DE1604885B2 - Electric dryer for granular or powdery material to be dried with riser pipes arranged one inside the other - Google Patents

Description

The invention relates to a flow dryer for granular or powdery material to be dried nested riser pipes and a downpipe, which is the upper end of the inner riser pipe with the lower end of the outer connects.

In such dryers, a gaseous medium such. B. air or combustion exhaust gas, simultaneously as a conveyor and as a drying agent. While the moisture is withdrawn from the material to be dried and from the Desiccant is absorbed, there is also a heat transfer. On the one hand, it is essential that the material to be dried reaches the desired residual moisture, but on the other hand other technological Properties and quality are not adversely affected. The optimal drying conditions can practically only be used in a specific case in a given dryer with a specific design Achieve the best quality of the dried in the shortest drying time with the lowest heat consumption Good is to be guaranteed. The dependence of the drying speed on the temperature of the desiccant and its relative humidity, the relative speed between desiccants and items to be dried and, in particular, on the technological conditions of the items to be dried therefore makes it necessary to adapt the drying conditions on a case-by-case basis to the properties of a given dryer.

US Pat. No. 1,927,596 discloses a two-stage device for combined pneumatic pre-drying and subsequent further heating of the material to be dried, in which a single drying air source is provided for both stages for heating and accelerating the drying agent. The second stage is a heat exchanger that consists of two riser pipe sections and one downpipe section, which can all be arranged one inside the other and in which the upper end of the inner riser pipe is connected to the lower end of the outer riser pipe through the downpipe. The material to be dried is fed into the first stage via a feed device and conveyed first through a vertical downpipe and then through a riser pipe through the drying agent to a separator. From there it reaches the second stage, the pneumatic heat exchanger, via a sloping pipe. The desiccant flows through the system in the opposite direction, i.e. first the three tubes of the heat exchanger and then the downpipe and the riser pipe of the first stage.
Initially, the items to be dried, which are still very moist, tend to stick. In a downpipe, the relative speed between the material to be dried and the drying agent and, due to the force of gravity, the risk of caking in such a section is low. Because of the very rapid onset of evaporation, the material to be dried takes on considerably lower temperatures than the drying agent, so that even temperature-sensitive material to be dried is treated gently, but is hardly dried. It is only in the second treatment section of this known pneumatic dryer, the riser pipe of the first stage, that extensive drying takes place, which allows and requires post-treatment of the material to be dried in this way in the second stage, the heat exchanger, because in the first stage the Surface moisture has been removed, but sufficient drying has certainly not yet taken place.

The invention is based on the object of determining the drying conditions in a dryer of a certain construction to be able to choose a sufficiently long drying flow path within a wider framework than before of the gas-solid mixture with a relatively low overall height with the lowest possible Achieve number of pipe sections, thereby reducing heat radiation losses and without the risk from caking during drying of temperature-sensitive materials, gently and evenly to dry.

This object is achieved according to the invention in that the entire treatment route consists of three There is pipe sections, of which the two riser pipes are arranged directly one inside the other, the downpipe runs next to the riser pipes, and its lower end joins the outer riser pipe at the bottom and to the side, so that a helical rising flow is generated therein.

In the first treatment section, which is designed as a riser pipe, the material to be dried is conveyed vertically upwards at a relatively high speed in order to avoid caking on the pipe walls. In the downpipe, only a small contribution is made to the drying process per se; sufficient through-drying of large particles is not achieved there. In the second riser pipe, the material to be dried is then carried by a helically ascending flow. The drying path compared to the overall length of this riser pipe and thus the dwell time is many times greater than in the inner riser pipe of this double riser pipe section. Through the concentric design of the two riser pipes al: riser pipe double section, the desired thermal advantages can also be achieved. Whoever flows through the two immediately adjacent drying sections in the same direction will, compared to the countercurrent principle, suffer a disadvantageous cooling at the beginning of the first drying section! the end of the second drying section avoided.
Only minor changes in the flow

speed of the desiccant lead due to the helical ascending flow in the outer Riser pipe to significant changes in the mean residence time of the material to be dried in the whole Treatment line. For example: Items to be dried that are initially very moist are put in a dryer in accordance with of the invention by a desiccant with high temperature and a speed that is at the lower The limit with regard to the risk of caking lies, promoted through the first riser pipe; about the Downpipe it gets into the second riser pipe and remains there with a relatively long residence time, because the relatively small flow rate of the desiccant has a small pitch angle the helical ascending flow causes. Initially not very damp items to be dried can, however, without difficulty with higher flow rate and lower temperature of the Desiccants are promoted; the residence time in the first riser differs insignificantly of that in the first example, but significantly in the second riser, because the angle of inclination is greater, the Dwell time is shorter.

An advantageous embodiment of the invention can be designed such that in the lower, in the outer riser opening end of the downpipe opposite this a line for additional desiccant leads whose entry angle can be changed by an adjustable blow-in end of the line.

This creates an additional possibility, the dwell time of the items to be dried in the outside To influence the riser. Due to the size of the entry angle, either the helically ascending one Flow intensified or weakened, in the first case the retention time of the material to be dried shortened, extended in the second. In addition, the additional drying agent with higher or lower Temperature are supplied so that the material to be dried reheat in the outer riser pipe or let it cool down.

Should the drying result be achieved after the items to be dried have run through the entire treatment section not yet satisfactory, there is the advantageous option of not yet sufficiently dried Separate particles in front of the separator, convey them to the feeder and with the fresh, to mix still moist items to be dried. In this way, some particles of the material to be dried can run through the treatment section several times, depending on their humidity on the End of a run by a separator classifying based on the speed differences brought about by more or less dried goods.

In the drawing are embodiments of the invention shown schematically. It shows

F i g. 1 a current dryer in view, partially in section,

F i g. 2 a flow dryer as in FIG. 1 with a sifter.

In both figures, the same parts are denoted by the same reference numerals. The fan 1 pushes the in it sucked in drying gas (air or combustion exhaust gas) through the heating element 2, the pipe elbow 3 and the upwardly directed feed pipe 4 into the riser pipe 6. The granular or powdery to be dried Material to be dried is poured into the hopper of the metering device 5 and through the Conveyor screw entered evenly into the feed pipe 4, so that it is in the drying gas flow is carried floating. The gas-solid mixture formed in the feed pipe 4 then passes into the actual treatment section and flows upwards in the riser pipe 6, becomes the same at the upper end deflected downward in the cap 7, then flows through the downpipe 8 running next to the riser pipes and is passed through its bent lower end 8 'into the outer riser pipe 9, which the inner Riser pipe 6 surrounds at a distance and thus forms a shell space. The lower end 8 'of the downpipe 8 opens in the outer riser pipe 9 below and laterally in such a way that therein a helically ascending flow is generated, with which the material to be dried rises until it passes the outer riser pipe 9 through the at his the upper end of the discharge nozzle 9 'leaves.

The drying gas stream loaded with the fresh, still moist material to be dried flows through the riser pipe 6 and the downpipe 8 vertically without any avoidable delay, thereby caking on the pipe walls be avoided. In the outer riser 9, the residence time of the gas-solid mixture is through the The helical ascending flow is considerably increased. Because the material is already pre-dried and there is caking are no longer to be feared, thorough drying can also be greater in the outer riser pipe 9 Particles take place.

In Fig. 1 also shows a line 10 for additional desiccant. This leads opposite the downpipe 8 into the lower end 8 'of the downpipe 8, which opens into the outer riser 9. The entry angle of the additional desiccant can be changed by an adjustable end of the line 10 and increased or decreased depending on its position the angle of inclination of the gas-solid mixture rising helically in the riser pipe 9. Through this there is no need to install baffles known per se. The line 10 is via a branch 12 with a Locking and regulating device 13 to a cold gas source and via the other branch 11 with a locking and Control device 14 connected to a hot gas source, namely the branch lines 12 and 11 behind the fan 1 and in front of or behind the radiator 2.

In the embodiment of the invention according to FIG. 1 is the gas-solid mixture that comes out of the discharge nozzle 9 'arrives, fed to a separator directly connected to it, a cyclone 15 the lower end of which the fallen items to be dried are removed through a discharge flap 16, while the drying gas freed from suspended solids via a connecting line 17 from sucked in by a fan 18 and blown through a vapor pipe 19 into the open air. That can be safe happen when material to be dried has been processed, which is after a single pass through the treatment section with the pipe sections 6 to 9 proves to be evenly dried.

With some items to be dried, the dry product is uneven, i. H. it contains lighter, sufficiently dried ones Particles and heavier particles which still have an impermissibly high level of residual moisture. For Such cases can be carried out without repeating the drying process with the entire preliminary product according to the in F i g. 2 illustrated embodiment of the invention the separator 15 to 19 a Separator 20 are connected upstream, which has a separating

tion of the solids carried along by the gas stream into heavier, d. H. even more humid, and in lighter, d. H. causes already dry particles. From the connected to the outflow nozzle 9 'of the jacket pipe 9 The heavier particles are sifter 20 through a downpipe 21 and a discharge lock 23 into the lower one End of the jacket pipe 9 returned, while the lighter particles through the pipe bend 22 in the cyclone 15 are passed.

By blowing the additional desiccant into the riser 9 can both improve the Residual drying of the material as well as a cooling of the pre-dried, possibly heat-sensitive Good can be achieved.

For this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Electric dryer for granular or powdery items to be dried with one inside the other Riser pipes and a downpipe connecting the upper end of the inner riser pipe to the lower end of the outer connects, characterized in that the entire treatment route consists of three Consists of pipe sections, of which the two riser pipes (6, 9) are arranged directly one inside the other, the downpipe (8) runs next to the riser pipes (6, 9), and its lower end (8 ') into the outer riser pipe (9) opens below and on the side, so that it creates a helical rising flow will. 2. Current dryer according to claim 1, characterized in that in the lower, in the outer Riser pipe (9) opening end (8 ') of the downpipe (8) opposite this a line (10) for additional Desiccant leads, whose entry angle through an adjustable injection end of the line (10) is changeable.