EP0554559A1 - Process and device especially for drying materials by use of microwave heating - Google Patents

Abstract

Process for subjecting materials, in particular piece goods stacked in consignments, to microwaves, in particular for drying, in batch mode. Device for carrying out the process, having a microwave chamber and a launching device connected to this chamber, as well as having at least one chamber door for material charging or material removal. In a working cycle, in each case at least two consignments of the material to be treated, which are located on different workplaces (PL1, PL2) and have different microwave absorptivity, are subjected to a common microwave field. The microwave chamber (MK) has doors (LT), arranged in the region of mutually opposite chamber walls, and a run-through track, extending between these doors, with a transporting device (TE), which comprises receiving places (PL1, PL2) for at least two consignments (LD1, LD2) of material to be treated. For driving the transporting device, there is preferably provided a control, which has position detectors assigned to the predetermined treatment positions of rest of the consignments. <IMAGE>

Description

The invention relates to a method for microwave exposure, in particular for drying, materials, in particular piece goods stacked in loads, in cyclical operation, with at least one component of the treatment material being absorbable and in a predetermined temperature range for the microwave field. The subject matter of the invention includes a device for the microwave exposure to materials, with at least one microwave chamber and at least one microwave coupling device connected to this chamber, and with at least one chamber door for material loading or removal.

Methods of heating or drying materials using microwaves are common. A prerequisite is a sufficient degree of absorption capacity for a microwave field of the frequency used in each case. For materials containing water within certain limits, this is readily the case, which is why the drying of such materials is a preferred microwave application. In many heating applications, but in particular in most drying applications, the microwave is in competition with conventional energy sources or forms of transmission (hot air, short-wave Heat radiation, direct heat conduction). The decisive factor for the use of microwaves in an egg case is whether it is possible to realize the specific potential benefits of the microwave with regard to the rapid, uniform and material-friendly introduction of energy into the material. In addition, the energy efficiency is an important selection criterion. The successful exploitation of the microwave properties depends on processes and equipment that are sufficiently adapted to the peculiarities of the microwave as well as the application conditions.

In this context, a first stage of the task of the invention is the creation of methods and devices which enable an increased efficiency of the working method, in particular an increased heating or drying speed with the same degree of efficiency and with gentle material treatment. A variant of the task of the invention is aimed at improving efficiency and operational safety. Another variant of the inventive task is the creation of facilities that improve the simplicity and operational reliability of the workflow. A comparatively simple and inexpensive construction of the devices is also within the scope of the inventive task. The achievement of this object according to the invention is determined by the features of the independent claims. Particularly advantageous and inventive refinements and developments are determined by the features of the dependent claims, in particular also by appropriate combinations of the features of independent claims and of dependent claims with one another.

Fig.1

ein Diagramm des Verlaufes der mittleren relativen Feuchte f des Behandlungsmaterials über der Zeit t für ein Ausführungsbeispiel eines erfindungsgemässen Mikrowellen-Trocknungsverfahrens,

Fig.2

ein entsprechendes Feuchte-Zeitdiagramm für ein als Vergleichsobjekt geeignetes Mikrowellen-Trocknungsverfahren üblicher Art,

Fig.3

ein Ausführungsbeispiel einer erfindungsgemässen Mikrowelleneinrichtung in Form einer "Multimode"-Mikrowellenkammer für Durchlaufbetrieb in einem Vertikal-Mittelschnitt parallel zur Durchlaufrichtung,

Fig.4

einen Ausschnitt aus Fig.3 in grösserem Massstab,

Fig.5

einen Teilschnitt der Mikrowelleneinrichtung gemäss Schnittebene V-V in Fig.4,

Fig.6

ein anderes Ausführungsbeispiel einer erfindungsgemässen Mikrowelleneinrichtung in Form einer "Multimode"-Kammer für Durchlaufbetrieb, wiederum in einem Vertikal-Mittelschnitt parallel zur Durchlaufrichtung entsprechend der Darstellung in Fig.1,

Fig.7

einen Teilschnitt aus Fig.6 gemäss der dortigen Schnittebene VII-VII,

Fig.8

einen Teilschnitt aus Fig.7 gemäss der dortigen Schnittebene VIII-VIII,

Fig.9

einen Teilschnitt gemäss der in Fig.6 strichpunktiert angedeuteten Schnittebene IX,

Fig.10

einen schematisch vereinfachten Teilschnitt aus Fig.9 gemäss der dortigen Schnittebene X-X, in wesentlich grösserem Massstab.

The features and advantages of the invention are further explained with reference to the exemplary embodiments illustrated in the drawings. It shows:

Fig. 1

2 shows a diagram of the course of the average relative humidity f of the treatment material over time t for an exemplary embodiment of a microwave drying method according to the invention,

Fig. 2

a corresponding humidity-time diagram for a microwave drying method of a conventional type suitable as a reference object,

Fig. 3

1 shows an exemplary embodiment of a microwave device according to the invention in the form of a “multimode” microwave chamber for continuous operation in a vertical central section parallel to the direction of passage,

Fig. 4

a section of Figure 3 on a larger scale,

Fig. 5

4 shows a partial section of the microwave device according to section plane VV in FIG. 4,

Fig. 6

another exemplary embodiment of a microwave device according to the invention in the form of a “multimode” chamber for continuous operation, again in a vertical central section parallel to the direction of passage corresponding to the illustration in FIG. 1,

Fig. 7

6 shows a partial section from FIG. 6 according to section plane VII-VII,

Fig. 8

7 shows a partial section from FIG. 7 according to the section plane VIII-VIII there,

Fig. 9

6 shows a partial section according to the section plane IX indicated by dash-dotted lines in FIG. 6,

Fig. 10

a schematically simplified partial section of Figure 9 according to the section plane XX there, on a much larger scale.

The process example according to the invention, the basic flow diagram of which is shown in the time diagram according to FIG. 1, is a drying of mold cores for metal casting carried out under industrial operating conditions. The cores were in a modern process with a sealant composed of water solutions or water suspensions, a so-called. "Water sizing", treated or soaked. The use of such sealants instead of conventional sealants based on alcohol or other organic solvents or suspending agents is desirable for reasons of economy and ease of disposal. However, conventional drying processes prove to be inadequate because of the much higher specific heat and evaporation heat of water, especially because of an unreasonable increase in the drying time and thus increasing heat losses, i.e. a low overall efficiency. Conventional microwave processes are also in need of improvement in this regard.

In the process example according to the invention, mold cores stacked in separate loads were treated in a continuous cycle mode in a multimode microwave field. The mold cores were introduced with a uniform, constant input moisture fe corresponding to a water content of approx. 120 g per core in loads of 50 pieces. The microwave field was supplied with a total electrical power of 100 kVA. The resulting water vapor was continuously extracted with the appropriate fresh air supply.

In one work cycle, two charges were exposed to a common microwave field. At the beginning of a work cycle, a new charge was introduced into the microwave field, while the other charge at the start of the cycle had already been subjected to microwave exposure in the previous work cycle. For the subsequent work cycle, the load with the largest loading cycle number was removed, i.e. in this case the charge introduced in the previous cycle, and an unloaded charge has been newly introduced. The charges were cycled through the common microwave field in succession in a serial arrangement between an inlet and an outlet. Each load was first brought to an entry point for partial drying in a first cycle and then moved to an exit point for final drying in the next cycle for final drying.

The work cycle duration was a constant 6 minutes. The total treatment time for each load was 12 minutes. In contrast, the duration of the transport breaks was negligible with a few seconds due to largely automated operation.

In FIG. 1, the drying progress in successive work cycles of the time period T is separated in diagrams arranged congruently with one another for the input location PL1 and the starting point PL2 is shown. Inlet E and outlet A of the loads as well as their shifting between the entry and exit points are indicated by vertical arrows.

On the basis of the aforementioned initial water content of approximately 120 g per core, according to intermediate measurements with decreasing drying speed due to the decreasing water content, an intermediate residual moisture fz corresponding to a water content of approximately 30 g per core resulted at the end of the first cycle in place PL1. These results were remarkably reproducible and essentially constant over a total working time of several hours. After moving the load from place PL1 to place PL2, the intermediate residual moisture fz formed the initial state for the final drying in place in one cycle to place PL2. After this final drying, there was still no measurable water content (final residual moisture equal to zero) for any load, as was specified as the process objective, for example. Equivalent results have also been achieved with larger loads (e.g. up to 130 cores per load) and higher initial moisture levels.

Particularly noteworthy was the comparatively low outlet temperature of the cores of approx. 40 ° C and the cargo containers made of steel profiles of approx. 45 ° C, an indication of a high useful absorption of the microwave, i.e. low loss absorption as a result of wall currents and currents in the metallic fittings or cargo containers. The overall energy efficiency was about 25%.

In the comparative experiment shown in the diagram according to FIG. 2, two loads of 50 cores each, identical to those of the above procedure and with the same water content, were treated in the same microwave chamber, but together and simultaneously, otherwise under the same process conditions. The total electrical power was unchanged at 100 kVA.

The treatment was carried out in a first cycle of 2 x T = 12 min. The duration of treatment for each load was therefore already the same as in the outlet state of the process example according to the invention, but a residual moisture corresponding to a water content of about 10 g per core was always found. An additional treatment time Tr of several minutes was then required to expel the residual moisture. The overall energy efficiency was approx. 20%. In the final state, cores and containers had assumed a considerably higher temperature, namely approx. 65 ° C and approx. 70 ° C, which indicates higher wall currents and correspondingly lower useful absorption.

By splitting the absorption load into several batches of absorptivity, a considerable intensification of the total absorption or an improvement in the energy efficiency and the process efficiency is achieved in a reproducible manner under otherwise identical process conditions. This effect is surprising and presumably cannot be explained elementarily. It is likely to be related to the field distribution and mode formation of the microwave, which depends on the spatial distribution of the absorbents or guide materials embodied by the payload.

It is therefore to be regarded as essential to the invention that in one work cycle a plurality of treatment material loads, which have different absorption capacities, are subjected to the microwave exposure during a heating process, in particular a drying process, which proceeds in the idle state. In general, this can be achieved in such a way that in each work cycle at least two separate treatment material loads, at least one of which at the start of the cycle already has a microwave load which differs in terms of time duration and / or intensity from another charge or a plurality thereof has been exposed to a common microwave field.

According to the exemplary embodiment shown, several, preferably two, charges are advantageously exposed to a common microwave field in one work cycle, one of which has been newly introduced into the microwave field at the start of the work cycle, while the other charge or several of them have already been introduced at the start of the cycle subjected to microwave exposure or a plurality of such cycles. For the subsequent work cycle, the load with the largest loading cycle number is removed and a still unloaded load is introduced.

For the industrial practice of the method, it is particularly favorable if the charges are guided successively in cycles, preferably in a serial arrangement, between an inlet and an outlet through a common microwave field.

Furthermore, it was found to be particularly advantageous, both in terms of efficient energy absorption and also in terms of the process and device expenditure, when the charges are exposed to the microwave field in a common, frequency and mode-splitting resonance room (multimode resonance room).

The device shown in FIGS. 3 to 5 is particularly suitable for carrying out the method according to the invention, but also offers significant advantages in connection with other methods.

The device comprises a microwave chamber MK of the "multimode resonance room" type with a relatively large number of low-power magnetrons, which are arranged in a grid-like distribution on two mutually transversely to the transport direction (arrow P) opposite chamber walls are arranged. The microwave energy is coupled directly into the chamber (without a matching waveguide) through the antenna domes ADM of the magnetrons projecting beyond the inner surface of the chamber wall. The metallic chamber walls form a resonance space which is deliberately delimited on all sides, in which an essentially stationary microwave field with mode and frequency splitting is formed by multiple reflection and superimposition of the coupled waves. This prevents the formation of pronounced vibration nodes and bellies.

Loading doors LT are arranged in the chamber walls, which are opposite to each other in the transport direction P, for the material loading or removal. In principle, such a chamber can handle all the gas exchange processes with only one door, although two or more doors are often more advantageous. It goes without saying that, if necessary, several such microwave chambers can also be functionally and / or spatially constructively combined to form a complex system of high performance.

Furthermore, a material passageway extending between the chamber doors is provided with a transport device TE with feed switches VW. The transport device includes receiving places PL1, PL2 for two loads LD1 and LD2 of treatment material. These receiving places are arranged one behind the other in the microwave direction in the transport direction P.

The drive of the transport device can be designed in a conventional manner and is therefore not shown in detail. It is expediently provided with a clock control device of a known type for the automation of the workflow. As can be seen from FIG. 5, optical position detectors SD are provided in the example with regard to the cyclical positioning of the charges in the method according to the invention Treatment rest positions of the charges are assigned. The loads, each consisting of a large number of relatively small units FKR, here mold cores as mentioned, are accommodated in containers BH1 and BH2 next to and on top of each other in separate receptacles. The containers are designed as frame frames and consist essentially of thin profile bars or tubes, so that the coupling of the microwave field to the material stacks is not adversely affected, even if the frame frames consist of materials with high electrical conductivity or dielectric constant. In a practical embodiment, even containers with metallic profile bars and tubes have been used without the treatment material being noticeably shielded or without undesirably high loss absorption. Furthermore, in the example, a plurality of transport carriers TT are provided, which are adapted to the receiving locations PL1, PL2 and have holding means for cargo containers. Such carriers facilitate the change of charge and are expediently guided in a circuit from the outlet to the inlet of the microwave chamber in order to achieve independence from the various further processing routes of the treated charges.

The feed rollers VW of the transport device are provided with drive shafts AW and support axles TA which, in those areas of the chamber walls which are coupled with comparatively weak field areas and carry only low wall currents, are led through wall recesses into the field-free outside space and are coupled here with conventional drive means, not shown or are stored. For example, a common chain drive can be provided for one chamber side. In the example, the feed-through recesses of the drive shafts or support axles are arranged in wall areas which extend along the longitudinally projecting lower inner edges of the chamber. The sections of the drive shafts or support axles which are adjacent to the end sections and still lie in the chamber interior are also in diameter in the direction of the respectively adjacent chamber wall increasing field influencing elements, here conical roller end sections WE, made of electrically conductive material in order to avoid disturbing field concentrations

Closing surfaces SF of the chamber doors and borders UR of the associated wall openings extend in parallel planes in the open position of the doors, the door bodies being mounted on the chamber housing so as to be longitudinally displaceable and additionally transversely displaceable to the plane of their closing surface between a release position and a cover position with respect to the chamber opening. The borders UR are provided with microwave seals MD of the usual type. In the cover position, the door body is already approximately in front of the wall opening in question, but still at a distance from the border or the microwave seal. This enables the doors to move easily and quickly along most of their long displacement between the release and cover positions. In Figure 3 the entrance-side chamber door is indicated in its covering position, in Figure 5 in its closed position.

In the course of a last, comparatively short part of the longitudinal displacement path, the door body is additionally displaced in its closing position in the direction transverse to the door plane against the edge of the wall opening and the microwave seal. For this purpose, wedge gears KT which can be activated by the longitudinal movement of the chamber door are provided between the chamber door and the chamber housing. These gears essentially consist of wedge elements KE on the outside of the door body and associated support rollers SR arranged fixed to the housing. This construction is characterized by simplicity and operational reliability. Furthermore, by means of self-locking dimensioning of the wedge angle effective in the closed position, possibly reinforced by suitably dimensioned depressions in the wedge surfaces, a secure locking in the closed position can be achieved independently of the door drive. Conversely, this locking is automatically released by the start of the opening movement.

In the example, a plurality of wedge gears are arranged in a multi-point support arrangement, preferably in a three or four point arrangement, distributed over the edge regions of the chamber door. This results in an elegant, because particularly simple securing of the position of the door body in its closing plane.

In addition or in the event that self-locking of the wedge gears is dispensed with, self-locking door drive means TAM which can be disengaged into a freewheeling position are provided in the example. They are shown in detail in FIGS. 4 and 5.

For the longitudinal guidance of the door body TK, a cylindrical rail SH is provided which is fixed to the housing and extends (according to FIG. 4 at right angles to the plane of the drawing) essentially over the width of the chamber and the displacement path of the door. Several guide sleeves FH are mounted on this rail, preferably those with recirculating ball guides. The door body TK is movably suspended on each guide sleeve FH by means of cross guide bolts QB in the direction transverse to the door plane or to the longitudinal displacement direction. During the longitudinal displacement of the door body between the release and cover position, in which there is a distance between the closing surface SF of the door and the border UR of the chamber opening or the microwave seal MD, a compression spring DRF ensures the position of the door body in the transverse direction, by pre-tensioning against it an abutment WDL on the cross guide pin QB. The support rollers SR as components of the wedge gears (not shown in detail here) for the closing movement (see FIG. 5) therefore do not need to participate in this position securing. Such a longitudinal guide is present in the manner shown in FIG. 3 on the upper and lower border sections of the chamber opening.

The guide sleeves FH, each mounted on a rail SH, jointly carry a rack ZS which extends parallel to the rail SH and essentially over its entire length. The pinion RZ of a door drive motor TMO, preferably a self-locking geared motor, arranged in a housing-fixed manner engages with this toothed rack. The door switch connected to the rack ZS via the guide sleeves FH and the transverse guide bolts QB can thus be displaced in its longitudinal direction by a conventional switching control of this motor.

The door drive motor TMO is pivotally mounted with respect to the chamber housing by means of a joint GK about an axis parallel to the longitudinal displacement direction of the door and also - also articulated - connected to a pulling spindle ZSP which leads upwards out of the drive housing ACH. On this spindle sits, for example, a manually actuated release nut AMT, which is supported on the upper edge of a collar KR on the housing ACH. In this way, the pinion can be disengaged from the rack ZS and thus the self-locking door drive can be transferred to a release position. This allows the door to be opened by hand in the event of a power failure (of course when the microwave power is switched off).

In the example shown, the fresh air is fed into the chamber interior via grid inserts GES arranged in the side walls of the chamber, each of which surrounds the antenna dome ADM of a magnetron. The air flow supplied therefore also serves to cool the magnetron. A central suction channel SGK connected to the chamber ceiling is provided for steam extraction.

The treatment chamber MK shown in FIG. 6 corresponds in numerous features to the embodiment according to FIG. 1, which is illustrated by corresponding reference symbols. In this regard, there is no need for another explanation. As an advantageous special feature of the embodiment according to Fig. 6 are provided for the loads LD1, LD2 - again consisting of a large number of relatively small units FKR - transport frames TG1, TG2, which, with their essentially flat underside or formed from rectilinear side members, are directly connected to an appropriately dimensioned transport device TE can kick. In this way, support frames with conventional foot elements projecting relatively far downward can be used in this device, which benefits the inclusion of the charge change operations in the operational transport process. The relevant features of the transport device and the supporting frames are explained in more detail.

As can be seen in FIGS. 6, 7 and 8, the transport device also comprises a multiple arrangement of feed rollers VW in this embodiment. In a departure from the embodiment according to FIGS. 3 and 5, however, the drive shafts AW and support axles TA are guided inside the chamber interior into a drive housing AH or into a bearing housing LH. The corresponding shaft or axis bushings are made microwave-tight to a sufficient extent by means known per se and therefore not shown, so that no disruptive discharges or heating can occur on sharp-edged elements within the housings mentioned. As a microwave sealant, e.g. on the one hand into consideration with the shafts or axes and on the other hand with the housings, electrically conductive rings or lips.

8 shows, in cross section of the box-shaped, elongated drive housing AH, a chain wheel arrangement KRA with which the feed rollers are coupled to one another and to an electric motor M.

The construction of the feed roller arrangement shown in FIGS. 7 and 8 with associated drive or. Storage means inside the microwave chamber offers significant advantages. This means that the chamber walls can be kept free of voluminous shaft and axle bushings and can be optimally designed, for example with regard to the arrangement and design of microwave generators, waveguides, coupling elements, power supplies, auxiliary units such as cooling devices, cooling air ducts and the like. The interior of the chamber also has significantly improved freedom of movement, especially with regard to the design of the transport device. For example, the axial length of the feed rollers and thus the width of the transport device can be kept smaller regardless of the chamber dimensions that may be selected according to microwave technology requirements and can be adapted to the conditions of the treatment material or associated receptacles, holders and the like. Experience has shown that the microwave-technical requirements for the external shaping of the drive or bearing housing, especially with regard to avoiding field concentrations and disruptive discharges as well as local heating, can generally be adequately taken into account without significant effort, at least with field densities that are customary in practice in the microwave room.

A design of the drive or bearing housing in the form of elongated boxes arranged along the continuous path has proven to be particularly advantageous. In the example, a drive housing box AH extending parallel to the continuous path is provided on one long side of the feed roller arrangement and a bearing housing box LH of the same type is provided on the other long side of the feed roller arrangement. In the case of larger longitudinal dimensions, a division into successive housing boxes, which may also be arranged with a mutual longitudinal spacing, is advantageous.

7 and 8 also show the following essential construction and functional features:

The outer side boundaries of the drive or bearing housing boxes - measured transversely to the continuous path - are arranged at a distance from the adjacent chamber walls or from the side edges of the door opening. This favors a relatively intensive formation of the microwave fields in the side area of the transport device and thus a more uniform exposure to the treatment material.

In addition, there are the following significant advantages with regard to material transport:

The transport frames TG1, TG2 shown in FIGS. 6 and 8 are provided on their underside with a support frame TRR which has foot elements FE which project downwards and are arranged on the outer frame corners. This is a widespread frame construction that is advantageous for many transport and continuous treatment functions for small piece goods. In this context, it can be seen from FIGS. 7 and 8 that the width of the transport device TE with feed rollers VW and lateral drive or bearing housing AH, LH lies within the clear width between the foot elements FE projecting downwards. The foot elements are located to the side of the box-shaped housings AH and LH. The transport frames are therefore supported directly on the feed rollers VW with longitudinal spars of their support frames TRR, in such a way that each support frame is always supported on a plurality of rollers. This is illustrated in FIG. 7 by a support frame TRR, indicated by dash-dotted lines in plan view. This enables the transport racks to run continuously without having to attach and remove special auxiliary racks, bridging runners or the like at the transition between the transport routes outside and inside the chamber.

As in the embodiment according to FIG. 1, each chamber door can be moved longitudinally between a release position and a covering position with respect to the chamber opening and can also be moved laterally stored on the chamber housing. In the cover position, the door body is already approximately in front of the wall opening in question, but still at a distance from its border or from the microwave seal. In the course of a last, comparatively short part of the longitudinal displacement path, the door body is also shifted here in the direction transverse to the door plane against the border UR of the wall opening and the microwave seal MD into its closed position by means of wedge drives KT. A special feature in this embodiment according to FIG. 9 is a pendulum-link arrangement PL, by means of which the chamber door is suspended in the direction transverse to the plane of the door regardless of its longitudinal movement on the chamber housing. This results in a particularly simple and reliable storage of the door and enables reliable pressing of the microwave seals.

In the embodiment according to FIG. 6, the fresh air is fed into the chamber interior via grille inserts GES arranged in the side walls of the chamber, each of which is assigned to a magnetron. In the example, a central suction duct SGK connected to the chamber ceiling with a suction fan (not shown, known per se) is provided for the steam extraction. This suction creates a negative pressure in the chamber, which results in corresponding air inflows via the grille inserts, which act as warm air suction for the magnetrons arranged on the outside of the chamber wall in question.

The following in detail with reference to the schematic illustration of a magnetron unit in FIG. 10:

The magnetron MGT arranged on the outside of the chamber wall is provided in a manner known per se with airflow coolants which comprise a lamella cooler LMK and a cooling fan KBL directed against the latter. As indicated by arrows in FIG. 5, this results in an air flow LST, which by means of a guide plate LB acting as a collecting and deflecting means in the Suction area of the associated mesh insert GES is guided and is therefore connected to the chamber interior. This results in a very effective, but advantageously simple cooling device.

These microwave generator units with Magnetron MGT, KBL blower and deflecting or collecting means for the cooling air flow, here in the form of a baffle plate LB, are arranged in a partial housing TGH adjoining the chamber wall in question, which shields the cooling air flow against external interference flows.

Claims (25)

Method for microwave exposure, in particular for drying, of materials, in particular of piece goods stacked in loads, in cyclical operation, at least one component of the treatment material being absorbable and in a predetermined temperature range for the microwave field, characterized in that in one working cycle (T) in each case at least two separate charges (LD1, LD2) of the treatment material, which have different microwave absorption capacity, are exposed to a common microwave field. A method according to claim 1, characterized in that in a work cycle (T) at least two separate, different microwave absorption capacity loads of molds or mold cores (FKR) for the metal foundry are exposed to a common microwave field. Method according to claim 1 or 2, characterized in that in one work cycle (T) at least two separate treatment material loads (LD1, LD2), at least one of which at the start of the cycle is already one compared to another load or several of them with regard to duration and / or has experienced different microwave exposure levels, are exposed to a common microwave field. Method according to one of claims 1 to 3, characterized in that in a work cycle (T) several, preferably two, charges (LD1, LD2) are exposed to a common microwave field, one of which was newly introduced into the microwave field at the start of the work cycle while the other charge or several of them have already been subjected to a work cycle with microwave exposure or a plurality of such cycles at the beginning of the cycle, and that for the subsequent work cycle the charge with the largest load cycle number is replaced by a still unloaded charge. Method according to one of the preceding claims, characterized in that the treatment material loads are carried out successively, preferably in a serial arrangement, between an inlet (E) and an outlet (A) through a common microwave field. Method according to one of the preceding claims, characterized in that in a work cycle (T) a plurality of treatment material loads (LD1, LD2) is subjected to the microwave exposure in the idle state. Method according to one of the preceding claims, characterized in that the treatment material charges (LD1, LD2) are exposed to the microwave field in a common, frequency and mode-splitting resonance chamber (MK). Device for the microwave exposure to materials, for carrying out the method according to one of the preceding claims, with at least one microwave chamber and at least one microwave coupling device connected to this chamber and with at least one chamber door for material loading or removal, characterized in that the microwave chamber (MK ) Has at least two, preferably opposite (LT) and a continuous path extending between these doors with a transport device (TE), the receiving spaces (PL1, PL2) for at least two treatment material loads (LD1, LD2), and that for the transport device (TE) a drive control with predetermined treatment rest positions of the charges (LD1, LD2) associated position detectors (SD) is provided. Device according to claim 8, characterized in that the receiving spaces (PL1, PL2) for the treatment material loads (LD1, LD2) are arranged one behind the other within the microwave chamber (MK) in the transport direction (P). Device for microwave exposure, in particular for drying, materials, in particular piece goods stacked in loads, comprising at least one microwave chamber and at least one microwave feed connected to this chamber and at least one inlet or outlet device designed as a door for material loading or removal, in particular according to claim 8 or 9, characterized by the following features: a) the microwave chamber (MK) is provided with a transport device (TE) which extends along a passage for the material to be treated (FKR); b) the transport device comprises a multiple feed roller arrangement (VW) which extends along the path of the material to be treated and is coupled to drive means; c) the drive shafts (AW) or support axles (TA) of the feed rollers (VW) are in areas of the chamber walls which are coupled with weaker field areas in relation to the mean microwave field intensity and correspondingly lower wall currents, through wall recesses in the field-free outside space guided and coupled here with drive means. Device according to claim 10, characterized in that the lead-through recesses of the drive shafts or supporting axles are arranged in wall areas which extend along the longitudinally projecting inner edges of the chamber (MK). Device according to claim 10 or 11, characterized in that the wall-side end sections of the feed rollers and / or the sections of the drive shafts or support axles which are adjacent to these end sections and still lie in the chamber interior, with field influencing elements (WE) increasing in diameter in the direction of the respectively adjacent chamber wall electrically conductive material are provided. Device for microwave exposure, in particular for drying, of materials, in particular piece goods stacked in loads, comprising at least one microwave chamber and at least one microwave feed connected to this chamber and at least one inlet or outlet device designed as a door for material loading or removal, in particular after a of claims 8 to 12, characterized by the following features: a) the microwave chamber (MK) is provided with a transport device (TE) which extends along a passage for the material to be treated (FKR); b) the transport device (TE) comprises a multiple feed roller arrangement (VW) which extends along the path of the material to be treated and is coupled to drive means; c) the drive means of the multiple feed roller arrangement (VW) are accommodated within the chamber interior in at least one drive or bearing housing (AH or LH), which is provided with at least approximately microwave-tight shaft or axis bushings for the feed rollers (VW). Device according to claim 13, characterized in that the drive or bearing housing (AH or LH) is designed as an elongated box arranged along the continuous path. Device according to claim 14, characterized in that a drive housing (AH) extending parallel to the continuous path is provided on one longitudinal side of the feed roller arrangement (VW) and a bearing housing (LH) of the same type is provided on the other longitudinal side of the feed roller arrangement (VW). Device according to claim 14 or preferably according to claim 15, characterized in that the outer side boundaries of the box-shaped drive or bearing housing (AH or LH) measured transversely to the continuous path at least over part of the box height at a distance from the adjacent chamber walls or from the Side edges of the door opening are arranged. Device according to one of claims 8 to 16, characterized in that a plurality of transport carriers (TT) is provided which are adapted to the shape of the receiving places (PL1, PL2) for treatment material loads (LD1, LD2) in the microwave chamber (MK) and holding means for cargo containers (BH1, BH2). Device for the microwave application of materials, in particular according to one of claims 8 to 17, with at least one microwave chamber and at least one microwave coupling device connected to this chamber and with at least one chamber door for material loading or removal, characterized by the following features: a) the closing surface of the chamber door (LT) and the border (UR) of the wall opening assigned to it extend in the open position of the chamber door (LT) in at least approximately parallel and mutually spaced planes, and the chamber door (LT) is at least approximately parallel to Plane of its closing surface between a release position and a cover position with respect to the chamber opening is longitudinally displaceable and additionally slidably mounted on the chamber housing; b) at least one wedge mechanism (KT) which can be activated by the longitudinal movement of the chamber door (LT) and which moves the chamber door (LT) transversely to the plane of the chamber opening into its closed position is arranged between the chamber door and the chamber housing. Device according to claim 18, characterized in that a plurality of wedge gears (KT) in a multi-point support arrangement, preferably in a three or four point arrangement, is arranged distributed over the edge regions of the chamber door (LT). Device according to claim 18 or 19, characterized in that at least one self-locking wedge gear (KT) is provided. Device for microwave exposure, in particular for drying, of materials, in particular piece goods stacked in loads, comprising at least one microwave chamber and at least one microwave feed connected to this chamber and at least one inlet or outlet device designed as a door for material loading or removal, in particular after a of claims 8 to 20, characterized by the following features: a) the closing surface of the chamber door (LT) and the border (UR) of the wall opening assigned to it extend in the open position of the chamber door (LT) in at least approximately parallel and mutually spaced planes, and the chamber door (LT) is at least approximately parallel to Plane of its closing surface between a release position and a cover position with respect to the chamber opening is longitudinally displaceable and additionally slidably mounted on the chamber housing; b) the chamber door is suspended in its longitudinal movement by a pendulum link arrangement (PL) which is movable in the closing and opening directions on the chamber housing. Device for the microwave exposure to materials, with at least one microwave chamber and at least one microwave coupling device connected to this chamber and with at least one chamber door for material loading or removal, in particular according to one of claims 8 to 21, characterized in that the chamber door between a release position and a closed or cover position is movably mounted with respect to the chamber opening and is connected to a self-locking drive device (RZ, ZS) that can be disengaged into a freewheel position. Device according to one of claims 8 to 22, characterized in that opening and / or closing drive means (TAM) are provided for the doors, which are operatively connected to a clock control device. Device for microwave exposure, in particular for drying, materials, in particular piece goods stacked in loads, comprising at least one microwave chamber and at least one microwave feed connected to this chamber and at least one inlet or Outlet device for material loading or removal, in particular according to one of claims 8 to 23, characterized by the following features: a) the microwave supply comprises at least one microwave generator device (MGT) arranged in the region of at least one outside of the chamber wall and provided with air flow coolants (LMK), in particular a magnetron unit, preferably a plurality of such generator devices, the coupling elements (ADM) of which are connected to the chamber interior Active connection; b) the microwave chamber is connected to a suction device (SGK), which generates a negative pressure atmosphere in the chamber interior during operation compared to the outside environment; c) the coolants (LMK) of the generator device (MGT) are connected to the chamber interior in such a way that a cooling air flow (LST) is created from the outside environment via the coolants into the chamber interior; c) the coolants comprise at least one blower KBL) which acts on the generator device (MGT) with a cooling air flow (LST) running essentially parallel to the acute angle to the chamber wall; d) in the direction of the cooling air flow (LST) behind the generator device (MGT), at least one air passage (GES) is provided in the chamber wall, in the region of which deflecting and / or collecting means (LB) are arranged on the outside of the chamber wall, which provide the cooling air flow (LST) lead at least partially into the intake area of the air outlet (GES). Device according to claim 24, characterized in that the microwave generator device (MGT) with cooling devices and cooling air drive means or conduction means (LMK, KBL, LB) is arranged in a housing space which shields the cooling air flow against external interference flows.

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