BE1003206A7 - METHOD FOR CLOSING A GAS CHANNEL IN A DRY COKE COOLING SYSTEM AND DEVICE FOR CARRYING OUT THIS METHOD. - Google Patents

Abstract

Method and device for closing the exhaust gas channel of a circuit system consisting of a dry coke cooling well, a gas outlet channel, a waste heat recovery system and a channel gas supply, characterized in that, for the construction of a closure wall in the gas evacuation channel, several closure elements are introduced closing a partial cross section of the gas evacuation channel; in that, in the gas flow direction, in the gas flow direction, two closure walls are arranged at a distance from each other and that, in the space between the closure walls , a fine grain vras material resistant to high heat or fire is introduced.

Description

Method for closing a gas channel in a dry coke cooling system and device for implementing the method The invention relates to a method for closing the gas evacuation channel of a circuit comprising a cooling well dry coke, the exhaust gas channel, a waste heat recovery system and a gas supply channel.

In installations for dry coke cooling, it is necessary to be able to close the circuit system between the dry coke cooling well and the waste heat recovery system to allow monitoring work on the heat recovery system. waste heat. Regardless of the repairs required by corrosion or erosion in the steam and water circuit of the waste heat recovery system, it is necessary, according to legal regulations, to carry out, at the rate of two to three years, parts under pressure. As the coke well normally has a very large volume and as this volume is limited correspondingly to the temperature conditions prevailing at the start of cooling, by very strong masonry, the coke well represents a large heat reservoir and it is necessary , to save repair or inspection times, decouple the hot coke well from the waste heat recovery system to allow repair or overflow as soon as possible.

It is known to associate a separation drawer with the gas evacuation channel, passing the hot cooling gas from the dry coke cooling well to the waste heat recovery system. It has become apparent that in large sections of the gas channel, it is no longer possible to handle a one-piece drawer and that, in certain cases, its sealing effect is no longer sufficient.

The problem posed on the basis of the invention is to provide a method by which the closing of the gas discharge channel is surely possible even in the case of large sections of channels.

To solve this problem, it is proposed that, for the establishment of a closure wall in the gas evacuation channel, several closure elements are placed closing a partial cross section of the gas evacuation channel; that, looking in the direction of flow of the gas in the gas discharge channel, two closure walls should be constructed which are spaced apart from each other; and that, in the space between the closure walls, a fine-grained bulk material placed under the test of high heat or fire is placed.

By installing the single closure wall in several closure elements covering only a partial cross section each time, it is possible to construct closure walls of relatively large cross section. The individual closure elements may, by means of suitable lifting or lowering devices, be placed one after the other or if, for each closure element, such handling devices have been provided, can introduce them simultaneously in the cross section.

The fine-grained bulk material to be poured into the intermediate space between the two closure walls ensures the sealing function of the closure device so that gases from the dry coke cooling well can no longer enter the waste heat recovery system. Due to the porosity of the packing with fine-grained material, good thermal insulation is further obtained with respect to the dry coke cooling well.

On the other hand, it is possible to subject the intermediate space filled with a fine-grained bulk material to an inert closing gas. The overpressure thus produced means that no gas can escape from the dry coke cooling well towards the waste heat recovery system. It is also possible to expand the intermediate space using an emergency chimney, so that due to the pressure drop, a sealing function is ensured and that gas from the cooling well dry coke cannot flow into the area of the waste heat recovery system.

The invention also relates to a closure device according to the preamble of claim 4.

This device is characterized, according to the invention, by the fact that it has two closing walls at a distance in the gas evacuation channel and “closing walls which can be introduced separately from each other, prepared for advancing and closing part of the cross section of the gas exhaust channel, and in that the intermediate space between the closing walls is filled with fine grain bulk material resistant to high heat, respectively fire resistant.

Preferably, the closure elements consist of elongated guides, extending vertically, and refractory bodies guided by them. The guides can firstly be housed alone in the cross section to be closed and the refractory bodies can then be introduced between the guides using suitable transport devices. The guides can however also be beams which grip the refractory bodies, for example pass through them through suitable openings, so that the transport devices can grip the beams and lower them in the cross section, with the refractory bodies carried by them, preferably with the refractory bodies arranged thereon. It is then still advantageous that between the refractory bodies of a closing element and the refractory bodies of a neighboring closing element, a connection is created with adaptation of shapes to further improve the stability of the wall.

It is also advisable that between the wall surfaces of the gas evacuation channel and the refractory bodies of the closure elements, there is a connection with adaptation of the shapes.

As transport devices, it is possible to envisage pneumatic lifting or lowering devices, threaded rods, cable arrangements or the like.

It is judicious also if between the refractory bodies arranged in series one above the other, of a closure element, there is a connection with adaptation of shapes, preferably a connection with adaptation of shapes with centering effect .

Guides or beams can be shaped into tubes and flow through with the flow of a coolant.

The space between the closing walls can be subjected to a closing gas to further improve the closing effect of the bulk packing against gases from the well. It is also possible that this intermediate space can be connected to a gas suction device.

The invention will now be explained in more detail with the aid of the attached figures. We see there, in - Figure 1, a vertical section in an embodiment of a stop device according to the invention, with a cable transport installation; - Figure 2, a section comparable to Figure 1, with a pneumatic lifting or lifting device; - Figure 3, a horizontal section of Figures 1 and 2 along the line III-III of Figures 1 and 2; - Figure 4, a section comparable to Figures 1 and 2 in the case of the complete construction of the closure walls and the lining of spilled bulk material, with gas cooling which at the same time serves to make the intermediate space inert ; and in - Figure 5 "a representation comparable to Figure 4, where the cooling of the tubes forming the beams of the closure elements is provided by water and where the inertia device is shaped separately.

As can be seen in Figures 1 to δ, we built in a dry coke cooling well, shown diagrammatically, with a gas evacuation channel δ connecting it to a waste heat recovery system 2, two walls closure 4 and 5 arranged one behind the other, looking in the direction of gas flow. The gas cooling circuit K also includes the gas supply channel δ * back to the well 1 for dry coke cooling. The closing walls consist of individual closing elements 6 which can be placed separately from one another from above in slots δη 'of the cover Sa of the gas evacuation channel . Each closure element comprises nine refractory bodies 7 which are aligned on a single vertically extending beam and are held thereon by a stop plate 9 · Up to the closure elements (edges 6a and 6b, the bodies refractories 7 comprise an elastic blade 7a and a groove 7b, so that it is possible to have a lateral connection with adaptation of shapes between the individual closure elements.

The elements 6a and 6b of the edges are shaped so that one can establish a connection with adaptation of comparable shapes with the corresponding grooves 10 of the side walls δ6 and δο of the gas evacuation channel δ. The section 8a protruding from the beam 9 towards the bottom of the elongated beams, penetrates into corresponding recesses in the bottom öd of the gas evacuation channel.

In the embodiment, the lowering and lifting of the various closing elements is done by means of a cable device 11 shown diagrammatically, which attacks the upper end 8b of the beams 8. The frame of the cable system according to the Figure 1 can be traversed perpendicular to the plane of the drawing by a vehicle 15 to bring the various closure elements in position one after the other.

It would also be conceivable to introduce elongated elements as guides first in the manner of a palisade along the wall to be built in the cross section and then to lower individually - here by means of a system '· de cable 11 - the refractory bodies, respectively the refractory stones. To this end, it is not necessary either that the guides pass through the refractory bodies, but they could also be shaped so that the refractory bodies are disposed each time between two guides and that these embrace them by their surfaces. lateral, for example in the form of arcs of a circle.

The embodiment according to Figure 2 differs from the embodiment of Figure 1 in that the positioning of the closure elements 6 takes place not by means of a cable system but by means of a pneumatic lifting device 14 indicated diagrammatically. Hydraulic or threaded rod drives could also be used here.

Whereas, in the embodiments according to FIGS. 1 and 2, the refractory bodies are shaped as discs and are superimposed by flat horizontal surfaces, in the embodiment according to FIGS. 4 and 5, not only is a connection provided lateral between the refractory bodies 7 of the individual closing elements, but also a cooperation with adaptation of forms with centering effect between the refractory bodies 15 of the individual closing element 16. For this purpose, the different refractory bodies 15 have their upper side a cover 15a, and on their lower side, they have a recess 15b of corresponding shape.

Figures 4 and 5 show walls 4 and 5 whose construction is complete. In the intermediate space 17 between the two closing walls 4 and 5, a loose material 18 has been introduced with fine grains, resistance to high heat, respectively to fire, for example of corundum in hollow balls: * by a feed 19 · The bulk material 18 can be removed by a feeder 20 after which there is, for example, a cell wheel lock.

By means of the beams in the form of hollow tubes 8 and lateral openings 8c in the beams, it is possible, in FIG. 4, to introduce from the closure wall 4, an inert gas, for example Ng " in the intermediate space 17 and withdraw it through the intake well 19. Due to the pressure drop, a sealing function is thus ensured.

In the embodiment according to FIG. 5, an inertia production system 21 is provided separately from the cooling of the tubes 8. The tubular beams 8 can be subjected separately to cooling water, as indicated by the arrows W to Figure 5 ·

While in the embodiments shown in the figures, the guides, respectively the beams 8, is arranged each time a refractory body, it is also possible that a refractory body is associated each time two or more guides, as is shown in Figure δ, in the lower part of the right closing wall 5. Simple handling must remain ensured.

Of course, one could, for the supply and departure of the material a fine-grain bulk, also provide several supply lines, respectively of departure.

As shown in Figure / 4, in; this embodiment - but also in other embodiments - provision could be made for sealing boxes 22 preventing gas from escaping from the lateral side of the wall of the channel. - In this embodiment according to FIG. 2, this function is provided by the beam 9.

If the transport device is hydraulically actuated, this system can be connected, on the pressure side, to the hydraulic device which is used to close and open the dry coke cooling well.

Claims (10)

1. Method for closing the exhaust gas channel of a circuit system consisting of a dry coke cooling well, a gas outlet channel, a waste heat recovery system and a d channel gas supply, characterized in that, for the construction of a closing wall in the gas evacuation channel, several closing elements are introduced closing a partial cross section of the gas evacuation channel, in that , in the direction of gas flow, in the direction of gas flow, two closure walls are constructed spaced apart from each other and in that, in the space between the closure walls, introducing a fine-grained bulk material resistant to high heat or fire. 2. Method according to claim 1, characterized in that the intermediate space filled with fine-grained bulk material is subjected to an inert closing gas. δ. Method according to either of Claims 1 and 2, characterized in that the intermediate space is expanded by means of an emergency chimney. 4. Closure device for closing the gas evacuation channel of the circuit system comprising the dry coke cooling well, the gas evacuation channel, a waste heat recovery system and a supply channel for gas, in particular for implementing the method according to at least one of claims 1 to δ, characterized in that it has closing walls (4) consisting of two closing elements (6; 16) arranged at distance from each other in the gas evacuation channel (δ) and in several closing elements (6; 16) prepared in advance, separated from each other, and closing part of the cross section of the gas discharge channel, and in that the intermediate space (17) between the closure walls is filled with loose material with fine grains, resistant to high heat, respectively to fire. 5. Closure device according to claim 4, characterized in that the closure elements (6; 16) consist of elongated guides (8) s * extending vertically and of refractory bodies (7; 15) guided by them. 6. Closure device according to any one of claims 4 and 5 "characterized in that, between the refractory bodies (7; 15) of a closing element and the refractory bodies of the neighboring closing element is produced a cooperation with adaptation of forms. 7. Closure device according to at least one of claims 4 to 6, characterized in that between the wall surfaces (<$ a, Sb, 3c, 3d) of the gas evacuation channel (δ), and the refractory bodies of the closing elements, there is cooperation with adaptation of shapes. 8. Closure device according to at least one of claims 4 to 7, characterized in that there are provided transport devices (11; 14) which attack the refractory bodies or the beams of a closure element. 9. Closure device according to at least one of claims 4 to 8, characterized in that, between the refractory bodies (15) arranged in series one above the other, with a closure element (16), there is a connection with adaptation of the forms. 10. Closure device according to at least one of claims 4 to 9, characterized in that the guides or the beams (8) are of tubular shape and can be traversed by a stream of * coolant. 11. Closing device according to at least one of claims 4 to 10, characterized in that 1 * space (17) between the closing walls (4,5) can be subjected to an inert closing gas.