CN104334285A

CN104334285A - Centrifugal separator

Info

Publication number: CN104334285A
Application number: CN201380013225.4A
Authority: CN
Inventors: 拉尔夫·亚伯拉罕; 多布林·托波罗夫; 多梅尼科·帕沃内
Original assignee: ThyssenKrupp Industrial Solutions AG
Current assignee: ThyssenKrupp Industrial Solutions AG
Priority date: 2012-03-07
Filing date: 2013-02-25
Publication date: 2015-02-04
Anticipated expiration: 2033-02-25
Also published as: PL2822694T3; EP2822694B1; ES2887334T3; PT2822694T; EP2822694A1; WO2013131768A1; CN104334285B; DE102012004590A1; DK2822694T3; TW201347851A; RU2014137999A

Abstract

With a method and also a device for optimizing a centrifugal separator, in particular a recirculation cyclone in a high-temperature gasifier, the degree of separation of a centrifugal separator is to be markedly increased. This is achieved in terms of the method in that, via internals on the descender tube of the centrifugal separator, a local increase in the centrifugal force is performed.

Description

Whizzer

Technical field

The present invention relates to a kind of method for optimizing whizzer, being specially adapted to the recirculation cyclone (separator) in high-temperature gasification stove.

Background technology

The various designs of whizzer are known.Such as, DE10346692 A1 shows liquid drop separator, and it is positioned at the outer rotating vane placed of dip pipe end having to the transition position in hopper region, to realize the rotation of inlet air flow at hopper place.The cyclone separator that can be unlocked and close is illustrated by such as DE10205981 A1, and DE19516817 C1 shows the cyclone separator with additional element such as sparking electrode.

High-temperature gasification stove is developed the utilization in order to improve brown coal, such as, by means of fluidized bed gasifying process, by being used as the so-called high temperature Winkler (HTW further developed of Winkler coal gasification, High-Temperature Winkler) gasification furnace, wherein Winkler coal gasification is run at atmosheric pressure originally.Advantage is mainly to utilize raw material better, provides larger gasification furnace capacity and avoid the formation of accessory substance for large-scale plant.

The shortcoming of this process, one is the separative efficiency of recirculation cyclone separator is not remarkable especially, and this causes the hot gas filter that must provide cost-intensive in the downstream of this cyclone separator and unstrpped gas cooler.Another serious factor is that the dust being deposited on hot gas filter still contains a large amount of carbon.Thus this dust can not be sent to waste landfills field, and must or be returned to gasification furnace by pipeline and auger conveyor or be burned at considerable cost by means of auxiliary fuel in a separate container.

Summary of the invention

This is the origin that the present invention is contemplated, and its target is the separation degree increasing whizzer significantly, is particularly useful for the recirculating gas rotary separator in high-temperature gasification stove.

By means of in these referenced at the beginning class methods, according to a modified example of the present invention, this target is implemented by increasing the local of the centrifugal force that the internals of the dip pipe by whizzer is implemented.

In order to increase the separation capacity of cyclone separator, the method be suggested is that mobile dip pipe is inner to " dead water region (dead water region) ", and namely dip pipe is inlaid in cyclone separator prejudicially.This measure only has economic implications when newly-built cyclone separator.Transformation and the follow-up optimization carried out therefrom, can not realize in this way and economically.In contrast, the internals of dip pipe can by being reequiped without any problem.

According to the present invention, for the feasible modified example optimizing object is by arranging knockouts in the upstream of this cyclone separator entrance area, and mechanically increase the size of particle to be separated.Knockouts has the effect affecting particle size, and this realizes by improving collision rate between bulky grain and granule at the entrance area of cyclone separator, this significantly improves separation degree.Knockouts is known substantially, such as, in DE 19815976 A1, have the description about this respect.

Because cyclone separator only can run best under the running status of harshness customization, such as, when there being dust, the best tangential inlet speed entering cyclone separator is 10 meter per seconds, and when load changes, its runnability has fluctuation.By changing the cross section of whizzer entrance, this is the origin that the present invention is contemplated to optimize this cyclone separator, and it is possible for changing its cross section in a completely different way, as rear further specifically described.

The desin speed that the changeability of cross section achieves this cyclone separator is always kept constant effect.

In modified embodiment, according to the present invention, the aforementioned method step mentioned side by side is implemented.

In order to realize described target, present invention also offers device or whizzer, they are significantly different based on following characteristics: the diversion member for the fluid passage of narrowing this whizzer is provided at dip pipe place.As offered by the present invention, this element being used for narrowing fluid can be formed dish type dividing plate.

In order to realize the special fluid optimized, according to the present invention, also can provide eccentric at this, dish type dividing plate, it is arranged on the perimeter of this dip pipe roughly relative with gas access, this dividing plate is stretched to below the lower edge of gas entrance passage, and subsequently towards the lower end of this dip pipe, again narrow the tubular form into tapered manner.The position of dividing plate also can change according to the design of whizzer.

In order to realize the size mechanically increasing particle, knockouts according to the present invention is formed by the multiple tubular fluid interfering components through fluid passage, and it is arranged on the porch of whizzer.These tubular fluid interfering components can by level, vertical or be inlaid in fluid passage with unspecified angle.

As already described above, in order to the desin speed of whizzer can be kept constant, even if when load is vicissitudinous, in further modified embodiment, present invention also offers inlet fluid passage and be equipped with moveable metope or ceramic sliding, to change the cross section of this passage, improvement project may comprise: the moveable metope of horizontal or vertical direction is formed slide plate or wall unit, and it is arc in the region being transitioned into centrifuge.

Accompanying drawing explanation

Further aspect of the present invention, details and advantage are launched hereinafter with reference to accompanying drawing, wherein

Fig. 1 shows the rough schematic view of high temperature Winkler gasification furnace, and

Fig. 2-7 shows the rough schematic view of the whizzer of the internals with different alter.

Detailed description of the invention

In FIG, high temperature Winkler gasification system is displayed in simplified form, and charging is transported to gasification furnace 1 by it mode comprised by means of basin 2.Such as by means of auger conveyor 4, the product of bottom is discharged at tower bottom 3 place.Gas is processed in whizzer 5, and solid particle is returned in gasification furnace 1 by pipeline 6; This gas is transferred away for further PROCESS FOR TREATMENT by pipeline 7.

The modified example of the mode that the fluid in whizzer 5 is affected is shown in figures 2-7 which.

The mixture that Fig. 2 shows solid and gas is fed (arrow 8) in whizzer 5, and this mixture flows around dip pipe 9.

In order to accelerating fluid, dip pipe 9 has diversion member 10, and it is soldered on dip pipe 9 or in other certain modes as bending dividing plate and is fixed on dip pipe 9.As shown in Figure 2, dividing plate 10 is tapered, indicates lower region thereof by 10a, and in this way, the original cross-sectional of fluid passage touches again in the end of this dip pipe 9.Cleaned gas leaves whizzer 5 by conduit 7, and it is indicated by arrow 11.Solid particle leaves this separator facing downward, and this is indicated by arrow 12.

In fig. 2, the dividing plate 10 with taper 10a is reproduced in precalculated position, to provide better characteristics.This must not correspond to its actual mounted position.

In accompanying drawing below, structurally identical all elements all indicate with identical Reference numeral, and have similar arrow instruction.

With Fig. 2 unlike, in the exemplary embodiment shown in Fig. 3, tubular fluid interfering component 15 is inlaid in the knockouts indicated by 13 with formation in the access road 14 of whizzer 5, these elements not only can be flatly, as at this show, and can vertically or diagonal be positioned in access road 14, this is possible.

In the exemplary embodiment shown in Fig. 4, the cross section entering the access road 14 of whizzer 5 can be changed by the barrier element that can rise or can decline or ceramic sliding 16.This motion mode is indicated by double-head arrow 17.

Presented in Figure 5 is that the cross section of the access road 14 allowing whizzer 5 can reformed modified example, and particularly by can to rise and the base plate that can decline changes, be formed ceramic wafer such as equally, it is denoted as 18; The possibility of motion mode is indicated by double-head arrow 19.

In figure 6, be denoted as the ceramic wafer of 20 at this, for changing described cross section, it can vertically pivotable, and this is indicated by double-headed arrow 21.

Finally, Fig. 7 also show the possibility of the cross section being reduced the admittance area entering whizzer 5 by plate 22, and it is suitable for the wall of the curved shape of separator; This motion mode is indicated by double-head arrow 23.

As front further statement ground, various measure also can be implemented in combination, such as, in order to provide the possibility of only a kind of modified example, in conjunction with knockouts 13 and flow baffle 10,10a, narrowed the cross section of access road 14 by corresponding ceramic wafer 18,20 or 22 simultaneously.

Reference numeral:

1 gasification furnace

2 storage tanks

3 tower bottom product discharge portions

4 helical feed portion

5 whizzers

6,7 pipelines

8,11,12 arrows

9 dip pipes

10,10a flow baffle

13 knockouts

14 access roades

15 flow interference elements

16 ceramic sliding

17,19,21,23 double-head arrows

18,20,22 ceramic wafers

Claims

1. for optimizing the method for whizzer, being specially adapted to the recirculating gas rotary separator in high temperature gasifier, it is characterized in that, the local of centrifugal force increases implements by means of the internals of the dip pipe of described whizzer.

2. for optimizing the method for whizzer, be specially adapted to the recirculating gas rotary separator in high temperature gasifier, it is characterized in that, mechanically increase particle size to be separated and knockouts is set by the upstream of the entrance area at described whizzer implements.

3. for optimizing the method for whizzer, being specially adapted to the recirculating gas rotary separator in high temperature gasifier, it is characterized in that, the variable change of entrance cross-section is implemented in described whizzer porch.

4. for optimizing the method for whizzer, being specially adapted to the recirculating gas rotary separator in high temperature gasifier, it is characterized in that, the multiple method steps as described in claim 1-3 are implemented simultaneously.

5. for implementing the device of particularly the method for claim 1, it is characterized in that, being provided at dip pipe (9) place for the diversion member (10) narrowing the fluid passage of described whizzer (5).

6. device according to claim 5, is characterized in that, the dish type dividing plate (10) for narrowing described fluid passage is provided at the perimeter of described dip pipe (9).

7. device according to claim 6, it is characterized in that, eccentric, dish type dividing plate (10) is arranged on the perimeter of the described dip pipe (9) roughly relative with gas access, described dividing plate (10) is stretched under the lower edge of access road (14), and subsequently towards the bottom of described dip pipe, again narrow the tubulose into tapered manner.

8. for implementing the device of particularly method as claimed in claim 2, it is characterized in that, be made up of the flow interference element of the multiple tubuloses through described fluid passage at the described knockouts (13) at access road (14) place of described whizzer (5).

9., for implementing the device of particularly method as claimed in claim 3, it is characterized in that, described access road (14) is equipped with moveable metope or ceramic sliding (16), for changing the cross section of passage.

10. device according to claim 9, it is characterized in that, the moveable metope of horizontal or vertical direction (16,18,20) is formed slide plate or wall unit (22), and it is arc in the region being transitioned into described whizzer.