DE1276598B - Plant for drying and cooling hot lignite - Google Patents

Description

Plant for drying and cooling hot lignite The invention relates to a further training of the plant for drying and cooling hot lignite after Patent application M 54775 VI b / 10 b (German Auslegeschrift 1206 388), according to a known tube dryer with a known, operated with warm air Fluidized bed dryer for rapid de-aerating and post-oxidation of the tube dryer discharged dry coal is combined.

Serves to move the dry material over the fluidized bed floor according to the main patent application a mechanical conveying element with which the dwell time and the continuous discharge of the dry coal on the fluidized bed floor is regulated is.

Such a conveyor element, for example designed as a chain drive must go through the fluidized bed box at the front and rear ends of the fluidized bed floor be passed through. The required seal is difficult and only to solve at great expense. In addition, mechanically moving parts always represent a failure-prone operation. The invention is based on the object to dispense with mechanical conveying elements arranged above the fluidized bed floor.

This object is achieved according to the invention in that for continuous Deduction of the coal desrassed on the fluidized bed floor via a level indicator arranged for the fluidized bed speed-controlled air seal and discharge organ is.

In this way, the bed height of the fluidized bed can be regulated the dwell time of the dry coal required for cooling on the fluidized bed floor can be adjusted in a simple manner, with a separate seal being omitted. That which is made flowable in the area of the fluidized bed floor, the discharge organ Dry material flowing in takes place in the space behind the fluidized bed floor reverts to the character of a bulk material. Through this change in the good state in connection with the discharge organ it is guaranteed that with a good airtight Conclusion of the dryer failure, a constant, regulated outflow of good particles the fluidized bed takes place towards the discharge organ.

Speed-controlled discharge devices and cooling devices are per se known in lignite briquette factories. However, this can only be used for the The amount and not the residence time of the dry coal within the cooling device is regulated will. Since the speed of a tube dryer always corresponds to the initial water content of the must be adapted to the raw lignite to be dried, the amount emerging from the dryer fluctuates Amount of dry coal continuously. But the outlet organ of the must have these fluctuations Automatically follow fluidized bed to avoid overfilling or emptying of the fluidized bed floor to avoid. This measure and in particular the requirement for a precisely measured one The bed height of the fluidized bed cannot be achieved with the known discharge device to be met.

The withdrawal capacity of the host organ should now be more advantageous automatically adjust so that the thickness of the dry carbon layer above the fluidized bed floor commutes up and down within two limits. To this end, the invention also proposed that two level indicators above the fluidized bed floor are arranged such that a previously precisely determined upper and lower layer height automatically adjusts the de-carbonated coal on the fluidized bed floor. One Such a device has the additional advantage that it is also airtight Closure between the dryer failure housing and the one receiving the dry coal Abförderorgan guaranteed below the tube dryer without additional equipment will. Either a screw conveyor or a chain conveyor can be used as the discharge device to be used. It is also proposed according to the invention that the air seal and discharge organ is designed as a cell lock on which a discharge chute is connected, which is in the screw box of the discharge screw flows out. Instead of the cell lock can also be connected to the fluidized bed floor Connect a discharge shaft, which is in the screw box as an air seal and Discharge organ trained discharge screw opens, the dropout with the screw box the conveyor screw is connected. Through these two discharge devices is An airtight seal between the dryer failure and the discharge unit is guaranteed at all times, at the same time there is always a minimum bed height of the fluidized bed above the fluidized bed bottom is available.

Another advantage of the invention is seen in the fact that the discharge from the failure housing only by an element with a rotating drive, i.e. one Star wheel or a screw conveyor, is accomplished. This becomes a low wear and a very simple mode of operation is achieved.

Three exemplary embodiments are shown schematically in the drawing, namely shows A b b. 1 the fluidized bed floor with a cellular wheel as the discharge device, A b b. 2 a fluidized bed base with a discharge screw as discharge element and A b b. 3 an inclined fluidized bed floor.

The A b b. 1 shows a tube dryer 1, in which the dried and hot brown coal falls into the lower part of the drop box 2. To the case 2 is followed by a further housing 3, which downwards through a porous Fluidized bed 4 is complete. The through the fluidized bed 4 to be pressed Air is sucked in by means of a fan 5 through the line 6 and via a Heating source 7 and the line 8 the individual air boxes 9 below the fluidized bed floor 4 supplied. The air passes through the air at a temperature of around 60 to 80 ° C Fluidized bed into the dry coal 10 lying on top and through it. The case 3 only has the opening 11 on one end face, to which the housing 12 is attached for the bucket wheel 13 connects. There is a discharge chute below the cellular wheel 14, which opens into the screw box 15 for the discharge screw 16.

So that within the housing 3 there is a lower and an upper layer thickness level is in both the end wall 17 of the housing 3 and in the cover plate 18 of the extended housing 12 each have a level indicator 19, 20 as a contact sensor arranged. Via a control line 21, the drive member, not shown, is for the cell wheel this mediates the respective speed, so that the previously described layer thickness sets and thus at the same time an airtight seal between opening 11 in housing 3 and discharge shaft 14 is reached.

A b b. 2 shows the rest of the same arrangement as A b b. 1. Only the discharge element for the coal that has already been de-carbonated is different here. Following the opening 11 in the end wall 17 of the housing 3, the discharge chute 14 connects, which opens into the screw box 22 of the discharge screw 23. The worm 23 is driven by a gear motor 24 and a clutch 25 . Here, too, the speed control of the geared motor 24 takes place via a line 21, which in turn receives its impulses from the two level indicators 19 and 20. The dropout 26 of the screw box 22 is. connected to the screw box 15 of the screw conveyor 16. With this arrangement, too, the up and down pendulous layer thickness of the dry coal ensures that the discharge chute 14 is filled with dry coal, there is a sufficiently high layer height and thus an airtight seal between housing 3 and conveyor screw 16 and sufficient cooling of the dry coal is effected. Instead of the discharge elements described, namely cellular wheel and discharge screw, any other discharge element can also be used, provided that it ensures the required airtight seal.

A b b. 3 shows essentially the same arrangement as A b b. 1 and 2, however, in this design, the discharge device is the dryer the downstream housing 3, namely the fluidized bed box, in the axial direction of the dryer arranged. Thus the flow of the dry coal is not like that of the Embodiments according to A b b. 1 and 2 opposite to the direction of rotation of the dryer and across the dryer axis, but in the direction of the dryer axis. Also is the fluidized bed floor 4 is provided with an incline that extends in a central floor opening 27 expires. The discharge shaft closes at this central bottom opening 27 14 at. Here, the bottom opening 27 can extend over the entire length of the housing 3. In this case, the discharge chute 14 and thus the discharge element 13 or 23 can also be made as long as the housing. It is also conceivable that the fluidized bed is inclined not only in one plane but in both planes is arranged so that it runs out in a central bottom opening. With this arrangement can then use the same discharge organs as in A b b. 1 and 2 described, to be ordered.

Above the opening 27 there is a roof-shaped attachment 28. This prevents the coal from flowing out through the bottom opening in an irregular amount. The level indicators 19 and 20 are mounted in a side wall 29 of the housing 3 and here again ensure that the fluidized bed height levels off. So that within the fluidized bed box 3 there is no different layer height above the porous plates of the fluidized bed base 4, the inclination can be made very small without losing its effect. An inclination of about 1 or 2 ° with respect to the horizontal would easily support the flow of coal from the fluidized bed floor to the discharge element. This also ensures that the coarse grain in the dry coal is removed at all times. So that the air supply in all areas of the dry coal 10 lying on the fluidized bed floor 4 is the same everywhere, 4 diaphragms can be installed in the raised edge zones 4 a of the fluidized bed floor 4, through which the air supply can be throttled.

The arrangement according to the invention of the entire discharge device offers yet another benefit. The vertical discharge chute 14, which is both laterally as well as below the housing 3 can be arranged, allowed in excellent Way the water content of the total amount of dry coal escaping from the housing 3 to be measured continuously according to the known DK method. The vertical discharge shaft 14, which is always filled with carbon, must be designed as an electrical capacitor will. Its readings are then used to determine the supply of wet coal to the To control the filling chute of the dryer.

Claims (7)

Claims: 1. Plant for drying and cooling hot lignite according to patent application M 54775 VIb / l0b, characterized in that for the continuous withdrawal of the coal (10) which is de-razed on the fluidized bed floor (4), an air seal and discharge element ( 13, 23) is arranged. 2. Plant according to claim 1, characterized in that that two level indicators (19, 20) above the fluidized bed floor (4) for scanning a predetermined upper and lower layer height of the de-carbonized coal (10) arranged are. 3. Plant according to claim 1, characterized in that the air seal and Discharge organ is designed as a cell lock (12, 13) on which there is a discharge shaft (14), which opens into the screw box (15) of the conveyor screw (16). 4. Plant according to claim 1, characterized in that a discharge chute (14) is connected to the fluidized bed (4) , which opens into the screw box (22) of a discharge screw (23) designed as an air seal and discharge element, whose Dropout (26) is connected to the screw box (15) of the conveyor screw (16). 5. Plant according to claim 1, characterized in that the opening (11) in the fluidized bed box for the connection of the exhaust element (12) in an end wall (17) is located. 6. Plant according to claim 1, characterized in that that the fluidized bed floor (4) has a trough-shaped inclination and a central floor opening (27) for the connection of the extraction element, the bottom opening (27) over the entire length of the fluidized bed box (3) and the discharge element is designed according to the bottom opening (27) of the fluidized bed box (3). 7. Plant according to claim 6, characterized in that the fluidized bed floor (4) is divided into several plates (4a) and to the higher lying porous fluidized bed floor plates (4a) guided air lines have apertures for throttling the air supply. Into consideration Printed publications: German Patent No. 575 743; »Chemical engineering technology«, 29th year, 1957, no. 7, p. 467 and No. 11, p. 748; K. Kegel, »Preparation and Briquetting«, Vol. IV, part 1, "Briquetting of brown coal", Halle 1948, p. 116.