WO2007057076A1

WO2007057076A1 - Centrally controlled coke oven aeration system for primary and secondary air

Info

Publication number: WO2007057076A1
Application number: PCT/EP2006/009799
Authority: WO
Inventors: Franz-Josef Schücker; Ronald Kim
Original assignee: Uhde Gmbh
Priority date: 2005-11-18
Filing date: 2006-10-11
Publication date: 2007-05-24
Also published as: RU2008124810A; CA2628316C; AU2006314857A1; MY149240A; EP1948759A1; AR056158A1; UA91571C2; KR20080069170A; RU2422490C2; TWI319432B; BRPI0618679A2; JP2009516033A; AP2008004466A0; CN101309996B; ZA200804138B; TW200720417A; DE102005055483A1; JP5114422B2; AU2006314857B2; HK1122061A1

Abstract

The invention relates to an aeration device for non-recovery coke ovens, wherein the aeration device consists of at least one opening which passes through the wall or through internals such as, for example the oven door, and connects the oven interior to the outer atmosphere surrounding the oven and can be wholly or partly closed by means of a closure element. In this case two or more of these closure elements are coupled by means of at least one mechanical connecting element, by the connecting element being fastened directly or via a lever to the closure elements, and each connecting element being connected to at least one central actuating element in such a manner that the closure elements can be moved, wherein the respective openings can be closed, completely opened, or can be set in any desired intermediate position. Ideally, this connecting element is a chain or a screw spindle.

Description

Centrally controlled coke oven ventilation system for primary and secondary air

The invention relates to an apparatus and method for supplying combustion air for the combustion of coking gas in coking chambers constructed of flat construction and arranged as a battery coke ovens, for the so-called non-recovery or heat recovery process. In this case, the device comprises at least one ventilation opening per coking chamber, which runs through the respective coke oven door or its framing wall and ventilation openings for the supply of secondary air in the heating cables. Each ventilation opening is associated with a movably mounted closure element.

All closure elements are mechanically connected to at least one actuating element which is controlled and driven from a central location. In this case, the actuator continuously actuates the closure elements depending on the need for combustion air in the coking chamber. The mechanical connection of each individual closure element with the central control element can be made separately, wherein in particular the starting position of a single closure element at the beginning of the coking process of the associated coking chamber can be made independently of the other closure elements of the adjacent coking.

[0003] The heating of heat recovery furnaces is usually carried out by combustion of the gas formed during the coking. The combustion is controlled so that a portion of the gas burns above the coal charge with primary air in the furnace chamber. This partially combusted gas is supplied via channels, which are also referred to as "downcomers", the heating cables in the bottom of the furnace chamber and completely burned here by adding further combustion air, the secondary air.

In this way, the coal charge heat is supplied directly from above and indirectly from below, which has an advantageous effect on the coking rate and thus on the performance of the furnaces. To carry out the method, it is necessary that supplied primary air and secondary air, exactly sized and over the duration of the cooking time, which can take up to 20 to 96 hours, is variably controlled. In the prior art, heat recovery and non-recovery coke ovens in flat construction are described extensively. By way of example, mention may be made of US Pat. No. 4,344,820, US Pat. No. 4,287,024, US Pat. No. 5,114,542, GB 1 555 400 or CA 2 052 177 C. According to the conventional art, the primary air is sucked through openings in the doors from the atmosphere. The secondary air is sucked in through openings near the floor and passed through channels in the heating cables, which run essentially horizontally under the coke oven chamber. The openings for primary and secondary air are either permanently open or provided with flaps for adjusting the amount of air to be sucked.

Since the oven batteries are very spacious, usually a very high temperature prevails and a strong dirt is given, only manually adjustable ventilation flaps are disclosed in the prior art. Such a coke oven battery is shown in US Pat. No. 5,928,476, wherein three manually operated openings are provided in each coke oven door, in or in front of which a plate or disk which is adapted to the opening cross section and mounted on a central axis is arranged. These opening flaps are manually adjustable via levers in their position.

In practice, however, shows that the required change in the primary and secondary air quantity over the cooking time at a manual adjustment is very isolated and thus the ideal time-dependent adjustment is far from being achieved. Furthermore, the manual operation is a high health burden for the staff.

[0008] The object of the invention is therefore to remedy the described deficiencies in an economical manner and to ensure an optimized supply of primary and / or secondary air. Here, the reliability must be ensured even at the usually given high temperatures and heavy contamination.

The invention solves the problem by a device for supplying combustion air for the combustion of coking gas in coking chambers constructed of flat construction and arranged as a battery coke ovens is provided, wherein the ventilation device consists of at least one ventilation opening per coking chamber, through the respective coke oven door or its framing wall runs and for each ventilation opening a movably mounted locking element is provided, wherein

all the closing elements of the ventilation openings are mechanically connected to at least one adjusting element which is controlled and driven from a central location, the closure elements are to be actuated by means of the actuating element, depending on the need for combustion air in the coking chamber,

- The mechanical connection of each closure element with the central actuator can be made separately, in particular the starting position of a single closure element at the beginning of the coking process of the associated coking chamber can be adjusted separately and independently of the other closure elements of the adjacent coking.

[0010] In the context of the connection between the closure element and the adjusting element, the following is to be understood as meaning that the two elements can be detached from one another directly or via a coupling element such as a lever, a cable, a chain, a lever arm, etc., as well as combinations of these elements can be connected.

[0011] Advantageous embodiments provide for the actuating element to be designed as a circulating chain or a steel cable. Likewise, there is a suitable embodiment in the use of a screw as an actuator. All of these control elements allow a permanent operation in one direction, which is very advantageous for the continuous overall process.

Furthermore, the device according to the invention can be designed to the effect that closure plates are used as closure elements, which are mounted such that they are moved during operation by the connecting element substantially parallel to the oven door.

It is for a directed flow of the primary gas advantageous if the ventilation opening is rotationally symmetrical. Therefore, the use of closure elements is advantageous, which are formed as vertical closure plates and are mounted vertically or horizontally rotatable about a central axis.

[0014] In a further improved embodiment of the ventilation device, the closure elements are formed from at least two overlapping and mutually displaceable facets, with facets ideally releasing a polygonal and point-symmetrical or approximately circular cross-section at a partial opening. Thus, there is no deflection of the sucked air in the ventilation opening and it is led deeper into the furnace chamber due to the higher flow rate. An even further improvement is to make the closure elements cone-shaped, wherein the tip is directed to the furnace interior in the installed state. This embodiment can be further optimized in that the ventilation opening have the same or a larger opening angle than the associated conical closure elements. In this embodiment of the closure element for the device according to the invention, the intake air is minimally swirled in the region of the closure element and the ventilation opening and formed into a gas jet, regardless of the size of the released cross-section.

With a different size of the cone angle of the ventilation opening and closure element can be ensured that contaminants that are deposited in the ventilation opening, not prevent the complete closure of the ventilation opening. The conical closure element is moved via a lever construction and / or a spindle in the longitudinal axis direction of the opening, so that in a partial opening a circular annular gap is released.

The ventilation device can be improved in that the closure element is connected to the actuating element such that it is automatically released in the end position, with complete closure of the ventilation opening, from the control element.

The invention further comprises a method for supplying combustion air in coke ovens, in which the aeration device according to the invention described above is used in one of its variants, wherein the sequence of the method is as follows: a) After emptying and refilling a Coking chamber, the closure elements are connected in their initial position, which is the complete or almost complete release of the vent, with a central actuator. b) During the cooking time, the closure elements are actuated by the central control element continuously and substantially at a constant average speed or setting frequency, so that the ventilation openings are closed continuously. c) At the latest at the end of the cooking time of a coking chamber, the closure elements have the ventilation openings of the coking chamber completely closed and can be released from the actuator. d) After emptying and refilling, the process is restarted with step a).

An improved variant of the method is that the closure element is automatically released in the end position of the actuator.

In a further improved embodiment of the method according to the invention, at least two central adjusting elements are provided, wherein the one adjusting element, the closure elements for the primary air and the other central actuating element moves the closure elements for the secondary air. The two control elements are completely independently controllable during the entire cooking time.

Advantageously, a central actuator is operated continuously and substantially at the same speed or setting frequency.

From the invention is also included, the use of the ventilation device according to the invention in one of the above embodiments in a method for supplying combustion air in the coking chambers constructed of flat construction and arranged as a battery coke ovens.

The invention is described by way of example with reference to three embodiments in Figure 1 to Figure 3, wherein the invention is not limited to these embodiments. Fig. 1 shows a coke oven 1 in the front view. The coke oven 1 has in the front surface on a coke oven door 2, in which two ventilation openings 3 are arranged for the primary air. Below the coke oven door 2 dashed lines 4 are shown, which extend under the oven room. The ventilation openings 5 for the supply of secondary air in these heating cables 4 are located near the bottom below these heating 4.

Furthermore, in Fig. 1, the closure elements 6 for the ventilation openings 3 of the primary air supply and the closure elements 7 for the ventilation openings 5 of the secondary air supply. Each closure element consists essentially of a closure plate 9 and a lever arm 10 and is mounted on an axis 8, about which the respective closure element can be rotatably moved. The lever arms 10 of the closure elements 6 are detachably connected to a peripheral chain 11 and the closure elements 7 are detachably connected to a revolving chain 12. By the continuous movement of the chain 11, the closure elements 6 are moved counterclockwise by the angle α and the closure elements 7 in the clockwise direction by the angle ß. The chains themselves are driven via the central control elements 13 and 14, respectively.

Fig. 2 shows the front view of two coke ovens 1, which stand for a larger coke oven battery, as indicated by the two arrows I and Il. The two coke ovens 1 shown are in different cooking states. The coke oven 1 shown on the right is located at the beginning of the coking process, therefore cover the closure elements 6, the ventilation openings 3 barely. The lifting arm 10 is connected in this embodiment via a smaller chain 15 with the revolving chain 11. The structure in the area of the ventilation openings 5 for the secondary air is analog. Here, the closure elements 7, or their lever arms 10 are connected via smaller chains 16 with the revolving chain 12.

The air supply in the left coke oven 1 is already completely closed and the lever arm 10 and the chain 15 is released from the circulating chain 11. The closure elements 7 for the control of the secondary air of the coke oven 1 shown on the left are just before the closure, but not yet completely closed. Thus, it is very easy to understand that each coke oven 1 can be controlled individually despite a common central control.

A particular embodiment of the closure element 6 and 7 is shown in FIG. 3. In this sectional drawing, a rotationally symmetrical closure element 6 is shown, which has a closure head 17 in the form of a conical stub which is fastened to a cylindrical guide rod 18. The guide rod is fixedly connected to a spring bridge 19, which is fastened to the coke oven door 2. The guide rod 18 is guided in a guide tube 20 and connected to the rear end via a small chain 15 with the circulating chain 11. At the beginning of the cooking time, the springs of the spring bridge 19 are biased by expansion, so that the ventilation opening 3 is largely open. As a result of the movement of the revolving chain 11, the spring bridge 19 is relaxed, the closure element 6 is moved in the direction of the coke oven door 2 and the closure head 17 is inserted into the conical ventilation opening 3. In this case, the bias is to be selected such that after the relaxation of the chain 15 and the spring bridge 19, a complete closure of the ventilation opening 3 takes place. LIST OF REFERENCE NUMBERS

1 coke oven

2 coke oven door

3 ventilation opening (primary air)

4 heating trains

5 ventilation holes (secondary air)

6 closing elements (primary air)

7 sealing elements (secondary air)

8 hinge

9 closure plate

10 lever arm

11 chain (primary air)

12 chain (secondary air)

13 control element

14 control element

15 chain

16 chain

17 closure head

18 management staff

19 spring bridge

20 guide tube

Claims

claims

1. Ventilation device for supplying primary and secondary air for the combustion of coking gas in coking chambers constructed of flat construction and arranged as a battery coke ovens, wherein the ventilation device consists of at least one ventilation opening per coking chamber for the primary air passing through the respective coke oven door or its framing wall extends and further consists of at least one ventilation opening per coking chamber for the secondary air and at least for a part of the ventilation openings movably mounted closure elements are provided, characterized in that

at least part of the closure elements of the ventilation openings are mechanically connected to an actuating element which is controlled and driven from a central location,

the closure elements are to be actuated in the coking chambers by means of the actuating element, depending on the demand for combustion air,

- The mechanical connection of each closure element with the central control element can be made individually, in particular the starting position of a single closure element at the beginning of the coking process of the associated coking chamber can be made separately and independently of the other closure elements of the adjacent coking.

2. Ventilation device according to claim 1, characterized in that at least part of the closure elements for the primary air are mechanically connected to an actuating element and at least a part of the closure elements for the secondary air are mechanically connected to a further adjusting element.

3. Ventilation device according to one of claims 1 or 2, characterized in that the adjusting element is a circulating chain.

4. Ventilation device according to one of claims 1 to 3, characterized in that the actuating element is a screw.

5. Ventilation device according to one of claims 1 to 4, characterized in that the closure elements are closure plates, which are mounted such that these are moved during operation by the connecting element substantially parallel to the oven door.

6. Ventilation device according to one of claims 1 to 5, characterized in that the closure elements are perpendicular closure plates which are mounted vertically or horizontally rotatable about a central axis.

7. Ventilation device according to one of claims 1 to 5, characterized in that the closure elements are formed from at least two overlapping and mutually displaceable facets, with facets ideally release at a partial opening a polygonal and point-symmetrical or approximately circular cross-section.

8. Ventilation device according to one of claims 1 to 5, characterized in that the closure elements are conical, wherein in the installed state, the tip is directed to the furnace interior.

9. Ventilation device according to claim 8, characterized in that the opening has the same or a larger opening angle than the associated conical closure elements.

10. Ventilation device according to one of claims 8 or 9, characterized in that the conical closure element can be moved in the longitudinal axis direction of the opening, so that in a partial opening a circular annular gap is released.

11. Ventilation device according to one of claims 1 or 10, characterized in that the closure element is connected to the actuating element such that it is automatically released in the end position, with complete closure of the ventilation opening, from the actuating element.

12. A method for supplying combustion air for the combustion of coking gas in coking chambers constructed of flat construction and arranged as a battery coke ovens, characterized in that at least one device according to claim 1 to 11 is used, wherein a) after emptying and refilling a coking chamber the closure elements are brought into the starting position, which is the complete or almost complete opening of the ventilation opening, and connected to the central actuator, then b) during the cooking time, the closure elements by the central actuator or the c) the closing elements of a coking chamber are at the end of the cooking time of the respective coking chamber in its final position and are released from the actuator, and d) the process according to a) again is started.

13. The method according to claim 12, characterized in that after the complete closure of the ventilation opening, the detachment of the closure elements of the control element takes place automatically.

14. The method according to any one of claims 12 or 13, characterized in that the central actuating element is operated during the entire cooking time continuously and substantially at the same mean speed or setting frequency.

15. The method according to any one of claims 12 to 14, characterized in that the at least one central control element for the closure elements of the primary air and at least one central control element for the closure elements of the secondary air are provided.

16. The method according to claim 15, characterized in that the central control element for the primary air and the central control element for the secondary air are operated independently of each other during the entire cooking time continuously and substantially at the same average speed or setting frequency.

17. Use of an apparatus according to claim 1 to 11 for a method for supplying combustion air in the coking chambers constructed of flat construction and arranged as a battery coke ovens.