EP1453936A2

EP1453936A2 - Coke oven door with wraparound gas channel and membrane

Info

Publication number: EP1453936A2
Application number: EP02787814A
Authority: EP
Inventors: Hans-Josef Giertz; Klaus Dieter Ruthemann; Jürgen GEORGE; Franz Liesewitz; Horst Schröder; Friedrich Wilhelm Cyris
Original assignee: Deutsche Montan Technologie GmbH
Current assignee: DMT GmbH and Co KG
Priority date: 2001-12-14
Filing date: 2002-11-26
Publication date: 2004-09-08
Anticipated expiration: 2022-11-26
Also published as: WO2003052027A2; JP5221836B2; CN100510005C; JP2005525434A; US20050040025A1; BR0214823A; CN1604953A; DE50214979D1; AU2002352140B2; TWI322178B; ES2360693T3; EP1453936B1; KR100633226B1; WO2003052027A3; US7166197B2; AU2002352140A1; DE10161659C1; CA2470144A1; KR20040065211A; ATE502991T1

Abstract

A coke oven door (1) comprises a gas channel (5) completely surrounding the oven door and a membrane (3) fixed on the oven door and pressed in a spring-mounted manner against the chamber frame. The gas channel is fixed on a membrane consisting of at least two layers. An Independent claim is also included for an alternative coke oven door. Preferred Features: The membrane comprises two sheets, especially four thin sheets. The sheets (3', 3'', 3''') have different thicknesses. At least one sheet is made of heat- and corrosion-resistant material, and at least one sheet is a spring.

Description

Coke oven door with all-round gas channel and membrane

The invention relates to a coke oven door with a circumferential gas channel and membrane.

Such a door is known from WO 01/30939 A2. The gas duct on the coke oven door creates a sealing system to avoid emissions and air ingress into the coke oven chamber, which reliably prevents both the escape of raw gases from the coke oven chamber and the air entry into the coke oven chamber.

With the gas duct, it is important that the door sealing strips or door sealing edges of the gas duct lie over the entire area.

It is known that the chamber frame undergoes deformation in the sense of deflection due to the temperature effect in the vertical direction. There are numerous suggestions for adapting the sealing strips of coke oven doors to these deformations. All these solutions have the disadvantage that the spring travel is not sufficient to adapt to these deformations.

DE 41 03 504 C2 discloses a coke oven door in which a membrane with springs is pressed against the chamber frame. The problem with this arrangement is that the membrane must have a sufficient material thickness to be able to absorb the contact forces, ie the membrane must have high mechanical strength. sen. The membrane must not be damaged or destroyed during cleaning processes. On the other hand, the membrane must have sufficient deflection in the elastic range. These two conflicting requirements could not be met so far, so that the spring travel was not sufficient with appropriate mechanical strength of the membrane and resulted in an unsatisfactory sealing.

The invention has for its object to provide a coke oven door with a circumferential gas channel, the sealing strips have such a large spring travel that the gas channel can adapt to all deformations taking place, so that a complete seal is guaranteed at all times. In addition, the sealing system on existing coke oven doors should be retrofittable even in tight spaces.

This object is solved by the features of claim 1 or 2.

Further developments take place according to the characteristics of the subclaims.

The invention is based on two essential basic ideas. On the one hand, the spring travel for pressing the gas duct should be as large as possible and its contact pressure in the longitudinal direction should be as uniform as possible, on the other hand, the springs should act on the gas duct in such a way that the contact pressure of the outer door sealing strip is greater than or at least equal to the contact pressure on the inner door sealing strip there is. The seal between the gas duct and the coke oven door is ensured by a membrane which has such a large deflection capacity and at the same time sufficient mechanical strength to adapt to all deformations. The gas duct must be designed to be flexible in such a way that the contact pressure of the outer door sealing strip of the gas duct is approximately the same at each contact point.

Due to the flexibility of the membrane, it is possible to perform a large deflection in the smallest space. Due to this property, existing coke oven doors that have very limited space in the area of the seal can be retrofitted using the existing fastening options. The design of the membrane in combination with the spring element and the resulting large spring travel is also an invention in itself, ie this embodiment can also be used with the sealing systems known from the prior art, without the gas channel.

If e.g. Due to the geometric conditions, an arrangement of the gas channel is not possible, the sealing according to the invention can be carried out with all sealing systems known from the prior art. Thanks to the membrane with its high level of deflection, a better seal is guaranteed even with conventional sealing systems.

The seal according to the invention makes it possible to compensate for all deformations of the chamber frame and also the coke oven door, so that a complete seal is guaranteed at all times. When using the gas channel, the sealing system also has the advantages named in WO 01/30939 A2, i.e. a gas pressure equalization between the gas channel and the coke oven chamber and thereby a reduction in the raw gas pressure that prevails on the outer sealing strip.

According to the invention, the membrane consists of at least two layers. This embodiment has the advantage that the bending capacity of the membrane is improved in the elastic range compared to a membrane that has the same total material thickness. Due to the elastic behavior of the membrane, the membrane returns to the starting position when the contact pressure is reduced by the spring element.

The membrane according to an embodiment of the invention is sandwiched from several materials. The membrane plate arranged towards the gas channel can be designed to be corrosion-resistant, while the middle membrane plate assumes the spring action (eg spring steel) and the upper one increases the spring pressure. According to a further embodiment, the membrane consists of two 731 plates. The individual sheets have a higher elasticity than a single sheet, the wall thickness of which corresponds to the wall thickness of the two sheets and can shift against one another when deformed by the spring pressure.

The membrane can also be designed in composite construction. In the simplest case, the two sheets are connected to one another in the sense of a composite system. This can e.g. by webs or also by other materials, e.g. Plastics and / or adhesives are made. The tar produced in the coking plant can also be used for these composite construction methods.

The individual sheets of the membrane can have a different material thickness. As a result, the membrane's bending behavior can be varied over a wide range and optimally adapted to the respective requirements.

The individual sheets of the membrane can even be made with a material thickness in the tenths of a millimeter range. In this embodiment, the membrane consists of many individual layers that can move against each other. This creates sliding planes on the contact surfaces of the individual layers. The membrane thus becomes more flexible overall and has a larger elastic range. This allows a larger spring travel. This embodiment has the advantage that any damage to the individual membrane sheets is automatically sealed due to the adhesive effect of the condensates (tar).

It is also possible to design the sheet of the membrane that seals the door opening from heat and corrosion-resistant material and to design the other sheets of the membrane in such a way that the membrane has sufficient bending capacity.

According to a further embodiment of the invention, at least one sheet of the membrane is designed as a spring. Through this measure, the membrane contributes to the contact pressure of the spring elements. The sheets forming the membrane can also be formed as molded parts. Any embodiments of springs or membrane sheets known from the prior art are possible.

It is of course also possible to combine the individual sheets of the membrane with the properties mentioned above.

The membrane according to the invention can be combined with all spring elements known from the prior art. Due to its large deflection behavior, it adapts to all specified spring travel.

It is also possible to design the membrane as a spring element. All you have to do is spring or one sheet of the membrane.

According to one embodiment, the spring element consists of a plurality of leaf springs arranged one above the other, which are jointly attached to the door plate above the membrane and press on the gas channel. The leaf springs are designed as individual springs in segments so that the sealing edges can better adapt to the deformations.

Another possibility is to arrange a holding element on the door plate for receiving a pressure tappet which presses on the gas channel. The pressure ram can e.g. can be pressed against the gas duct by disc springs, coil springs or also hydraulically / pneumatically.

A further possibility of exerting a contact pressure on the gas duct is to resiliently attach a spring plate to the door plate. In this embodiment, the spring plate itself can also be designed as a rigid element with low elastic properties and the actual travel can be mainly caused by the resilient bracket.

The resilient bracket can, for. B. by disc springs that are clamped on a screw. Another possibility is the attachment of a spring element on a spring rod. It is also possible to design a spring element in such a way that it takes over the spring function of the plate springs or the spring rod. This design has the advantage that only a single spring component that can perform both spring functions has to be manufactured.

This arrangement ensures that the gas channel is arranged in a spring system with a relatively large spring travel. The spring travel is composed of the spring travel of the spring element and the spring travel which results from the resilient mounting of the spring element.

The diaphragm must be designed in such a way that the diaphragm can follow this travel. On the other hand, the membrane must also have such a large spring action that it springs back into its starting position. Of course, this applies to all spring components of the spring system.

According to the invention, it is possible for the first time to bring a rigid “double seal” (gas channel) with a large spring travel to the door frame, the contact pressure being the same over the entire length.

With the spring systems described above, it is possible to generate any contact pressure with any distribution and any spring characteristic, i.e. any different or identical pressures can be provided on the outer and inner sealing strips of the gas duct. So z. B. different leaf springs can be combined with one another in such a way that the spring effect increases with increasing spring travel: this can be adjusted either by a different shape or length of the leaf springs or by providing distances from the respective point of application of the spring.

You have the same options with the other spring systems. When using the systems with pressure tappets, make sure that the contact pressure is achieved by a corresponding pressure distribution bar is evened out. The pressure distribution bar must be designed so flexibly that an adaptation of the gas channel to the unevenness of the chamber frame is still possible.

The springs can have a desired adjustable preload due to different clamping.

The springs can also be designed in composite construction. All known techniques can be used. Since the requirements for the composite construction of the diaphragms and springs are the same in terms of flexibility, the composite construction can be used for both the diaphragm and the spring elements.

The composite construction can also be carried out in such a way that channels are created between the individual elements of the springs or the membrane. The channels can be designed as cooling or heating channels by introducing an appropriate medium. It is also possible to design the channels with an insulating material as an insulating layer.

The gas duct must be designed in such a way that it can adapt to the unevenness and deformations of the chamber frame. On the other hand, the gas channel must have such a large cross section that the raw gas can be removed without pressure build-up. In any case, the gas duct is designed with an inner and an outer sealing strip. In the area of door sealing, the gas duct must be as flexible as possible. This is e.g. B. possible in that the wall of the gas channel is made in the material of the door seal in a lesser material thickness or by indentations or bends, thereby increasing the ability to bend in this area.

It is also possible to mount a door seal on the inner and outer sealing strip of the gas duct. The gas channel can also consist of appropriately shaped elements of the membrane or the springs (leaf springs).

The corners of the door represent a particular problem for the tightness of coke oven doors. According to the invention, it is proposed to manufacture the membrane in the corner area from one piece, i.e. The individual layers of the membrane are made in one piece for the upper and lower area, so that each has a U-shape. The membrane that seals the long sides of the coke oven door is fitted to this U-shape. This arrangement ensures the permanent gas-tightness of the membrane, since the seams are arranged outside the heavily loaded corner area.

The individual membrane parts can be connected by welding. Due to the structure of the membrane from individual layers, the membrane can be connected in such a way that the individual layers are offset with their seams. Due to the overlap of the individual membrane layers in this area, gas tightness is achieved. In order for the membrane to have the same material thickness in this connection area, the individual membrane sheets must be arranged “in a butt joint”. This butt joint can be carried out in different ways. In the simplest case, the individual membrane layers are cut at right angles and arranged in an abutting manner. It is also It is possible to have the individual membrane sheets meet diagonally. The edges of the individual membrane sheets can also be beveled so that there is a so-called sharpened joint. The diagonal design of the joint edges increases the length of the sealing channels, while the bevel (sharpening) increases Membrane layers the sealing surface is enlarged.

Because of the membrane according to the invention with its layer structure, it is even possible to connect the membrane in the corner area. In this embodiment, the individual membrane layers must overlap in the material. rial thickness are mutually reduced such that the two overlapping layers together give the layer thickness of the individual layer. This can e.g. B. by beveling (sharpening) or by appropriate millings (step formation).

These compounds are additionally sealed by the tar contained in the raw gas, which settles in the cracks or gaps in the event of gas penetration. According to a further development, tar can also be used in the manufacture of the membrane as an adhesive and sealant for connecting the individual membrane layers.

In the embodiment of the membrane with sheets in the tenths of a millimeter range, the individual membrane layers in the connection area can be arranged overlapping without further measures. It is sufficient to arrange the individual membrane sheets offset in the connection area.

Since the profile of the gas channel rests on the chamber frame and does not take part in the spring deflection in the event of any deformation, there is little or no tension in this area. With the gas channel, a miter can be provided in the area of the door corners. Since the weld seams are only exposed to low stresses in this area, any other type of connection can also be selected. It is also possible to design the gas duct as a plug connection in the corner area. A possible plug connection is shown in the drawing. The arrangement of plug connections can also be provided at any point in the gas channel.

The sealing system according to the invention with membrane, gas channel and spring element is ideal for retrofitting leaky coke oven doors. All Koskofen doors on the market can be retrofitted. The diaphragm according to the invention with the spring element can also be used for retrofitting with all sealing systems known from the prior art. The size, shape, material selection and technical conception of the above-mentioned components as well as the components to be used according to the invention described in the exemplary embodiment are not subject to any special exceptional conditions, so that the selection criteria known in the field of application can be used without restriction.

Further details, features and advantages of the subject matter of the invention result from the following description of the accompanying drawing, in which - by way of example - preferred embodiments of the coke oven doors according to the invention are shown.

The drawing shows:

FIG. 1 shows a partial view of a coke oven door with gas channel, membrane and leaf springs,

FIG. 2 shows an embodiment with a pressure tappet and disc springs,

FIG. 3 shows an embodiment with a spring element held in a resilient manner,

Figure 4a u. an embodiment with a spring element, which consists of a component Figure 4b,

5 shows an embodiment of the membrane in composite construction,

Figure 6 shows an embodiment in which the spring element, the membrane and the

Gas channel are designed as a component.

FIG. 7 shows an embodiment of the gas duct with a flexible door sealing cutter,

8 shows an embodiment of FIG. 1, in which there is a spring force in the region of the outer door sealing strip of the gas duct,

Figure 9 shows an embodiment of the corner region of the gas channel with a

Connector,

Figure 10 shows an embodiment with a very large travel.

FIG. 1 shows a partial view of a coke oven door 1 in the area of the circumferential gas channel 5. A membrane 3 with a holding element 4 is fastened to the door plate 2 of the coke oven door 1. The holding element 4 has a bevel 4a. The membrane 3 is made from three sheets 3 ', 3 "and 3'" arranged one above the other. On the outer area of the membrane 3, the gas channel 5 is arranged with an outer door sealing edge 5a and an inner door sealing edge 5b. The gas channel 5 has a bevel 5c on the inner door sealing strip 5b. Leaf springs 6, which are held by a holding element 7, are arranged on the holding element 4. The holding element 7 also has a bevel 7a. The leaf springs 6 press on a strip 8 which is attached to the membrane 3 in the region of the gas channel 5. The gas channel 5 is pressed by the leaf springs 6 against the chamber frame 9 of a coke oven chamber, not shown. As a result, the gas channel 5 lies sealingly on the chamber frame 9. Movements due to deformations of the chamber frame 9 and / or the coke oven door 1 are compensated for by the leaf springs 6 in such a way that the gas channel 5 is always pressed against the chamber frame 9 in a sealing manner. The flexible membrane 3 generates only a slight resistance to the leaf springs 6. Due to the bevels 4a and 5c of the holding element 4 and the gas channel 5, the membrane 3 is able to understand the spring travel predetermined by the leaf springs 6. The possible movements of the coke oven door 1 are indicated by arrows A and B. The bevel 7a of the holding element 7 causes a larger lever arm and thus a larger spring travel of the leaf springs 6.

Another embodiment of the sealing system according to the invention is shown in FIG. A holder 11 for a pressure tappet 10 is attached to the door plate 2 with the membrane 3 and the holding element 4. On the pressure tappet 10, plate spring columns 12 are provided, which press the pressure tappet 10 onto the bar 8 as a pressure distribution bar and thus onto the membrane 3 and the gas channel 5 and thus press the gas channel 5 against the chamber frame 9. The plate springs 12 are preloaded by self-locking nuts 13.

It can be seen from FIG. 3 that the gas channel 5 is pressed against the chamber frame 9 with a leaf spring 15. The leaf spring 15 is clamped on a screw 16, which is arranged on the holding element 4, with spring washers 17. Due to this resilient bracket, a larger spring travel of the leaf spring 15 is possible. FIG. 4a shows a further embodiment of the sealing system of the coke oven door 1 according to the invention with a spring element which is designed as a spring component 20. The spring component 20 presses the bar 8 and the membrane 3 onto the gas channel 5, which is thereby pressed against the chamber frame 9. The spring travel and the spring characteristic can be varied by clamping the spring component 20 to a different depth into a holding element 21 (corresponding to double arrow A).

The same embodiment of the spring element is shown in FIG. 4b. A preload can also be generated by a screw 22 on the spring component 20.

FIG. 5 shows a membrane 25 in a composite construction. The membrane 25 consists of membrane sheets 26, 27, 28 and 29. The membrane sheets 27 and 28 are connected to one another by webs 30. Through the webs 30, the space between the membrane sheets 27 and 28 is designed as channels 31. A medium can be passed through the channels 31, so that the channels 31 are used as cooling or heating channels. It is also possible to provide the channels 31 and / or the spaces between the membrane sheets 26 and 27 and 28 and 29 with insulating material, so that the membrane 25 or at least part of the membrane 25 functions as an insulating layer.

FIG. 6 shows a membrane 40 with membrane sheets 41 and 42. The membrane sheets 41 and 42 are bent at a right angle at their front end and clamped at their other end in such a way that the gas channel 5 results between the two right-angled bends. In the lower area of the right-angled bends, the membrane sheets 41 and 42 have bends 43. These bends 43 result in a sealing cutting edge 43 ′ which seals the gas channel 5 against the chamber frame 9. Leaf springs 44, 45 and 46 press on the membrane 40. The leaf springs 44, 45 and 46 are of different lengths. This measure increases the spring force with increasing deflection.

7 shows the gas channel 5 with an outer door sealing strip 50 and an inner door sealing strip 51. The inner door sealing strip 51 has one at its lower end Slot 52 on. Below the groove 52, the inner door sealing strip 51 is provided with a bevel 54, so that a door sealing cutting edge 56 results. The outer door sealing strip 50 accordingly has a groove 53 and a bevel 55 at its lower end. The bevel 55 extends beyond the wall thickness of the door sealing strip 50. This makes it possible to press the door sealing blade 57 directly with a spring force F and thus achieve a more flexible adaptation to the chamber frame 9.

It can be seen from FIG. 8 that the membrane 3 and the leaf springs 6 are fastened to the holding element 4 on the door plate 2. The lowermost leaf spring of the leaf springs 6 is angled at its non-clamped end and presses in a punctiform or line-shaped manner on the membrane 3 and the outer door sealing strip of the gas channel 5. The punctiform or line-shaped contact pressure of the leaf spring 6 can be increased adjustable in that a Wedge 60 is pushed between the individual leaf springs of the leaf springs 6.

FIG. 9 shows a corner area of the gas duct 5. The gas duct 5 is connected in the corner area by plugging in the direction of arrow A. For this purpose, the right part of the gas channel 5 is inserted into an opening 64 in the left part of the gas channel 5. Through an opening 65 in the right part of the gas channel 5, an unobstructed gas passage in the corner region of the gas channel 5 is possible. With an appropriately fitting design, an additional connection of the two parts of the gas duct 5 is unnecessary, since any gas leaks are eliminated by the tar. It is also possible to use tar or another adhesive for the connection of the two gas channel parts.

It can be seen from FIG. 10 that a leaf spring 70 with a sliding surface 71 presses on the bar 8 and thus on the membrane 3 and the gas channel 5. When the coke oven door 1 and / or the chamber frame 9 are deformed in the direction of arrows A and B, the leaf spring 70 moves with its sliding surface 71 along the edge of the strip 8. The spring travel is composed of the spring travel of the leaf spring 70 and the spring travel by compressing the angle formed by the sliding surface 71 and the leaf spring 70 and from the sliding path of the strip 8 on the sliding surface 71. The sum of these three spring travel results in a large total spring travel. A gap 72 is provided on the inner door sealing strip 5b of the gas channel 5. When the coke oven door 1 moves In the sense of arrow B, the outer door sealing strip 5a of the gas channel 5 comes into contact with the chamber frame 9. With further movement in this direction, the inner door sealing strip 5b of the gas channel 5 is brought into contact and the gap 72 closes. This increases the already large travel of this system. When the coke oven door 1 moves in the opposite direction in the direction of arrow A, the inner door sealing strip 5b of the gas channel 5 lifts off the chamber frame 9, while the outer door sealing strip 5a of the gas channel 5 still reliably seals.

LIST OF REFERENCE NUMBERS

1 coke oven door

2 door panels

3 membrane

3 'sheet

3 "sheet

sheet

4 holding element

5 gas channel

5a door sealing strip

5b door sealing strip

5c bevel

6 leaf springs

7 holding element

8 bar

9 chamber frames

10 pressure plungers

11 bracket

12 disc spring columns

13 nuts

15 leaf spring

16 screw

17 disc spring columns

20 spring component

21 holding element

22 screw

25 membrane

26 membrane sheet

27 membrane sheet

28 membrane sheet 29 membrane sheet

30 bridges

31 channels

40 membrane

41 membrane sheet

42 membrane sheet

43 angulation

43 'sealing edge

44 leaf spring

45 leaf spring

46 leaf spring

50 outer door sealing strip

51 inner door sealing strip

52 groove

53 groove

54 slant

55 slant

56 door sealing cutter

57 Door sealing cutter

60 wedge

64 opening

65 opening

70 leaf spring

71 sliding surface

72 gap

A arrow

B arrow

Claims

claims

1. coke oven door (1) with a gas channel essentially completely surrounding the gas door and a membrane which is fastened to the coke oven door (1) and can be pressed resiliently against the chamber frame, characterized in that the gas channel (5) on a membrane (3 ) is attached from at least two layers.

2. coke oven door (1) with a membrane which is attached to the coke oven door (1) and can be pressed against the chamber frame in a sealing manner, characterized in that the membrane (3) consists of at least two flexible, mutually displaceable layers.

3. coke oven door (1) according to claim 1 or 2, characterized in that the membrane (3) consists of two sheets.

4. coke oven door (1) according to claim 1 to 3, characterized in that the membrane (3) consists of at least four thin sheets with a material thickness in the tenth of a millimeter range.

5. coke oven door (1) according to claim 1 to 4, characterized in that the membrane (25) is designed in composite construction.

6. coke oven door (1) according to claim 1 to 5, characterized in that the sheets (3 ', 3 "and 3'") have a different material thickness.

7. coke oven door (1) according to claim 1 to 6, characterized in that at least one sheet consists of heat and corrosion-resistant material.

8. coke oven door (1) according to claim 1 to 7, characterized in that at least one sheet is designed as a spring.

9. coke oven door (1) according to claim 1 to 8, characterized in that the sheets are formed as molded parts.

10. coke oven door (1) according to claim 1 to 9, characterized in that at least three sheets with properties according to the preceding claims are combined.

11. coke oven door (1) according to claim 1 to 10, characterized in that the gas channel (5) with membrane (3) with known spring elements on the chamber frame (9) can be pressed.

12. coke oven door (1) according to claim 1 to 11, characterized in that the spring element consists of leaf springs (6).

13. coke oven door (1) according to claim 12, characterized in that the leaf springs (6) are of different lengths.

14. coke oven door (1) according to claim 12, characterized in that at least one distance is provided between the leaf springs (6).

15. coke oven door (1) according to claim 12, characterized in that an angled portion (43) is provided on at least one leaf spring in the front region.

16. coke oven door (1) according to claim 12, characterized in that a displaceable clamping wedge (60) is provided between the leaf springs (6).

17. coke oven door (1) according to claim 12, characterized in that set screws are provided on at least one leaf spring.

18. coke oven door (1) according to claim 1 to 11, characterized in that the spring element consists of plungers (10) on the spring forces act.

19. Coke oven door (1) according to claim 18, characterized in that a pressure distribution strip (8) is arranged under the pressure tappets (10).

20. coke oven door (1) according to claim 1 to 10, characterized in that the spring element consists of at least one disc spring column.

21. coke oven door (1) according to claim 1 to 11, characterized in that the spring element consists of a spring component (20) which is attached to the door.

22. coke oven door (1) according to claim 21, characterized in that the spring component (20) by a screw (22) is made adjustable.

23. coke oven door (1) according to claim 1 to 11, characterized in that the spring element consists of a leaf spring (15) which is resiliently arranged on a screw (16).

24. coke oven door (1) according to claim 1 to 11, characterized in that a leaf spring (15) is attached to a spring rod which is attached to the door.

25. coke oven door (1) according to claim 12, characterized in that the leaf springs (6) are designed in composite construction.

26. Coke oven door (1) according to claim 1 to 25, characterized in that cooling or heating channels or insulating layers are provided on the membrane (3) and / or the spring elements.

27. coke oven door (1) according to claim 1 to 26, characterized in that the gas channel (5) through the membrane (40) with the membrane sheets (41, 42) is formed.

28. Coke oven door (1) according to claim 1 to 27, characterized in that on the gas channel (5) grooves (52, 53) with bevels (54, 55) are provided and the bevel (55) with the door sealing edge (57) a spring force F can be pressed against the chamber frame (9).

29. Coke oven door (1) according to claim 1 to 28, characterized in that the gas channel (5) in the corner area and outside is designed as a plug connection.

30. coke oven door (1) according to claim 1 to 29, characterized in that seals are provided by tar on the sealing surfaces of the membrane (3) and / or the gas channel (5).

31. Coke oven door (1) according to claim 1 to 30, characterized in that a sliding surface (71) is provided on a leaf spring (70) and the gas channel (5) on its inner door sealing strip (5b) has a gap (72).

32. Use of the coke oven door (1) according to claim 1 to 31 for retrofitting existing coke oven doors.