DE202017102255U1 - Continuous furnace for heating material by means of microwaves - Google Patents

Abstract

Continuous furnace (4) for heating material (2) by means of microwaves, comprising a treatment space (7) for heating the material (2), wherein in the treatment space (7) one or more openings (6) for introducing the radiation (5) via waveguides are arranged in the treatment chamber (7) and / or the microwave generators in the treatment chamber (7) are arranged directly, at least one endless circulating conveyor belt (1, 8) for transporting the material (2) through the continuous furnace (4), characterized in that the material (2) facing surface of the treatment chamber (7) is at least partially provided with an antistatic coating.

Description

The invention relates to a continuous furnace for heating material by means of microwaves according to claim 1.

In the production of material plates, in particular wood-based panels made of lignocellulose-containing material, it is known to preheat the material scattered to a nonwoven before pressing in a press. Due to the higher heat at the beginning of the compression, the press needs less time to completely heat the fleece. Accordingly, the press can be made shorter or operated faster. In particular, hot-air or steam preheating systems or the use of high-frequency radiation, for example microwaves, for preheating in microwave continuous furnaces, referred to below as the continuous furnace, have proved successful. The physical principle is based on the conversion of electromagnetic energy into heat energy in the absorption of microwaves by the material to be heated.

So it is for example from the DE 197 18 772 A1 It is known to expose the material scattered to a nonwoven fabric to microwaves prior to introduction into a heated, preferably continuously operating press so as to accelerate a subsequent heating and pressing operation. The heating with microwaves has the advantage that the desired heat is generated directly in the product by the microwaves penetrate into the product, are absorbed and there to stimulate existing water molecules or other electric dipoles to vibrate. In contrast, when using hot plates or hot air preheating systems or the like, the heat is applied substantially from the outside, whereby a full penetration of the product to be manufactured with this heat can not always be guaranteed. In the case of products preheated by means of microwaves, such a heat distribution is to be ascertained in the heated press in which the core of a product also reaches a desired temperature, without critical temperatures already being exceeded during pressing on the areas lying further outside.

Compared to the use of steam preheating systems, the use of microwaves has the advantage that no additional moisture is introduced into the material to be compacted during preheating. Due to the additional moisture which is introduced with the Dampfvorwärmsystemen, the material is to be dried prior to application to the conveyor belt such that the maximum moisture content of the material before pressing by adding moisture, such as steam, is not exceeded. This leads already in the pretreatment of the material to an intensive drying of the material and high energy consumption.

When using microwaves or high-frequency radiation in a continuous furnace to heat the material can be dispensed with intensive drying of the material under maximum moisture in advance, which has a positive effect on the energy balance.

In known microwave ovens, as used in the field of gastronomy or in the household, a hermetically delimited treatment chamber is usually provided, which is to be sealed off to the outside with respect to the leakage of microwaves.

In contrast, in the continuous furnace described here, the material to be treated is deposited on a for the radiation, especially microwaves, permeable conveyor belt and transported by this through the treatment room, the material to be treated both from below and possibly even from above evenly with microwaves is irradiated.

The problem with this is that the conveyor belt due to the requirements of transparency for microwave radiation consists of plastic, for example polyester, so that it may possibly come to electrostatic charges during its movement over a wall chamber covering the bottom area, since such floor areas also made a microwave-permeable plastic, for example made of polypropylene, so that for a homogeneous heating of the material 2 and radiation 5 can be introduced below the material and thus below the bottom area in the treatment room and absorbed by material.

In the case of the relative movement of the conveyor belt relative to these floor areas, it may be due to triboelectric effects for the separation of charges and thus to an electrostatic charge. This transmits and also affects the material to be treated. As a result, individual charged particles of the material tend to dislodge from the mat, particularly from its surface, during transport through the continuous oven.

Such dissolved particles then settle within the treatment room, especially at exposed locations. Here form corresponding agglomerates. These can lead to malfunctions of various kinds, be it that they disturb a uniform distribution of microwaves within the treatment room, be it that they grow and detach from a certain size and fall back on the cake, which can lead to unwanted irregularities in this, or even that they ignite in unfavorable constellations.

Object of the present invention is therefore to prevent such accumulation of electrostatically charged particles within the treatment room.

This object is achieved according to the invention for a continuous furnace in that the material-facing surface of the treatment chamber is at least partially provided with an antistatic coating.

The advantage of the invention is that the antistatic coating forms a uniformized electrostatic field within the treatment space, so that there is no longer any excessive compaction of field lines at optionally exposed areas. As a result, there are no longer any punctual deposits of charged particles from the material, and thus agglomerates of such particles with the disadvantages described above are avoided.

In a preferred embodiment of the invention, the antistatic coating is designed as a paint or as a paint. In this way, it is particularly easy to apply within the treatment room.

In a development of the invention, the antistatic coating is designed to be electrically conductive. As a result, electrostatic charges can be derived directly and in this way the problems can be avoided.

Preferably, only the side walls of the treatment space, which run parallel to the production direction, coated.

Advantageously, the material used is a lignocellulosic material, such as chips or fibers of wood.

A preferred embodiment provides that an absorption chamber is arranged adjacent to and / or after the treatment space. In this way it can be ensured that radiation which is not absorbed by the material and can not escape from the continuous furnace.

Preferably, at least one Deionisationselement for deionization of the conveyor belt is arranged. As a result, the generated charge can be at least partially subtracted from the conveyor belt.

Further advantages and features of the invention will become apparent from the following description of an embodiment.

• 1 eine Prinzipskizze eines erfindungsgemäßen Durchlaufofens.

Showing:

• 1 a schematic diagram of a continuous furnace according to the invention.

In the 1 can be seen a schematic diagram of a continuous furnace 4 for heating material 2 , in particular of lignocellulosic material 2 , as used for example in the wood-based panel industry for the production of wood-based panels. Lignocellulosic material 2 , such as chips or fibers, is placed on an endlessly circulating conveyor belt 1 scattered to a mat or a nonwoven and in the production direction 3 a continuous furnace only symbolically represented here 4 fed. The continuous furnace 4 includes a treatment room 7 in which the material 2 , which is present here in the form of a mat or a fleece, with radiation 5 , in particular with microwave radiation, is irradiated from below and / or above.

If necessary, it can be the top of the material 2 by means of another conveyor belt 8th be covered at the same speed as the material 2 through the treatment room 7 starts to rotate. The upper conveyor belt 8th that on the material 2 rests on the one hand has the function of the surface of the material present as a mat 2 Protect if this by the continuous furnace 4 and, on the other hand, it also prevents particles, such as product fibers, dust, etc., from easily separating from the surface of the material 2 to solve.

In the treatment room 7 becomes the radiation 5 preferably above and / or below the material 2 introduced to a uniform heating of the material 2 to ensure. The radiation 5 can by means of microwave generators (not shown) outside the continuous furnace 4 be generated and waveguide via openings 6 in the treatment room 7 of the continuous furnace 4 be coupled. Alternative may be the radiation 5 also within the treatment room 7 generated, resulting in waveguides and the corresponding openings 6 can be waived. The radiation generator for generating the radiation 5 within the treatment room 7 or the openings 6 for the entry of radiation 5 in the treatment room 7 are preferably at a distance from the material 2 arranged around a spatial, in particular even propagation of the radiation 5 in the complete treatment room 7 to enable.

In production direction 3 before and / or after the treatment room 7 are in the example shown here absorption chambers 9 arranged with which prevents being in the treatment room 7 introduced radiation 5 , In particular microwave radiation, in an undesirable manner from the continuous furnace shown here 4 can escape. In the absorption chambers 9 will the residual radiation, which is not from the material 2 was absorbed on absorption elements 11 For example, water storage or plates made of ceramic materials, passed to which the residual radiation is converted into heat and destroyed.

In the area of the treatment room 7 runs the lower conveyor belt 1 with its bottom over one for the radiation 5 or microwave permeable plate 7 , Instead of a plate 7 From microwaveable material may also be provided a grid structure or the like, which is the radiation 5 lets go through and at the same time can take a carrying function, so that the lower conveyor belt 1 , which is loaded with the weight of the mat, does not sag.

Because the conveyor belt 1 . 8th and the plate 7 consist of different plastics, it comes due to triboelectric effects to an electrostatic charge. The case on the conveyor belt 1 . 8th Charges arising from this are partly due to the material 2 delivered, which thus also charges electrostatically or already, for example by the scattering, has an electrostatic charge. Individual particles of the material 2 , in particular if they are arranged on the edge, detach from the material due to this electrostatic charge or by the electric field generated by the charge separation 2 and then fly especially into the treatment room 7 ,

So that such separated, electrostatically charged particles do not precipitate in an undesired manner is within the treatment room 7 their surface, preferably the surface of the side surfaces, which are parallel to the production direction 3 run, at least partially provided with an anti-static coating.

Because of this antistatic coating, it is prevented that the mentioned electrostatically charged particles precipitate in an undesired manner and possibly form agglomerates which can disturb the operation of the flow unit.

The mentioned coating may in particular also be an antistatic paint.

It is also within the scope of the invention, if an electrically conductive coating is used here, in order to be able to derive electrostatic charges directly in this way.

LIST OF REFERENCE NUMBERS

1

conveyor belt

2

material

3

production direction

4

Continuous furnace

5

radiation

6

openings

7

treatment room

8th

conveyor belt

9

absorption chamber

10

plate

11

absorbing elements

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19718772 A1 [0003]

Claims (8)

Continuous furnace (4) for heating material (2) by means of microwaves, comprising a treatment space (7) for heating the material (2), wherein in the treatment space (7) one or more openings (6) for introducing the radiation (5) via waveguides are arranged in the treatment chamber (7) and / or the microwave generators in the treatment chamber (7) are arranged directly, at least one endless circulating conveyor belt (1, 8) for transporting the material (2) through the continuous furnace (4), characterized in that the material (2) facing surface of the treatment chamber (7) is at least partially provided with an antistatic coating. Continuous furnace (4) after Claim 1 , characterized in that the antistatic coating is a paint. Continuous furnace (4) according to one of Claims 1 or 2 , characterized in that the antistatic coating is electrically conductive. Continuous furnace according to one of the preceding claims, characterized in that the side walls of the treatment space (6), which run parallel to the production direction (3), are coated. Continuous furnace (4) according to one of the preceding claims, characterized in that the material (2) is lignocellulose-containing material. Continuous furnace (4) according to one of the preceding claims, characterized in that the material is lignocellulose-containing material. Continuous furnace (4) according to one of the preceding claims, characterized in that an absorption chamber (9) is arranged adjacent to and / or after the treatment space (7). Continuous furnace (4) according to one of the preceding claims, characterized in that at least one deionization element for deionization of the conveyor belt (1, 8) is arranged.

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