FURNACE

Abstract

A furnace for the thermal treatment, particularly for carbonization and/or graphitization, of material, particularly of fibers, particularly of fibers made from oxidized polyacrylonitrile (PAN), the furnace having a furnace housing and a process chamber located in the interior chamber of the furnace housing, which is delimited by a process chamber housing and into which the material to be treated can be introduced. A process chamber atmosphere prevailing in the process chamber can be heated by means of a heating system. An insulation layer thermally insulates the process chamber. The insulation layer is an insulation fill made from a solid particulate material.

Claims

1. A furnace for the thermal treatment of fibers, comprising: a) a furnace housing; b) a process space which is located in the interior space of the furnace housing and is delimited by a process space housing and into which the material to be treated can be introduced; c) a heating system by means of which a process space atmosphere present in the process space can be heated; d) an insulation layer which thermally insulates the process space, wherein e) the insulation layer is an insulating bed composed of a solid particulate material.

2. The furnace as claimed in claim 1, wherein the solid particulate material of the insulating bed has been densified.

3. The furnace as claimed in claim 1, wherein the solid particulate material is a granular material, in the form of a grain-like material, a pulverulent material or a powder material, or has been processed to give a pellet material.

4. The furnace as claimed in claim 1, wherein the solid particulate material is a carbon black material having a carbon content of more than 99.5%.

5. The furnace as claimed in claim 5, wherein the carbon black material is a gas black, a furnace black, a flame black, a carbon black from cracking, an acetylene black, a thermal black, a channel black or a mixture of a plurality of these types of carbon black.

6. The furnace as claimed in claim 1, wherein the insulating bed is present in an insulation space which surrounds the process space housing at least in regions.

7. The furnace as claimed in claim 6, wherein the insulation space is configured as an annular space whose outer boundary is formed by corresponding regions of the furnace housing.

8. The furnace as claimed in claim 6, wherein the insulation space adjoins the process space housing at least in regions.

9. The furnace as claimed in claim 1, wherein the heating system comprises at least one heating element which is arranged in the process space.

10. The furnace as claimed in claim 1, wherein the heating system comprises at least one heating element which is arranged in a heating space which adjoins the process space.

11. The furnace as claimed in claim 10, wherein the heating space is arranged on the upper side or on the underside of the process space.

12. The furnace as claimed in claim 10, wherein the heating element is a first heating element and the heating space is a first heating space, where the heating system comprises at least one second heating element which is arranged in a second heating space which adjoins the process space.

13. The furnace as claimed in claim 12, wherein the first heating space is arranged on the upper side and the second heating space is arranged on the underside of the process space.

14. The furnace as claimed in claim 1, wherein the process space housing is configured as a muffle, in particular as a muffle composed of graphite.

15. The furnace as claimed in claim 10, wherein the process space housing delimits the process space and the one or more heating spaces.

16. The furnace as claimed in claim 1, wherein the furnace is a continuous furnace and the material to be treated can be passed through the process space.

Description

[0032] Working examples of the invention are described in more detail below with the aid of the drawings. The drawings show:

[0033] FIG. 1 a perspective view of a furnace for the thermal treatment of carbon fibers;

[0034] FIG. 2 a longitudinal section of the intake section of a first working example of the furnace as per FIG. 1;

[0035] FIG. 3 a cross section of this first working example of the furnace as per FIG. 1 in the sectional plane III shown there;

[0036] FIG. 4 a corresponding cross section of a second working example of the furnace;

[0037] FIG. 5 a corresponding cross section of a third working example of the furnace.

[0038] The figures show the furnace 10 for the thermal treatment of material, in which the working examples shown in FIGS. 1 to 5 relate to fibers 12 and by way of example fibers 14 composed of oxidized polyacrylonitrile, which will hereinafter be referred to as oxPAN fibers 14.

[0039] The furnace 10 comprises a furnace housing 16 which delimits an interior space 18. The furnace housing 16 is made of steel in the working examples described. The furnace housing 16 has a fiber entry passage 20, which can be seen only in FIG. 2, at one end face and a fiber exit passage, which owing to the view shown cannot be discerned in the figures, at an opposite end face. Apart from these passages, the furnace housing 16 is gastight.

[0040] In the interior space 18 of the furnace housing 16 there is a process space 22 which is in turn delimited by a process space housing 24 in the form of a muffle 26. The process space housing 24 has a rectangular cross section, but other, for example curved or round, cross sections are also possible. In the present working example, the muffle 26 is made of graphite. The process space housing 24, i.e. the muffle 26, has a fiber inlet opening 28, which can again be seen only in FIG. 2, at one end face and a fiber outlet opening, which can likewise not be discerned in the figures, at an opposite end face. During operation of the furnace 10, a process space atmosphere 30 is present in the process space 22.

[0041] The furnace 10 comprises a heating system 32 by means of which the process space atmosphere 30 is heated. Successive heating zones 34, of which five heating zones 34.1, 34.2, 34.3, 34.4 and 34.5 can be discerned in FIG. 1, are formed in the process space 22 between the fiber inlet opening 22 and the fiber outlet opening of the muffle 26. The temperature rises from heating zone to heating zone in such a way that a temperature gradient from about 800 C. to about 1800 C. is present in the process space 22. Each heating zone 34 is assigned a dedicated heating device 36 which heats the muffle 26 in the associated heating zone 34 appropriately, as is known per se. The furnace 10 comprises an insulation layer 38 which thermally insulates the process space 22.

[0042] The heating devices 36 and the insulation layer 38 will be discussed in more detail in connection with FIGS. 3 to 5.

[0043] At the entry end, the furnace 10 has an intake lock 40 having a separate lock housing 42 and an exit lock, which can likewise not be discerned because of the view shown, likewise having a separate lock housing. An inert gas 46 is fed via the outer lock which cannot be seen into the interior space 18 of the furnace housing 16 and thus also into the process space 22 with the aid of an inert gas apparatus 44, so that the thermal treatment of the oxPAN fibers 14 proceeds under an inert gas atmosphere. As mentioned at the outset, nitrogen N.sub.2 or argon Ar are in practice used as inert gas at temperatures above 1800 C. The process space atmosphere 30 is a mixture of the inert gas and a pyrolysis gas liberated in the treatment of the oxPAN fibers 14.

[0044] The furnace 10 additionally comprises an extraction system denoted overall by 48 by means of which the process space atmosphere 30 can be drawn off from the process space 22. In the present working example, a through-housing 50 of an extraction device 52 of the extraction system 48, which delimits a flow space 54, can be seen between the entry lock 40 and the furnace housing 16. This flow space 54 is connected in a gastight manner with the entry lock 40 at one end and connected in a gastight manner with the furnace housing 16 at the other end, so that the inert gas 46 can flow in from the entry lock 40 through the flow space 54 into the process space 22.

[0045] The oxPAN fibers 14 are conveyed by means of a transport system known per se, which is not individually shown, as fiber cartridge 56 through the entry lock 40, through the flow space 54 and further through the fiber entry passage 20 of the furnace housing 16 into the interior space 18 thereof and there through the fiber inlet opening 26 of the process space housing 24 into the process space 22. The fiber carpet 56 flows through the process space 22 and the heating zones 34 established there and is then conveyed out through the fiber outlet opening of the process space housing 24 and through the fiber exit passage of the furnace housing 16 and finally through the exit lock connected thereto out from the furnace 10.

[0046] The furnace 10 is consequently designed as continuous furnace. For materials other than fibers 12, the furnace can, in a modification which is not individually shown, also be constructed as batch furnace. In this case, the material is both introduced into the process space 22 and taken from the latter when the treatment is concluded via the passages shown.

[0047] The insulation layer 38 mentioned above is an insulating bed 58 composed of a solid particulate material 60. In practice, the solid particulate material is free-flowing bulk material.

[0048] The insulating bed 58 is located in an insulation space 62 which surrounds the process space housing 24 at least in regions. In the working example shown, the insulation space 62 adjoins the process space housing 24 at least in regions.

[0049] In the working example shown, the insulation space 62 is configured as an annular space 64 whose outer boundary is formed by corresponding regions 66 of the furnace housing 16. In the direction of the entry lock 40 and the exit lock, the annular space 64 is closed in each case by a circular wall 68, of which the corresponding circular wall 68 can be discerned in FIG. 2.

[0050] The insulating bed 58 is firstly introduced into the insulation space 62 with the detached housing lid, which is not individually labelled, and densified by means of rammers. It is also possible to densify the insulating bed 58 by means of vibration. For this purpose, parts of the furnace housing 16 can be vibrated at times from the outside. As an alternative, vibration generators can also be introduced into the insulating bed 58.

[0051] Over the course of time, the insulating bed 58 densifies as a result of the operation-related temperature change on heating up and cooling. In addition, shrinkage of material by reactions with the atmosphere is possible. This occurs particularly at relatively high temperatures above 1800 C.

[0052] To be able to compensate for such densification or such material shrinkage, the furnace housing 16 has closable entrance openings 70, for example in the form of entry ports as are illustrated only in FIG. 1. The insulation space 62 can be divided by intermediate walls into insulation sections which can then be accessed via a respective entrance opening 70. For example, each heating zone 34 can be assigned such an insulation section.

[0053] Solid particulate materials 60 supplemented in this way can also be densified by means of rammers and/or by means of vibration, as has been described above.

[0054] The solid particulate material 60 can be a granular material, in particular in the form of a grain-like material, a pulverulent material or a powder material. As an alternative, the solid particulate material can also have been processed to give a pellet material. A particularly good thermal insulation effect, i.e. poor thermal conductivity, is obtained in the case of carbon black material, in particular in the case of carbon black material having a carbon content of more than 99.5%, which is preferably a gas black, a furnace black, a flame black, a carbon black from cracking, an acetylene black, a thermal black, a channel black or a mixture of a plurality of these types of carbon black.

[0055] In all the working examples shown in FIGS. 2 to 5, the process space housing 24, i.e. the muffle 26, is mounted on struts 72 which extend downward through the insulation space 62 and are anchored on the bottom of the furnace housing 16. An entry-end and discharge-end fastening of the process space housing 24 on the furnace housing 16 may be sufficient; in this case, the struts 72 can be omitted.

[0056] FIGS. 2 and 3 show a first working example of the furnace 10, in which the insulation space 62 completely surrounds the process space housing 24 in the circumferential direction and completely adjoins the process space housing 24 in the circumferential direction. This can be seen in FIG. 3. In this case, the insulation space 62 for the insulating bed 58 is thus delimited in the circumferential direction on one side by the abovementioned region 66 of the furnace housing 16 and on the other side by the process space housing 24, i.e. the muffle 26.

[0057] The heating device 36 comprises a heating element 74, which is arranged in the process space 22, for each heating zone 34. The heating element 74 is plate-shaped in the present working example. Possible materials for the heating element 74 are, for example, graphite or composite materials in the form of carbon fiber carbon composite (CFC). The heating elements 74 are operated in a manner known per se by means of heating modules which are present on the outside on the furnace housing 16 and are not shown individually and are connected via connecting heads 76 and electrical connecting pins 78 to the heating elements 74, where the connecting pins 78 extend through the process space housing 24, the insulation space 62 and the furnace housing 16.

[0058] In the working example shown in FIGS. 2 and 3, the process space housing 24 is configured as a single-chain housing 80 which as such delimits only the process space 22.

[0059] In the second working example of the furnace 10 shown in FIG. 4, the process space 22 is adjoined by a heating space 82 in which the heating element 74 is arranged. The heating space 82 is separated by a dividing wall 84 from the process space 24.

[0060] For this purpose, the process space housing 24, i.e. the muffle 26, is configured as multichamber housing 86, in this case a two-chamber housing 88, which delimits firstly the process space 22 and secondly the heating space 82.

[0061] In a modification which is not shown individually, the heating space 82 can also be delimited by a dedicated housing which is installed on the process space housing 24.

[0062] The heating space 82 is located on the upper side of the process space 22. In a modification which is not shown individually, the heating space 82 with the heating element 74 can also be arranged on the underside of the process space 22.

[0063] In the third working example of the furnace 10 shown in FIG. 5, the heating space on the upper side of the process space 22 is a first heating space 82a and the heating element accommodated therein is a first heating element 74a. The dividing wall is a first dividing wall 84a. In addition, the process space 22 is adjoined by a second heating space 82b in which a second heating element 74b is arranged. The second heating space 82b is separated from the process space 24 by a second dividing wall 84b.

[0064] For this purpose, the process space housing 24, i.e. the muffle 26, is once again configured as a multichamber housing 86, in this case as three-chamber housing 90, which delimits firstly the process space 22 and secondly both the first heating space 82a and also the second heating space 82b.

[0065] In a modification which is not shown individually, the first heating space 82a and/or the second heating space 82b can correspondingly be delimited in each case by a separate housing which is installed on the process space housing 24.

[0066] The second heating space 82b is located on the underside of the process space 22.

[0067] In modifications which are not shown individually, it is possible, as an alternative or in addition to the heating spaces 82 or 82a and 82b respectively, for one or more heating spaces to be provided on the side next to the process space 22, in which space or spaces vertically oriented heating elements are then arranged.

[0068] In the working examples with the heating space 82 or with the heating spaces 82a, 82b, it is accordingly not possible for the insulation space 62 or the insulating bed 58 to completely adjoin the process space 22 in the circumferential direction. In the region of the heating spaces 82, 82a and 82b, these are in each case arranged between the process space 22 and the insulation space 62 and the insulating bed 58.

[0069] In a modification which is likewise not shown individually, the furnace 10 can in its entirety or at least in the process space 22 be crossed in the vertical direction by the fibers 12. In this case, the heating elements 74, 74a and 74b and any associated heating spaces 82, 82a and 82b are in each case no longer oriented horizontally, but instead vertically.

[0070] In a further modification which is not shown individually, the furnace housing 16 can itself further comprise a supplementary thermal insulation.