EP1231434A2 - Method for the combustion of materials of low-combustibility - Google Patents

Abstract

A method for incinerating otherwise difficult to burn material has the inlet air passed through an ioniser to ionise the oxygen into ozone. This produces a highly reactive gas which enhances the burn which efficiently reduces the materials without causing build-up of carbon and unburnt residues. The gas flow rate is regulated to match the burn requirement.

Description

The invention relates to a method for burning of flame-retardant material, the material in a combustion chamber of a burnout furnace with feed is burned by air. The invention also relates a device for burning combustible Material according to the preamble of claim 9.

Models in wax or sintered are used in the furnace Parts embedded in plaster, sand or ceramic melted out at a high temperature and the remaining Rest with an even higher temperature (above 600 ° C burned. This happens through the combustion with air in a chemical reaction.

Such burnout furnace are, for example, in the Used in the jewelry industry or in foundry needs, where wax and cast resin bound materials, which in Sand, ceramics or plaster are embedded, burned out become.

Most of the kilns built so far take place incomplete combustion of the embedded models (e.g. wax) instead. This creates smoke and Charring of the residual material. The charred material is driven out by the smoke and sets partly in the combustion chamber and also in the forms firmly.

The smoke created by the charred material is contaminated the environment. This problem is mostly caused by the - costly - limited use of a catalyst.

The far bigger problem is that the charred material on the ceramic, plaster, or sand molds sticks. It prevents the complete Emptying the cavity used for casting metals is necessary. It also combines with the melt and the cast parts and thus leads to one poor surface and defects in the castings.

Experiments are known from practice, by a higher Air supply to prevent charring or flush.

Many materials, especially sintered parts and resin-bound materials, charring, despite air supply, through the resulting temperature shock instead burn completely.

The present invention is based on the object a method and an apparatus for burning difficult to burn material by means of a burn-out furnace to create an almost smoke - free and residue-free combustion of the material, if possible at low temperatures, preferably in short Firing cycles should be achieved.

According to the invention this object is achieved in that the air supplied to the combustion chamber of the burnout furnace is ionized.

According to the invention, this object is also achieved by the characterizing part of claim 9 solved.

Because the air supplied to the combustion chamber ionizes is the result of extensive tests has shown a smoke-free and residue-free Burning the difficult to burn material. This is already at temperatures of only a maximum of 650 ° C possible. In addition, short firing cycles can go through a resulting from the ionized air rapid reaction start already achieved when heating up become.

Ionization converts oxygen molecules (O ₂ ) into an ion, which creates ozone (O ₃ ). The ozone formed is an unstable ion and is very quickly split into the molecule (O ₂ ) and the atom (O).

The ozone is an aggressive gas that is very quickly disassembled. The released O-atom connects with other O atoms to form an oxygen molecule. However, the O atoms prefer a chemical reaction with foreign material, especially carbon (C) and carbon monoxide (CO). This creates a compulsion for complete combustion.

The difficultly combustible lead in an advantageous manner Materials are forced to a chemical Reaction. The result is clean combustion without smoke in the form and in the Combustion chamber. The firing results are residue-free and only need a low energy consumption. In addition, carbon precipitation or Deposits in the combustion chamber avoided. thats why no closed heating coil necessary and it can an open heating coil can be used.

By the inventive method or the inventive Device will be the health burden Reduced gases and vapors. As in experiments has shown, protects the method according to the invention or the device according to the invention the shape, so that a high mechanical resistance is guaranteed is.

As has been shown in experiments, the Method according to the invention all known 3D models made of polystyrene, polystyrene (SLS), STL materials, Thermopolymers and even those infiltrated with wax or resin Starch / cellulose for metal investment casting directly embedded in plaster, ceramic or sand and at Temperatures around 600 ° C are burned out without residue.

The resulting pollutants are also neutralized. With the method according to the invention or by the device according to the invention, each difficult to burn material at low temperatures can be burned out smoke-free from a maximum of 650 ° C.

By the inventive method and the inventive Prototype can be made of metal inexpensively and in a particularly simple manner of excellent quality.

The inventive method and the inventive Device can be particularly advantageous can be used for the well-known 3D inkjet process. The models created by the 3D inkjet process can be used for model investment casting directly in plaster molds be embedded. Pass through these procedures the models made of flame retardant, with wax or Resin infiltrated starch / cellulose. After extensive and lengthy trials at different temperatures the models were completely successful in the mold at low temperatures of maximum 650 ° C to burn smoke-free. The possibility of the models Made of starch material, smoke-free and without residues burnout reduces lead times and improves the quality of the parts considerably.

It is advantageous if the amount of the combustion chamber supplied, ionized air by means of an air flow control device is checked.

As has been shown in experiments, the combustion process by means of an air flow control device control in a particularly advantageous manner. Thus a minimal activated air (ionized) into the combustion chamber of the burnout furnace.

By the air flow control device, the conditioned air is controlled in the combustion chamber of the Bring the burnout furnace.

According to the invention it can be provided that the Air before being fed into the combustion chamber by means of a Air ionization device is ionized.

The ionization of the air by a known principle Air ionization device has been in trials turned out to be particularly suitable and inexpensive.

Advantageous refinements and developments result itself from the further subclaims and from the shown in principle below with reference to the drawing Embodiment.

Fig. 1

eine schematische Darstellung eines Ausbrennofens, einer Luftionisierungseinrichtung und einer Luftdurchflußregeleinrichtung; und

Fig. 2

eine Luftdurchflußregeleinrichtung gemäß Fig. 1 im Detail.

It shows:

Fig. 1

a schematic representation of a burnout furnace, an air ionization device and an air flow control device; and

Fig. 2

an air flow control device according to FIG. 1 in detail.

The inventive method and the inventive Device are based on the in the first and 2 illustrated principle explained in principle, however, are not limited to this. The one in Fig. 1 Burnout furnace 1 shown is particularly suitable for the production of prototypes from metal. The stake such a burnout furnace 1 or the burnout However, difficult to burn material various other, obvious to the expert Reasons.

Burnout furnaces can be of different designs, for example as a chamber, slide-in car or hood oven be trained. The device according to the invention as well as the method according to the invention for all conceivable burnout furnaces 1. Since burnout furnaces are known in principle, is that contained therein Combustion chamber not shown.

The burnout furnace 1, as shown in FIG. 1, ionized air supplied through an air inlet 2, those in the combustion chamber of the burnout furnace 1 for one complete and smoke-free combustion of the heavy combustible material leads.

In the illustrated embodiment, the ionized Air through a heat exchanger 3 below Tool 4 blown in. The tool 4 is the expert common and therefore not shown in detail.

As can also be seen from Fig. 1, the air before being fed into the burnout furnace 1 or its Combustion chamber by means of an air ionization device 5 ionized. Through the air ionization device 5 the air ionization device 5 is supplied Air is converted from the molecular to the ionic state. Then the ionized air enters the air 2 of the burnout furnace 1 supplied.

As can be seen from Fig. 1, is an air flow control device 6 for the metered supply of Air provided. It can thus be done in a simple manner the amount of fuel fed into the combustion chamber Air ionization device 5 Check ionized air. The combustion in the burnout furnace 1 or the combustion chamber can be controlled by the air flow control device 6 or the supplied ionized air Taxes.

In the illustrated embodiment, the air flow control device 6 in the direction of flow Air arranged so that the air flow control device 6 in front of the air ionization device 5 happens. In alternative configurations However, the air flow control device 6 can also between the air ionization device 5 and the Burnout furnace 1 may be arranged.

As can also be seen from FIG. 1, the Air flow control device 6 with an air pressure regulator 7 and a flow indicator 8 is formed. The compressed air is controlled by the air pressure regulator 7, which can also be called a maintenance unit, controlled or regulated. The air pressure regulator 7 will through an air pressure regulator input 9 with compressed air provided.

In one embodiment of the invention can be provided be that the air ionizer 5 for conversion of oxygen from the air in ozone, a component of the burnout furnace 1.

In one embodiment of the invention can also be provided that the air flow control device 6, the combustion chamber, and the air ionization device 5 components of the burn-out furnace 1.

The use of the air ionization device is particularly advantageous 5 with the air flow control device 6, which the air flow into the burnout furnace 1 controlled and thus a smoke-free and residue-free Burn the material in a particularly suitable way Way.

The air ionization device 5 for ionizing the Air and the air flow control device 6 can as separate from the burnout furnace 1 or the combustion chamber and thus connectable unit are formed. This ensures that this unit to everyone Burnout furnace 1 can be connected or retrofitted can. By burning residual gases and vapors this system also serves as a catalyst.

In a particularly advantageous embodiment, be provided that the ionized air from the outside in the combustion chamber designed as an electrical combustion chamber to be led. Alternatively, the combustion chamber also be designed as a gas furnace. The combustion process in the combustion chamber is complete Combustion carried out.

Fig. 2 shows an air ionization device known in principle 5. The air ionization device 5 consists of a safety switch 10, one Current control unit 11, a high voltage transformer 12, an air pressure vessel 13, ionizing plates 14 and an air inlet 15 and an air outlet 16. Since such air ionization devices 5 in principle are known, this will not be discussed in more detail.

Claims (16)

Method for burning difficultly combustible material, the material being burned in a combustion chamber of a burnout furnace with the supply of air,
characterized in that
the air supplied to the combustion chamber of the burnout furnace (1) is ionized. Method according to claim 1,
characterized in that
the air is ionized by means of an air ionization device (5) before being fed into the combustion chamber. The method of claim 1 or 2,
characterized in that
the amount of ionized air supplied to the combustion chamber is controlled by means of an air supply control device (6). The method of claim 1, 2 or 3
characterized in that
the ionized air is led from the outside into the combustion chamber, which is preferably designed as an electrical combustion chamber. Method according to claim 2, 3 or 4,
characterized in that
the air ionization device (5) converts oxygen from the air into ozone. Method according to one of claims 1 to 5,
characterized in that
the combustion in the combustion chamber is controlled by the amount of ionized air supplied. Method according to one of claims 1 to 6,
characterized in that
the combustion in the combustion chamber is carried out until the material to be burned is completely burned. Method according to one of claims 1 to 7,
characterized in that
the combustion takes place at a low temperature of a maximum of approximately 650 ° C., preferably 600 ° C. Device for the combustion of difficultly combustible material, in particular for the production of prototypes from metal, with a burnout furnace, which has a combustion chamber with an air inlet, through which air can be introduced into the combustion chamber,
characterized in that
the air that can be introduced into the combustion chamber of the burnout furnace (1) is ionized. Device according to claim 9,
characterized in that
An air ionization device (5) is arranged in front of the air inlet (2) of the combustion chamber. Device according to claim 9 or 10,
characterized in that
an air flow control device (6) is provided for the metered supply of air. Device according to claims 10 and 11,
characterized in that
the air flow control device (6) is arranged upstream or downstream of the air ionization device (5) in the flow direction of the air or ionized air. Device according to claim 11 or 12,
characterized in that
the air flow control device (6) has an air pressure regulator (7) and a flow indicator (8). Device according to one of claims 9 to 13,
characterized in that
the air ionized by the air ionization device (5) can be blown into the burnout furnace (1) or the combustion chamber through a heat exchanger (3). Device according to one of claims 9 to 14,
characterized in that
the air ionization device (5) for ionizing the air and the air flow control device (6) are designed as a unit which is separate from the burnout furnace (1) or the combustion chamber and can be connected to it. Device according to one of claims 9 to 14,
characterized in that
the air ionization device (5) for ionizing the air, the electrical combustion chamber and the air flow control device (6) are designed as components of the burnout furnace (1)

Images