The invention relates to a device for conveying bulk material and to a method for conveying bulk material. The bulk material, which can be a pasty, powdery, lumpy, free-flowable/free-flowing, or cohesive conveyed material, is to be conveyed into a pressure chamber.
Conveying devices or pumps of this type, which are also referred to as dry material pumps, are used for introducing dry bulk materials such as, e.g., coal into a pressurized chamber, such as a gasification reactor.
When coal is processed in gasification reactors, high temperatures and/or pressures of 25 bar to 80 bar are customary for the efficient operation of the plant. Particularly with regard to the gasification of low-quality coal or in the case of fuels from biomass, certain requirements cannot be ignored with regard to the conveying of the particular bulk material. Usually, there should be no high costs for providing the base material, which includes its movement, comminution, classification, and storage. In addition, the conveying devices should be robust and inexpensive and the escape of process gases, which leads to pressure losses, should be largely avoided during the conveying process. In addition, it must be taken into account that particularly bulk materials in the form of fuels have very different characteristics and frequently exhibit fluctuations in residual moisture or moisture content, are coarse-grained, or even have aggressive properties or characteristics that attack the surface of the conveying device.
The loss of process gas with which the required pressure in the conveying device or a working space of the conveying device is generated relative to the ambient pressure is fundamentally dependent on the respective sealing of the working space. On the one hand, there are conveying devices, such as piston pumps, disk pumps, rotary feeders, or pressure containers arranged one behind the other, in which a seal is achieved by means of geometrically defined components. Mechanical seals, piston rings, or soft and hard sealing components running opposite to each other are used.
The bulk material to be conveyed has an influence on the sealing effect of the components insofar as the components wear more rapidly or more slowly depending on the particular nature of the bulk material. In the design of conveying devices of this kind, therefore, a compromise between the wear of the components and their replacement and the sealing must often be addressed with regard to the sealing effect.
Most of the aforementioned conveying devices or dry material pumps are relatively expensive, have a high energy loss, and are very inefficient overall.
For example, conveying devices which use seals in the form of material plugs made of the material to be processed can be found in WO 95/06610 A1 or U.S. Pat. No. 4,197,092. In this regard, these devices continuously convey the material into the pressure chamber. In both cases, however, a great deal of energy is required to compact the material plug to the extent that the desired sealing effect is achieved. The entire bulk material to be conveyed must be compacted in the conveying process either continuously or discontinuously to the density of the desired material plug. This is particularly difficult with inhomogeneous materials and also entails high wear on the components coming in contact with the plug.
In addition, all of the conveyed material must be processed before the conveying process to the extent that it can pass through the device and the compacting section. This increases the expenditure for the processing of bulk material before the conveying process.
It is therefore an object of the present invention to convey bulk material into a pressure chamber with the lowest possible energy expenditure and to guarantee the conveyance independently of fluctuating material properties. The disadvantages known from the prior art and the aforementioned disadvantages are overcome in this regard.
In an exemplary embodiment, the invention provides a device for conveying bulk material comprising a movable conveying member and an outer wall that is stationary in relation to the conveying member, wherein the device can be pressurized or is connected to a further processing chamber or a pressure chamber for receiving and further processing the bulk material. In this case, a dynamic seal seals with respect to the differential pressure between the further processing chamber and the regions lying upstream in the process. This means that the dynamic seal, disposed in the conveying device, must withstand the differential pressure between the further processing chamber and the regions lying upstream in the process, for example, the ambient pressure or a bulk material source. A dynamic seal can be understood here as a component or element that provides the sealing action between a movable part and a stationary part of the conveying device. In the present invention, a seal element of the dynamic seal made of a sealant is provided in the form of a material charge or material seal that can be regenerated during operation of the conveying device, wherein, in contrast to known conveying devices, the seal element is provided only from a branch flow of the bulk material to be conveyed and/or from a separate sealant source.
This has the advantage that no energy has to be applied for compacting the entire bulk material conveying flow but only for the branch flow or the separate sealant flow. In addition, also only a part of the bulk material is altered thereby with regard to its original properties, so that there is no need to restore the original properties before entry or upon entry into the pressure chamber.
Nevertheless, the seal element made of the bulk material or separate sealant acts as a regenerable sacrificial seal and the abrasion which necessarily occurs during operation can also be used/further treated during the gasification process. Furrows or depressions which are formed by wear, for instance, on the inner side of the conveying device, are compensated by the regeneration of the seal element with the bulk material or sealant and the associated filling of the depressions during the course of the process.
Thus, a conveying device with very high service lives can be produced at low energy costs for the sealing.
In this regard, the seal element of the dynamic seal can be provided as a primary or secondary seal. In the case of a primary seal, the seal element of the dynamic seal is formed entirely of the material of the bulk material branch flow or a separate sealant flow or a mixture of the two. Alternatively, the seal element can have a conventional shaping sleeve component and the filling of this sleeve component from the branch flow of the bulk material or the sealant flow can be provided as a secondary seal. In the case of the secondary seal, the sealing effect of the seal element results from the joint action of the sleeve component and the filling.
An embodiment of the invention provides that the dynamic seal can be provided as a translatory or rotary seal on the movable conveying member or the stationary outer wall of the conveying device.
Thus, this can be used, for example, in a conveying device which comprises a cylinder and in which a piston, which can be moved back and forth in the cylinder, is provided as the conveying member. Here, the dynamic seal can be arranged both radially on the cylinder wall and on the piston.
Accordingly, the seal element of the dynamic seal in the form of the material charge or material seal can be shaped as a sealing jacket.
In this case, it is advantageous if the sealing jacket has a wall thickness as small as possible, which, on the one hand, is large enough to maintain the arising forces and pressures during operation and, on the other hand, is so small that only a small mass and/or a small volume of the material charge or material seal are present.
The sealing effect is improved when the compacting device, the compaction path which is traversable by the compacting device, the sealing chamber, the cylinder, the shape, and the resistance force of the piston are matched to one another such that a radial outward striving of the sealing material is forced during compaction caused by the compressing device.
Alternatively, the seal element of the dynamic seal can also be arranged as a plug or disk on the end face of the reciprocable piston. In this case, either an already compacted plug or an already compacted disk can be used, or a compaction device can be arranged such that sealing material introduced into the conveying device can be processed into a seal element.
With regard to the material composition of the seal element of the dynamic seal, one additive or a plurality of additives may be added to the branch flow of the bulk material and/or to the separate sealant flow. Advantageously, these additives only have characteristics that are inert with respect to further processing in the pressure chamber. Thus, the material property of the bulk material to be conveyed is not adversely affected by the separate sealant flow or the additives.
For example, water, oil, for instance, waste oil, graphite, grease, or other lubricants, with preferably good sliding and/or lubricating properties, are conceivable as an additive. Preferably, the additive, on the one hand, optimizes the sliding properties of the seal element on the conveying device and, on the other hand, particularly in the case of liquid additives, improves the flowability of the sealing material in order to improve the feeding of the sealing material for the regeneration of the seal element.
An embodiment of the invention provides in addition that the seal element of the dynamic seal comprising a pasty or liquid material is provided. This property can be adjusted in its form, for instance, by the addition of liquid additives. The advantage of this property is the improved conveying capacity of the seal element for the purpose of regeneration. In this case, the removed density element is replaced by the feed under pressure from a source.
Furthermore, the invention provides a method for conveying bulk material into a pressurized chamber, in which method a seal element of a dynamic seal is formed from a branch flow of the bulk material flow to be conveyed and/or a separate seal flow for sealing a conveying device with respect to the ambient pressure or bulk material source.
In this case, the sealant can be conveyed continuously and discontinuously by means of a movable conveying member from the branch flow and/or seal flow into a working space of the conveying device, which space can be used for compacting.
Even if the sealant which is fed to the bulk material flow during operation of the conveying device is removed from a separate sealant flow, it can be processed together with the bulk material to be conveyed into the pressure chamber or the further processing chamber because this does not alter or worsen the material properties of the bulk material. The same applies to a sealant which has been removed from the bulk material flow and added to the additive in order to possibly improve the cohesion or the sliding properties.
A stable conveying device, on the one hand, and an efficiently operable conveying device, on the other, are realized in this way.
Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes, combinations, and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.
The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus, are not limitive of the present invention, and wherein:
There is a sealing gap 10 between the outer side of piston 8 and an inner side or inner surface 9 of cylinder 3. Sealing gap 10 is sealed by means of a dynamic seal, the seal element 11 of which is provided in the form of a primary seal or a material seal. Seal element 11 is made annular and has an inner surface 12 which rests against a conical outer surface 13 of piston 8.
Piston 8 has a slot 14 in the manner of a long hole in which a pin 15 of a compacting device 16 is guided. Compacting device 16 is made in the manner of a hollow-bore shaft.
Seal element 11 is constructed from a branch flow of bulk material 4 but also contains a small quantity of additive elements and/or elements different from the bulk material.
In the illustrated exemplary embodiment, bulk material 4 to be processed is first supplied from a starting material feeder 17 to a conveying flow divider or a conveying flow dividing device 18. In this regard, e.g., 90% of the bulk material to be conveyed is fed directly to feed device 5 via filter, screen, comminution, rolling, or grinding processes, and the remaining 10% of the material is fed after the same or similar preprocessing steps to a seal element feed unit 19 shown in
In this case, seal element feed unit 19 can be designed as a “side feeder” or “top feeder.” A so-called “side feeder” is shown in which the bulk material to be conveyed is introduced into working space 2 of conveying device 1 via a side inlet. As is evident from
The lower end of cylinder 3 has an outlet which projects into a further processing chamber 23. This outlet is closed by a closing component 21, so that the corresponding pressure can be built up for further processing in working space 2 of cylinder 3.
In the next step, as shown in
It is evident in
As soon as the defined pressure is reached, working space 2 of conveying device 1 can be opened, for instance, via an auxiliary piston 22, and a discharge of bulk material 4 as shown in
In this case, however, bulk material 4 is largely not compacted but only working space 2 is brought to the pressure as it prevails in further processing chamber 23. After the compression phase from
Whereas the fuel preparation takes place in a step 25, the dynamic seal can be produced as a primary or secondary seal in a separate step 27, as an alternative to the methods already described. For example, a material seal can be produced in the form of a disk or stopper. This can be done optionally with the addition of additives or by simple compaction. Alternatively, branch flow 26 can also be used for the production of a secondary seal which is filled into a shaping elastic seal element. An additional quality test 28 can be provided for checking the sealing effect of the primary or secondary seal. The further processing of prepared bulk material from fuel preparation 25 and from branch flow 26 with or without additives is then carried out in a step 29 in the further processing chamber, wherein the dynamic seal can be produced in the processing process itself or can be introduced into the conveying process as a finished seal.
The advantage of the conveying device of the invention and of the conveying method of the invention is that the energy required to seal the pressure chamber against the ambient pressure can be considerably reduced in comparison with compacting or continuously compacting conveying devices because the entire bulk material flow or conveying flow does not need to be compacted.
An approximately continuous charging of a further processing chamber 23 or of a pressure chamber can be achieved, however, by the combination of a plurality of conveyor systems.
The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are to be included within the scope of the following claims.
Number | Date | Country | Kind |
---|---|---|---|
10 2015 002 769 | Mar 2015 | DE | national |
This nonprovisional application is a continuation of International Application No. PCT/EP2016/000385, which was filed on Mar. 4, 2016, and which claims priority to German Patent Application No. 10 2015 002 769.7, which was filed in Germany on Mar. 5, 2015, and which are both herein incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
3841465 | Miller, Jr. | Oct 1974 | A |
3897889 | Hindermann | Aug 1975 | A |
4033730 | Baron | Jul 1977 | A |
4043471 | Trumbull | Aug 1977 | A |
4044904 | Trumbull | Aug 1977 | A |
4274786 | Svensson | Jun 1981 | A |
4302143 | Grimminger | Nov 1981 | A |
4400125 | Jensen | Aug 1983 | A |
4702177 | Narisoko | Oct 1987 | A |
4738687 | Smieskol | Apr 1988 | A |
7314538 | Lashofer | Jan 2008 | B2 |
7976259 | Craig | Jul 2011 | B2 |
8322951 | Kvalheim | Dec 2012 | B2 |
9211515 | Fink | Dec 2015 | B2 |
9533839 | Nierescher | Jan 2017 | B2 |
9617086 | Rusterholz | Apr 2017 | B2 |
20070034642 | Pendleton | Feb 2007 | A1 |
20100126069 | Stein | May 2010 | A1 |
20140003968 | Gross-D'Aillon et al. | Jan 2014 | A1 |
Number | Date | Country |
---|---|---|
1 932 787 | Jun 2008 | EP |
WO 03013714 | Feb 2003 | WO |
Entry |
---|
International Search Report dated May 17, 2016 in corresponding application PCT/EP2016/000385. |
Number | Date | Country | |
---|---|---|---|
20170362519 A1 | Dec 2017 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/EP2016/000385 | Mar 2016 | US |
Child | 15695238 | US |