The invention relates to an industrial oven having a rotary pipe and a fixed material supply device which is connected in the region of a front-face opening of the rotary pipe.
Such industrial ovens are used, for example, as so-called retort ovens and serve, for example, to thermally process metals. Another field of application is in thermally processing oil shale in order to obtain oil vapour.
So that the thermal processing can be carried out in a defined atmosphere, there is provided between the rotary pipe and the supply device a sealing arrangement which comprises a gas seal. In that manner, it is also possible to adjust in the operating chamber a selective pressure (in accordance with the method, this may be excess or reduced pressure).
A necessary gap is provided between the rotating rotary pipe and the fixed material supply device and has dimensions which are as small as possible in order to prevent material from the operating chamber from reaching the gas seal via the gap.
In specific applications such as, for example, processing oil shale, the rotary pipe is operated with a material filling level of approximately 50% and more. Owing to the high filling level, the use of a rotating transfer wall or the like for introducing the material into the operating chamber is impossible.
Therefore, it has already been proposed to place a material supply chute having an upright end wall upstream of the rotating rotary pipe. Owing to the high filling level and the resultant high hydrostatic pressure in the material mound of the operating chamber, a substantial quantity of material is urged through the gap within a relatively short space of time in the ovens known in practice. Subsequently, the material quickly reaches the gas seal so that it is destroyed in a relatively short time.
DE2119650A therefore proposed a sealing arrangement which comprises a fixed cylinder which is connected to a material supply device and a cylinder which rotates with a rotary pipe, there being formed between the two cylinders an annular space, in which a helical screw component which rotates with the rotary pipe is arranged in order to convey any powder-like material which has been introduced into the annular space back into the rotary pipe. However, the material located in the rotary pipe impedes this operation so that adequate sealing is ensured in the rotary pipe only at relatively low filling levels. At relatively high filling levels of, for example, more than 50%, the material is urged out of the rotary pipe into the annular space in a substantially increased manner.
Therefore, an object of the invention is to improve the sealing arrangement in such an industrial oven so that the gas seal is better protected from any material which is discharged from the operating chamber.
According to the invention, this object is achieved by the features of claim 1.
The industrial oven according to the invention has a rotary pipe and a fixed material supply device which is connected in the region of a front-face opening of the rotary pipe, there being provided between the rotary pipe and the material supply device a sealing arrangement which comprises a gas seal which is delimited from the operating chamber of the rotary pipe acted upon with material by at least a first gap between the rotary pipe and the material supply device. The sealing arrangement further has an annular chamber which is provided between the first gap and the gas seal and which has a discharge opening which is connected to the operating chamber. A lifting device is further provided in the annular chamber in order to lift out of the operating chamber material which has become introduced into the annular chamber through the first gap and to convey it back to the operating chamber through the discharge opening.
The invention is based on the notion that the gap can be reduced only to a limited extent. Consequently, it is impossible to prevent material from inevitably accumulating at the gap in the case of a high filling level of 50% and more and a portion of the material from being urged through the gap in the course of time. Owing to the lifting device arranged in the annular chamber, however, this material is then lifted and directed back in the operating chamber again through the discharge opening so that at least a majority of the material introduced through the gap is kept away from the gas seal and is directed back in the operating chamber.
The service-life of the gas seal can thereby be substantially increased, with not only costs for the gas seal being able to be saved but also shorter down-times of the industrial oven being produced.
The dependent claims relate to other constructions of the invention.
According to a preferred construction of the invention, the sealing arrangement comprises a fixed cylinder which is connected to the material supply device and a cylinder which rotates with the rotary pipe, the annular chamber being delimited by the two cylinders. It is particularly possible to make provision for the discharge opening to be constructed in the fixed cylinder. Consequently, the discharge opening is preferably arranged so as to be fixed above a material level which is formed during operation of the rotary pipe.
According to another construction of the invention, there are provided in a region of the annular chamber guiding elements which are constructed in the manner of a screw conveyor and are orientated in such a manner that any material reaching the region of the guiding elements is conveyed into the lifting device with a predetermined direction of rotation of the rotary pipe. In that manner, there is also picked up material that could not be conveyed back into the operating chamber by means of the lifting device the first time. Consequently, those guiding elements constitute an additional, optional means for protecting the gas seal. Those guiding elements can be constructed in particular in the manner of a one-strand or multiple-strand screw.
The lifting device is advantageously formed by a plurality of lifting shovels which are arranged so as to be distributed over the periphery and which rotate with the rotary pipe.
It is further possible to delimit in the annular chamber a preliminary chamber which is connected to the operating chamber via the first gap and is connected to the remainder of the annular chamber via a second gap. That preliminary chamber has a delimiting wall which rotates with the rotary pipe and which is provided with a plurality of openings, via which any material which may be introduced into the preliminary chamber via the first gap reaches the lifting device directly.
The material supply device can further have a static end wall, with which the end-face opening of the rotary pipe is closed, and can comprise a supply chute which opens in the fixed cylinder which is secured to the end wall.
According to a third means for protecting the gas seal, there can further be provision for a third gap, which connects the annular chamber to an overflow device, to be provided between the cylinder which rotates with the rotary pipe and the end wall.
Whereas the lifting device alone already constitutes a very effective means for protecting the gas seal, the guiding elements and/or the overflow device afford the gas seal additional protection. Owing to a combination of all three means, the gas seal is substantially 100% protected from any material from the operating chamber.
Other advantages and constructions of the invention will be explained in greater detail below with reference to the description and the drawings, in which:
There is further provided a sealing arrangement 6 which comprises a gas seal 7 which is conventional in this context. It is constructed in such a manner that it can compensate for both the tumbling movement and any vertical impacts of the rotary pipe 2. Such a gas seal is described in greater detail, for example, in EP0274090 B1.
It further has a fixed cylinder 9 which is connected to the static end wall 4 of the material supply device 3 and a cylinder 10 which rotates with the rotary pipe, there being delimited between the two cylinders 9, 10 an annular chamber 11 which is connected to the operating chamber 2c of the rotary pipe 2 via a first gap 8.
The annular chamber 11 is again illustrated to a slightly larger scale in
In the upper region thereof, the annular chamber 11 has a discharge opening 18 constructed in the fixed cylinder 9. As can be seen particularly in
In addition to the lifting device 17, there are further provided in the remaining region of the annular chamber 11 guiding elements 19 which are constructed in the manner of a screw conveyor and are arranged in such a manner that they convey into the lifting device 17 any material which is introduced into the region of the guiding elements with a predetermined direction of rotation of the rotary pipe 2. That material is particularly material which is not immediately picked up by the lifting shovels 17 and material which is introduced through the second gap 12.
The cooperation between the lifting device 17 and the guiding elements 19 is also very readily apparent from the developed view according to
The end of the annular chamber 11 that is remote from the operating chamber 2c is delimited by the static end wall. In this regard, a third gap 20 which connects the annular chamber 11 to an overflow device 21 is formed between the co-rotating cylinder 10 and the end wall 4. The gas seal 7 to be protected is arranged only downstream of a fourth gap 22 which is formed between the fixed overflow device 21 and the co-rotating cylinder 10.
It is possible reliably to prevent a substantial portion of material from reaching the gas seal 7 with a combination of the three means (lifting device 17, guiding elements 19 and overflow device 21) so that the service-life thereof can be substantially extended.
Number | Date | Country | Kind |
---|---|---|---|
10 2009 058 311 | Dec 2009 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
3552721 | Phillips | Jan 1971 | A |
3698697 | Gillies et al. | Oct 1972 | A |
4115136 | Hansen | Sep 1978 | A |
4545764 | Gillies et al. | Oct 1985 | A |
4813689 | Statler et al. | Mar 1989 | A |
5906435 | Callaghan et al. | May 1999 | A |
6578850 | Rothlisberger | Jun 2003 | B1 |
Number | Date | Country |
---|---|---|
1280475 | Oct 1968 | DE |
1157528 | Nov 1968 | DE |
Number | Date | Country | |
---|---|---|---|
20110143298 A1 | Jun 2011 | US |