DE3412173A1 - Process for regenerating adsorbents in adsorption units, especially molecular-sieve cartridges, of a drying appliance, and drying appliance for drying material held in a drying-material container - Google Patents

Abstract

In a process for regenerating adsorption cartridges of a drying appliance for heat-sensitive material to be dried, the adsorbent is dried with hot air and is then cooled via a part stream of the dry air used for drying the material to be dried. Said dry-air part stream is then returned to the dry-air main stream, specifically before the latter flows through the adsorption cartridges. As a result, the part stream is cooled by mixing with the dry-air main stream before being passed on for drying the material to be dried. Consequently, excessive heating of the dry-air stream used for drying, which could damage the material to be dried, can be avoided. The drying appliance used to carry out this process has a bypass line which is connected to the adsorption cartridges and, upstream of the adsorption units, debouches into a return line.

Description

Process for regenerating adsorption

medium in adsorption units, especially microscopic sieve cartridges, a drying device and drying device for drying in a dry goods container stored dry material The invention relates to a method for regeneration of adsorbents in adsorption units, in particular circular sieve cartridges, a drying device and a drying device for drying in a dry goods container stored dry goods according to the preamble of claims 1 or 5.

One known method of this type is an adsorption dryer provided, which consists of several units, namely adsorption cartridge, the be cooled with room air after regeneration. Here, the adsorbent takes the adsorption cartridges gradually regain the moisture contained in the room air on, even before the adsorption cartridge starts the actual drying process has been fed back.

In another known method in which several adsorption cartridges are provided, these are alternately regenerated and then with a Partial flow of dry air cooled. This allows the regenerated adsorbent without Partial saturation by room air work with higher efficiency. This method however, has the disadvantage that the respective adsorption cartridge to cooling The partial flow of dry air flowing through it after flowing through the adsorption cartridge directly with the residual partial flow flowing through the remaining adsorption cartridges mixes in order to be fed to the drying material for drying. This can heat the drying air so much that heat-sensitive dry goods that are relatively Must be dried at low temperatures, damaged or even unusable can be. This risk is particularly acute when there are only a small number of adsorption cartridges is present. This procedure is known in a Drying device carried out in which the adsorption cartridges with the supply and Return line are each connected via a valve.

The invention is based on the object of a method and a drying device to train this type so that a high efficiency is achieved and the drying temperature the dry air can be kept as low as possible.

According to the invention, this object is achieved with the characterizing features of claim 1 or 5 solved.

As a result of the method according to the invention is used to cool the dry air partial flow used in front of the adsorptive unit regenerated with hot air returned to the return line before being forwarded to the material to be dried, where the heated partial flow of dry air with that of the dry material to the adsorption units The flowing cooler dry air main flow mixes to the adsorption units as a mixed air flow to be fed. When flowing through the adsorption units, the mixed air flow is cooled so that it can then be used for drying temperature-sensitive items to be dried can be used.

With the drying device according to the invention, the method can can be carried out easily and at low cost without any special structural effort. The drying circuit is separated from the hot air lines, so that during the Regeneration of one adsorption unit with the other adsorption unit Drying can be carried out further.

Further features of the invention emerge from the further claims, the description and the drawings.

The invention is illustrated below with reference to one in the drawing Embodiment described in more detail.

It shows: FIG. 1 a drying device according to the invention in schematic form Representation and FIG. 2 is a schematic diagram of a second embodiment of an inventive Drying device.

The drying device according to FIG. 1 has an adsorption dryer 1 with four adsorption cartridges designed as molecular sieve cartridges in the exemplary embodiment 2 to 5, each via a connecting line closable with a valve 6 to 9 10 to 13 are connected to a dry air supply line 14. This lead 14 leads to a dry goods container 15, which is preferably heat-sensitive Plastic granulate which is dried with dry air. A heater is located in the supply line 14 17, with which the dry air coming from the adsorption cartridges 2 to 5 is heated will. A return line 18 leads from the dry goods container 15 via connecting lines 19 to 22 and associated valves 23 to 26 for the adsorption cartridges 2 to 5.

In the return line 18 lie one behind the other in the direction of flow (arrow 27) a filter 28 and a blower 29 via lines 10-14 and 18-22 the adsorption cartridges 2 to 5 are connected to a dry air circuit.

The adsorption cartridges 2 to 5 are also used for their regeneration Via connecting lines 30 to 33 with valves 34 to 37 to a hot air supply line 38 connected, in which a heater 39 and one in the flow direction 54 of the hot air upstream fan 40 are. The adsorption cartridges 2 to 5 are on the output side via valves 41 to via an outlet 49a 44 and connecting lines 45 to 48 with a discharge line 49 for the hot air which opens into an enum geDenden space. Finally, the adsorption cartridges 2 to 5 are each on the output side with one third valve 56 to 59 and connecting lines 60 to 63 connected to a Connect bypass line 64. This opens between the filter 28 and the fan 29 in the return line 18 or optionally seen in the direction of flow before Filter 28.

In the bypass line 64 are in the flow direction 50 in front of the adsorption cartridges 2 to 5 a filter 51 and a heat exchanger 52 arranged one behind the other. He is lying also in a suction line 65 for room air, in the direction of flow 54 or the heat exchanger 52 is a second filter 66.

With one between the bypass line 64 and the return line 18 lying pressure differential controller 53 can flow from the bypass line 64 into the return line 18 flowing air volume can be regulated, so that, for example, in the event of a pressure increase in the dry air circuit via the pressure differential controller 53 a connected to this Throttle member 67 in the bypass line 64 is closed until in both Lines 18, 64 the same pressure difference prevails.

Lines 30 to 33, 38, 45 to 49 form a regeneration circuit ' , and the lines 60 to 55 a cooling circuit in which the adsorption cartridges 2 to 5 lie.

For drying the dry goods present in the dry goods container 15 First, the valves 34 to 37, 41 to 44 and 56 to 59 of the regeneration circuit closed and the valves 6 to 9 and 23 to 26 of the dry air circuit opened. Then the circulating in the feed line 14 in the flow direction of the arrow 27 Air in the heater 17 is heated to the desired temperature, with the in the air existing moisture is removed. The air then flows in the supply line 14 to the dry goods container 15. When passing through the dry goods container, the preheated Dry air removes the moisture due to the existing partial vapor pressure gradient the material to be dried, whereby it is dried and at the same time the drying air is cooled. The exiting dry air is sucked in by the fan 29, over that the circulation of the drying air is also maintained. This dry air flows # in ## direction uf then via the return line 1 adsorption cartridges 2 to 5 of the adsorption dryer 1, whereby it passes through the filter 28 in which impurities be retained from the dry air. This dry air finally flows Via the connecting lines 19 to 22 and the open valves 23 to 26 in the individual adsorption cartridges 2 to 5. The dry air is in these dried again by the adsorbent present there and over the opened Valves 6 to 9 and the connecting lines 10 to 13 are fed to the feed line 14 again.

After a certain moisture absorption, the adsorbent must dried in the adsorption cartridges or

regenerated so that there is again moisture from the dry air can accommodate. For this purpose, only some of the adsorption cartridges 2 to 5 connected to the regeneration circuit, while the remaining adsorption cartridges continue to be flowed through by the moisture-laden air. For example, if only the adsorption cartridge 5 is to be regenerated, while the other adsorption cartridges should remain connected to the drying circuit for drying the hot air, then the valves 9 and 22 of this adsorption cartridge become valves374 ff s ch losen, nas e ase in In the supply line 38 switched on. This will go through the suction line 65 room air is sucked in in the direction of arrow 54 and when flowing through the filter 66 cleaned.

This air is heated to a temperature in the following heating device 39 heated from for example 2000 to 3000C. It then flows through the connecting line 33 and the valve 37 in the adsorption cartridge 5 and strokes there over the existing one Adsorbent away. The adsorbent is due to the high partial vapor pressure gradient the moisture is removed between the hot air and the adsorbent. Through this the adsorbent is dried and the hot air is cooled accordingly.

The hot air leaves the adsorption cartridge 5 via the valve 44 and flows via the connection line 48 and the discharge line 49 into the surrounding space.

Thereafter, the valves 37 and 44 are closed again and the valves 26 and 59 open, so that for cooling the adsorption cartridge 5 via the return line 18 a partial flow of the cool dry air can flow into the adsorption cartridge 5. Due to the dry air partial flow, which is much colder compared to the adsorption cartridge 5 the adsorption cartridge is strongly cooled, while the temperature of the it flowing through Dry air partial flow increases accordingly.

This heated partial flow of dry air leaves the adsorption cartridge 5 through the valve 59 and then flows through the connecting line 63 into the bypass line 64.

The filter 51 is used to cool the adsorption cartridge 5 Partial stream of dry air cleaned.

When the regeneration of the adsorption cartridges via the fan 40 sucked in and flowing in the line 65 room air is cooler than that in the Bypass line 64 flowing dry air partial flow, then takes place via the heat exchanger 52 a temperature equalization, whereby heat is withdrawn from the partial flow and the air in the room is heated. This allows the partial flow of dry air to be mixed with the dry air can be cooled. By mixing the partial flow with the im Dry air circulation circulating main flow formed mixed air flow therefore remains relatively cool.

The partial flow flowing in the bypass line 64 flows at the point 55 between the filter 28 and the fan 29 in the return line 18, where it is mixes with the dry air main stream coming from the dry material container 15.

During the regeneration and cooling process of the adsorption cartridge 5 the remaining adsorption cartridges 2 to 4 continue to be exposed to the dry air or the mixed air flows through and for drying the dry goods in the container used.

After the regeneration and cooling of the adsorption cartridge 5 the valves 37 and 59 closed and the valves 9 and 26 opened again, so that the adsorption cartridge 5 is reconnected to the dry air circuit. on In this way, all adsorption cartridges can be used individually or several at the same time by activating the corresponding valves for regeneration and cooling in the regeneration circuit be connected.

The adsorption cartridges connected to the dry air circuit 2 to 5 then flows to the mixed air formed in the return line 18. The temperature fluctuations respectively.

the temperature rise is due to the adsorption mass that in the dry air circuit located adsorption cartridges are very small. As a result of this buffer effect, the circulating dry air essentially constant temperature.

In addition, the dew point curve is determined by the adsorption cartridge to be cooled not adversely affected. Because the partial flow used to cool the adsorption cartridge to no appreciable increase in temperature of the dry goods container 15 supplied Dry air leads, this dry air cannot cause any damage or destruction of the very heat-sensitive items to be dried during drying.

By lying in the bypass line 64 heat exchanger 52 can The temperature of the mixed air can be reduced to further lower the dew point. The heat extracted from the partial flow is transferred to the regeneration cycle via the Supply line 65, 38 supplied again.

The partial flow flowing through the bypass line 64 can be with the Regulate differential pressure meter 53. This increases the amount of air in the drying circuit in the event of pressure fluctuations, e.g. due to increasing resistances in the dry goods container 15, not adversely affected.

The device according to FIG. 2 differs only in this from the device according to Figure 1 that the dry air used for cooling is regenerated Adsorption cartridge 5a flows through in the opposite direction. This causes the valve to lie 26a, through which the partial flow of dry air flows into the adsorption cartridge 5a, seen in the flow direction 27 of the main dry air flow, on the outlet side at the Adsorption cartridge, while the other valve 59a, through which the partial flow, the adsorption cartridge leaves, is arranged with respect to the flow direction 27 on the inlet side.

This can reduce the temperature gradient running from the outside to the inside balanced in the adsorption cartridge and thus the dew point is significantly evened out will.

Claims (12)

Claims: 1. A method for regenerating adsorbent in Adsorption units, especially molecular siehpa troilen, a drying device for dry goods that are too dry, especially for plastic granulate, where a Hot air flow and then, for cooling, a partial flow of drying air for drying of the dry material used and returned from these to the adsorption units Dry air main flow optionally through at least one of the adsorption units is passed, characterized in that the dry air partial flow is the dry air main flow before it enters the adsorption units (2 to 5) and fed with this is mixed. 2. The method according to claim 1, characterized in that the from the dry air partial flow exiting the adsorption unit to be cooled before the inlet is cooled in the main stream of dry air. 3. The method according to claim 1 or 2, characterized in that the for mixing with the main dry air flow in this introduced dry air partial flow is controlled depending on the differential pressure. 4. The method according to any one of claims 1 to 3, characterized in that that the for cooling the adsorption unit (5a) serve against the dry air partial flow the flow direction (27) of the main dry air flow and that in the same direction Hot air flowing into the adsorption unit (5a) through the adsorption unit (5a) is directed. 5. Drying device for drying in a dry goods container housed dry material, in particular plastic granulate, with at least two Adsorption units, which are connected downstream of the dry goods container and in one Drying circuit with one of the adsorption units to the dry goods container leading supply line and a return line for a main stream of dry air, and with a hot air supply and discharge line connected to the adsorption units are, in particular for performing the method according to one of claims 1 to 4, characterized in that the adsorption units (2 to 5) with a bypass line (64) are connected to the return of a for cooling the respective adsorption unit used dry air partial flow in the dry air main flow in the return line (18) opens and which can be shut off with at least one switching element (56 to 59). 6. Drying device according to claim 5, characterized in that the bypass line (64) in the flow direction (27) of the main dry air flow a fan (29) in the return line (18) of the drying circuit 14, 10 to 13, 18, 19 to 22) opens. 7. tsock device according to claim 5 or 6, characterized in that that in the bypass line (64) there is at least one heat exchanger (s2). 8. Drying device according to claim 7, characterized in that in the direction of flow (50) that is provided for cooling the adsorption units (2 to 5) Dry air partial flow upstream of the heat exchanger (52) is a filter (51). 9. Drying device according to claim 7 or 8, characterized in that that the heat exchanger (52) in a feed line connected to the cutting air feed line (38) (65; for room air lies. 10. Drying device according to claim 9, characterized in that In the hot air supply line (38) in the direction of flow (54) upstream of the heat exchanger (52) a filter (66) is located. 11. Drying device according to one of claims 5 to 10, ddby characterized in that between the return line (18) and the bypass line (64) a throttle device (53), preferably a differential pressure regulator, is arranged is. 12. Drying device according to one of claims 5 to 9, characterized in that that a switching element (26a and 59a) is provided on the adsorption units (2 to 5) and that the inlet-side Switching element (26a) in the flow direction (27) of the main dry air flow before output-side switching element (59a) is located.