EP2391433A1

EP2391433A1 - Method for discharging the dust arising during operation of a dedusting system for raw gas

Info

Publication number: EP2391433A1
Application number: EP10701100A
Authority: EP
Inventors: Stefan Hamel
Original assignee: Uhde GmbH
Current assignee: ThyssenKrupp Industrial Solutions AG
Priority date: 2009-01-30
Filing date: 2010-01-19
Publication date: 2011-12-07
Also published as: US20110277635A1; TW201035305A; AU2010207789A1; DE102009006878A1; UA106063C2; ZA201106318B; CA2750431A1; KR20110125213A; CN102300616A; RU2011135432A; WO2010086104A1; BRPI1008351A2; RU2520466C2; CN102300616B

Abstract

The invention relates to a method for discharging the dust arising from pressure gasification using a dust precipitator having an associated discharge container, designed such that nitrogen entry into the raw gas is minimized or completely prevented, in order to keep subsequent chemical syntheses from experiencing nitrogen entry as much as possible in advance. The aim is achieved in that the filter elements positioned in the dust precipitator are backflushed using a gas comprising carbon dioxide or pure CO₂ gas.

Description

"Method for discharging the dust generated during the operation of a dedusting plant for raw gas"

The invention is directed to a method for discharging the resulting in the operation of a dedusting system for raw gas dust of the type specified in the preamble of claim 1.

The thermal gasification solid fuel, such as a variety of coals, peat, hydrogenation residues, residues, waste, biomass and fly ash or a mixture of these substances is carried out under elevated pressure and high temperature with the aim of a raw gas with high energy content and / or to produce with a composition favorable for further chemical syntheses. The raw gas is loaded with fly ash, which has its origin in the ash content of the supplied fuel. The fly ash is in the form of particles that must be separated before further use and discharged from the pressure chamber. In a dry deposition, for example in a cyclone or in a filter, the usually very fine-grained solid falls as a bed, before it is discharged from the pressure chamber. Naturally, there is gas in the void volume of the particle bed, in this case raw gas which is discharged with the solids and which must be removed before further use or disposal of the ashes.

After separation of the fly ash from the raw gas, it is first collected over a certain period of time before this batch is discharged. The batch is usually transferred from the buffer in a lock container, which is still at this time at the same high pressure level. The lock container is then decoupled and relaxed to a lower pressure level. The ash in the lock container is removed for further treatment, disposal and / or storage. After emptying the fly ash, the empty lock container is brought back to system pressure by gas supply and coupled to the buffer to receive the next collected batch of fly ash.

Possible constructive embodiments of such filter apparatuses and the arrangement of the filter elements therein for the separation of dust from the raw gas of a pressure-gasification plant are described, for example, in DE 40 08 742, DE 35 15 365 or in US Pat. No. 7,182,799.

For continuous filtering of the raw gas stream, it is necessary to clean the filter elements from time to time by a short backwash and free so from the raw gas side constructed filter cake. For this, the purge gas must be available at a pressure level above the filter pressure, so that a short-term gas flow with a required impulse can be achieved.

Normally, in gasification plants, the covering of the lock container and also the cleaning of the filter elements with nitrogen are carried out, which is available to a sufficient extent from the air separation plant. The use of nitrogen has been proven and largely mature. If the aim of the gasification plant is the production of a synthesis gas for the subsequent performance of various chemical syntheses, then the nitrogen content in the synthesis gas is extremely undesirable and, moreover, usually limited to limits that are dependent on the respective synthesis. The object of the present invention is to provide a method for discharging the resulting dust in such a way that a nitrogen input into the raw gas is minimized or completely avoided in order to free subsequent chemical syntheses from the outset of a nitrogen input.

With a method of the type described, this object is achieved according to the invention in that filter elements are positioned in the dust, which are backwashed by means of a carbon dioxide-containing gas or pure CO ₂ -GaS.

With the procedure according to the invention, it is noticeably achieved that no additional nitrogen is introduced into the system when cleaning the dust separator or backwashing the filter elements, but rather the CO ₂ obtained anyway is used for this procedure.

In the carbon dioxide-containing gas, the proportion of inert gases (such as N ₂ , Ar) and of hydrocarbons (such as CH ₄ , C _x H _y ) together should be <50%. The remainder consists of CO ₂ and may possibly also contain synthesis gas components (CO, H ₂ ) etc.

In principle, it is known to use CO ₂ in a coal dust pressure gasification as inerting and conveying medium in the entry system, as described in DE 10 2007 020 333 A1.

Advantageous embodiments of the invention will become apparent from the dependent claims, wherein the invention provides that the C0 ₂ -containing backwash gas is preheated to those inevitably in relaxation processes, such as regulation, tank cover, supply of carbon dioxide at low Pressure u. like. to compensate occurring temperature decreases of the carbon dioxide in order to enable safe operation.

In this case, according to the invention, the carbon dioxide is raised to a temperature level for backwashing, such that the required temperature is maintained at the filter elements.

In a further embodiment, the invention provides that the CO ₂ -containing backwashing gas is used for fluidizing and loosening the fly ash fill in the dust separator. Such fluidization or loosening may be expedient, since the mean particle diameters are very small, for example <2 microns. The use of CO ₂ -containing gas or pure CO ₂ as a loosening gas has the advantage that only these gas components reach the raw gas. Since, according to the invention, the CO ₂ -containing backwash gas is also used to cover the lock container, this component enters the raw gas while the ash passes into the lock container where it expels the portion of the gas present in the lock container, which then flows back into the raw gas.

In addition to avoiding the introduction of nitrogen into the raw gas, a further advantage of the invention is that lower volume flows are necessary for cleaning the filter elements compared to nitrogen, since smaller amounts of carbon dioxide are necessary to exercise certain pulses for cleaning the filter elements due to the higher density of the carbon dioxide , so that smaller quantities and lower compressor power will be necessary.

Appropriately, supply lines which are externally heated can be used to heat the CO ₂ -containing gas. A further embodiment of the invention consists in that the gas discharged from the lock container is fed to a dedusting device.

Such a dedusted gas from the lock container according to the invention can be fed to an intermediate buffer and then partially used as a gas for carrying out the method steps described above, as the invention also provides.

Further features, details and advantages of the invention will become apparent from the following description and from the drawing and the cited example.

In the single figure, a system diagram is simplified, with raw gas according to arrow 1 to the filter or dust collector 2 is supplied. The dedusted raw gas leaves the dust collector 2 according to arrow 3 after passing through the generally designated 4 filter elements.

In the collecting space 5 of the dust collector 2, the adhering to the filters and purged of these dust collects in a discharge area, which is equipped with fluidizing 7 to loosen the dust for further transport, including CO ₂ or CO ₂ -containing gas line 6th supplied to these fluidizing devices. The dust is then passed via the connecting line 8 into a lock container 9, which in turn is equipped with fluidizing devices 11 in the outlet region, which are operated by means of CO ₂ or by means of CO ₂ -containing gas, line 10.

The gas from the gas dome of the lock container 9 is returned by means of compensation line 12 into the gas space of the dust collector 2. To clean the filter elements 4, a gas supply line 13 for CO ₂ or CO ₂ -containing gas is provided, which act on the backwash lines 14, the filter elements optionally impact or impulsively.

In addition to the compensation line 12, a further line 15 is provided from the gas dome of the lock container 9, which acts on a filter element 17. From here, a buffer tank 21 can be acted upon via the line 18, the gas is optionally applied via a recycle line 19 to the expansion tank 9 or derived via a line 20 as a relaxed gas according to line 22 into the environment or for further use.

The pressing or the partial pressing of the lock container 9 can also be advantageous backwards through the filter 17 (not shown). For this purpose, the valve to the line 18 (as generally when pressed) is closed. Backwash gas, which is used, for example, to supply 6 and 10, is used to clean the filter 17, wherein the gas then passes through the line 15 for covering the lock container.

The discharge line for the dust is designated 16, via which the dust can be disposed of after pressure equalization.

The operation of the system is explained below with the aid of a filtering separator. However, all types of separators requiring cyclic or occasional gas cleaning are covered by this invention:

The pressurized crude gas containing the fly ash is fed into the filter 2. You get a Dusted synthesis gas 3 and fly ash, the latter being temporarily stored in the collecting space 5. The collecting space 5 is characterized by a conical shape, which opens into the connecting line 8 to the lock container 9. In the conical region of the collecting space fluidizing or loosening devices 7 are provided according to the prior art, to allow the discharge of the ash in the lock container. The fluidizing or loosening devices 7 are operated with gaseous carbon dioxide 6. The collecting chamber 5 may be geometrically integrated into both the lower part of the container of the filter housing or consist of a separate constantly connected to the filter container. In the latter case, the lower part of the filter housing is also provided with fluidizing and loosening devices to assist the transport of the fly ash into the collecting space. In the first case, in which collecting chamber and filter housing form a geometric unit, it is generally sufficient to provide fluidizing and loosening devices in the lower part in or near the conical region.

If the fly ash is to be transferred from the collecting space 5 into the lock container 9, loosening gas is added and the connecting line 8 is opened. The lock container is for this purpose at the same pressure level as the filter 2 and collecting chamber 5. In order that the gas displaced by the ash guided into the lock container can escape, it is advantageous to provide a compensation line 12 with the filter 2 or the collecting space. The equalizing line 12 may also be for discharging the displaced gas to another destination, such as e.g. another container, another filter, etc.

In principle, however, it has proved to be advantageous to displace the displaced gas into the solids-transmitting container. recirculate. The volume released in the sending container by the leaking solid must be replaced with gas in order to achieve pressure maintenance. In the use of carbon dioxide according to the invention as a loosening gas and as a filling gas of the lock container, a return of the gas displaced in the lock container 9 is advantageous because there are inevitably raw gas portions in the voids volume of the fly ash charge. These are transported with transfer of the fly ash in the lock container and mix there at least partially with the displaced gas, so this contains fractions of raw gas, the return partially via the compensation line back into the raw gas chamber of the filter 2 and 5 of the collecting space.

As with all filtering dust collectors, a dust cake builds up on the filter elements in the course of cleaning the raw gas. If this reaches a predetermined thickness, defined by the pressure loss, which increases in accordance with the filter cake layer thickness, a cleaning of the filter elements 4 by backwashing is performed. The filter elements 4 can be acted upon individually or in groups with a backwash gas 13, 14. This flows counter to the filter direction through the filter elements 4 and provides with a corresponding pulse for the replacement of the filter cake.

Once the fly ash has been transferred to the lock container, equalization line 12 and connecting line 8 are closed and decoupled from the filter and collecting space. The filled lock container 9 is expanded to a lower pressure level, which is sufficient to carry out the further method steps, the expansion gas is discharged 15. A portion of the expanded gas 15 is passed through a filter 17 in a buffer tank 21 intermediate. saved. The rest of the expansion gas 20 is removed.

The use of at least one buffer tank 21 is particularly advantageous because it allows a portion of the gas 18 expanded from the lock 9 to be used again for partial covering 19 of the lock after emptying. As a result, the amount of gas to be discharged, consisting of carbon dioxide-containing gas and raw gas components, is reduced.

Another advantage of the buffer tank is equalization of the flash gas quantities. In the classic approach of BehälterentSpannung occurs at the beginning of the highest mass flow, which is smaller with decreasing tank pressure. Since, as described, inevitably small amounts of raw gas constituents are present in the gas to be expanded, the expansion gas must be supplied for proper use or disposal. In practice, this type of gas is usually supplied to combustion. Through the buffer container, it is possible to gradually equalize the amount of gas removed, which allows optimized operation of the combustion device.

The fly ash is transferred from the lock container 9 for further handling. For this purpose, fluidizing and loosening devices 11 are located in the outlet area of the lock container 9 as well as in the collecting space 5 in order to facilitate the transfer of the fly ash. The loosening and fluidization takes place with carbon dioxide 10. After the lock container is emptied it must be brought back to the pressure level of the filter 2 and the collecting chamber 5 to accommodate the next stored in the collection chamber 5 batch fly ash. With the help of the stored gas in the buffer tank 21 19 of the lock container partially covered. The pressing of the lock container to the required operating pressure is effected by further addition of carbon dioxide 10, for example via the fluidizing and loosening devices 11 of the lock container 9 or via additional supply devices, such as those provided for the supply of the stored gas 19.

The further process steps to which the fly ash is subjected may be, for example, the return to the gasification process or the treatment for storage or disposal. In the latter case, care must be taken to remove the raw gas components that are inevitably still in the void volume of the fly ash. For this purpose, for example, US 4,838,898 A and US 2007/0084117 A1 describe processes which liberate the fly ash separated from a synthesis gas in a plurality of process steps from the remaining crude gas constituents.

Example:

The isenthalpic relaxation of carbon dioxide, as occurs, for example, in valves, reducing elements or perforated disks, in the case of carbon dioxide a significant decrease in temperature result.

For example, carbon dioxide is released from state 1 with pl = 50 bar and Tl = 150 ⁰ C to state 2 with p2 = 2 bar, resulting in a temperature of T2 = 126, 7 ° C. If nitrogen were used, the temperature would be T2 (N2) = 146, 4 ° C, assuming the same state change. In order to ensure a temperature of 150 ⁰ C, the carbon dioxide must be preheated at pl = 50 bar to about 170 ⁰ C. If a period of a temperature T = 80 ⁰ C, would be at Anson - li ¬

set the same relaxation a temperature T2 = 40.7 ⁰ C, which would be in the case of nitrogen T2 (N2) = 73, 6 ⁰ C.

The above example is selected from the range of typical operating parameters, as they occur when stringing the lock container.

The examples illustrate that when using carbon dioxide compared to nitrogen, the temperature of the carbon dioxide used must be adjusted by preheating in order to compensate for the cooling effect in the throttling. This is necessary in order to be able to meet the required process temperatures and not to exceed the permissible temperature gradients, for example via the filter elements and the loosening devices.

According to the invention, the carbon dioxide or carbon dioxide-containing gas used for cleaning the filter elements is preheated to the point where, after expansion to operating pressure (of the filter), it has a temperature which is above the boundary to the two-phase region. At the same time, the carbon dioxide or the carbon dioxide-containing gas should advantageously after relaxation have a temperature which is above the condensation temperature of the raw gas components.

The same requirements apply in the area of fluidizing and loosening elements, for the operation of which the carbon dioxide or carbon dioxide-containing gas used must be expanded. Likewise, the preheating of the carbon dioxide or the carbon dioxide-containing gas must take place so far that its temperature during and during the covering of the lock container is above the boundary to the two-phase region. Reference list:

1 raw gas

2 filters, dust collector

3 dedusted raw gas

4 filter elements

5 collection room

6 feed line for CO ₂ or CO ₂ -containing gas

7 fluidizing device

8 connection line

9 lock container

10 feed line for CO ₂ or CO ₂ -containing gas

11 fluidizing device

12 equalizing line

13 gas supply line

14 backwash lines

15 expansion gas line

16 discharge management

17 relaxation gas filter

18 Relaxed gas

19 recycle gas

20 Relaxed gas

21 buffer tank

22 Relaxed gas

Claims

Claims:

1. A method for discharging the resulting in the operation of a dedusting system for raw gas dust from the pressure gasification using a dust collector with at least one associated lock container, characterized in that in the dust filter elements are positioned backwashed by means of a carbon dioxide-containing gas or pure CO ₂ -GaS become.

2. The method according to claim 1, characterized in that the C0 ₂ -containing backwash gas is preheated.

3. The method according to claim 1 or 2, characterized in that the CO ₂ -containing backwashing gas is used for fluidizing and loosening the fly ash in the dust collector.

4. The method according to any one of the preceding claims, characterized in that the CO ₂ -containing backwashing gas is used for covering the lock container.

5. The method according to claim 4, characterized in that the CO ₂ -containing backwashing gas is used for loosening the dust in the lock container.

6. The method according to claim 4 or 5, characterized that the CO ₂ -containing gas is supplied by externally heated supply lines to the place of its use.

7. The method according to any one of the preceding claims, characterized in that the gas discharged from the lock container gas is supplied to a dedusting device.

8. The method according to any one of the preceding claims, characterized in that the dedusted, withdrawn from the lock tank gas is fed to an intermediate buffer and at least partially used as a gas for performing one of the preceding method steps.