RU2469250C1 - Rotating furnace for preparation of cement clinker - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: furnace includes housing supported through bandages by support rollers, dual drive consisting of two electric motors and two reduction gears, two under-ring gears, one ring wheel, supply pipe of slurry for roasting of cement clinker, head for supply of fuel and air to the furnace, chain filter-heater, heat exchangers, grate-shearing cooler, water cooling plant and central lubrication system. Housing is installed horizontally and made of three or more trapezoidal strips twisted along screw line in longitudinal direction and bent in transverse direction along screw line on conical mandrel. Strips have different dimensions as to width with their increase along the length of housing from loading to unloading, with formation along the housing perimetre of three or more spiral grooves and screw lines with variable increasing pitch from loading to unloading. Strips form internal curved surfaces of convex or concave shape relative to housing rotation axis with curvature centres outside or inside the housing.

EFFECT: enlarging manufacturing capabilities, simplifying operation and intensifying heat exchange.

12 dwg

Description

The invention relates to a technique for firing cement clinker and can be used in the cement industry.

Known rotary kiln for firing bulk material (AS No. 1322051, class 27 B7 / 16, 01/07/86), containing heat exchangers and a screw insert located in the working space of the furnace and equipped with a helical ring and brackets, the plane of which is directed along forming a furnace, moreover, a screw insert is fixed on one side of the bracket and a screw ring on the other side, and a screw ring is fixed at an angle to the radial direction of the furnace and the screw insert is fixed in front of the heat exchangers, counting along gas movement.

A disadvantage of the known device is the lack of heat transfer and limited technological capabilities.

Known rotary kiln for the preparation of cement clinker (Komar A.G. / Building materials and products // A.G. Komar / textbook. Higher school, 1988, p.147-148), containing a cylindrical body, resting through the bandages on the support rollers , a double drive, consisting of two electric motors and two gears, two gears, one crown wheel, a feed pipe for feeding sludge for firing cement clinker, a head through which fuel and air are fed into the furnace, a chain filter heater, heat exchangers, grates per flicker freezer. The housing has a slope of 3.5-4% and is equipped with a water cooling unit and a central lubrication system.

A disadvantage of the known rotary kiln for firing cement clinker is the need to create a slope for transporting slurry for firing cement clinker from loading to unloading, due to the complexity of its operation, insufficient heat transfer rate and limited technological capabilities.

The technical solution to the problem is the expansion of technological capabilities, simplification of operation due to the lack of slope and the intensification of heat transfer.

The technical solution is achieved by the fact that the rotary kiln for the preparation of cement clinker contains a housing supported through shafts on the support rollers, a double drive, consisting of two electric motors and two gears, two gears, one crown wheel, a feed pipe for feeding slurry for burning cement clinker , a head for supplying fuel and air to the furnace, a chain filter heater, heat exchangers, a grate-repulsive cooler, and is equipped with a water cooling unit and a central lubrication system, the casing is mounted horizontally and made of three or more twisted along the helical line in the longitudinal direction and curved in the transverse direction along the helical line on the conical mandrel strips of trapezoidal shape with different sizes in width, with an increase in length along the length of the body from loading to unloading, with the formation along the perimeter of the body of three or more helical grooves and helical lines with a variable, increasing step from loading to unloading, as well as internal curved surfaces of concave or convex shape relative to the rotational axis of the centers of curvature of the outside or inside of the housing.

According to the patent literature, no technical solution was found that is similar to the claimed one, which allows one to judge the inventive step of the proposed design of a rotary kiln for the preparation of cement clinker.

The novelty lies in the fact that such a structural design of the casing allows for axial movement of sludge particles for firing cement clinker from loading to unloading with a horizontal axis of rotation of the casing, which simplifies the operation of the furnace, which rotates due to the lack of slope of the casing.

The novelty is due to the fact that the casing is multi-starting with the formation along the perimeter of the casing of three or more helical grooves and helical lines with a variable incrementing step from loading to unloading, therefore, along with the intensification of the process of mixing sludge particles, not only their movement along the horizontal axis of the casing is ensured, which eliminates the need for mounting the housing at an angle to the horizontal, i.e. not only axial movement of sludge particles is ensured when the axis of rotation of the casing is horizontal, but the intensity of heat exchange processes also increases, and technological capabilities expand.

The novelty of the proposal lies in a smooth increase in the bore of the body along the length from loading to unloading, which increases the speed of movement of the particles of the sludge, expands the technological capabilities.

The novelty also lies in the fact that due to the twisting of trapezoidal bands of variable width in the transverse direction, curved surfaces of various curvatures are formed inside the body in each cross section along the length of the body, which not only changes the trajectory of the movement of sludge particles at each point of the curved surface of the body, but also accelerates the process of movement of particles of sludge, expands technological capabilities.

The novelty is due to the fact that the housing along the perimeter is equipped with three, four, five, six, etc. helical lines, the step of which varies from loading to unloading and, accordingly, three, four, five, six, etc. helical grooves inside the casing, which increases the speed of movement of sludge particles from loading to unloading, intensifies heat transfer processes, expands technological capabilities.

The novelty is also seen in the fact that the pitch of helical lines increases from loading to unloading, which ensures an increase in the speed of longitudinal movement of the sludge and expands technological capabilities.

The novelty is also due to the fact that the cross-sectional area and shape of the body changes from loading to unloading, which changes the speed and trajectory of the movement of sludge as they move from loading to unloading, intensifies heat transfer processes, increases the intensity, energy intensity and frequency of their interaction, expands technological capabilities .

The novelty also lies in the fact that the casing is made with concave or convex internal curved surfaces relative to the axis of rotation of the casing with centers of curvature located outside or inside the drive casing, which violates the stationary motion of sludge particles for firing cement clinker, intensifies heat transfer processes, swirls heat fluxes and expands technological capabilities.

The novelty also lies in the fact that helical surfaces and helical grooves swirl the gas heat flow, which intensifies heat transfer.

Figure 1 shows a General view of a rotary kiln rotating for the preparation of cement clinker; figure 2 is a part of the housing of a rotary kiln for the preparation of cement clinker, front view mounted from three trapezoidal strips; figure 3 is a view a in figure 2; figure 4 is a part of the housing of a rotary kiln for the preparation of cement clinker, front view mounted from four trapezoidal strips; 5 is a view B in figure 4; 6 is a part of the housing of a rotary kiln for the preparation of cement clinker, front view mounted from five trapezoidal strips; Fig.7 is a section bB in Fig.6; in Fig.8 is a section bb In Fig.6 housing of a rotary kiln for the preparation of cement clinker made of helical strips in which the centers of curvature are located outside the cross section of the housing; in Fig.9 - section bb in Fig.6 of the rotary kiln body for the preparation of cement clinker made of helical strips in which the centers of curvature are located inside the cross section of the body; figure 10 - trapezoidal strip after twisting in the longitudinal direction relative to its own longitudinal axis of symmetry; 11 - a trapezoidal strip after bending along a helical line in the transverse direction on a conical mandrel; in Fig.12 is a section GG in Fig.11.

The rotary kiln for the preparation of cement clinker (Fig. 1) consists of a housing 1, supported through shafts 2 on the support rollers 3. The housing 1 is mounted horizontally and rotates, providing a process for the movement of slurry particles in it for the preparation of cement clinker. The kiln’s drive is double and consists of two electric motors 4, two gears 5, one ring gear 6 and two gear gears 7. The rotary kiln is equipped on one side with a feed pipe 8 for feeding slurry for burning cement clinker into the housing 1, and on the opposite side with a head 9 for supplying fuel and air. From the side of the head 9, fuel and air are supplied to the furnace. As a result of fuel combustion, hot gases are obtained, the flow of which is directed from the hot end of the furnace to the cold towards the moving particles of sludge for burning cement clinker. To improve heat transfer and dust removal of gases inside the furnace, a chain filter heater 10 is placed at its cold end, a chain curtain 11 is created, and heat exchangers 12 are installed. The dust collected as a result of gas cleaning is returned to the furnace. It is transported by a pneumatic pump to the hopper, and from it, using a peripheral loader 13, is sent to the hollow part of the furnace, located next to the chain curtain from the hot end. To cool the particles of the finished cement clinker, the furnace is equipped with a grate-firing cooler 14. The housing 1 is equipped with a water cooling unit 15 and a central lubrication system 16.

Case 1 (figure 2, figure 3) is made of three trapezoidal bands 17, 18, 19 with different dimensions in width, increasing along the length of the case 1 from loading to unloading, twisted along a helical line in the longitudinal direction and curved along helical line in the transverse direction. After bending, the strips 17, 18, 19 are connected to each other by the lateral sides by known methods, for example, by welding, with the formation along the perimeter of the housing 1 of helical lines and internal helical grooves with a variable, increasing along the length of the housing 1 by step S ₁ , one of which is 20-21 shown in figure 2, figure 3 thickened line.

The housing 1 (Fig. 4, Fig. 5) is made of four trapezoidal bands 22, 23, 24, 25 with different dimensions in width, increasing them along the length of the housing 1 from loading to unloading, twisted along a helical line in the longitudinal direction and curved in a helical line in the transverse direction. After bending, the strips 22, 23, 24, 25 are connected to each other by lateral sides by known methods, for example, by welding, with the formation along the perimeter of the housing 1 of helical lines and internal helical grooves with a variable, increasing along the length of the housing 1 step S ₂ , one of which 26 -27 is shown in Fig.6, Fig.5 thickened line.

Housing 1 (Fig.6, Fig.7) is made of five trapezoidal strips 28, 29, 30, 31, 32 with different dimensions in width, increasing them along the length of the housing from loading to unloading, twisted along a helical line in the longitudinal direction and curved in a helical line in the transverse direction. After bending, the strips 28, 29, 30, 31, 32 are connected to each other by the lateral sides by known methods, for example, by welding, with the formation along the perimeter of the housing 1 of helical lines and internal helical grooves with a variable, increasing along the length of the housing 1 step S ₃ , one of which 33-34 is shown in Fig.6, Fig.7 thickened line.

The housing 1 can be made with concave internal curved surfaces with centers of curvature located outside the housing 1 (Fig. 8), or convex in relation to the axis of rotation of the housing 1 with centers of curvature inside the housing 1 (Fig. 9).

Each of the trapezoidal bands 17, 18, 19; 22, 23, 24, 25; 28, 29, 30, 31, 32 twisted in the longitudinal direction relative to its own axis of symmetry, for example, as a trapezoidal strip 17 in figure 10, in which one of its ends is fixed in a hot or cold state and the other end of the strip is rotated in a given direction. Thus twisted strip 17 is placed on a conical mandrel 35 (Fig. 11, Fig. 12) and bent so that the edges of the strip are placed in the transverse direction along a helical line. In this case, the strip is deformed and it is either removed from the mandrel or fixed on it in a deformed position. Similarly, the remaining strips forming the housing 1 are deformed. Next, three, four, five or more strips thus deformed are connected by known methods along the lateral helical edges. The twisting of each strip of trapezoidal shape provides an additional curvature of the surface of the housing 1, which intensifies the process of interaction of particles of sludge and heat transfer processes.

The proposed rotary kiln for the preparation of cement clinker works as follows. The housing 1, mounted horizontally, rotates. Slurry for firing cement clinker is fed into the feed pipe 7 using bucket or volumetric batchers located at the cold end of the furnace (housing 1). From the side of the head 9, fuel and air are supplied to the furnace (housing 1). The combustion of the fuel produces hot gases, the flow of which is directed from the hot end of the furnace (housing 1) to the cold, towards the moving particles of the sludge for burning cement clinker. The particles of sludge for firing cement clinker, while inside the rotating housing 1, carried away by its screw surfaces, rise up and, rising in the direction of rotation of the housing 1 slightly higher than the angle of their natural slope, slide down like an avalanche. Since the housing 1 along the perimeter is equipped with a multi-start screw surface, the particles of the calcined cement clinker are moved inside the housing 1 and move them from loading to unloading with a horizontal arrangement of the housing 1. The filter-heater 9 improves heat transfer and removes gases. The dust collected as a result of gas cleaning is returned to the furnace. It is transported by a pneumatic pump to the hopper, and from it, using a peripheral loader 12, is sent to the hollow part of the furnace, located next to the chain curtain from the hot end. After firing, the particles of cement clinker are cooled in a grate-repulsive cooler 14.

Technical and economic advantages arise due to the provision in the rotary kiln of longitudinal movement of sludge particles for the preparation of cement clinker with a horizontal arrangement of the casing and the creation of their counter flows due to the fact that inside, along the entire length of the casing, helical surfaces and helical grooves are formed that provide no only the movement of sludge particles, but also contribute to the intensification of the interaction of sludge particles for the preparation of cement clinker with each other and with the walls to housing, which allows not only to influence the nature of the movement of sludge particles for the preparation of cement clinker and change the direction of their speed, but also expands technological capabilities, increases the heat transfer rate, simplifies the operation of a rotary kiln with its horizontal arrangement, expands technological capabilities.

Claims (1)

A rotary kiln for the preparation of cement clinker, comprising a housing supported through shafts on the support rollers, a double drive consisting of two electric motors and two gears, two gear wheels, one crown wheel, a feed pipe for feeding slurry for firing cement clinker, a head for feeding into a fuel and air oven, a chain filter heater, heat exchangers, a grate-cooler and equipped with a water cooling unit and a central lubrication system, characterized in that o the body is installed horizontally and made of three or more twisted along the helical line in the longitudinal direction and curved in the transverse direction along the helical line on the conical mandrel strips of trapezoidal shape with different sizes in width, increasing them along the length of the body from loading to unloading, with the formation along the perimeter of the housing of three or more helical grooves and helical lines with a variable increasing step from loading to unloading, as well as the internal curved surfaces of a concave or convex relative shape but the rotational axis of the centers of curvature outside or inside the housing.

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