DE102011083210B4 - Apparatus and method for pneumatically conveying dusts with a reduced amount of fluidizing gas - Google Patents

Abstract

The invention relates to an improved technical solution for the pneumatic conveying of fine-grained solid fuels from a fluidized bed. It is characteristic that gas volumes are withdrawn on the way of conveying and thus the specific solids content in the gas-solid suspension is increased. This allows the conveying density to be increased. This increases the funding efficiency. It is possible to reuse or reuse the withdrawn gas volumes, which reduces the specific media consumption of the delivery system but also of the entire system (e.g. gasification or combustion system).

Description

The invention relates to an apparatus and a method for the pneumatic conveying of fluidized solid suspensions with a reduced, the customer supplied amount of fluidizing gas.

The invention relates to a reduction of the specific transport gas content in gas-solid suspensions in pneumatically operated dust extraction systems, which are operated out of a fluidized bed, with the features of the first claim. In particular, the invention relates to an improved technology for the pneumatic conveying of fuel dusts from a fluidized bed, which aims to minimize the specific gas content in the conveyed suspension until reaching the end point of the transport arrangement. Such an end point of the promotion is, for example, the burner mouth of a gasification fuel burner of an entrainment gasifier. The main apparatus of the method is a pressurized delivery container in which the fuel to be delivered is held by means of a uniformly over the surface of a fluidized bed upwardly flowing gas volume in a fluidized bed. The fluidizing gas in the majority of applications is an inert gas. In the fluidized bed formed protrudes according to the demands made on the conveyor system requirements to be defined number of conveying pipes whose inlet opening (s) are in the range of fluidized by the fluidized bed dust. The throughput of the gas-solid suspension can be regulated by way of a controllable pressure difference between the delivery container and the delivery target. Dust feed systems according to this basic mode of operation are known, for example, from the following patent and utility model publications: DE 10 2008 049 542 A1 . DE 20 2005 021 660 U1 . DE 20 2006 020 601 U1 ,

The amount of gas required to fluidize a combustible dust is a function of its density, the size distribution present, and the grain shapes within the bed. At the point of free flow, a suspension density is established with which the fuel dust can then be conveyed via a pressure difference, similar to a liquid.

In the case of specifically particularly light fuel dusts, as given for example by pulverized biomasses or lignite coal, there is a technically and economically unfavorable ratio of transported fuel mass and conveying gas volume within the suspension, which progressively unfavorably designed with increasing pressure. It turns a low delivery density. The reason for this is the increasing density of the gas volume associated with increasing operating pressure in relation to the constant density of the solid and the absolutely increasing specific gas requirement for conveying purposes. On the other hand, a low transport density is advantageous for reasons of the specifically low pressure loss over the run length of the delivery line.

The invention is based on the object to increase the efficiency of a pneumatic conveying system.

The object is achieved by a device having the features of claim 1 and a method having the features of claim 12.

According to the invention it is proposed to remove a portion of the gas volume contained in the suspension after overcoming the main part of the conveying path or at the end of the conveying path from the feed line again. The solids transport is then realized over a short line section with a higher conveying density. Then prevailing, specifically higher pressure losses affect absolutely in the tolerable range because of the short remaining travel of the delivery line. The advantage of this solution is the exploitation of the advantages of a low delivery density in terms of low pressure drop in the flow and yet minimized supply of inert gas in the reaction chamber of the carburetor. Furthermore, the gas volume withdrawn from the delivery line can be supplied for reuse and is therefore not to be regarded as media consumption in the media balance of the overall arrangement. The proportion of the conveying gas in the feed to the end user is reduced, wherein the efficiency of the gasifier is increased by reducing the registered inert gas volume. By applying the invention, therefore, an improvement in the efficiency of the entire system fuel feed / carburetor is achieved. The product produced by the consumer of the fluidized-solids suspension, such as the raw gas produced by an entrained flow gasifier, is loaded with only a reduced amount of conveying gas.

Advantageous developments are specified in the subclaims.

The invention will be explained below as an exemplary embodiment in a scope necessary for understanding with reference to two figures.

In the figures, like names denote like elements.

In the application example, there is the task of supplying thermally treated and pulverized biomass to an entrained-flow gasifier. The required Mass flow of fuel is 53 · 10 ³ kg / h. 1 schematically illustrates the interconnection of the systems.

The fuel dust is introduced into the delivery tank via an entry system 1 fed. There is the inert gas stream 21 supplied to the fluidized bed as fluidizing gas with the fuel dust 7 to build. The air flow gasifier 6 has an operating pressure of 3.5 x 10 ⁶ Pa. As differential pressure P2 - P1 between reactor 6 and bucket 1 should be set for the pumped fuel mass flow 6 · 10 ⁵ Pa. The delivery tank 1 thus operates at 4.1 · 10 ⁶ Pa. In this example, the conveyor system has three identically designed conveyor lines 2 . 3 and 4 with a nominal diameter of DN 65.

The bulk density of the fuel is 235 kg / m ³ , the density of the flowable suspension 7 has been determined to be 139 kg / m ³ . As a conveying gas 21 Nitrogen is used at a temperature of 50 ° C for use. The flow velocity of the gas-solid suspension is about 10.5 m / s in each of the three delivery pipes. This flow rate is determined by measurements S1A, S2A and S3A.

It is desirable that the bulk density of the material to be transported the highest possible, producible with reasonable effort Brennstoffeintragsdichte in Flugstromvergaser 6 over the gasification fuel burner 5 represents. Consequently, the gas-solid suspension contains around 5180 Nm ³ / h of nitrogen, based on the considered load case, which would be introduced into the gasifier as an inert gas volume. To reduce this volume flow, the delivery lines 2 . 3 and 4 with the gas sampling elements 8th . 9 and 10 as well as the recoveries 11 . 12 and 13 equipped.

The gas sampling elements 8th . 9 and 10 are formed by a gas-permeable continuation of the delivery line (DN65), which is surrounded by a gas-tight, pressure-bearing jacket and forms a gap with this. Via the connected cables 14 . 15 and 16 can under throttling the control valves 17 . 18 and 19 a gas stream 20 (Sum) are taken. The Elements 8th . 9 and 10 because of their design they filter, the current 20 can therefore be considered as little to no dust-laden.

It is an actual feed density of the suspension of 170 kg / m ³ sought. This will be over power 20 about 2310 Nm ³ / h nitrogen taken. This raises the density of the suspension to the desired value, but at the same time reduces its operating volume flow and thus the flow velocity. In order not to drop these, the nominal diameter of the delivery line will be from collection 11 . 12 and 13 reduced to DN50.

As a controlled variable for the amount of gas removed from the delivery line 20 (Sum) serves in this example to increase the flow velocity SD1, SD2 and SD3 in the production pipe 2 . 3 and 4 , which is formed as a difference S1B - S1A, S2B - S2A and S3B - S3A. The flow is increased in the present case to about 14.7 m / s. There is therefore no risk that the flow comes to a standstill.

As dust gas accompanying the gasification reactor 2870 Nm ³ / h of nitrogen are fed. This means a reduction of the inert gas load to 55.4% of the original value.

1 shows the schematic structure of the dust injection system according to the invention using the increase in the flow velocity in the delivery line as a controlled variable for the amount of gas to be removed.

2 represents the re-integration of the withdrawn gas volume flow 20 into the overall process. This is the current 20 a buffer tank 23 supplied by means of compressor 24 recompressed and the buffer volume 25 fed. From buffer 25 will be the provision of fluidizing gas 21 realized. To cover the total gas demand of the stream 21 is an external make-up 26 for buffers 25 intended.

The invention also relates to a method for the continuous pneumatic conveying of fine-grained solid fuels from the state of fluidization in a fluidized bed, according to which the promotion takes place in any number of delivery lines, are taken from each of the delivery lines conveyor gas volumes regulated and the density of the gas-solid -Suspension on the way of the conveyor line increases.

In a particular embodiment of the invention, the delivery target is an apparatus for gasification of the subsidized fuel.

In a particular embodiment of the invention, the delivery target is an apparatus for combustion of the subsidized fuel.

In a particular embodiment of the invention, the gas is removed from the delivery line at one or more point (s) along their entire run length.

In a particular embodiment of the invention, the gas is removed from the delivery line at the end of the delivery line.

In a particular embodiment of the invention, a return of the gases removed from the conveyor system for reuse in the pneumatic conveying process is realized.

In a particular embodiment of the invention, the withdrawn gas volume undergoes compression before returning to the pneumatic conveying process.

In a particular embodiment of the invention, the conveying gas is a gas without free oxygen and without condensable constituents.

In a particular embodiment of the invention, the conveying gas is nitrogen, carbon dioxide but also combustible gases such as natural gas, synthesis gas or residual gases of a synthesis.

In a particular embodiment of the invention, the withdrawn gas volume is at least partially used for rinsing in Flugstromvergaser.

In a particular embodiment of the invention, an individual control of the removal amount is realized for each withdrawal line.

In a particular embodiment of the invention, the extraction lines are combined in a manifold, wherein the regulation of the withdrawn gas volume is realized in this as a sum.

LIST OF REFERENCE NUMBERS

1

transport container

2

delivery line

3

delivery line

4

delivery line

5

Gasification fuel burners

6

Entrained flow gasification reactor

7

homogeneous fluidized bed

8th

Gas sampling element

9

Gas sampling element

10

Gas sampling element

11

Confiscation in the promotion line

12

Confiscation in the promotion line

13

Confiscation in the promotion line

14

Gas extraction line

15

Gas extraction line

16

Gas extraction line

17

Control valve for gas extraction

18

Control valve for gas extraction

19

Control valve for gas extraction

20

Total flow taken gas volume

21

Vortex gas supply

22

Raw gas outlet of the carburetor 6

23

Intermediate buffer tank

24

rear compressor

25

Main buffer tank

26

external gas supply to main buffer tank 25

Claims (13)

Device for the pneumatic conveying of fluidized solid suspensions with a reduced, the customer ( 5 ) supplied amount of fluidizing gas in the, - a metering vessel ( 1 ) a connection ( 21 ) for supplying fluidizing gas, - the inlet of a delivery line ( 2 ) in a fluidized bed ( 7 ) is immersed in the dosing vessel, - the delivery line a sampling point ( 10 ) for discharging fluidizing gas separated from the solid. Apparatus according to claim 1, characterized in that the delivery line to the sampling point a reduced cross-section ( 13 ) having. Device according to one of the preceding claims, characterized in that the removal point is arranged in the vicinity of the pickup. Device according to one of the preceding claims, characterized in that the removal point is arranged at the end of the conveying line. Device according to one of the preceding claims, characterized in that the removal point is formed with a filter element, which continues the solid in the delivery line and fluidizing gas separated from the sampling point. Device according to one of the preceding claims, characterized in that with the removal point a control valve ( 19 ) is connected to control the flow of fluidizing gas, which is withdrawn from the sampling point. Device according to one of the preceding claims, characterized in that the purchaser a gasification device ( 6 ), in particular entrained flow gasification device, for the gasification of carbon-containing fuel dusts under multiple atmospheric pressure. Device according to one of the preceding claims, characterized in that the metering vessel, the delivery line, the removal point, a backcomer ( 24 ) and a buffer tank ( 25 ) form a circuit for the fluidizing gas. Device according to one of the preceding claims, characterized in that a plurality of removal points are arranged in the delivery line. Device according to one of the preceding claims, characterized in that between the metering vessel and the recipient a plurality of delivery lines ( 2 . 3 . 4 ) with respective withdrawal points ( 10 . 9 . 8th ) are arranged. Device according to one of the preceding claims, characterized in that the withdrawal lines ( 16 . 15 . 14 ) of several delivery lines ( 2 . 3 . 4 ) to a manifold ( 20 ) are summarized and the regulation of the current to be taken in fluidizing gas is realized in this sum. Process for the continuous pneumatic conveying of fine-grained solid fuels out of the state of fluidization in a fluidized bed, according to which the delivery takes place in any number of delivery lines, are taken from each of the delivery lines regulated gas volumes and the density of the gas-solid suspension over the way the conveyor line increases. A method according to claim 12, characterized in that the flow velocity in the feed line is used as a controlled variable for the current to be removed to fluidizing gas.

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