DE19648366C1 - Thermal treatment system for products using microwave energy e.g. ceramics - Google Patents

Abstract

The system includes a heating chamber with a housing (10) and a thermal insulation (12) arranged on the inside of the housing. A microwave energy source is used for coupling in of the microwaves across a coupling unit (14) into the heating chamber, treatment chamber (16). At least one body (22) absorbing microwaves, is arranged between the products (20) to be treated and the housing. The body has the function of a temp. probe and is connected to an evaluation unit. The probe records a temp. actual value which is compared with a reference desired value, and the microwave energy to be coupled in is adjusted corresp. to a possible difference value.

Description

The invention relates to a system for thermal treatment development of products using microwave energy.

Such systems are in EP 0 500 252 B1 and WO 95/05058. In particular WO 95/05058 gives a comprehensive overview of the state of the art Heat treatment of various products, in particular Ceramic parts to which reference is made.

Heated opposite, electrically or with fossil fuels ovens are expected from furnace systems that use micro wave energy are operated, especially an accelerator the combustion process, especially for large-volume ones Molded parts, as well as an optimization of the material properties of the kiln.  

WO 95/05058 also describes problems with "microwave-heated" ovens, which can be summarized as follows:
Due to the heat loss of the fired material that is heated from the inside, a parabolic temperature profile across the cross-section arises, particularly in the case of large-volume parts. In the case of materials which have a so-called "thermal break-away" effect, in which the coupling takes place suddenly at a certain temperature level, there is considerable thermal tension in the firing material.

In general, this represents completely different microwave Absorption behavior of different materials is a problem There are materials in which the absorption ver keep largely constant over large temperature ranges. Others show a sinusoidal course, some call it thermal break-away effect.

In the case of discontinuously operating furnaces, one possibility arises minimal temperature difference between the inside of the Brenngutes and the environment at any time of the day Firing cycle. The same applies to continuous ovens also along the transport route, i.e. at every point.

A dense stock of firing material makes the formation of a difficult more or less constant temperature levels. Through the described heat losses arise on the outside a greater temperature gradient between the core and outer surface as between the core and the inside or in workpieces that are arranged in the center.  

In order to overcome these problems, a microwave oven has been proposed in the prior art to combine with a conventionally heated chamber, via which convection and radiant heat into the Microwave chamber is transmitted. There are two heating systems and a relatively complex one Oven construction needed.

DE 37 06 336 C1 discloses a device with microwave heating, in which the inner wall of the Device via inserts which can be inserted temporarily into the furnace space to a specific measured temperature is heated. At this temperature, the inserts lose their function and are removed from the Oven chamber moved out.

DE 37 36 365 C2 describes a microwave oven with combined heating (resistance heating, Microwaves). If heating is carried out with the resistance heating, a temperature measurement takes place. With microwave heating this is not provided and also not possible.

The invention has for its object a system for the thermal treatment of products to specify, at which - with exclusive microwave heating - a temperature profile for the to be treated The product can be set with as little delay as possible.

In its most general embodiment, the invention comprises a system with the features of the claim 1.

Only one heating chamber (where the term includes heating channels from continuous ovens) is required. In addition to the products to be treated, bodies are placed in the heating chamber that absorb microwaves and have the following functions:
The surfaces of the bodies serve as absorption surfaces and reflection surfaces for the coupled or reflected microwaves. They are heated or cooled to a certain temperature level accordingly. The bodies remain more or less static in the heating chamber, which means that they are usually only removed if they are defective. The temperature of the bodies in the heating chamber can be determined at any time. The measured temperature values indicate whether the temperature level in the furnace has to be increased or decreased. The required microwave energy can be additionally fed in or the microwave energy fed in is reduced via an associated control or control device.

In this way, the microwaves absorb Body two functions:

• 1. The function of heating / cooling surfaces,
• 2. the function of temperature sensors.

At the same time, heat loss from the products to the Atmosphere or isolation significantly reduced or even ver prevents because the body according to the invention treating products and the housing of the heating chamber are arranged.

They can both be fed through the microwave Heat energy as well as by reflected microwaves.

Basically, it would be possible to use the body (s) instead of the use thermal insulation. However, it appears in beneficial in several ways, multiple bodies within the  Arrange heating chamber, spaced from each other to the products to be treated around or between the products to be in the immediate vicinity of the treated Products absorption surfaces and temperature measuring points too create.

For example, firing material is placed in a certain furnace section a continuous oven, so it can get colder, be warmer or warmer than the one mentioned Body pre-heated to target temperature. As long as namely, in the case of a continuously operating furnace, none yet When the kiln is fed, the body mainly serves as Heating surfaces.

If there is a temperature difference between the firing material and the Bodies find a temperature with practically no delay equalization instead. If the fired goods are warmer, there is one practically instantaneous warming of the body. The the currently measured temperature is compared with a reference Value compared and corresponding to any difference the microwave energy to be coupled in is worth it set. This applies analogously to the case that the The temperature of the fired material is lower than that of the neighboring one Body, in which case the heat transfer is reversed runs and the temperature of the body drops analogously.

It is therefore a feature of the invention that System with a device for determining current Training temperature values in the heating chamber and a Provide control unit with which one of the Temperature sensor registered actual temperature value  comparable with a reference target value and accordingly the possible microwave value to be coupled in Energy is adjustable.

This way, with a single type of heating (Microwaves) and a single heating chamber not just that Possibility created a certain temperature profile (time-dependent), but also the temperature in to compare the heating chamber over the entire cross-section moderate.

This not only leads to a reduction in thermal Tensions in the kiln, but above all to be optimized Material properties of the treated products as well a reduction in overall treatment time.

Usually the housing of the heating chamber is on the inside have insulation. Is the coupling device arranged outside the insulation, so the insulation Be microwave-permeable.

The bodies mentioned fulfill their task in particular Dimensions, if they consist of thin elements of low mass, for example from thin plates, webs or pipes. Of the The term "thin" becomes a few millimeters Understood. The bodies react to the low mass Temperature changes in the furnace space practically delayed free. This enables an equally immediate adjustment of the Microwave energy to be fed in and thus practical instantaneous regulation.  

Thin plates can also be easily separated between neighboring ones Assemble products (firing parts).

Basically, the body can be made of the same material as the products to be treated exist.

Because of the different described above Absorption behavior of the individual materials at under however, this behavior will occur at different temperatures the selection of the body is taken into account, especially when continuously operating stoves, in which the firing material for example from a heating zone via a burning zone in a cooling zone is run.

According to the material of the respective firing material and the required firing curve are also size in the same way and arrangement of the bodies and their material selection festge sets.

As a rule, products in an oven (a heating chamber) of a genus, for example porcelain, Ferrite or the like, this selection must be the body and their order is not constantly changed; much more As a rule, it is sufficient to apply this once to the firing material as well as to set the furnace conditions.

At least part of the bodies arranged in the heating chamber can also consist of a material that adjusts bares absorption behavior towards microwaves.

Especially with continuously working ovens in addition, the microwave feed in sections can be regulated separately, for example for heating,  Burning and cooling zone. Microwaves can also be the same Propagation characteristics (homogeneous microwave energy) and Microwaves with different propagation characteristics (inhomogeneous microwaves).

Further features of the invention result from the Features of the subclaims and the other filing documents.

The invention is illustrated below by means of an embodiment game described in more detail.

The only figure shows a vertical section through a heating chamber of a continuously operating furnace Treatment of ceramic fired goods.

The heating chamber comprises a housing 10 and an inner insulation 12 which is permeable to microwaves. Rollers 15 extend across the width of the heating channel through corresponding openings in the housing 10 and the insulation 12 . The rollers 15 are driven on the outside, as is known from conventional roller ovens.

Openings 14 are arranged in the bottom 10 B and in the ceiling 10 D of the housing 10 , via which microwaves are coupled through the insulation 12 into the treatment space 16 enclosed by the insulation 12 .

On the rollers 15, which are arranged one behind the other in the transport direction of the firing material, there are underlay plates 18 for the products 20 to be fired, the firing material 20 being guided through the treatment chamber 16 in accordance with the transport movement of the rollers 15 .

Above and next to the products 20 to be burned, thin plates 22 made of a microwave-absorbing material are arranged, the plates 22 here having a thickness of only 5 mm.

The figure shows that a corresponding body 22 is arranged in the washer 18 , horizontally and parallel to the rollers 15 aligned.

Another body 22 is arranged between the two workpieces 20 shown in the figure in a vertical orientation.

A temperature sensor (not shown) is arranged on each of the plates 22 . The temperature sensors are connected to an evaluation unit (also not shown). There, the temperatures currently measured on the bodies 22 are determined (actual value) and compared with target temperature values which are desired in the corresponding furnace section.

If the firing material 20 now has a temperature in the relevant furnace section that is lower than the temperature of the plates 20 , heat transfer takes place between the plates 22 and the firing material 20 . In parallel, the temperature of the plates 22 drops, which is registered directly in the evaluation unit. A comparison of the actual values from the target values then leads without delay to a corresponding signal to a (not shown) microwave energy source, which adjusts the (increased) microwaves to be coupled in according to the difference value and couples them into the treatment room 16 via the openings 14 .

In this way - without separate heating devices - the thermal treatment of the firing material 20 in the treatment room 16 takes place exclusively by means of microwave energy, in such a way that, due to constant temperature monitoring and (post) regulation of the microwave energy to be coupled in, a largely constant temperature profile is obtained over the cross section of the treatment room 16 and thus also within the products 20 to be treated.

Claims (11)

1. Plant for the thermal treatment of products ( 20 ) by means of microwave energy with the following features:

• 1.1 a heating chamber with a housing ( 10 ) and a thermal insulation ( 12 ) arranged on the inside of the housing ( 10 ),
• 1.2 a microwave energy source, from which the micro waves can be coupled into the heating chamber (treatment room 16 ) via a coupling device ( 14 ), and
• 1.3 at least one microwave absorbing body ( 22 ) which is arranged between the products to be treated ( 20 ) and the housing ( 10 ) of the heating chamber, wherein
• 1.4 the body ( 22 ) has the function of a temperature sensor and is connected to an evaluation unit with which an actual temperature value registered by the temperature sensor can be compared with a reference target value and the microwave energy to be coupled in can be set according to a possible difference value .

2. Installation according to claim 1, wherein the or the body ( 22 ) between the products to be treated and the insulation ( 12 ) of the heating chamber is (are). 3. Plant according to claim 1 with a plurality of bodies ( 22 ) which are arranged at a distance from one another around the products ( 20 ) to be treated or between the products ( 22 ). 4. Installation according to claim 1, wherein the one or more bodies ( 22 ) consist of thin plates, webs or tubes. 5. Plant according to claim 1, wherein the body ( 22 ) consist of a material with low heat storage capacity. 6. Plant according to claim 4, wherein the body ( 22 ) have a maximum thickness of 10 mm. 7. System according to claim 1 with a through-channel formed from the heating chamber and a device ( 15 ) for transporting the products ( 20 ) through the heating channel ( 16 ), in which the microwave-absorbing body ( 22 ) one behind the other in the transport direction of the products ( 20 ) are arranged in different heating duct zones. 8. Installation according to claim 7, in which different bodies ( 22 ) - viewed in the transport direction of the heating duct ( 16 ) - differ in at least one of the following features: size, shape, arrangement in the heating duct, material. 9. Plant according to claim 1 with a microwave for casual insulation ( 12 ). 10. Plant according to claim 1, in which at least part of the bodies ( 22 ) arranged in the heating chamber consists of the same material as the products ( 20 ) to be treated. 11. The system of claim 1, wherein at least a portion of the body ( 22 ) arranged in the heating chamber consists of a material which has an adjustable absorption behavior towards microwaves.