RU112377U1 - CHAIN FOR CHAIN VALVE OF ROTARY FURNACE - Google Patents

Abstract

1. A chain for a chain curtain of a rotary kiln, consisting of interconnected links of any geometric shape with a cross-section of each link, the contour of which is made with ribbing, with the exception of a part of the contour at the point of contact of the chain links, which is made in the form of a circular arc with a radius equal to half chain pitch or the radius of the curved part of the chain pitch, characterized in that the cross-section of each link is made with the ratio of its vertical overall size to the horizontal overall size 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. ! 2. A chain for a chain curtain of a rotary kiln according to claim 1, characterized in that a circle is inscribed inside the cross-section of each chain link having an area of at least 60% of the area of the entire cross-section of the link.

Description

The utility model 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 furnaces of the building materials industry, at the moment, mainly round link chains are used, both welded and cast. (Valberg G.S., Griner I.K., Methododsky V.Ya. Intensification of cement production. - M.: Stroyizdat, 1971, p. 145)

According to patent RU 2285217, a chain is known for a chain curtain of a rotary kiln, consisting of interconnected links, where the links are made of any geometric shape hollow or with at least one recess located on the surface of the link, while the mass ratio of the removed material in the floor the link and in the link made with recesses to the initial mass of the link is 3-60% with the area of the smallest cross section of the link with the recesses, which is at least 70% of the cross-sectional area of the original link, and hollow links and links The holes with recesses are made of different sizes with the arrangement of links from larger to smaller to the free end of the chain.

The disadvantages of the known chain according to patent RU 2285217 are:

- low margin of safety for the chain with hollow links, since the tensile strength of the link in the form of a tube is significantly reduced;

- low dust collection of the chain curtain due to poorly developed surface of the chain links;

- increased wear of the mating part of the surface of the chain links due to the small surface area of the contact;

- not a very high effect from the intensification of heat transfer due to the underdeveloped surface of the chain links.

Closest to the claimed technical solution is the chain for a curtain curtain of a rotary kiln known according to the patent RU 2413106, which comprises interconnected links with a curved inner end surface of each of them, made in radius, while the cross section of each link is on the side of its outer surface made with ribbing, and on the side of the inner surface with a radius equal to half the chain pitch or the radius of the curved inner end surface of the link.

The disadvantages of the known chain are:

- low dust collection of the chain curtain due to poorly developed surface of the chain links;

- not a very high effect from the intensification of heat transfer due to the underdeveloped surface of the chain links.

The technical result of the claimed utility model is:

- increase the dust collection of the chain curtain;

- intensification of heat transfer with a higher effect;

- reduction of heat consumption for firing;

- increase the safety margin of the chain.

The technical result is achieved in that the cross section of each link of the inventive chain for a chain curtain of a rotary kiln, consisting of interconnected links of any geometric shape, for example, an oval or a circle, is made with a ratio of its vertical overall dimension to the horizontal overall dimension equal to 0.3 -0.9, and with ribbing of the surface of each link with ribs having a contour in the form of a circular arc or a triangular section.

At the same time, at the contact point of the chain links, a part of the cross-sectional contour of each link is made in the form of an arc of a circle with a radius equal to half the chain pitch (half the diameter of the inner ring of the link) or the radius of the curved part of the chain pitch (radius of the curved part of the inner ring of the link).

Inside the cross section of each chain link, a circle is inscribed having an area of at least 60% of the total cross section of the link.

According to the claimed utility model, the implementation of the cross section of each chain link with the ratio of its vertical overall dimension to the horizontal overall dimension equal to 0.3-0.9, allows you to increase the outer diameter of the link while maintaining the inner diameter (chain pitch), as well as the surface area of each link, therefore, increases the dust collection of the chain curtain. Reducing the entrainment of dust from the curtain area, and with it the heat, also leads to the intensification of heat transfer in the furnace. The increase in the area of the outer surface of the link, i.e. heat transfer surface, leads to the intensification of heat transfer from the gas stream to the material. The reduction of dust removal from the furnace leads to a decrease in heat loss with exhaust gases and fuel economy. The ratio of the vertical overall size (small size) of the cross section of the link to the horizontal overall size (large size) is, by analogy with an ellipse, the compression ratio of this section. The upper limit of the ratio of the overall dimensions of the cross section of the link in the form of a value equal to 0.9 is determined by the fact that if the compression coefficient is equal to 1, then the compression will be 0, therefore, the surface area of the link will be minimal. The lower limit of the ratio of the overall dimensions of the cross section of the link in the form of a value equal to 0.3 is determined by the fact that for lower values of this ratio, i.e. with an excessively low and excessively wide profile, the chain quickly loses its margin of safety. This is due to the fact that the cross section of each chain link with an excessively low profile weakens faster due to burnout of the material. Moreover, the wear of the chain increases due to the fact that with an excessively wide cross-sectional profile of each chain link, the chain links touch or intersect, which, in turn, exposes the chain to the effect of additional loads (shock load, friction, etc.).

According to the claimed utility model, the ratio of the overall dimensions of the cross section of the link, characterizing the degree of compression of the section, is limited by the possibility of inscribing into this section a circle with an area equal to at least 60% of the area of the entire cross section of the link. Therefore, the optimal ratio of the overall dimensions of the cross section of the link, so to speak, compression ratio, can be considered a value close to 0.5, i.e. equal ≈0.5. At lower values of the ratio of the overall dimensions of the cross section of the link, it becomes difficult to fit into this section a circle with an area of 60% of the area of the entire cross section of the link.

For example, when constructing a section of a chain link, which is a replacement of a link with a circular cross section with a diameter of 25 mm, the maximum developed surface of each chain link is obtained with a ratio of overall dimensions of the cross section of the link equal to 0.48-0.5. With this compression of the cross section, the surface of each link of this chain increases by ≈40-50%, which significantly increases the heat transfer in the rotary kiln, and the heat consumption for firing is reduced, since an increase in the width of the cross section of each chain link from 25 mm to 40 mm a significant reduction in dust removal.

Due to the fact that the heat transfer coefficient from the gas stream to the chains is less than from the chains to the material, there is a need for the chains to stay longer in the gas stream - above the surface of the material. (Yu.I. Deshko, M.B.Kreimer, T.A. Ogarkova. Adjustment and heat engineering tests of rotary kilns at cement plants. Second edition, revised and supplemented, - M .: Stroyizdat, 1966, p. 28) The use of compression of the cross section of each chain link makes it possible to quickly heat the chain in a gas stream, therefore, there is no need to delay it above the surface of the material. Reducing the size of the cross section of each chain link at the base of the ribs also contribute to a more rapid heating of the entire chain.

According to the claimed utility model, the implementation of the finning of the surface of each link with ribs having a contour in the form of a circular arc or a triangular section, allows you to further develop the surface of the chain link and to intensify heat transfer without overestimating the weight of each link in the chain. The number of ribs can be any.

The optimal cross-sectional shape of the rib with the smallest weight for a given heat flux is formed by circular arcs, which was first discovered by F. Weinig, and the proof of this position was given by E. Schmidt. (E.R. Eckert and PM Drake. Theory of heat and mass transfer. Translated from English by E.M. Furmanova, G.R.Malyavskaya and L.B. Shashkova, edited by Acad. ANSSR A.V. Lykov, - M. -L., Gosenergoizdat, 1961, p. 78-79)

The chain, having a reduced mass, being in the material, destroys it less, abrades, and accordingly the amount of dust carried out by the gas stream from the furnace decreases. The reduction of dust removal from the furnace leads to a decrease in heat loss with exhaust gases and fuel economy.

To build the contour of the section of the edge, you can use any part of the circle. The difference in weight with such concave surfaces and ribs of a triangular section is very small, and in production it is easier to obtain ribs of a triangular section. Circular arcs may not intersect, for example, when reinforcing the end rib. The regulation of the cross-sectional area, and hence the mass of the link, is carried out by increasing or decreasing the radii of these circles.

The implementation of the surface of each chain link with fins allows to increase the heat transfer from gas to the chain and from the chain to the material, because by increasing the heat transfer surface the thermal resistance of heat transfer decreases. (A.P. Baskakov, B.V. Berg, O.K. Witt and others. Heat engineering. Ed. 2, revised. - M.: Energoatomizdat, 1991, pp. 100-101). The efficiency of surface finning becomes more significant in the process of heat transfer from the gas to the circuit, since here the greatest thermal resistance takes place.

With a finned surface of a link of the claimed chain, the sludge film adhering to it is easier to separate from the surface of the links, since in the film relief, which repeats the relief of the links, multidirectional forces of its breaking and separation from the links arise, which contributes to quick self-cleaning of the chains in front of the decarbonization zone and preservation of the particle size distribution of the material, coming from the chain zone, and does not increase the dust content of the gas stream.

In order to ensure that the ribs do not quickly wear out and do not burn during operation in the hot zone, in the claimed chain they can be smoothed out by rounding.

According to the claimed utility model, the execution at the point of contact of the chain links of the cross section of each chain link in the form of an arc of a circle with a radius equal to half the chain pitch (half the diameter of the inner ring of the link), or the radius of the curved part of the chain pitch (radius of the curved part of the inner ring of the link ), increases the contact surface between the chain links, and due to the reduction of the load on the inner surface of the link reduces its wear.

According to the claimed utility model, the implementation of the cross section of each chain link with the need to fit inside the cross section of a circle having an area of at least 60% of the area of the entire cross section of the link, allows you to increase the margin of safety of the chain.

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 (rated) stresses during operation to become close to the limiting ones (technological impacts: material burnup, abrasion, tension, torsion, etc.), i.e. need to provide a margin of safety. During operation of the chain, when the cross-sectional area of its links approaches the value equal to 60% of the initial cross-sectional area, the safety margin is lost. So, the life of the chain depends on how quickly the chain loses its margin of safety. According to the claimed utility model, the critical area (circle area) has additional protection in the form of ribs, which allows to extend the life of the chain.

The essence of the claimed utility model is illustrated by the drawings:

In Fig.1 - shows a fragment of a section of a chain in the embodiment with links of round shape;

Figure 2 - shows a fragment of a section of a chain in the embodiment with links of an oval shape;

Figure 3 - shows a cross section of a chain link;

A chain for a chain curtain of a rotary kiln, consisting of interconnected links 1 of any geometric shape, for example, an oval or circle, with a cross section of each link, also of any shape, the contour of which is made with ribbing, except at the point of contact of 2 links of the chain part of the contour, which is formed as a circular arc with a radius r, equal to half of the chain pitch t / 2, or the radius r of the curved part of the chain pitch t, characterized in that the cross-section of each link is adapted to its vertical overall dimension ratio to the horizontal Dimensions b, equal to 0.3-0.9, i.e. (a / b) = 0.3-0.9, and all ribs 3 of each chain link have a contour in the form of an arc of a circle or a triangular section. The number of ribs 3 can be any. To build the contour of the section of the edge, you can use any part of the circle.

Inside the cross section of each chain link, a circle 4 is inscribed, having an area of at least 60% of the area of the entire cross section of the link.

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 improves. When the sludge dries, it loses its plasticity and no longer sticks to the chain. From that moment, 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, 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 (2)

1. Chain for a chain curtain of a rotary kiln, 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 links of the chain part of the contour, which is made in the form of an arc of a circle with a radius equal to half chain pitch or the radius of the curvilinear part of the chain pitch, characterized in that the cross section of each link is made 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 an arc of a circle or a triangular section. 2. A chain for a chain curtain of a rotary kiln according to claim 1, characterized in that 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.