KR100531994B1 - Movable stoker - Google Patents

Abstract

Two types of aeration passages formed through the upper and lower surfaces of the movable and fixed grids, the rear passages formed in the rear portion of the movable and fixed grids, and the front passages formed in the front of the movable and fixed grids. At least an upper end side of the rear aeration passage is formed at a right angle with respect to the upper surface, and at least an upper end side of the front aeration passage is inclined forward with respect to the upper surface, so that the supply air is blown out and between the movable grid and the fixed grid. Effect of cooling of the movable and fixed grating rear part by enabling supply air to be contacted with the workpiece and the supply air at the rear part of the movable and fixed grating while suppressing the engagement by inserting the object to be treated Can increase.

Description

Operation Grate {MOVABLE STOKER}

TECHNICAL FIELD This invention relates to the movable grate used for the clinker cooling cooler in a cement baking plant, the incinerator in a waste incineration plant, etc., for example.

Conventionally, as a movable stoker used in a clinker cooling cooler, a movable grating and a fixed grating each having a ventilation path penetrating between an upper and lower surfaces thereof, and a fixed grating or a rear side of a movable grating plate adjacent to the front of each front part thereof. Formed alternately, and the movable grid is reciprocated in the front and rear direction to push the object forward, and the air supplied from the lower side is brought into contact with the object through the air passage and cooled. As the movable grate, it is known that the air passage penetrates only the front part of the grating at a right angle to the upper surface of the grating, but also passes through the grating inclined with respect to the upper surface of the grating. 9-188552).

Moreover, although it is not a movable grate, it is also known that the grate which fixed all the gratings is fixed, and each grating is made into the box shape which supplies air inside, and the vent located in the upper surface inclined with respect to the top surface is known. Published Patent Publication No. Hei 6-3351).

However, in the movable grate, the passage of the air passage at right angles to the upper surface of the grating is likely to be blown out through a thin portion of the object layer loaded on the grating because the air emitted there rises immediately. Has a problem. If such an ejection is caused, the quantity of air supplied to the thick part of a to-be-processed object layer will fall, and cooling efficiency will fall overall. In addition, although a part of the air heated up by cooling the to-be-processed object is reused as fuel combustion air, when the supply amount of air is increased in order to obtain the required cooling state in the state in which cooling efficiency fell by the said blowout, the temperature of the recycled air And the combustion efficiency of the fuel is also lowered.

On the other hand, penetrating the air passage inclined with respect to the upper surface of the grating plate has an advantage that it is easy to obtain a Coanda effect in which air is blown out along the upper surface of the grating plate. By this Coanda effect, when air is blown out from the air passage along the upper surface of the grating, it is difficult not only to cause the above blowout, but also to cool the grating so that the protection effect of the grating cooling becomes higher, and further, from the air passage. The fall of the to-be-processed object can also be suppressed.

On the other hand, since the air passage in the conventional movable grate is formed only at the front part of the grating, the contact with air does not occur while the workpiece remains in the rear part of the grating, resulting in poor cooling efficiency. There is. Moreover, in the grating | lattice rear part without a ventilation path, there exists also a problem that the cooling protection effect of the grid | lattice as air passes through a ventilation path is not acquired, but it becomes easy to be overheated and to be damaged.

In order to solve the problem while preventing the ejection, it is conceivable to form the inclined air passage not only in the front portion but also in the rear portion of the grating plate.

However, as shown in FIG. 6, since the inclined air passage 2 becomes wider in the upper surface opening width, the to-be-processed object mass 3 is pinched here, and at the time of retreat of the movable grating plate 1a (when advancing) There is a problem that the workpiece mass 3 is inserted into the gap between the fixed grid 1b adjacent to the rear (front) and interlocks, and both the grids 1a and 1b are easily damaged. .

According to the conventional fixed grating, since there is no movement of the grating, there is no engagement, and an inclined air passage can be formed at both the front and the back of the grating to prevent the ejection and improve the overall cooling protection effect. .

However, in the case of the fixed grating, it does not have a conveying function of the object to be processed by the movement of the lattice plate, and therefore, there is a problem in that when a large lump is supplied, the congestion occurs and the conveyance of the object is easily inhibited. Moreover, in general, a movable grate excellent in the carrying function of the object to be processed is often employed, and there is also a problem that it requires a high cost to convert it to the fixed grate.

The present invention has been made in view of the above-mentioned problems, and is excellent in the carrying function of the object to be processed, and moreover, it is possible to operate the movable grate, which is generally spread while suppressing the engagement of the ejection of the supply air and the insertion of the object mass. And to enable contact between the workpiece and the supply air at the rear part of the fixed grating plate, and to increase the cooling protection effect of the operation by the supply air and the rear part of the fixed grating plate.

1 is a perspective view showing a schematic configuration of a movable grate according to the present invention.

FIG. 2 is a partial cross-sectional perspective view showing an example of a movable and fixed grating used in the movable grate of FIG. 1.

3 is an explanatory view of the operation of the present invention.

4 is another explanatory view of the operation of the present invention.

It is a schematic diagram which shows an example of the clinker cooling cooler provided with the movable grate which concerns on this invention.

6 is an explanatory diagram of a problem of the present invention.

The movable grate of the present invention includes an air passage formed through the upper and lower surfaces of each of the movable grating and the fixed grating, and a rear aeration path formed at the rear of the movable and fixed grating, and the front of the movable and fixed grating. Two types of formed front aeration passages are formed, at least an upper end side of the rear aeration passage is formed at right angles to the upper surface, and at least an upper end side of the front aeration passage is formed to be inclined forward with respect to the upper surface. . In addition, the present invention has the above-mentioned features, thereby providing the workpiece and the supply at the rear of the movable and fixed grid, while suppressing the ejection of the supply air and the engagement by the insertion of the workpiece mass between the movable grid and the fixed grid. The air can be contacted, and the cooling protection effect of the operation by the supply air and the rear part of the fixed grid can be enhanced.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail.

As shown in FIG. 1, the movable and fixed grating boards 1a and 1b are plate-like bodies each having an air passage 2 passing between the upper and lower surfaces, and are arranged in the front-rear direction. The movable grating board 1a is attached to the movable frame 4 located below, and it is possible to reciprocate with the movable frame 4 in the front-back direction. In addition, the fixed grating | lattice board 1b is attached to the side wall of a clinker cooler, or the side wall of an incinerator, for example, and is being fixed to a fixed position.

The movable grating plate 1a and the fixed grating plate 1b are alternately formed in the front-rear direction by superimposing their front portions on the fixed grating plate 1b adjacent to the front or the rear part of the movable grating plate 1a. The movable and fixed gratings 1a and 1b are respectively slightly inclined rearward and are arranged such that the line connecting the front ends of the respective movable and fixed gratings 1a and 1b is almost straight.

The movable frame 4 is a frame-shaped structure having the wheel part 6 supported on the guide rail 5, and reciprocates back and forth while rolling the wheel part 6 along the guide rail 5. have. The guide rail 5 has an inclination in accordance with the inclination of the movable and fixed grating plates 1a and 1b. When the movable frame 4 moves back and forth slightly obliquely along the inclination of the guide rail 5, The movable grating 1a is reciprocated in a slightly oblique front-rear direction within the range which can maintain partial overlap with the fixed grating 1b. Reciprocating movement of the movable frame 4 can be performed by a crank mechanism, a hydraulic cylinder mechanism, etc., for example.

The movable and fixed gratings 1a and 1b are for carrying and sequentially conveying a workpiece. When the movable grating 1a is reciprocated in the front-rear direction as described above, the movable gratings 1a and 1b move when the movable grating 1a moves forward. The front end of the lattice can convey the to-be-processed object by pressing the to-be-processed object forward. Moreover, at the time of the retreat of the movable grating board 1a, the front end of the fixed grating board 1b hangs on a to-be-processed object, and it can suppress that a to-be-processed object retreats with the movable grating board 1a. In addition, air is supplied from below and the workpiece is brought into contact with the workpiece through the aeration passage 2 to carry out cooling of the workpiece, acceleration of combustion, and the like.

The air passage 2 formed in the movable grating plate 1a and the fixed grating plate 1b is, in particular, as shown in FIG. 2, the rear air passage 2a formed in the rear portion, and the front air passage formed in the front portion ( 2b).

The rear part vent 2a in this example is a vertical slit which penetrated at right angles with respect to an upper surface between the upper and lower surfaces of the movable or fixed grating | lattice boards 1a and 1b in which this rear part vent 2a was formed. In addition, in the front part air passage 2b in this example, the lower end side is formed in the direction perpendicular | vertical to the upper surface of the movable or fixed grid | lattice board 1a, 1b in which the said front part ventilation path 2b was formed, The side is a <-shaped slit (bending slit) formed inclined forward with respect to the upper surfaces of the movable or fixed grating plates 1a and 1b in which the front part air passage 2b was formed.

Although the rear vent passage 2a and the front vent passage 2b in the present invention may be holes instead of slits, the workpieces on the movable grid 1a and the fixed grid 1b are in the width direction. Since it is easy to contact air uniformly, it is preferable to set it as the horizontally long slit formed in the direction perpendicular to the front-back direction.

If at least the upper end side is formed at right angles with respect to the upper face, the lower end side may be bent or inclined if the rear vent passage 2a is formed in the present invention. It is preferable to form at right angles. In addition, although the front vent 2b may be formed obliquely in whole, since the number of the front vents 2b which can be formed as inclination increases, the number of the front vents 2b will become small, and in order to reduce this, it is only made to incline to the upper end side. The lower end side is preferably formed at right angles to the upper surface.

The rear aeration passage 2a and the front aeration passage 2b may have the same slit width or hole diameter over the entire length, but the slit width of the upper side or the top side is easy to fall out when the workpiece is mixed. It is preferable to form so that the slit width or hole diameter of a lower end side may become larger gradually than a hole diameter.

When the rear vent passage 2a and the front vent passage 2b are formed as described above, as shown in Fig. 3, the rear vent passage 2a and the front of the slit width or the hole diameter in which necessary air flow is easily obtained can be obtained. When the air passage 2b is used, the upper surface opening width W ₁ of the rear passage 2a can be made smaller than the upper surface opening width W ₂ of the front passage 2b. Thus, for example, even if the object mass 3 is placed on the upper opening of the rear passage passage 2a of the movable lattice portion 1a (fixed grid portion 1b), the small portion of the rear passage passage 2a is kept. As shown in FIG. 4, it is pushed by the front end surface of the fixed grating | lattice board 1b (movable grating board 1a) adjacent to the back (front) at the time of retreat (advancing) of the movable grating board 1a, as shown in FIG. It is extruded and can be inserted in the gap between the movable grating 1a and the fixed grating 1b, and can prevent the engagement.

In the present invention, the rear ventilating passage 2a is formed at the rear of the movable grid portion 1a and the fixed grid portion 1b, and the air blown out from the rear venting passage 2a is also to be processed. Can be brought into contact with, thereby improving the processing efficiency. In addition, the rear part can be cooled by the air passing through the rear part air passage 2a, and overheating of the rear part can be prevented.

By the way, since at least the upper end side is formed at right angles with respect to the upper surface, the air passing through the rear part air passage 2a is easily raised and ejected easily. However, while the rear part of the movable grating board 1a and the fixed grating board 1b is covered with the front part of the fixed grating board 1b or the movable grating board 1a which adjoins the rear side along with the reciprocating movement of the movable grating board 1a, Since the movement of the to-be-processed object deposited thereon is performed reliably, it is hard to produce a jet substantially, and even if a jet occurs, the influence can be suppressed to the minimum. In addition, in order to reliably obtain such an effect, even if the rear vent passage 2a is a rear part of the movable and fixed gratings 1a and 1b, it is fixed with the movable grating plate 1a with the reciprocating movement of the movable grating 1a. It is preferable that it is formed only in the area | region which the grating plate 1b overlaps.

On the other hand, since at least the upper end side is inclined forward with respect to the upper surface of the front aeration passage 2b, air can be blown out along the upper surface by the Coanda effect, and air is effectively applied to the workpiece while suppressing the ejection. At the same time, the front part can be cooled to prevent overheating. It is preferable that the inclination angle (theta) (refer FIG. 3) with respect to the upper surface of an upper end side is 15-60 degree so that the front part air passage 2b will be easy to acquire a Coanda effect, without being largely limited by the number of formations, More preferably, it is 20-30 degree. In addition, since at least the upper end side of the front part air passage 2b is inclined forward with respect to the upper surface, and air is blown out toward the front, the object to be processed can also be conveyed by this air flow.

As shown in FIG. 4, the rear vent passage 2a in the present invention moves the movable grating plate to the majority of the front part of the fixed grating plate 1b (movable grating plate 1a) by reciprocating movement of the movable grating plate 1a. 1a) When the rear part of the (fixed grating board 1b) overlaps, it also serves to supply air to the front part air passage 2b formed in the front part of the fixed grating board 1b (movable grating board 1a). . At this time, if the gap between the lower surface of the fixed grid 1b (movable grid 1a) and the upper surface of the movable grid 1a (fixed grid 1b) is narrow, the front vent 2b and the rear vent Due to the positional shift of the furnace 2a, it is difficult to supply air to the front passage 2b. For this reason, the edge part 7 protrudes downward at the front end of at least the lower surface of the movable grating board 1a and the fixed grating board 1b, respectively, and the lower surface and the movable grating board of the fixed grating board 1b (movable grating board 1a). It is preferable to make it possible to ensure the clearance gap between the upper surfaces of (1a) (fixed grating board 1b) which is easy to maintain the flow of air. This edge 7 may be formed at the periphery of the lower surface of the movable grating 1a and the fixed grating 1b.

The thickness of the movable grating plate 1a and the fixed grating plate 1b is not particularly limited as long as the necessary strength can be obtained even when the rear gas passage 2b and the front gas passage 2a are formed. In the case of being composed of cast iron, the thickness is generally preferably 10 mm or more, and particularly preferably about 15 to 70 mm.

Next, an example of the clinker cooling cooler provided with the movable grate which concerns on this invention mentioned above is demonstrated based on FIG.

In the figure, reference numeral A denotes the movable grate according to the present invention, and the high temperature clinker 9 fired in the kiln 8 is discharged on the movable grate A. FIG.

The lower side of the movable grate A is divided into a plurality of air chambers 10 serially arranged along the conveying direction of the clinker 9, and each air chamber 10 has an air supply port 12 open to its side. It is supposed to be pumped from the blower 11 through.

The clinker cooling cooler as described above allows the clinker 9 to be efficiently cooled by air supplied from below while the moving grate A is conveyed, and the movable grating plate 1a by the heat of the clinker 9. ) And the fixed grid 1b are also easily prevented.

Firstly, the movable grate of the present invention has a rear aeration passage formed at a rear portion of the movable and fixed grating plate, at least the top side of which is perpendicular to the upper surface. Since the opening width of the upper surface can be reduced as compared with the front air passage formed to be inclined forward with respect to the upper surface, a large object mass is not caught in the upper surface opening. Accordingly, a large mass of the workpiece is caught in the opening of the upper surface, and the mass of the workpiece is inserted into and engaged with a gap between the fixed grid adjacent to the rear (front) at the time of retraction (advanced) of the movable grid. Since the grating can be prevented from being damaged, operation with less trouble is possible.

Secondly, since the movable grate of the present invention has not only the front vent but also the rear vent, the air flowing through the rear vent allows cooling protection of the rear part. In addition, the rear portions of the movable grid and the fixed grid are covered with the front of the fixed grid or the movable grid adjacent to the rear portion with the reciprocating movement of the movable grid, and the movement of the workpiece to be deposited thereon is ensured. Since it is performed, it is hard to produce a jet substantially, and the influence can be suppressed to the minimum even if a blow occurs. Therefore, the temperature drop of the recycled air can be effectively prevented, for example, when used for the clinker cooling cooler, and high cooling efficiency and high temperature maintenance of the recycled air can be achieved.

Third, the movable grate of the present invention is known because the front grate is provided with the front part of the movable and fixed grating which is always loaded with the workpiece, at least the upper end side of which is inclined forward with respect to the upper surface. It is possible to prevent the ejection by the effect and to provide good cooling protection of the front part.

Fourth, the movable grate of the present invention is not only hard to cause a large mass of condensation, such as a fixed grate, but also has a basic structure in common with the movable grate that is widely used, and thus, the movable grate of the present invention is conventionally operated. The grate can be retrofitted into the movable grate of the present invention easily and at low cost.

Claims (5)

Movable gratings and fixed gratings each having an air passage formed between the upper and lower surfaces are alternately formed by superimposing each front portion on the rear side of the fixed grating plate or the movable grating plate adjacent to the front, and the movable grating plate in the front-rear direction. A movable grate which reciprocates and presses an object to be processed forward and contacts air with an air supplied from below through an air passage. The aeration passage comprises a rear aeration passage formed at a rear portion of the movable and fixed grid, and a front aeration portion formed at a front portion of the movable and fixed grid, wherein at least an upper end side of the rear aeration passage is at an upper surface. It is formed in the direction perpendicular to the, grate grate characterized in that at least the upper end side of the front passage passage is inclined forward with respect to the upper surface. 2. The rear vent passage of claim 1, wherein the rear vent passage penetrates between the upper and lower surfaces of the movable or fixed grating plate on which the rear vent passage is formed at right angles to the upper surface, and the lower end side of the front vent passage is the front vent. While the furnace is formed in a direction perpendicular to the upper surface of the movable or fixed grating plate on which the furnace is formed, the upper end side of the front air passage is inclined forward with respect to the upper surface of the movable or fixed grating on which the front air passage is formed. Operation grate, characterized in that. 2. The movable grate according to claim 1, wherein the rear side passage and the front side passage are slits formed in a direction orthogonal to the front-back direction, and the slit width is wider than the upper surface side, respectively. The movable grate according to claim 1, wherein an edge portion protrudes downward at least at the front end of at least the lower surface of the movable and fixed grating. The movable grate according to any one of claims 1 to 4, wherein the rear vent is formed in an area where the movable grating plate and the fixed grating plate overlap by reciprocating movement of the movable grating plate.