DE667695C - Process and device for cooling and degassing dried brown coal - Google Patents

Description

Method and device for cooling and degassing of dried Brown coal The invention relates to an advantageous development of a Process for cooling and post-drying of dried brown coal. After this, well-known The dry coal is moved in cocurrent or countercurrent with the cooling air passed through a rotating drum with trickle fittings. The cooling air comes in at one end of the rotary drum in .dies and leaves the drum at the other end.

The direct current process is suitable for a coal that except. a large proportion of dust and the finest grains, comparatively little medium and contains even less coarser grain. The countercurrent process, on the other hand, is special suitable for a coal that contains only negligibly fine grain and dust, while the predominant part has a coarser grain of approximately the same size.

There is also a device for drying known in which the heating gas fed into the drum from both ends through tapered inlets and distributed over the entire length of the drum and through a series of over the whole Outlet slots distributed along the length of the shell are sucked out of the drum again. Included the heating gas does not migrate through the entire length of the drum, but measures the interior space the drum mainly transversely to the longitudinal axis. The entire dry material wanders through the entire length of the drum without escaping through the drum shell at any point to be able to.

Furthermore, a device is known in which the heating gas the drying drum, entering from one end, crosses the entire length of the drum and at the other end is sucked off, while the drying drum jacket is approximately in the middle of the sieve outlets has, through which only an exit of dry material, but not of heating gas can be done.

A drying drum is also known, the sieve outlets in the drum shell contains, from which in turn only dry material, but not heating gas escapes.

The method according to the invention differs from the known one Method in that, in one operation, the goods to be cooled are simultaneously in direct current and is passed through the drum in countercurrent to the cooling air.

Since the outlet temperature of the cooled coal is often only slightly differs from the temperature of the available cooling air, has the direct current method the economic disadvantage that it requires very large amounts of cooling air. That again has much larger and correspondingly more expensive rotary drums as a condition and also requires correspondingly larger dedusting systems for the cooling air. The larger amounts of air continue to have a greater air speed result. Therefore, larger amounts of dust are also removed from the drum by the cooling air carried away.

On the other hand, however, the cocurrent process has compared to the countercurrent process the advantage within certain grain boundaries of more even cooling and de-abrasion . of the different grain sizes, because the finer grain is carried by the air flow in the Conveying direction is conveyed faster than the coarser and therefore shorter time in the drum remains, while the finest grain, held self-floating by the air flow, is removed from the drum in a fraction of the time. For the coarser grains, on which the air flow has practically no influence at the low speed exercises more, these advantages of the 'direct current method no longer apply.

The sole application of the countercurrent process for a coal of different grain sizes but has the disadvantage that the finest grain particles are floating in the air and also the fine particles that are easily carried away by the air already at the coal incidence end of the drum from the already heated cooling air be discharged immediately, without these coal particles at all in the rotating drum had arrived.

The method according to the invention avoids these disadvantages in that that in one operation at the same time the cocurrent process and the countercurrent process be applied. In the first part of the rotating drum, the direct current method is used used because the temperature difference is still sufficiently large here. In the second Drum part, however, is because of the small temperature difference between the final temperature the coal and inlet temperature of the cooling air, the countercurrent method is used -brought, with just the coarser coal particles still located in the second drum part be effectively cooled with the fresh cooling air in countercurrent.

The fine coal particles that were already more dried and therefore less post-drying can be done from the drum through the Sieve shell shot fall out.

In this way, with the simplest possible means, that just at the beginning of the treatment the smallest grain sizes and dust in direct current about halfway through the airflow from the drum while the coarse grain migrates through the whole drum and the disadvantage of uneven cooling due to the countercurrent for the coarse grain is practically out of the question, since the small Air velocity on the coarse grain cannot have any appreciable influence. All the less so than the air speed when using the composite method is only half as large as in the countercurrent process and only a fraction as large as with the pure direct current method.

Furthermore, there is still the possibility, depending on the prevailing circumstances both the length and the diameter of the drum parts and also the To choose the amount of cooling air the same or different from each other.

In the accompanying drawing, Fig. I shows a rotatable drum to carry out the procedure shown schematically. The goods to be cooled pass through the chute a in the first part of the rotary drum b, wanders through this and arrives through a screen jacket part c into the second part of the rotating drum f. at the end of the drum g the chilled goods fall through a coarse sieve g into the discharge chute h. foreign body and parts larger than the largest allowable grain size will pass through the Sieve g into the failure chute i. The cooling air enters the two outer ones at the same time Drum ends through the coal incidence housing l and the discharge housing k into the first Part b or second part f of the rotary drum in this one, wanders through the drum parts up to the sieve part c connecting the two drum parts and is through the opening e extracted in the air extraction housing. At na, the device is driven. At In place of the composite drum shown schematically in Fig. I, as shown in Fig. z shown, two coaxially or approximately coaxially to perform the procedure arranged individual drums are used, the first of which, working in direct current Drum the throughput product directly into the second drum that works in countercurrent dispenses, with the sieve attached to either the first or second drum part can be. Both individual drum parts can either be used together or separately are driven.

Claims (1)

PATENT CLAIMS: i. Process for cooling and degassing of dried Lignite, in which the dried coal is simultaneously passed through Air through a rotating drum, which is closed on the periphery and provided with trickle plates is performed, characterized in that the cooling air from the two ends of the Rotary drum here enters and about in the middle of the drum shell is sucked out of the drum. : 2. Device for performing the procedure according to Claim i, characterized by two coaxial or approximately coaxial Rotary drums, one of which is attached to the parts facing the other drum with a sieve-shaped jacket bus is equipped.