RU148104U1 - CLINKER COOLING UNIT - Google Patents

Abstract

Installation for cooling the clinker, including a water bath, a rotating drum made of strips installed in it, means for loading and unloading the clinker, characterized in that the drum is made of five or more strips of convex curvilinear shape of variable width, curved along helical lines in the transverse direction on a barrel-shaped mandrel with the formation on the perimeter of the drum of helical lines and helical surfaces of a convex shape with centers of curvature inside the drum, as well as inlets inside the drum in the form of screw bars her throughout the length of the drum from the loading to the unloading.

Description

The utility model relates to the cement, coke, metallurgical industries, and in particular, to devices for cooling bulk materials, for example, clinker in the production of cement, coke, zinc, lead, tin and ore processing.

A device for cooling bulk materials (AS USSR, No. 1765154, class C10B 39/00, F27B 7/38), including a water bath, a rotating drum with cooling pockets installed in it, made of sections, each of which is mounted of six plates made in the form of isosceles trapezoid, means for loading and unloading. Each of the trapezoids is connected laterally with the subsequent trapezoid along its plane and passes through the top at the upper base and side, forming the internal cavity of the section in the form of a regular octahedron. The sections are interconnected into the drum with lower bases. The lower bases of the trapezoid are larger than the lateral side by the size of the upper base. The cooling pockets are formed by connecting in series along the perimeter of the section at an internal obtuse angle to each other alternately to the ends of the section with upper and lower bases with one-sided inlet in the direction opposite to the internal obtuse angle. One-sided inlet on the outer corner between the two plates is directed towards the rotation of the drum.

The disadvantages of the known device are limited technological capabilities due to insufficient cooling efficiency, due to insufficient heat exchange between bulk materials and cooling water, their low mixing capacity and a certain ordering of the movement of bulk materials inside the drum, the complexity of the assembly structure.

Closest to the proposed utility model is a device for cooling clinker (RF patent No. 2447130 IPC СВВ 39/00, publ. 04/10/2012, bull. No. 10), including a water bath, a rotating drum installed in it, made of three or more strips a variable width of a convex curvilinear shape rolled in a vertical plane in the longitudinal direction, curved along helical lines in the transverse direction and bent along notches, with beveled walls in the transverse-longitudinal direction, arranged in pairs at an angle to one another on both sides of the strips with the formation along the perimeter of the drum, broken helical lines and broken helical surfaces with variable pitch directed towards each other, as well as means for loading and unloading the clinker.

The disadvantages of the known device are limited technological capabilities due to insufficient cooling efficiency, the complexity of the assembly structure.

The technical result of the task is to expand technological capabilities, simplifying the assembly of the structure.

The technical result is achieved by the fact that in the installation for cooling the clinker, including a water bath, a rotating drum installed therein made of strips, means for loading and unloading the clinker, the drum is made of five or more strips of convex curvilinear shape of variable width curved along helical lines in transverse direction on a barrel-shaped mandrel with the formation along the perimeter of the drum of helical lines and helical surfaces of convex shape with centers of curvature inside the drum, as well as laps inside the drum in the form of helical blades across the length of the drum from the loading to the unloading.

According to the patent literature not found a technical solution similar to the claimed, which allows us to judge the usefulness of the proposed utility model of a device for cooling clinker.

The novelty is due to the fact that the drum along the perimeter is made of five or more vertically rolled curved and successively curved curved shapes along the length of the drum, rolled in a vertical plane in the longitudinal direction and curved in the transverse direction with helical lines to form a perimeter a drum of helical lines and helical surfaces of a convex shape, with centers of curvature inside the drum, and also inlets in the drum in the form of blades along the entire length of the drum from the dirt are narrow to unloading, which intensifies the cooling process and expands technological capabilities, while the speed of clinker particles inside the drum, as well as water outside the drum at each point of their flows pulsates randomly, so the clinker particles inside the drum, as well as water outside the drum make unsteady random movements along complex trajectories, and water turbulent movement.

The novelty lies in the fact that due to the internal helical surfaces of double curvature, the velocity vectors of the clinker particles change during transportation from load to unload, which contributes to the intensification of the clinker cooling process and expands technological capabilities.

The novelty of the proposed utility model lies in the fact that the drum is barrel-shaped and along the entire length has a variable not only transverse, but also longitudinal section, which intensifies the cooling process, increases the cooling efficiency and extends the technological capabilities of the clinker cooling system.

The novelty of the proposed utility model lies in the fact that such a structural design of the barrel-shaped drum allows for sequential gradual compaction and discharge of the flow of clinker particles from loading to unloading, which intensifies the cooling process and extends the technological capabilities of the installation.

The novelty is also seen in the fact that the area and shape of the cross and longitudinal sections of the drum change along the entire length from loading to unloading, which changes the speed and trajectory of movement of clinker particles inside the drum, as well as the water flows outside the drum. expands technological capabilities

The novelty also lies in the fact that along the perimeter of the drum there are formed helical surfaces with a variable width of a convex curvilinear shape along the length of the drum, which ensures a violation of the stationary motion of the flows of clinker particles inside the drum.

The novelty is also due to the fact that the pitch of the helical lines varies along the length of the drum; from loading it first increases, and then decreases towards unloading, which changes the speed of longitudinal movement of clinker particles and expands technological capabilities.

The novelty lies in the fact that the twisting of each strip in the transverse direction provides an additional curvature of the surface of the drum, which increases the difference between the angles of inclination of the vectors of movement of particles of clinker in neighboring sections of the drum. At the same time, clinker particles move along complex trajectories, increasing the frequency of collisions, intensifying the cooling process.

The novelty of the proposed utility model also lies in the fact that such a design of the drum allows for consistent gradual compaction and discharge of clinker flows, as well as water flows as the clinker moves from load to unload, as well as to increase the efficiency of mixing of clinker particles and their cooling.

The novelty is also seen in the fact that the area and shape of the cross and longitudinal sections of the drum change along the entire length of the drum from loading to unloading, which changes not only the speeds and trajectories of the clinker particles inside the drum, but also the water outside the drum, which make unsteady random movement along complex trajectories and provide turbulent movement of water in the bath, expands the technological capabilities of the device for cooling the clinker, increases the intensity of cooling.

The essence of the utility model is illustrated by drawings, where: in FIG. 1 shows the proposed installation for cooling clinker; in FIG. 2 - drum device, General view; in FIG. 3 is a view A in FIG. 2; FIG. 4 is a section AA in FIG. 2; in FIG. 5 is a plan view of a strip of convex curvilinear shape; in FIG. 6 is a view of a strip of convex curved shape after twisting it relative to the longitudinal horizontal axis O ₁ -O ₁ ; in FIG. 7 is a view of a strip of convex curved shape after twisting it on a barrel-shaped mandrel; in FIG. 8 is a section BB in FIG. 7.

The installation for cooling the clinker (Fig. 1) includes a water bath 1, a rotating drum 2 installed in it with loading 3 and unloading 4 devices. A sprinkler 5 is installed above the drum 2. A reflux condenser 6 is installed above the water bath 1.

The convex-shaped drum 2 (Fig. 2, Fig. 3, Fig. 4) is made of five or more strips of convex curved shape 7, 8, 9, 10, 11 (Fig. 3, Fig. 4) with the formation along the perimeter of the drum 2 a hollow multi-start helical surface with helical lines 12-13, 14-15, 16-17, 18-19, 20-21 (Fig. 2) and convex helical surfaces with centers of curvature inside the drum 2, as well as laps inside the drum 2 in in the form of screw blades 22, 23, 24, 25, 26 (Fig. 4) along the entire length of the drum 2 from loading to unloading.

The strips of convex curved shape 7, 8, 9, 10, 11 (one of the strips shown in Fig. 5) are folded in a vertical plane in the longitudinal direction relative to the longitudinal axis O ₁ -O ₁ (in Fig. 6 shows one of the strips of convex curved shape , for example 7, with edges 27 and 28 rolled in a vertical plane in the longitudinal direction relative to its longitudinal axis O ₁ -O ₁ ). Then, the strips of convex curvilinear shape 7, 8, 9, 10, 11 are bent along helical lines in the transverse direction, on a barrel-shaped mandrel 29 (Fig. 7, Fig. 8), for example 7, with the formation of 2 helical lines and helical around the perimeter of the drum convex-shaped surfaces with centers of curvature inside the drum 2, as well as laps inside the drum 5 in the form of screw blades 22, 23, 24, 25, 26 along the entire length of the drum 2 from loading to unloading.

Thus, the drum 2 is made of five or more strips of convex curvilinear shape (Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5) of strips 7, 8, 9, 10, 11 twisted in the longitudinal and in transverse directions along helical lines in the form of a hollow helical multi-starting surface. Namely, a convex, curvilinear strip, for example 7, previously twisted in the longitudinal direction relative to the longitudinal axis O ₁ -O ₁ (Fig. 6), is placed on the barrel-shaped mandrel 29 (Fig. 7, Fig. 8) and bent so that the edges 27 and 28 stripes, for example 7, were folded along helical lines. After that, the strip 7 is deformed and removed from the mandrel 29, or fixed on this mandrel. The remaining strips 8, 9, 10, 11 are treated in a similar manner. Next, five strips 7, 8, 9, 10, 11, thus deformed in such a way, after combining the longitudinal edges of the strips with the formation of slits 22, 23, 24, 25, 26 (Fig. 4) connect, for example by welding. As a result, five smooth helical lines 12-13, 14-15, 16-17, 18-19,20-21 and five internal smooth helical grooves 30, 31, 32, are formed along the perimeter of the drum 2 (Fig. 2) on the outer surface 33, 34 (Fig. 3) Since the strips 7, 8, 9, 10, 11 have a variable width (Fig. 5), the drum 2 (Fig. 2, Fig. 3, Fig. 4) has a variable longitudinal section and a variable cross section along the length of the drum 2. Therefore, the helical grooves 30, 31, 32, 33, 34 along the length of the drum 2 also have a variable cross section.

A device for cooling clinker works as follows.

Hot clinker, coke, etc. enters the rotating drum 2 using the loading device 3. The drum 2 is irrigated with water coming from the sprinkler 5. Inside the drum 2 due to the movement of clinker particles along complex paths and at different angles, their intensive mixing and cascade movement relative to each other and to the axis of rotation of the drum, as well as the walls, in the form of curved pockets, the contact frequency of the clinker particles with each other and with the walls of the drum 2 increases, therefore, intense heat transfer the expected particles of clinker and the walls of the drum 2, cooled from the outside of the drum 2 with water, while the process is intensified by watering the walls of the drum with water located along helical lines on the curved surfaces of the grooves 30, 31, 32, 33, 34, more precisely with pockets on the outer surface of the drum 2 at the junction of these grooves with each other around the perimeter of the drum 2. As the clinker particles pass inside the drum 2, the particles are cooled and removed from the device using the unloading device 4. The movement of the clinker particles the inside of the drum 2 from loading to unloading is carried out due to the presence of screw grooves 30, 31, 32, 33, 34 and screw blades 22, 23, 24, 25, 26 inside the drum. The steam released during cooling of the clinker particles condenses in the reflux condenser 6, which allows reduce water quenching. Water in the form of a film, flowing down the outer surface of the drum 2, cools the most thermally loaded side of the drum 2. This is also facilitated by the fact that, since the strips from which the drum 2 is mounted are folded not only in the longitudinal but also in the transverse direction , then along the perimeter of the drum 2 there are formed helical inner surfaces in the form of helical grooves 30, 31, 32, 33, 34. The formation of a complex inner surface in the form of a combination of two curved surfaces, at each point of which there are multidirectional components traffic, enhance the cooling effect due to the presence of divergent vectors. Thus, the double curvature of the surface of the drum 2 enhances the technological and transport effect, due to the presence of multidirectional vectors at each point on the inner surface of the drum 2. Due to the fact that the strips 7, 8, 9, 10, 11 have a variable width, with the formation along the perimeter of the drum 2 curved surfaces, a gradual discharge and compaction of the mass flows of clinker particles is carried out, which intensifies the cooling process. Thus, when the drum 2 rotates, clinker particles. they are captured by the internal helical surface, as well as by the blades 22, 23, 24, 25, 26, and in the direction of rotation they rise up and move towards the discharge side. Upon reaching a certain height under the influence of gravitational forces and the angle of repose formed, the clinker particles move towards each other at certain angles and to the walls of the rotating drum 2 and moves towards the discharge side. As a result, the heat transfer of clinker particles and the walls of the drum 2 increases. Since the curved surface of the drum 2 is continuous, the process of movement of subsequent portions of clinker particles, which rise up and fall down, is moving at different angles. Since the inner surface of the drum 2 is curved, curved and the blades 22, 23, 24, 25, 26, each portion of clinker particles moves along its direction vector towards the discharge side, which greatly intensifies the process of their interaction with each other and with the walls of the drum 2 , increases the intensity of cooling and expands technological capabilities. Since, due to the curvilinearity of the barrel-shaped surface of the drum 2, the range of changes in the resulting displacement vectors of clinker particles is significantly expanded, each clinker particle moves in different direction vectors, which makes them more likely to collide at the initial moment of their separation from the walls of the drum 2, where they have a certain a supply of kinetic energy and move with high kinetic energy, therefore, intensification of their interaction with each other and with the walls of the drum 2 is provided, increasing vayutsya heat flow and cooling processes are intensified.

Technical and economic advantages arise due to the expansion of technological capabilities, due to an increase in cooling efficiency due to an increase in the intensity of heat exchange between clinker particles and cooling water, an increase in their miscibility and intensification of the movement of clinker particles inside the drum, simplification of assembly of the structure.

Claims (1)

Installation for cooling the clinker, including a water bath, a rotating drum made of strips installed in it, means for loading and unloading the clinker, characterized in that the drum is made of five or more strips of convex curvilinear shape of variable width, curved along helical lines in the transverse direction on a barrel-shaped mandrel with the formation along the perimeter of the drum of helical lines and helical surfaces of a convex shape with centers of curvature inside the drum, as well as inlets inside the drum in the form of screw bars her throughout the length of the drum from the loading to the unloading.

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