RU117594U1 - GARRIER GRAIN COOLER COOLER TYPE - Google Patents

Abstract

1. A grate of a push-type grate cooler, containing a horizontal base and an inclined working plate of a rectilinear shape with through passages for cooling air, characterized in that the working plate is made with recesses, which in the vertical-longitudinal section of the grate have the shape of a triangle or several triangles, adjoining each other with the formation of alternating depressions and protrusions. ! 2. The grate of the push-type grate cooler according to claim 1, characterized in that heat-insulating and wear-resistant lining is made in all recesses in the working plate of the grate. ! 3. The grate of the pushing-type grate cooler according to claim 1, characterized in that the recesses in the working plate are made in all areas between the through passages for cooling air. ! 4. The grate of the pushing-type grate cooler according to claim 1, characterized in that the recesses in the working plate are made in areas above the stiffeners.

Description

The utility model relates to equipment for the production of cement, in particular, to devices for cooling and transporting bulk materials in grate-type coolers of a repellent type, and can be used in the building materials industry.

In Russia, the most common constructive solution used in the manufacture of grate-iron grate coolers is the grate-type design of a domestic grate-type refrigerator “Volga”, developed by UZTM and the Research Institute NIITSEMMASH. (A.I. Boganov. Mechanical equipment of cement plants. - Moscow-Sverdlovsk: Mashgiz, 1961, pp. 241-246). Known grate has an inclined or horizontal rectilinear working surface with slots for the passage of cooling air. When the grate of this design is working, the strength of the working plate decreases in areas where through passages for cooling air are not performed, due to the acceleration of the process of chemical corrosion due to the strong heating of these areas. To extend the life of the grate with this design, it is necessary, without considering the selection of the alloy, to resort to thickening of the working plate. An increase in the metal consumption of the grate leads to its appreciation, to overloading of the podkosolnikovy beams.

Closest to the claimed technical solution is the grate, known according to the application for invention 94030089/33, 08/10/1994 "Grate of a repulsive grate cooler" containing a horizontal base, an inclined curved working surface with slots for cooling air and thresholds, characterized in that the working inclined the surface is equipped with wavy protrusions and depressions arranged in the transverse direction in parallel rows symmetrical on both sides relative to the longitudinal axis of the grate and form between them an angle equal to 120 °, wherein the slots formed in the depressions trapezoidal profile and with alternate reciprocal of direction in each adjacent cavity.

The disadvantages of the known grate of the overhead grate cooler are:

- the complexity of the design due to the complex shape of the working surface, leading to a rise in the cost of manufacturing equipment for the production of grate;

- a relatively high speed of abrasive wear of the surface of the working plate of the grate due to the lack of wear-resistant protection;

- high working temperature of the grate;

- a relatively high corrosion rate of wear of the surface of the grate plate due to the destruction of the protective films on the metal surface during the sliding process;

- low strength of the grate working plate in areas where through passages for cooling air and thermal insulation protection are not performed, due to the acceleration of chemical corrosion of metal with strong heating of these areas.

The technical result of the claimed utility model is the elimination of these disadvantages, namely:

- simplification of the design, since in the inventive device it is permissible to use a straightforward, straightforward manufacturing plate with through passages for cooling air, for example, the grate of the Volga type grate cooler known and common in Russia, which will allow the manufacturer to produce the grate with the part equipment he already has;

- reduction of metal consumption and the cost of grate;

- reduction of the working temperature of the grate by reducing heat transfer due to the use of thermal insulation;

- reduction of abrasive wear;

- reduction of corrosion wear;

- increasing the strength and life of the grate, and, consequently, increasing the utilization of the refrigerator.

According to the claimed utility model, the technical result is achieved by the fact that the grate of the grate-type cooler of the repulsive type contains a horizontal base and a slab of a rectilinear shape inclined to it with through passages for cooling air, while in the working plate there are recesses that have a vertical-longitudinal section of the grate the shape of a triangle or several triangles adjacent to each other with the formation of alternating depressions and protrusions.

In all recesses in the working plate of the grate, heat-insulating and wear-resistant lining is performed.

The recesses in the working plate of the grate are made in all sections between the through passages for cooling air.

The recesses in the working plate of the grate are made in areas above the stiffeners.

According to the claimed utility model, the implementation of the working plate of the grate of the grate cooler of a pushing type of rectilinear shape with through passages for cooling air makes it possible to use the working plate of the grate of the grate cooler of the Volga type with minimal changes to the equipment already available to the manufacturer. At the same time, through passages for cooling air can be performed both in the form of slots and in the form of round holes.

According to the claimed utility model, the implementation of the recesses in the grate working plate makes it possible to fill these indentations with some heat-resistant and wear-resistant material, which during the operation of the grate cooler reduces heat transfer from the hot working material (clinker) to the grate and protects the surface of the grate working plate from abrasive wear and tear. This recess-filling material is a heat insulating and wear-resistant lining, for example, of the same working material, i.e. fine clinker. The implementation of the recesses in the working plate of the grate reduces the thickness of the working plate in the places of the recesses, and therefore, reduces the metal consumption of the grate and reduces its cost.

According to the claimed utility model, the implementation of the recesses in the working plate, having in the vertical-longitudinal section of the grate the shape of a triangle or several triangles adjacent to each other with the formation of alternating depressions and protrusions, allows you to most completely and evenly fill these recesses even with dry bulk material, as well as allows the friable bulk material that has fallen into these recesses to become denser under constant load and remain there for a long time during operation of the grate serve as a heat insulator, preventing the heat of the working surface of the grate plate and protecting it from abrasion. The larger the number of triangles, the more uniform the lining layer. The smaller the angle that forms the cavity, the better the filling of this cavity with dry bulk material. The larger the angle forming the protrusion, the lower the wear rate of this protrusion.

According to the claimed utility model, the implementation of heat-insulating and wear-resistant lining in all the recesses in the grate plate allows to separate the surface of the grate plate from the hot clinker with a layer of heat-insulating and wear-resistant material, which leads to a lower operating temperature of the grate, reduces wear and preserves films formed on the metal surface, restraining the spread of corrosion deep into the metal.

During the operation of the grate, there is a need to protect the grate plate from heat exposure in order to slow down the process of chemical corrosion of the metal, which consists in the interaction of the metal at high temperatures with oxygen and other active media. The chemical corrosion mechanism is reduced to reactive diffusion of metal atoms or ions through a gradually thickening film of corrosion products and counter diffusion of oxygen atoms or ions. With the simultaneous exposure of a metal to an aggressive environment and mechanical stresses, corrosion cracking occurs. Transcrystalline cracks appear in the metal, which lead to the destruction of the grate plate.

As a result of exposure to relatively rapidly changing heating and cooling, the surface of the grate working plate undergoes variable expansion and contraction. Their consequence is crack propagating over the surface. The presence of such cracks also reduces the strength of the grate plate. When protecting the surface of the grate plate from heat, the working temperature of the grate is reduced, which means that the likelihood of such cracks also decreases.

Various heat-resistant materials with low thermal conductivity and high wear resistance can act as a heat insulator. The best option is the option of filling the recesses with working material, i.e. clinker. It is best to fill the recesses in the working plate with a cold fine clinker before starting the grate cooler. But the hot clinker of small fraction, having got into these recesses with the grate cooler working, will cool quite quickly due to the limited time for heat transfer due to the constant movement of the working material. In this case, further heat transfer will be carried out as follows: from hot material to cold material, and then from it to the surface of the grate plate. Since the material is constantly moving, the heat exchange time between hot and cold material is limited. Clinker has tens of times less thermal conductivity compared to steel, therefore, with the regenerative method of heat transfer from the hot working material to the grate, the surface of the grate working plate is much less heated. In this case, naturally, during the operation of the grate cooler, we obtain protection of the grate working plate in the form of a heat-insulating lining. If necessary, the recesses in the grate working plate can be forcibly lined with other heat-resistant materials with low heat conductivity and high abrasion resistance, for example, heat-resistant concrete. The thickness of the lining is controlled by the thermal conductivity of its material.

Choosing a material with a hardness similar or higher than the hardness of the working material as a heat insulator, i.e. clinker, we also get protection of the surface of the grate working plate from abrasive wear, which, in turn, will reduce the intensity of corrosion wear. Corrosion wear occurs when surface contact occurs in corrosive environments. In the process of sliding, the films formed on the metal surface are destroyed and the corrosive effect propagates deep into the metal.

The inventive design of the grate of the grate cooler of the repulsive type allows naturally, in the process of its operation, to obtain or forcefully perform heat-insulating and wear-resistant lining of the grate working plate to reduce heat transfer and protect against abrasive wear, which leads to an increase in the life of the grate, and therefore increases the utilization rate the refrigerator.

According to the claimed utility model, the implementation of the recesses in the working plate in all areas between the through passages for cooling air allows you to protect against heating and wear the largest surface area of the working plate.

According to the claimed utility model, the implementation of the recesses in the working plate in areas above the stiffeners allows, in the absence of the possibility and need to protect all sections between the through passages for cooling air, to protect the surface of the working plate in areas where there is no air cooling from heating and wear.

The sections of the grate plate, where it is difficult to pass through the passages for cooling air, are more susceptible to both thermal and mechanical stresses than air-cooled sections. Such sections are all sections of the grate working plate around the through passages for cooling air. But it is not always possible and necessary to make recesses between all through passages for cooling air. For example, with a grate working plate in the design with through passages for cooling air in the form of round holes, there is no need to make recesses between the holes due to the small distances between them. And sections of the grate working plate above the stiffening ribs or some other protrusions on the lower surface of the working plate require protection in the form of heat-insulating and wear-resistant lining.

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

Figure 1 - shows a General view of the grate of the grate cooler of a repulsive type having a working plate with through passages for cooling air in the form of slots, where the recesses are made in all sections of the working plate between through passages for cooling air;

Figure 2 - shows a General view of the grate of the grate cooler of a repulsive type having a working plate with through passages for cooling air in the form of round holes, where the recesses are made in sections of the working plate above the stiffeners;

Figure 3 - shows a vertical longitudinal section of the grate of the grate cooler of the repulsive type without lining;

Figure 4 - shows a fragment of a vertical longitudinal section of the grate of the grate cooler of the repulsive type with forced lining.

The grate of the grate cooler of the repulsive type contains a horizontal base 1 and an inclined working plate of a rectilinear shape 2 with stiffeners 3 and with through passages 4 for cooling air. Through passages 4 for cooling air can be performed both in the form of slots and in the form of holes.

In the working plate 2 in all sections between the through passages 4 for cooling air, recesses 5 are made. (See Fig. 1)

In the working plate 2 in areas above the stiffening ribs 3 are made recesses 5. (see figure 2)

In the vertical-longitudinal section of the grate, the recesses 5 in the working plate 2 are in the form of one or more triangles 6 adjacent to each other with the formation of alternating depressions and protrusions. If necessary, the recesses 5 in the working plate 2 are forcedly lined with heat-insulating and wear-resistant material 7, for example, heat-resistant concrete.

The structure of the grate cooler of the repulsive type includes a grate, base, casing, scraper conveyors for cleaning the spill, grate drives, a discharge device with a hammer mill, fans for cooling air supply, a unit for cooling and humidification of excess air discharged through the suction unit into the surrounding medium, suction unit, lining.

All parts of the cooler exposed to high temperatures (grates and other details of the grate) are made of heat-resistant high-alloy steel.

On the grate, the clinker is cooled and transported from a rotary kiln to clinker conveyors. The grill consists of several sections arranged with a ledge relative to each other. The moving grates of each section are equipped with a separate crank-connecting rod and lever drive. Movable and fixed grid-irons are fixed respectively on movable and motionless transverse podkarolnikovy beams. Each transverse row of moving grate is overlapped by the next row of fixed grate. Between the grates there are gaps to compensate for their temperature expansion.

The clinker entering the cooler from the furnace at a temperature of 1150–1350 ° C is cooled by a stream of air blown through the clinker located on the grate with fans. The clinker temperature at the outlet of the cooler is 60-100 ° C

The grate of the grate cooler of the repulsive type is used as follows:

The burnt clinker from the furnace enters through the cooler receiving shaft directly to the loading section of the grate.

Clinker is moved on the grate with the simultaneous mixing of its layer due to the inclined reciprocating motion of the moving grate at a certain angle to the horizontal. Grids have slots for the passage of cooling air, therefore, when transporting clinker along the grate, small pieces wake up through these gaps into the armrest space and are removed using two scraper conveyors.

The podkolosnikovy space is divided by partitions into separate chambers into which cooling air is supplied from the fans. Cooling is done by air blown by fans through the grate and the clinker layer behind it. At the same time, the air heats up and enters partly into a rotary kiln, partly through a special duct into the decarbonizer, where it is used to maintain the combustion of fuel. Excess air from the cooler is discharged into the environment through the pipe and the suction unit.

Claims (4)

1. The grate of the grate cooler of a repulsive type, containing a horizontal base and a sloping plate of straight shape with through passages for cooling air, characterized in that the working plate is made with recesses, which in the vertical-longitudinal section of the grate have the shape of a triangle or several triangles, adjacent to each other with the formation of alternating depressions and protrusions. 2. The grate of the grate cooler of the repulsive type according to claim 1, characterized in that in all the recesses in the working plate of the grate the heat-insulating and wear-resistant lining is made. 3. The grate of the grate cooler of the repulsive type according to claim 1, characterized in that the recesses in the working plate are made in all sections between the through passages for cooling air. 4. The grate of the grate cooler of the repulsive type according to claim 1, characterized in that the recesses in the working plate are made in areas above the stiffeners.