EP1131590A1 - Drying method and dryer for carrying out said method - Google Patents

Abstract

The invention relates to a method and a dryer for drying items in a drying area of the dryer (10). The items that are to be dried are introduced into the drying area (60) at an upper end of said area and are impinged upon with hot drying gas in the drying area (60). Dried items are removed from the drying area (60) at a lower end of said area. The drying gas is introduced at the lower end of the drying area and circulated in an upward manner through the entire range of items that are to be dried. The dried items that are removed are replaced by a new flat layer of items on the upper end of the drying area (60) by means of a feeder (16). The dryer (10) has a horizontally displaceable delivery device (14) for the dried items. Gas outlet ducts (18) are arranged upstream from the delivery device in the lower area of the dryer (10) at a distance. A device for introducing the drying gas into the items is connected to said ducts. An outlet (20) for gas from the dryer (10) is arranged in the upper area of the dryer (10). The feed device and delivery device (14, 16) ensure the same pouring height for the items that are to be dried above the drying area (60).

Description

 METHOD FOR DRYING AND DRYER FOR CARRYING OUT THE METHOD

description

Technical field

The invention relates to a method and a dryer of the type specified in the preamble of claims 1 and 14, respectively.

Such a method and such a dryer are known from German patent specification 934 160, which will be discussed in more detail below.

State of the art

DE 29 06 358 A1 describes a device for the continuous drying of grain, in particular maize. This comprises at least one pre-dryer provided with warm air inlet and exhaust air outlet. The grain is fed to the pre-dryer under the influence of gravity from top to bottom within a chamber-like container. Furthermore, the device has a discharge device for the at least predried grain material below the chamber-like container. The device is also provided with a level-controlled entry device for grain and a leveling device for leveling the grain surface in the container. The warm air inlet opens into a hood at the top of the grain material level and the exhaust air outlet is provided below the grain material level, so that the drying in the device takes place according to the direct current principle.

A disadvantage of maize in particular is that newly added moist maize comes into contact with the relatively hottest drying air, and so the still moist maize is damaged by the hot air sweeping over its surface. Another disadvantage is that the drying gas heats to very high temperatures between about 150 ° C and 210 ° C and is introduced into the grain, whereby the grain can be damaged and a high demand for heating medium arises.

German laid-open specification 2 261 972 describes a shaft dryer for granular dry material, in which the dry material in a certain layer thickness is passed through an essentially vertical drying shaft and heated dry air flows through it in countercurrent. A layer support formed by grate bottoms arranged in parallel one above the other is arranged in the bottom of the drying shaft and can be moved back and forth transversely to the general direction of movement of the dry material. The grate floors are each made up of a large number of mutually parallel, horizontally oriented and gaps-enclosing sieve strips and arranged in a frame spanning the cross section of the drying shaft. Furthermore, each screen plate strip is assigned a forced scraper which is immovable relative to the drying shaft.

The disadvantage here is that the shaft dryer requires a large amount of heating medium to dry, which causes high operating costs. Another disadvantage is that the drying of the goods to be dried is insufficiently feasible and controllable and that the degree of moisture in the dried goods discharged from the drying shaft is therefore not constant.

German patent 934 160, already mentioned at the beginning, relates to a trickle dryer operated in countercurrent with a continuously operating feed and discharge device. The material to be dried is fed into the upper part of the dryer and discharged into the lower part after it has moved vertically through the drying zone by gravity. The goods are fed into the drying zone by means of a screw conveyor arranged within a perforated trough, and rollers are provided for discharging the goods, which are pocket-shaped on their surface in order to pick up grain in one position and to discharge it in another position can. In this case, hot air is to be continuously conveyed in countercurrent essentially through the entire bulk material, but in practice this is not possible because chambers for the supply of the hot air are arranged between the grain discharge rollers, the hot air outlets of which are located far above the grain discharge rollers, so that the grain which Hot air outlets has passed, can no longer be supplied with hot air. This arrangement of the hot air outlets is necessary in the known giant dryer, however, because the grain feed by means of the screw conveyor in the drying zone accumulates a high pile of grains forming slopes on both sides and the hot air inlet se should be in parallel to the grain slope in order to bring about uniform heating of the grain over the entire surface of the dryer. This may be possible, but it has the problem that below the hot air inlets in the center of the dryer at the lower end of the dryer, up to the grain discharge rollers, a large grain volume accumulates, which is no longer subjected to hot air and thus no longer affects its moisture content can be, so that a constant residual moisture of the discharged material is not guaranteed. The use of grain discharge rollers presents a further problem, namely that a trough-shaped inlet for the pockets of the grain discharge rollers must be formed by means of partition walls, but such a trough-shaped inlet leads to bridging in the grain material. Furthermore, grain discharge rollers have the problem that the moisture content of the dried material cannot be measured from below the grain discharge rollers before discharge. The embankments formed due to the grain supply and the parallel position of the hot air outlets of the chambers used for the supply of hot air mean that the chambers must have a special and different design and that such a trickle dryer always only for a certain type of grain and only for a certain one Width can be built.

The dryer known from German patent specification 934 160 is also only suitable for free-flowing material which can form an embankment which corresponds to the position of the outlet openings of the gas outlet channels. When processing non-free-flowing material, no embankment would form and therefore the parallel position between such an embankment and the outlet gaps of the gas outlet channels, which should be sought for uniform drying, would not be achieved.

The free-flowing material emerges from the perforated trough in which the screw conveyor is arranged until a heap, which forms slopes on both sides, has accumulated so high that grain can no longer fall through the holes, but until the end of the Troges must go on. A steady replenishment of material to be dried on the entire surface of the embankments is difficult to achieve and presupposes a very slow rotation of the rollers, i.e. a very slow throughput of the material to be dried through the trickle dryer.

A heat treatment device for granular material is known from German published patent application DE 31 00 614 A1, which has grain discharge rollers in the form of rotary valves and thus also has the problems associated with grain discharge rollers. The heat Handling device has a plurality of passage elements, which are V-shaped in cross section and are arranged in a container for the granular material, the passage elements being arranged horizontally or slightly inclined in parallel in a plurality of vertical rows and a plurality of horizontal rows. The evenly horizontal row passages are staggered between the odd horizontal row passages, and some of the passage elements operate as air supply passage elements and the remainder act as air outlet passage elements. In this known heat treatment device, too, there is a large volume of material to be dried above the discharge rollers, which can no longer be charged with air before discharge.

Finally, German Offenlegungsschrift 2,229,684 shows a device for treating granular goods by means of heat or cold in a treatment room with a goods inlet at the top and a goods outlet at the bottom, in which the goods to be treated are moved from the goods inlet to the goods outlet by gravity and with the aid of guidance means and is directly and / or indirectly exposed to the treatment medium. The guide means for supplying the treatment medium are provided with channels for the treatment medium or are designed entirely or partially as a channel for the latter. A guide body is arranged in the treatment room and is tapered both upwards and downwards. The structure of the device described above serves the purpose of realizing a toaster in which the goods are moved through the individual toaster stages solely by gravity without driven conveying elements, which ensures a uniform sinking and free flow of the goods and both direct and indirect heating or Cooling allowed.

Presentation of the invention

The object of the invention is to provide a method for drying with the steps specified in the preamble of claim 1 and a dryer of the type specified in the preamble of claim 14 in such a way that an impairment of the material to be dried during drying can be safely avoided that for Drying a small amount of heating medium is required that they can be used for different dry goods and that in particular a constant degree of residual moisture of the dried goods can be achieved.

This object is achieved by the steps specified in claim 1 or by the features specified in claim 14. The method according to the invention advantageously provides that drying gas is introduced into the material to be dried at a lower end and is passed through the entire material to be dried from the lower end to an upper end of the drying zone. This ensures that essentially all of the material to be dried is acted upon by the drying gas until it is discharged. The drying gas almost completely saturates with moisture at the outlet from the material to be dried, and the outlet temperature of the drying gas is only slightly above the temperature of the material to be dried at the upper end of the drying bed, which is why the process is highly efficient and only uses small amounts of heating medium Dry are needed. All of the energy used is used in the drying process. It is also advantageous that in the process according to the invention, relatively low temperatures of the drying gas are sufficient for drying and that the material to be dried can be dried in a manner which is gentle on the product.

The temperature and the degree of saturation of the drying gas emerging from the material to be dried can be influenced by increasing or decreasing the height of the bed of the material to be dried in the drying zone, that is to say by constructive measures. Furthermore, the degree of saturation of the dry gas emerging from the material to be dried is dependent on the quantity of dry gas introduced into the material to be dried and on the pressure difference from the surroundings of the dryer and can be influenced in a simple manner by increasing the pressure and the speed of the dry gas.

Another advantage is that the drying gas, which has the greatest temperature difference to the temperature of the material to be dried when it is introduced at the lower end of the drying zone, comes into contact with the material to be dried already adapted to the temperature of the drying gas during operation of the dryer. This advantageously prevents damage or impairment of the goods to be dried. The inventor has recognized that, especially when drying cereals, in particular maize, the exposure of cool, crop-moist cereals to hot dry gas leads to grain breakage and thus a loss due to material loss. The material shrinkage is reduced to a minimum by the invention.

Since the layer-by-layer discharge of hot, dry material from the drying zone takes place according to the invention by horizontally moving the dry material, it is advantageously ensured that only a desired layer height and a precisely verifiable amount of the dried material are discharged from the drying zone. It can be easy process conditions that can be determined and have slight deviations over the entire course of the drying process are guaranteed. Furthermore, it is advantageously ensured that dried material is only discharged from the drying zone below a residual moisture limit value. The discharge in layers takes place via forced displacement, which contributes to the fact that the method according to the invention can be carried out fully automatically.

In order to maintain constant operating parameters in the drying zone during drying, the dried material discharged from the drying zone is replaced by a layer of material to be dried at the upper end of the drying zone. This ensures in a simple manner that the drying gas introduced into the material to be dried at the lower end of the drying zone always flows through the same bed height of the material to be dried in the drying zone.

The dryer according to the invention has an outlet for the exhaust gas from the dryer in its upper region. It is advantageous that the dry gas exits from the gas outlet channels and flows through it in counterflow to the material to be dried and only then exits at the upper end as a moist gas from the drying zone via the outlet and is taken up by the dry gas as it flows through the material to be dried Moisture is discharged from the dryer. The discharge device, which is arranged in the dryer according to the invention and is designed as a layer discharge device, is intended to discharge dried material horizontally from the drying zone in a certain layer height once a predetermined degree of residual moisture or degree of dryness has been reached. With this arrangement according to the invention, the drying gas can advantageously be introduced into material to be dried at a lower end of a drying zone and can be passed through the entire material to be dried from the lower end to an upper end of the drying zone. This ensures that the entire material to be dried is acted upon by the drying gas and the drying gas has reached almost complete moisture saturation at the upper end of the drying bed when it emerges from the material to be dried. The outlet temperature of the drying gas in the dryer according to the invention is only slightly above the temperature of the material to be dried at the upper end of the drying bed or drying zone, which makes it clear that the dryer can be operated with a high degree of efficiency and requires only small amounts of heating medium. The degree of saturation of the dry gas and the exhaust gas temperature when the gas emerges from the material to be dried can be changed in a simple manner by changing the bed height of the material to be dried in the drying zone, in particular the bed height above the gas outlet channels.

Another advantage of the dryer according to the invention is that due to the dry gas supply at the lower end of the dryer into the material to be dried and due to the dry gas outlet from the dryer at the upper end of the drying zone and due to the layer discharge device in the area of the dry gas supply, the dryers with relative operated low dry gas temperatures and the goods to be dried can be dried in a way that is gentle on the product.

A further advantage is that the drying gas, which has the highest temperature when it is introduced at the lower end of the dryer, comes into contact with material which has already been heated to be dried during operation of the dryer. This advantageously prevents damage or impairment of the goods to be dried. The inventor has recognized that, especially when drying cereals, in particular maize, the exposure to hot dry gas in the cool, moist condition of the harvest would lead to grain breakage.

Since in the method and the dryer according to the invention the hot gas always flows through the material to be dried essentially over the entire bed height, a constant residual moisture content of the discharged material can be ensured. By moving the dry material horizontally to discharge it, a much larger volume can be discharged than with application rollers having pockets, which have to rotate very slowly during operation. A higher dryer throughput can thus be achieved by the invention. Since the material is shifted horizontally during discharge, the moisture of the material can be easily sensed below the outlets between the gas outlet channels before it is discharged. In the invention, the walls of the gas outlet channels are much steeper than in the prior art, so that bridging is prevented. In particular, the discharge according to the invention by means of horizontal displacement does not require a trough-shaped inlet through appropriately arranged partition walls, so that bridging is excluded. In addition, the gas outlet channels in the invention can all have the same construction, so that the dryer according to the invention can be made in any width by juxtaposing the same gas outlet channels. It is particularly important that the same horizontal bed in the dryer according to the invention by uniformly distributing the material to be dried in a substantially flat layer over the drying zone everywhere the same bed height of the material to be dried, which can be the use of the invention Drying of difficult-flowing goods such as fine sand, sewage sludge, straw, hemp litter etc. is permitted.

Advantageous embodiments of the invention form the subject of the subclaims.

In a further development of the invention it is provided that additional dry gas is introduced into the gas to be dried above the lower end of the drying zone, so that part of the dry gas flow flows through the entire material to be dried over its entire bed height and the other part of the dry gas flow in the region of the Dry bed of the material to be dried is introduced into this. This advantageously ensures that material to be dried can also be dried with high moisture in the drying zone and that the drying gas only reaches its degree of moisture saturation at the outlet from the material to be dried.

In the method according to the invention, in one embodiment variant, the drying is carried out at least partially in a region of the drying zone which narrows downwards in a funnel shape. It is advantageous here that the dry gas introduced into the material to be dried can be easily distributed in the material to be dried from a narrow area of the funnel-shaped zone into the region of the drying zone which widens upwards, and thus that entire material to be dried is flowed through by the drying gas. It has proven to be particularly advantageous to additionally introduce drying gas in the funnel-shaped area of the drying zone above the lower end of the drying zone.

In a further embodiment variant of the method according to the invention it is provided that the same amount of material to be dried is fed into the drying zone as is carried out of dried material. This ensures that the same bed height of material to be dried is always present in the drying zone, so that at least approximately stationary operating conditions are present in the dryer during the drying process and the process can be controlled and regulated in a simple manner. In a further development of the dryer according to the invention it is provided that the gas outlet channels decrease in width over their height from their end facing the discharge device to their other end and extend in length at least approximately over the entire width of the dryer. As a result, a funnel-shaped area of the drying zone is formed in the space between two adjacent gas outlet channels, which advantageously guides the material to be dried and the counter-flowing drying gas is optimally distributed in the material to be dried.

In an advantageous embodiment of the invention it is provided that the gas outlet channels are attached to a wall of a housing of the dryer facing the interior of the dryer, which advantageously contributes to the stability of the entire dryer.

In a further development of the dryer according to the invention it is provided that the gas outlet channels each have gaps at their end facing the discharge device, through which the dry gas can be introduced into the material to be dried. This ensures in an advantageous manner that the drying gas is introduced into the drying zone and that the outlet opening is prevented from being closed by material to be dried. The material to be dried flows past the openings from above. It has proven to be particularly advantageous if the gaps extend at least in sections over the entire length of the gas outlet channels, since this enables uniform distribution of the drying gas over the entire width of the dryer.

In a further development of the gas outlet channels, the gaps according to the invention can be formed between one of the side walls of the gas outlet channel and a U-shaped bottom part of a gas outlet channel, the bottom parts being designed as U profiles that extend across the width of the dryer. This advantageously prevents the material to be dried from entering the interior of the gas outlet channel and prevents the gaps from being closed by material to be dried. This can be achieved in particular if the two legs of the base parts of a gas outlet duct, which extend in the direction of the upper region of the dryer, are overhanged by the side walls of the gas outlet duct at a horizontal distance.

In order to achieve particularly high drying capacities, it can be provided in a development of the invention that the gas outlet channels have further gaps above their height in order to introduce drying gas at a higher level into the material to be dried. In order to predrying of the material to be dried is advantageously achieved, so that material to be dried with very high degrees of moisture can be dried in a suitable drying time and the residence time of the material to be dried in the dryer can be kept short.

In an advantageous embodiment of the invention, it is provided that the side walls of the gas outlet channels for forming the further gaps are formed from a plurality of parts which extend at least approximately over the width of the dryer and which overlap like roof tiles. The gaps can then advantageously be arranged in an overlap area between the individual parts of the side walls, so that again the gaps can be prevented from being closed by flowing material to be dried and the drying gas is first introduced into the material to be dried in the direction of flow and thereafter against the flow direction of the material to be dried flows upwards through the material to be dried.

In a further development of the invention, the discharge device of the dryer can comprise elements arranged underneath the gas outlet channels and spaced apart from one another and a control system for discharging the dried goods layer by layer from the drying zone. It is particularly advantageous if the discharge device has sensors for measuring the degree of moisture in the material to be dried, which are arranged below the gaps formed between adjacent gas outlet channels. This ensures that dried goods are only removed from the drying zone above a certain predetermined residual moisture level by means of the elements. Another advantage is that only a certain layer of dried material having the desired degree of residual moisture is discharged from the drying zone by means of the elements.

In a particularly advantageous embodiment of the dryer according to the invention, the elements for discharging the dried goods in layers can be moved transversely to the direction of movement of the goods to be dried in the dryer and transversely to the longitudinal direction of the gas outlet channels and extend at least approximately over the entire width of the dryer. It is advantageous that the layer of dried material to be discharged is discharged horizontally from the elements for layer-by-layer discharge from the drying zone and the height of the layer discharged corresponds to the height of the elements for layer-by-layer discharge. This means that the same amount of dried material can always be discharged with each discharge process. In a development of the dryer according to the invention, the elements for discharging in layers can be designed as U-profiles, which are each arranged at the same distance from one another. The outer width of two elements, which corresponds to the sum of the clear width between two elements and the width of the two elements, corresponds at least approximately to the width of the bottom part of a gas outlet channel. This advantageously creates a smooth transition between the side walls of the gas outlet channels and the elements for discharge in layers, so that the flow of the material to be dried in the drying zone is not hindered and an unfavorable flow profile in the funnel-shaped for uniform drying of the material to be dried Area of the drying zone can be avoided. In addition, the pairs of elements causing the discharge process can be moved alternately under the gas outlet channels, where there is an opening through which the dried material can exit vertically downwards, and under the funnel-shaped area or space between adjacent gas outlet channels in order to be filled with the material to be discharged become.

It has proven to be advantageous if the discharge device in the area between two gas outlet channels each has a rail arranged below the elements for discharging in layers and an opening is provided in the area below the gas outlet channels, both of which extend across the widths of the dryer. This ensures in an advantageous manner that the material to be dried remains in the drying zone until it has reached the desired moisture level during drying and can be pushed horizontally out of the drying zone when the moisture level is reached and can exit down through the opening.

In an embodiment of the invention, the width of the rails corresponds at least approximately to the clear width between two elements of the discharge device arranged next to one another, so that material to be dried cannot accidentally emerge from the drying zone. With this design, the discharge device is closed between two discharges of dried material from the drying zone and no material to be dried can emerge from the drying zone.

If the width of the opening corresponds to the clear width between two elements of the discharge device arranged next to one another, it is ensured that when the layer is discharged in layers, the entire dried material falls down through the opening, and when a new layer of dried material is subsequently discharged layer by layer, no dried material net material is pushed back into the drying zone and can be damaged if it is re-exposed to dry gas.

In a further development of the dryer according to the invention it can be provided that a collecting funnel is arranged in the dryer below the discharge device and is provided with sensors for determining the filling quantity of dried material. The advantage here is that the dried material is left in the collecting funnel before being discharged from the dryer and so-called re-sweating or post-heating of the dried material can be carried out. This re-sweating represents a further drying process of the dried material, which, however, can be carried out without any further expenditure of energy, and the post-heating can also take place outside the dryer.

In a particularly advantageous development of the dryer according to the invention, it is provided to form the housing of the dryer from several layers, an intermediate space being formed between the layers of the housing. In a constructional development it can be provided that the intermediate space extends over the entire circumference and the entire length of the dryer and at least one opening for introducing fresh gas into the dryer or the intermediate space is provided in the housing of the dryer.

It is advantageous that fresh gas is introduced through the opening into the space between the housing of the dryer and is preheated in a simple manner by the radiant heat of the dryer before heating to drying temperature and thus advantageously heat recovery and thus reduction in the amount of heating medium required is achieved.

A particularly high efficiency of the dryer according to the invention can be achieved if the space between the housing of the dryer is connected to a furnace of the dryer for introducing the fresh gas from the space into the furnace and the furnace is also in flow communication with the dispensing device. This ensures that the fresh gas entering the dryer according to the invention is first preheated in the discharge device and in the intermediate space of the dryer before it is brought to drying temperature in the oven. Thus, the residual heat from the dried material and the radiation heat of the dryer are used to preheat the incoming fresh gas, and energy losses and the heating medium requirement are greatly minimized. In further developments of the dryer, the feed device has a control device for controlling the feed quantity of material to be dried in the dryer and sensors for detecting the fill level of material to be dried in the drying zone, or a chain conveyor. This ensures in an advantageous manner that after the discharge of dried material from the drying zone via the feed device, the correct amount of material to be dried is introduced into the drying zone from above and is distributed as a flat layer over the drying zone, so that the same filling level is to be dried Good in the drying zone or in the dryer is present as before the discharge of the dried material and for drying again almost the same operating conditions are present in the dryer and in particular the same bed height of the material to be dried is produced over the entire drying zone.

Corresponds to the distance between two gas outlet channels at least approximately the clear width between two elements, it is advantageously ensured that the material to be dried between the gas outlet channels opens into an area of the drying zone, the width of which corresponds approximately to the width of the openings of the discharge device.

Brief description of the drawings

Embodiments of the invention are described in principle below with reference to the drawings.

It shows:

Figure 1 is a longitudinal sectional view of a dryer.

Fig. 2 is a cross-sectional view of the dryer along the line II-IJ in Fig. 1, wherein

Gas outlet channels are shown rotated by 90 ° in the drawing plane of FIG. 2; and FIG. 3 shows an enlarged illustration of gas outlet channels of the dryer with a layer discharge device arranged below the gas outlet channels.

Best way to carry out the invention

1 shows a side view of a dryer 10 in section. The dryer 10 has a housing 12, a discharge device 14 arranged in the lower region of the dryer 10, a feed device 16 and arranged in the upper region of the dryer 10 In front of the discharge device 14 in the lower region of the dryer 10 there are gas outlet channels 18 arranged at a distance. A device (not shown in more detail) for introducing dry gas into the material to be dried is provided on the gas outlet channels 18. Furthermore, the dryer 10 has an outlet 20 for the moist gas, which has flowed through the material to be dried, from the dryer 10 in the upper region. Furthermore, a fan 22 for conveying the escaping moist gas, the drying gas and the fresh gas drawn into the dryer 10 is arranged in the dryer 10.

2 shows a schematic front view of the dryer 10 in section, the housing 12 of the dryer 10 being formed from two layers 12a and 12b. Between the two layers 12a, 12b, an intermediate space 24 is formed, through which fresh gas is passed through an opening 26 to an oven 27 of the dryer 10. When the fresh gas is supplied to the furnace 27, the fresh gas is preheated by radiant heat from the dryer 10.

Below the gas outlet channels 18, which are shown rotated by 90 ° into the drawing plane of FIG. 2, a collecting funnel 28 is provided for collecting dried material in the dryer 10. A discharge device 30 for the dried goods from the dryer 10 is arranged below the collecting funnel 28, which is provided as an after-drying zone for the dried goods. The dispensing device is designed as a double-floor chain conveyor 30, which comprises a circulating chain 32 and paddles (not shown in more detail) for conveying dried material. The chain 32 and the paddles are surrounded by a housing 34 of the raised floor chain conveyor. In the lower area of the housing 34 of the double floor chain conveyor 30, gas passages 36 are provided for sucking in fresh gas. The gas passages 36 are formed by shortened side walls 38 of the housing 36 of the double floor chain conveyor 30 and by angle profiles 40 arranged outside the housing 30 at a short distance from the side walls 38.

In further embodiments, not shown, which differ from the present exemplary embodiment, the gas passages can be designed at the discretion of the person skilled in the art in such a way that the selected configuration is adapted to the product to be dried and the escape of dried material from the double-floor chain conveyor 30 via the gas passages 36 is avoided and fresh gas can be easily introduced into the dryer 10. In the collecting funnel 28 according to the present exemplary embodiment, sensors (not shown) are attached to determine the filling quantity of dried material, which give a signal to the raised floor chain conveyor 30 when a specific filling quantity is reached, so that the dried material is carried out of the dryer 10.

In Fig. 3, several gas outlet channels 18 are shown side by side. The gas outlet channels 18 have side walls which are formed from parts 42 which extend over the width of the dryer and which overlap like roof tiles. In the overlap areas 44 and between the parts 42 and the bottom parts 46 of the gas outlet channels 18 designed as U-profiles, gaps 48 are provided for introducing dry gas into the material to be dried from the gas outlet channels 18. Furthermore, at least one opening (not shown) is provided in each of the bottom parts 46, through which dry gas can exit from the gas outlet channels 18 into the collecting funnel 28. In this way, the collecting funnel 28 is under excess pressure and forms an expansion chamber for the dry gas in the dryer 10. If not all gas outlet channels 18 are supplied with the same amount of dry gas, pressure equalization between the gas outlet channels 18 takes place via the openings in the base parts 46 instead, so that the same amount of drying gas is introduced into the material to be dried for uniform drying over all gas outlet channels. Furthermore, the openings in the base parts 46 are provided for blowing out impurities which cannot be discharged via the gaps 48, 49 and which can block them, from the gas outlet channels 18.

In a development of the dryer, not shown, the gas outlet channels 18 can have additional air baffles in their interior in order to be able to shut off the connection between the gas outlet channels 18 and the oven 27 of the dryer 10. The dry gas can be extracted with a suction fan and cleaned in a dust separator downstream of the suction fan. This removes contaminants introduced into the gas outlet channels 18 with the dry gas and the cleaned dry gas can be returned to the furnace 27 without heat losses.

The discharge device 14 has elements 50, rails 52 spaced apart from one another and, in the region below the gas outlet channels 18, openings 54 for dried goods. The elements 50, the rails 52 and the openings 54 extend over the entire width of the dryer 10. The elements 50 are arranged in the dryer 10 above the rails 52 horizontally and transversely to the longitudinal direction of the gas outlet channels 18. The discharge device 14 has, in areas below spaces 51, which are present between adjacent gas outlet channels 18, and immediately below the rails 52, probes 53 as sensors for measuring the degree of moisture of the material to be dried. The degree of moisture of the hot, dry material can thus be optimally measured immediately before it is discharged. The optimum measuring location is made possible in the dryer described here in that the bottom layer of the material located in the spaces 51 is first shifted horizontally transversely to the longitudinal direction of the gas outlet channels 18 until it is above the openings 54, via which it is finally down exits to get into the collecting funnel 28. The probes 53 allow the dried material to be discharged only when its moisture level has reached the correct value. As soon as this is the case, an actuator 15 (FIG. 1) is actuated in order to move the elements 50 together horizontally. The gaps between adjacent elements 53 of dried material are then emptied into the openings 54, while at the same time new pairs of elements 50, which were previously located under the gas outlet channels, are moved under the gaps 51, in order to be filled with them as a result. In the next discharge process, the actuator 15 is actuated so that the elements 50 are moved horizontally in the opposite direction, etc.

In the present exemplary embodiment, the elements 50 are designed as U-profiles, the open side of the U-profile being arranged on the side of the element 50 facing the rail. It is also possible to produce the elements 50 from a closed square profile or the like.

The mode of operation of the dryer 10 will be described below with reference to FIGS. 1 to 3.

The material is introduced into the dryer 10 via a filling funnel 56 of the feed device 16 and distributed with a chain conveyor 58 of the feed device 16 over the entire length and width of the dryer 10 with an identical bed height of the material to be dried. The oven 27 of the dryer 10 is then put into operation and drying gas at a dry temperature is introduced via the gas outlet channels 18 into the cold material to be dried via the columns 48 and 49. The material to be dried warms up slowly, and as soon as a layer of about 5 cm in height has reached a degree of moisture of, for example, 15%, the discharge device 14 is actuated by a control (not shown). This means that the elements 50 are moved together transversely to the direction of flow of the material to be dried without changing their distance from one another, and layered dried material from a drying zone 60, which is arranged between the discharge device 14 and the feed device 16, is displaced horizontally via the rails 52 and falls down through the opening 54 into the collecting funnel 28.

The material to be dried in the drying zone 60 which is arranged above the discharge device 14 lowers in the direction of the discharge device 14 in the drying zone 60 in accordance with the volume of dried material discharged. Then sensors (not shown) in the drying zone 60 send a signal to a controller (not shown) of the feed device 16 due to the lowering of the fill level in the drying zone 60. The latter is actuated by the controller and it becomes cold material to be dried via the hopper 56 filled into the dryer from above and by means of the chain conveyor 58 evenly distributed over the drying zone 60 on the surface of the drying bed of the material to be dried, so that the same bed height of material to be dried is present over the entire drying zone 60. Exactly enough material to be dried is introduced into the drying zone 60 in such a way that the bed height after filling the bed height corresponds to the discharge of dried material and the same operating conditions are ensured in the dryer 10.

After the discharge of dried material, the entire material to be dried moves in the drying zone 60 in the direction of the discharge device 14 until the volume released by the discharge in the drying zone 60 is again filled with the material to be dried.

The bed height of the material to be dried in the drying zone 60 is provided in the present exemplary embodiment in such a way that the gas outlet channels 18 are completely covered by the material to be dried. This means that the bed height is greater than the height of the gas outlet channels 18. However, it is at the discretion of the person skilled in the art to adjust the bulk height of the material to be dried in the drying zone 60, depending on the application, to the height of the gas outlet channels 18 or to set it lower.

The material to be dried is filled for drying in the dryer 10 via the hopper 56 and horizontally distributed with the chain conveyor 58 in the drying zone 60 on the surface of the drying bed as a uniform, flat new layer. As a result of the discharge of dried material from the drying zone 60, the surface of the drying bed drops in the direction of the discharge device 14 and the new layer of material to be dried is guided into the dryer 10. In this way, a layer of material to be dried gradually sinks from top to bottom in the drying zone 60. This layer initially covers an area extending over the entire length and width of the dryer 10 above the gas outlet channels 18 of the drying zone 60. When the layer reaches the tips of the gas outlet channels 18, the latter enters an outlet located between the gas outlet channels 18 in the direction of the discharge device 14 region of the drying zone 60 narrowing in a funnel shape. The layer of material to be dried is divided by the gas outlet channels 18. After each discharge, the material to be dried slides along the side walls of the gas outlet channels 18 which delimit the funnel-shaped regions of the drying zone 60 until the material to be dried forms the bottom layer of the drying bed, which is discharged from the drying zone 60 into the collecting funnel 28 when it is subsequently discharged becomes.

Hot drying gas is introduced into the material to be dried via the gaps 48, 49 with a drying temperature which is strongly dependent on the product and can be about 120 ° C. when drying maize, as already described above. In this way, hot material to be dried is subjected to hot drying gas via the gaps 48. The drying gas flows in the direction of the chain conveyor 58 in the funnel-shaped area of the drying zone 60 and is cooled by the material to be dried and enriched with moisture. Column 49 introduces drying gas at the same temperature as column 48 into the material to be dried. The drying gas from columns 49 flows into the material to be dried and mixes with the already cooled and moisture-enriched drying gas in column 48. This procedure turns the material to be dried, which is located above and / or in the area of column 49, and has a lower temperature than the material to be dried in the area of the column 48, to which dry gas is applied, the temperature of which is below the maximum temperature of the dry gas. This prevents damage to the goods to be dried and, on the other hand, increases the performance of the dryer.

Since the drying gas is gradually cooled further as the material to be dried flows through it, the material to be dried which is introduced into the dryer 10 at ambient temperature is subjected to drying gas whose temperature is only slightly above the material temperature. As a result, the newly introduced material to be dried is gently dried and heated.

Due to the physical law that hot dry gas can absorb a much greater amount of moisture than cold, the dry gas in the middle layers of the goods to be dried is enriched with moisture and gives it Moisture from a layer of material to be dried lying higher in the flow direction of the drying gas. This layer absorbs the moisture and releases it again until the dry gas is saturated and no further absorption of moisture or water is possible. The moisture or amount of water given off by the drying gas to the material to be dried accumulates on the outer layers of the material to be dried, heats it and diffuses into the outer layers of the material to be dried. Due to the diffusion of moisture into the uppermost surface layers of the material to be dried, an enrichment with moisture is generated. In this way, the upper part of the material to be dried is not initially dried, but the material to be dried is enriched with water and preheated. The outermost layers of the material to be dried or layers of shell in grain products become smooth and smooth. Only in the lower areas of the drying zone 60 is the material dried slowly and evenly.

After being discharged, the dried material collects in the collecting funnel 28 and remains there for about an hour until the sensors of the collecting funnel control the double-floor chain conveyor 30 and the dried material is carried out of the dryer 10. Fresh gas is supplied via the gas passages 36 of the double-floor chain conveyor 30, which are arranged in a lower region of the double-floor chain conveyor 30, which is separated from an upper region by a floor 66. The fresh gas is passed through the dried material in the lower region of the double floor chain conveyor 30 and passed via a connection 62 into a channel 64 for the supply of the fresh gas and the dry gas to the oven 27. When the dried goods flow through, the fresh gas is heated and moisture is further removed from the dried goods.

Furthermore, fresh gas is introduced into the dryer 10 via the opening 26 of the housing 12 of the dryer 10 via the intermediate space 24, which is provided as the gas supply zone of the dryer. The fresh gas is heated by the space 24 extending over the entire circumference and the entire length of the dryer 10 by radiant heat from the dryer 10 before it is fed to the oven 27 of the dryer 10 for heating to drying temperature. This creates an optimal heat recovery which, together with the previously described heat recovery in the double-floor chain conveyor 30, brings about a reduction in the heating medium requirement.

The fresh gas from the intermediate space 24, which is sucked into the dryer 10 via the double floor conveyor 30, is via the channel 64, which is by a side wall 70 of the Collection funnel 28, the layer 12b and a lower part 72 of the housing 12 of the dryer 10 is limited, introduced into the oven 27 and through a channel 68 for the heated dry gas, which from a side wall 74, the layer 12b and a lower part 76 des Housing 12 is limited, introduced into the gas outlet channels 18 via a further channel (not shown) that runs vertically to the housing 12 between the channel 68 and the gas outlet channels 18. The direction of flow of the fresh gas and the dry gas, which is led from the collecting funnel 28 into the channel 64, is represented by two arrows 78 and 80. The channels 64 and 68 are formed in the dryer 10 without additional material expenditure.

In the double-floor chain conveyor 30, two sealing devices, not shown, are provided in order to prevent heated gas from escaping from the dryer 10. One of these two sealing devices is arranged in addition to adjusting the bulk height of the dried material conveyed in the double floor chain conveyor 30.

In the present exemplary embodiment, air from the environment is used as fresh or dry gas. However, it is within the discretion of the person skilled in the art to use a different gas, such as, for example, inert gases or other fluids suitable for drying, depending on the goods to be dried in the dryer.

In an embodiment (not shown), the housing 12 of the dryer 10 is designed to slope slightly above the drying zone 60 from the center to the outside and has a channel-like device at its transition to its side walls. This is intended to collect condensing liquid on the inside, especially above the drying zone 60, of the housing 12 and to lead it out of the dryer 10 in a simple manner.

The dryer 10 is shown in the present embodiment as a stationary variant. However, in a different embodiment of the dryer, the dryer 10 can be made movable.

In a further embodiment of the dryer that differs from the present exemplary embodiment, it can be provided that the modular dryer can be extended by vertical housing segments to increase the capacity of the dryer. However, other segments of the double floor chain conveyor, the direction etc. used for adaptation and additional gas outlet channels, all of which are constructed identically, simply arranged in a corresponding number next to each other.

In a further embodiment of the dryer (not shown) it can be provided that the drying gas is introduced into the drying zone at a low drying temperature, for example in the freeze-drying of coffee or the like. Instead of the oven, a device for cooling the drying gas and a device for drying the drying gas are provided in the dryer. For example, the oven can be replaced by a chiller. In this mode of operation of the dryer 10, the gas passages 36 and the intermediate space 24 are provided for recovering the cooling energy in the dryer.

Due to the aforementioned embodiments of the dryer 10, it can be used over a wide temperature range and for a wide variety of products, such as, for example, flour, grains, porous products, bread, grasses, faeces, sugar, coffee or clay granules.

The above-described mode of operation of the dryer 10 when using dry gas, which is at a drying temperature below the temperature of the material to be dried newly introduced into the dryer 10, corresponds essentially to the described mode of operation of the dryer 10, in which the temperature of the dry gas is above the temperature of the goods to be dried that have been newly introduced into the dryer 10.

Claims

Patent claims

1.Procedure for drying material to be dried in a drying zone which has an upper and a lower end, between which the material to be dried moves vertically by gravity, with the following steps: a) introducing the material to be dried into the drying zone (60 ) at the upper end, b) applying hot drying gas to the goods in the drying zone (60), c) discharging dried goods from the drying zone (60) at the lower end thereof, and d) replacing the discharged dried goods with an equal amount of material to be dried at the upper end of the drying zone (60), characterized in that e) the drying gas is introduced at the lower end of the drying zone and through the entire material to be dried from the lower end to the upper end of the drying zone (60 ) is passed through, f) dried material is discharged in layers at the lower end of the drying zone (60) by horizontal displacement of the dried material from the drying zone ( 60), and g) the layer of discharged dried material at the upper end of the drying zone is replaced by a flat layer of material to be dried.

2. The method according to claim 1, characterized in that in addition drying gas is introduced into the material to be dried above the lower end of the drying zone (60).

3. The method according to claim 1 or 2, characterized in that the drying is carried out at least partially in a funnel-shaped narrowing down region of the drying zone (60).

4. The method according to claim 3, characterized in that the additional introduction of dry gas in the funnel-shaped area of the drying zone (60) takes place.

5. The method according to any one of claims 1 to 4, characterized in that the dried material is collected in an after-drying zone of the dryer and is left for a certain predetermined dwell time for after-drying in the after-drying zone before being discharged from the dryer.

6. The method according to any one of claims 1 to 5, characterized in that the drying gas is heated to a drying temperature above the temperature of the material to be dried before being introduced into the material to be dried.

7. The method according to claim 5 or 6, characterized in that the dried material in the after-drying zone is flowed through by cool, sucked-in fresh gas for cooling and for removing residual moisture from the dried material.

8. The method according to any one of claims 1 to 7, characterized ge ke n nze ichn et that cooler gas is supplied to the dryer (10) via a gas supply zone of the dryer (10), the fresh gas in the gas supply zone by heat radiation from the dryer is heated.

9. The method according to claim 8, characterized g e ke n nze i ch n et that the fresh gas from the gas supply zone and from the after-drying zone is further heated by the supply of energy and is then supplied as the hot drying gas to the material to be dried.

10. The method according to any one of claims 1 to 5, characterized in that the drying gas is cooled to a drying temperature below the temperature of the material to be dried before being introduced into the material to be dried.

11. The method according to claim 10, characterized in that the dried material in the after-drying zone is flowed through by warm, sucked-in fresh gas for warming up and for removing residual moisture from the dried material.

12. The method according to claim 10 or 11, characterized in that the dryer (10) via the gas routing zone of the dryer (10) is supplied with warm fresh gas, the fresh gas in the gas routing zone being cooled by radiation from the dryer.

13. The method according to claim 12, characterized in that the fresh gas from the gas supply zone and from the after-drying zone is further cooled by energy removal and is then fed as cold drying gas to the material to be dried.

14. dryer for carrying out the method according to claim 1, with a) a at the upper end of the drying zone (60) arranged supply device (16) for the material to be dried, b) at the lower end of the drying zone (60) arranged discharge device ( 14) for dried goods, c) in front of the discharge device (14) spaced-apart gas outlet channels (18) between which the goods can move, d) a device connected to the gas outlet channels (18) for supplying dry gas for introduction into the material to be dried, and e) an outlet (20) for the gas from the dryer (10) arranged at the upper end of the drying zone (60), characterized in that f) the gas outlet channels (18) each have a discharge device (14) have an adjacent end, which has gaps (48) through which the drying gas can be introduced into the material to be dried, g) the discharge device (14) is a layer discharge device which is below de r gas outlet channels (18) arranged and spaced apart elements (50) has, which can be moved horizontally to discharge the dried material from the drying zone (60), and

h) the feed device (16) is designed to evenly distribute the material to be dried in a substantially flat layer over the drying zone (60) in order to produce the same bed height of the material to be dried over the entire drying zone (60).

15. Dryer according to claim 14, characterized in that the gas outlet channels (18) decrease in their width from their end facing the discharge device (14) towards their other end in width and in their length at least approximately over the entire width of the Extend dryer (10).

16. Dryer according to claim 14 or 15, characterized in that the dryer (10) has a housing (12) whose wall consists of several layers (12a, 12b) of wall material, wherein between the layers (12a, 12b) of the housing an intermediate space (24) is formed.

17. Dryer according to one of claims 14 to 16, characterized in that the gaps (48) extend at least in sections over the entire length of the gas outlet channels (18).

18. Dryer according to one of claims 14 or 17, characterized in that the gaps (48) are each formed between one of the side walls of a gas outlet channel (18) and an at least approximately U-shaped bottom part (46) of a gas outlet channel (18) in cross section , wherein the base parts (46) are designed as profile parts which extend across the width of the dryer and are essentially U-shaped in cross section.

19. Dryer according to claim 18, characterized in that the two U-legs of the base parts (46) of a gas outlet channel (18) extend in the direction of the upper end of the drying zone (60) and are exceeded by the side walls of the gas outlet channel (18) at a horizontal distance.

20. Dryer according to one of claims 14 to 19, characterized in that the gas outlet channels (18) have further gaps (49) above their height.

21. Dryer according to claim 20, characterized ge ke nn ze ichnet that the side walls of the gas outlet channels (18) to form the further column (49) from a plurality of at least approximately across the width of the dryer extending parts (42) are formed, which overlap like a roof tile in an overlap area (44).

22. Dryer according to one of claims 14 to 21, characterized in that the discharge device (14) has sensors (probes 53) for measuring the degree of moisture of the material to be dried, which is located below between adjacent gas outlet channels (8). formed spaces (51) are arranged.

23. Dryer according to claim 14 to 22, characterized in that the elements (50) of the discharge device (14) extend at least approximately over the entire width of the dryer (10).

24. Dryer according to one of claims 14 to 23, characterized in that the elements (50) of the discharge device (14) are designed as U-profiles and are each arranged at the same distance from one another, the outer width of two elements (50) being approximately the largest Corresponds to the width of a gas outlet channel (18).

25. Dryer according to one of claims 14 to 24, characterized ge ke n nze ichnet that a distance between two gas outlet channels (18) corresponds at least approximately to the clear width between two elements (50) of the discharge device (14).

26. Dryer according to one of claims 14 to 25, characterized in that the discharge device (14) in the area between two gas outlet channels (18) each have a rail (52) arranged below the elements (50) and in the area below the gas outlet channels (18 ) has an opening (54), both of which extend over the width of the dryer (10).

27. Dryer according to claim 26, characterized in that the width of the rail (52) corresponds at least approximately to the clear width between two elements (50) of the discharge device (14).

28. Dryer according to claim 26 or 27, characterized in that the width of the opening (54) corresponds to the clear width between the elements (50) of the discharge device (14).

29. Dryer according to claim 16, characterized in that the gas outlet channels (18) are connected to the layer (12b) of the housing (12) of the dryer (10) facing the inside of the dryer (10).

30. Dryer according to claim 29, characterized in that the intermediate space (24) extends over the entire circumference and the entire length of the dryer (10).

31. Dryer according to claim 16, 29 or 30, characterized in that at least one opening (26) for introducing fresh gas into the dryer (12) is provided in the housing (12) of the dryer (10)

32. Dryer according to claim 31, characterized in that the fresh gas can be passed through the intermediate space (24) of the housing (12) of the dryer (10) and can be heated in the intermediate space (24) by heat radiation from the dryer (10).

33. Dryer according to claim 32, characterized in that the intermediate space (24) with an oven of the dryer (10) for introducing the fresh gas from the intermediate space (24) into the oven and heating the preheated fresh gas in the oven Dry temperature is connected.

34. Dryer according to one of claims 14 to 33, characterized in that the dryer (10) has a device for cooling the drying gas.

35. Dryer according to one of claims 14 to 34, characterized in that in the dryer (10) a fan (22) is provided for guiding the gas.

36. Dryer according to one of claims 14 to 35, characterized in that the feed device (16) has a chain conveyor (58) extending over the drying zone (60).

37. Dryer according to one of claims 14 to 36, characterized in that the feed device (16) has a control device for controlling the feed amount of material to be dried in the dryer (10) and sensors for detecting the level of material to be dried in the drying zone ( 60).

38. Dryer according to one of claims 14 to 37, characterized in that on the inside of the dryer (10) above the feed device (16) a channel-like device for collecting and carrying out condensing liquid from the dryer (10) is provided.