DE3935031A1 - radiant heater - Google Patents

Abstract

A radiant heat unit consists of a heating element, a heating element support and a thermal insulation located below the heating element support and is characterized in that the heating element support does not cover the entire surface of the underlying thermal insulation and the thermal insulation consists of a microporous thermal insulator. This radiant heat unit is used to heat a plate, in particular a glass ceramic plate, in radiant heaters of bakery ovens, in radiant heaters and halogen radiators.

Description

The invention relates to a radiant heating unit, enthal tend a heating element, a Heizelementträger and an under the heat element carrier arranged heat insulation.

Such radiant heating units are known from DE-A- 21 65 569, DE-A-25 51 137 and the corresponding US-A-41 61 648, 27 60 339 and EP-A-2 04 185 or the corresponding US Pat. 47 13 527.

DE-A-21 65 569 describes part-surface or full-surface Trä ger for the heating elements and an optionally below the Carrier arranged heat insulation consists of in layers ordered mineral and / or glass wool to a resilient To allow storage of the carrier.

DE-A-25 51 137, DE-B-23 39 768, DE-C-27 30 339 and EP-A-2 04 185 be write each full-surface carrier for the heating elements, wherein the heating element optionally in or on for seen recesses or supernatants by hanging up, Clamping or gluing can be attached, and one under the Carrier arranged thermal insulation of microporous heat insulation material.

As for the Heizelementträger a mechanically relatively solid Material is needed, the same time high temperature is, such materials have low thermal insulation ability, whereby full-surface configurations of heating Element carrier counteract high efficiencies.  

The object of the invention is to provide a radiant heating unit create, which is easy to handle during assembly and high efficiencies possible.

The invention relates to a radiant heating unit, containing a heating element, a Heizelementträger and a arranged under the Heizelementträger heat insulation, the characterized in that the Heizelementträger not over the entire surface with respect to the surface of the arranged underneath Heat insulation is formed and the heat insulation off a microporous thermal insulation material.

In a radiant heating unit according to the invention redu the total energy consumption is up to 10% on a radiant heater, where the heating element on a besiege full-surface heating element carrier.

The mounting of the radiant heating unit according to the invention is much easier because the heating element outside the Radiation heating unit introduced into the Heizelementträger can be and subsequently the final assembly to complete Radiation heating unit can be done. This is special because of the low mechanical stability of the heat isola tion of microporous thermal insulation of advantage.

The Heizelementträger is not full according to the invention flat with respect to the surface of the arranged underneath Thermal insulation formed. He covers preferably 5 to 70%, especially 10 to 20%, of the area of the lower ordered heat insulation.

For the heating element carrier is a mechanically fixed Material needed, the thermal shock resistance, high  temperature resistance, low temperature-related exp tion and shrinkage and / or high electrical Has resistance. Further, no alkalis should be present be to avoid damage to the heating elements.

Since the shape of the heating element carrier can be diverse, In addition, there are special requirements regarding the To direct shaping to the substrate, which is why mostly ceramic materials are used.

Such materials are known and, for example, in Singer, industrial ceramics, third volume, Springer-Verlag, 1966, in particular on pages 126-156 described.

Preferred support materials are clays, such as China Clay or Kaolin, bentonite, quartz, feldspar, cornish stone and scha moth of stoneware, porcelain, fire clay, sillimanite and Magnesite. In smaller quantities granite, basalt, Porphyry, chalk, calcite, dolomite, magnesite, corundum, Gra phit, talc, rutile, barite, gypsum, zirconium oxide, sillimanite, Cobalt ore, chrome ore, fused quartz, silicon carbide, Ferrosilicon, klinoenstatite, forsterite, plagioclase, nephe lin and cordierite be included.

Further, alumina and rutile are used.

Preferably kaolins, ball clays, potash late, pe gnatite, flint, quartz sand, crystalline quartz, chalk, valley kum and press oils for use.

In particular, alumina is used.

The shaping of the Heizelementträger done by in the Ceramics conventional molding processes, such as slip casting, here hollow casting for complicated and thin-walled pieces, as Vollguß for thick-walled pieces and casting under pressure.  

Other methods include hand painting with masses coarse-grained fireclay; as well as extrusion, extrusion, Pressing of fine-grained masses in the plastic state and hydrostatic pressing.

The shaped bodies thus produced are used at temperatures in Be rich burned from 400 to 1700 ° C.

Preferred forms for the heating element carriers are radiation or star shapes, the individual rays being strip-shaped are formed. Other shapes are nested te circles, connected by webs, as well as rectangular or oval figures and / or any combination mentioned geometric figures. The strips can be in cross section square, rectangular, triangular, round, oval or in com combined form.

On the top of Heizelementträger sit mostly hook-shaped, round, oval, cylindrical or pyramid-shaped mige, preferably hook-shaped or sawtooth-like Projections in or on which the heating elements attached who the. The hook-shaped projections may be the shape they may have an inverted "L" in their reason stay in shape or be slightly bent. are deformed the projections, so mostly mutually after the one or the other side, d. H. they either show off inside or out. The projections can counter each other be over or even arranged diagonally. critical It is that the heating element depending on the shape firmly in the Ver anchoring can be embedded.

Often it is sufficient if the top of the heating element Carrier has recesses, which partially the shape of the Emulate heating element. The distances of the Vor cracks or the diameter of the wells at least equal, better slightly smaller than the diameter of the heating be elements.  

In addition to these fixtures on the heating element carrier the heating elements can still by means of known Kle bern, as described for example in EP-A-1 30 629, which is expressly referred to in this context, be fixed.

Preferred adhesives are water glasses, silica sols and kera mix glue.

Since, according to these arrangements, the heating elements largely free lie d. H. contact with the protrusions or recesses is low, they radiate to all sides, causing the efficiency compared to radiant heaters with full surface Heating element carriers is substantially increased.

The radiant heating units are mostly circular in shape, by means of the heating element carrier used according to the invention however, any shapes of heated surfaces can be represented put.

The heating elements themselves usually have a meandering, spiral or straight design on and become mostly operated by electric current.

The heating element is usually during assembly by light Pressure or by turning in the Heizelementträger turned puts and is fixed but not rigidly clamped. As a result, a temperature-dependent expansion of the heating resistor stands not handicapped.

The radiant heating units can be with electronic and also conventional temperature monitoring by rule operate bars.  

The thermal insulation of a microporous thermal insulation material preferably has the following composition:

30-100% by weight of finely divided metal oxide,
0-50% by weight opacifier,
0-50% by weight fiber material,
0-15 wt .-% inorganic binder.

Preferred compositions contain:

30-89% by weight of finely divided metal oxide,
10-50% by weight opacifier,
1-50% by weight fiber material,
0-5 wt .-% inorganic binder.

Particularly good results are with the following compositions reached:

50-89% by weight of finely divided metal oxide,
20-40% by weight opacifier,
5-20% by weight of fiber material,
0.5-2% by weight of inorganic binding material.

Examples of finely divided metal oxide are fumed silicas, including arc silicas, alkali poor precipitated silicas, analogously prepared aluminum oxide, titanium oxide and zirconium oxide, and mixtures thereof. Before preferably pyrogenic silica, alumina or a mixture thereof are used. The finely divided metal oxides have specific surface areas of preferably 50-700 m ² / g, in particular 70-400 m ² / g.

Examples of opacifiers are ilmenite, titanium dioxide, Silicon carbide, ferrous iron-III mixed oxide, chromium dioxide, Zirconia, manganese dioxide, iron oxide, silica, aluminum minium oxide and zirconium silicate, and mixtures thereof. before Preferably, ilmenite and zirconium silicate are used. The  Clouding agents advantageously have an absorption maximum in the infrared range between 1.5 and 10 microns.

Examples of fiber material are glass wool, rock wool, Basalt wool, slag wool, ceramic fibers, as they are made Melting of aluminum and / or silica won who and asbestos fibers and mixtures thereof. Preferably fibers obtained from the melt of aluminum and / or silica.

As inorganic binders, all binders whose Use in microporous, pressed thermal insulation known is to be used. Examples of such binders are for example, in EP-A-29,227, incorporated in the This connection is expressly referred to. Preferably Borides of Aluminum, Titanium, Zircons, Calcium, silicides such as calcium silicide and calcium aluminum minium silicide, in particular boron carbide used. at games for other ingredients are basic oxides, esp in particular magnesium oxide, calcium oxide or barium oxide.

The production of heat insulation from microporous, pressed Thermal insulation material preferably comprises the following method steps:

• a) pre-compression of the thermal insulation based on fine distributed metal oxide at pressures of 1 to 5 bar, ins special 2 bar or about 2 bar;
• b) pressing the precompressed material into the ge desired shape at final pressures of 8 to 20 bar, the Thickness of the resulting molds preferably 1 to 25 mm, in particular 2 to 10 mm;  
• c) optionally heating the compressed body at Tem temperatures of 100 to 900 ° C.

When pre-compacting or pressing in the Schüt tion enclosed gases can escape. Therefore, done the compression and compression preferably under application of Negative pressure. Degassing can be done even before compacting or pressing done.

When pressing a pressing tool can be used, the Has elevations or depressions that the geometric Shaping the shape of the heating element carrier. This will be a Firm anchoring of the Heizelementträgers in the heat isola reached. The heating element carrier can additionally by stapling or gluing in or on the heat insulation be fixed.

Radiation heating units according to the invention are used for heating a plate, in particular a glass ceramic plate, in radiant heaters of ovens, in particular Ovens, in radiant heaters or halogen spotlights. Radiant heaters have a heating wire, Halo, as a heat source genstrahler a halogen lamp. Recently, halogen and Heating wire heaters combined in a radiant heater be has become known.

Preferred embodiments of the invention are shown in Figs. 1 and 2. In this mean:

1 microporous thermal insulation material
2 ceramic heating element carrier
3 heating coil
4 sawtooth-like holding cone

FIG. 2 shows an enlarged longitudinal section of FIG. 1. FIG .

example 1

Clay became a plastic, easily malleable water Mass pasted. This mass was to a thickness of 5 mm rolled out.

The result was an eight-pointed star cross with the knife be formed by a standing on top Square was additionally stabilized. The beam width was 11 mm. The diameter of the entire bracket was 178 mm. On the rays were sawed from the clay mass tooth-like holding cone positioned so that they have a Spiral geometry simulated. This heating element carrier was fired at a temperature of 1050 ° C.

With a ram, showing the geometry of the heating element carrier was a thermal insulation consisting of

62.5% by weight fumed silica,
31.7% by weight zirconium silicate,
5% by weight of aluminum silicate fiber,
0.8% by weight of boron carbide,

to a molded part with 198 mm diameter, rim height 10 mm, Total height 31 mm and ground height 16 mm pressed and at 800 ° C 1 hour in the oven.

A heating coil (diameter 5 mm, wire thickness 0.8 mm) was inserted in the heating element carrier. The so provided heating element carrier was inserted into the heat insulation, wherein the heating element carrier with 2 metal clamps in the heat iso was fixed.

The radiant heating unit with a power of 1800 watts was a 100-hour endurance test with 15-minute on and off Subjected to cyclization.  

Example 2

The procedure of Example 1 was repeated with the Modification, that the ceramic holder out square was formed. The beam width was also 11 mm, the Edge length of the square 240 mm. The appearance of the kerami The holder corresponded to Example 1, but were the Rays extended so far that they are a square of the edges length of 240 mm. The beam ends were through a square frame made of the same ceramic stabili Siert.

Made of a thermal insulation consisting of

62.5% by weight fumed silica,
37.7% by weight of zirconium silicates,
5.0% by weight of aluminum silicate fiber,
0.8% by weight of boron carbide,

was made by means of a ram, the geometry of the Heizelementträgers imaged, a molded part pressed with fol dimensions:

square. External length | 300 mm Border width 30 mm edge height 14 mm ground level 16 mm total height 30 mm

In this molding was the Heizelementträger with Heizwen del gem. Example 1 inserted and with 5 retaining clips fixed. This unit was according to the endurance test. example 1 subjected.  

Example 3

The procedure of Example 1 was repeated with the Modification that the resistance wire is not in the shape of a Wendel possessed, but designed as a flat flat wire was.

Claims (9)

1. radiant heating unit, comprising a heating element, a Heizelementträger and arranged under the Heizelementträger heat insulation, characterized in that the Heizelementträger not out over the entire surface with respect to the surface of the underlying thermal insulation out forms and the heat insulation consists of a microporous heat. 2. Radiant heating unit according to claim 1, characterized gekenn records that the Heizelementträger 5 to 70% of the Flä surface heat insulation covered. 3. Radiant heating unit according to claim 1, characterized records that the Heizelementträger 10 to 20% of the Flä surface heat insulation covered. 4. Radiant heating unit according to one or more of the An Claims 1 to 3, characterized in that the heating Element carrier made of a mechanically strong material exists, the thermal shock resistance, High temperature resistance, low temperature Expansion and shrinkage and / or a high having electrical resistance. 5. Radiant heating unit according to one or more of An Claims 1 to 4, characterized in that the heating element carrier consists of ceramic material. 6. Radiant heating unit according to one or more of the An Claims 1 to 5, characterized in that the heating element carrier consists of alumina.   7. Radiant heating unit according to one or more of the An Claims 1 to 6, characterized in that the heating element carrier has a ray or star shape. 8. Radiant heating unit according to one or more of claims to 1 to 7, characterized in that the heat insulation has the following composition: 30-100 wt .-% finely divided metal oxide,
0-50% by weight opacifier,
0-50% by weight fiber material,
0-15 wt .-% inorganic binder. 9. Use of the radiant heating unit after one or several of claims 1 to 8 for heating a plat te, in particular a glass ceramic plate, in radiation Furnaces of ovens, especially ovens, in Radiant heaters or in halogen lamps.