 shows sections of two-link segments of a chain with circular links and with the outer part of the cross-sectional contour of each link in the form of a convex curve of a line, first along one type of link, then along another type of link;

in FIG. 3 shows sections of two-link segments of a chain with oval-shaped links and with the outer part of the cross-sectional contour of each link in the form of a broken line, first along one type of link, then along another type of link;

in FIG. 4 shows the cross-sections of the links of two types of one chain with the outer part of the contour of the cross section in the form of a convex curve of the line;

in FIG. 5 shows the cross-sections of the links of two types of one chain with the outer part of the contour of the cross section in the form of a broken line.

The link chain for a chain curtain of a rotary kiln consists of interconnected links of any geometric shape, for example, an oval or a circle.

The cross section of each chain link has a profile that is an oval-shaped figure with a mutually perpendicular direction of the largest and smallest diameters.

The chain is made of two types of links with alternating through the link, the difference of which is that the longitudinal axis of the chain in one type of links 1 coincides with the largest diameter of the oval-shaped figure, and in the other type of links 2 coincides with the smallest diameter of the oval-shaped figure.

The smallest diameter of an oval-shaped figure representing the cross-sectional profile of each chain link is made equal to the diameter of the conditional circle 3 with an area equal to at least 40% of the cross-sectional area of the link.

The outer part 4 of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link is made by a convex curve, and the inner part 5 of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, at the contact point of 6 links, is made of a convex circular arc with a radius g equal to the radius K of the curved part of the inner ring 7 of the chain link mating with it.

The outer part 4 of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link is made by a broken line, and the inner part 5 of the contour of an oval-shaped figure representing a cross-sectional profile of each chain link, at the contact point of 6 links is made of a convex circular arc with a radius r, equal to the radius K of the curved part of the inner ring 7 of the chain link mating with it.

The chain for the chain curtain of a rotary kiln is used as follows. Chains are used as an internal heat exchanger. During the rotation of the furnace, some of the chains are in the gas stream, and the rest is immersed in the material. At the beginning of the chain zone, sludge adheres to chains in the gas stream. Chains in this part of the zone increase the contact surface of the sludge with hot gases, and as a result, heat transfer is improved. When the sludge dries, it loses its plasticity and no longer sticks to the chain. From this moment, the heat is transferred to the material by the chains according to the regenerative principle: the chains are heated in the gas stream and, when immersed in the material, they transfer heat to it. Along with this, the material receives heat from gases and lining.

The optimal design of the chains should ensure efficient heat transfer, be resistant to high temperatures, have a high margin of safety, maintain the particle size distribution of the material and not increase the dust content of the gas stream.

Claims (4)

CLAIM 1. Chain of different links for a chain curtain of a rotary kiln, consisting of interconnected links, each of which has a cross section, whose profile is an oval-shaped figure, the largest and smallest diameters of which are in mutually perpendicular directions, characterized in that the chain is made of two types of links with alternation through a link, while the longitudinal axis of the chain in one type of links coincides with the largest diameter of the oval-shaped figure, and in the other type of links coincides with the maximum smaller diameter oval shape. 2. Chain of various links for a chain curtain of a rotary kiln according to claim 1, characterized in that the smallest diameter of the oval-shaped figure, which is the cross-sectional profile of each chain link, is made equal to the diameter of the conventional circle with an area equal to at least 40% of the link section area . 3. Chain of different link for chain curtain rotating kiln according to claim 1, characterized in that the outer part of the contour of the oval-shaped figure, which is the cross-sectional profile of each chain link, is made with a convex curved line, and the inner part of the contour of the oval-shaped figure, which is the cross-sectional profile the cross section of each chain link, at the point of contact of the links, is made by a convex circular arc with a radius equal to the radius of the curvilinear part of the inner ring of the chain link associated with it. 4. Chain of different links for a chain curtain of a rotary kiln according to claim 1, characterized in that the outer part of the contour of the oval-shaped figure representing the cross-section profile of each chain link is made with a broken line, and the internal part of the contour of the oval-shaped figure representing the cross-section profile of each link of the chain, at the point of contact of the links, is made with a convex circular arc with a radius equal to the radius of the curvilinear part of the inner ring of the chain link associated with it.