DE3640999A1 - RADIATION RADIATOR - Google Patents

Description

The invention relates to a radiant heater for Glass ceramic hot plates, being on an insulating shell a heating coil is fixed by means of holding elements that sit with foot parts in the insulating shell.

Such a radiant heater is in the DD-PS 1 06 522 described. There is the holding element from a U-shaped metal bracket formed with their both ends is pressed into the insulating shell. The Metal clips must be placed after the Heating coil laid spirally on the insulating shell is. While the brackets are being attached, the Heating coil are held in their spiral position. This makes it difficult to fix the heating coil. Furthermore the brackets between the turns of the Heating coil are passed through that they are only on the winding sections lying on the insulating shell overlap, but not overhead Turn sections. This is the setting of the brackets difficult.

A bracket technique is also known in which The turns of the heating coil are completely gripped by brackets are. Here, however, is a sufficiently large one electrical insulation distance between the brackets too guarantee. This often makes one undesirable Increasing the distance between the turns of the heating coil necessary.

The object of the invention is a radiant heater  to propose of the type mentioned at the outset Holding elements are designed so that they before Lay the heating coil on the insulating shell are so that the heating coil immediately after laying the holding elements is held on the insulating shell.

According to the invention the above object is achieved in that the Holding element the surface of the insulating shell protruding neck and that on the neck one outstanding hook-like projection is formed, the reaches over the heating wire.

The holding elements are in the material of the Insulation shell pressed in before the heating coil is installed becomes. This makes insulating shells independent of the heating coil to be installed later with the Prepare holding elements. This represents one Manufacturing simplification. In addition, the Easy to attach holding elements to the insulating shell, since the heating coil does not interfere.

The heating coil is placed on the Insulating shell snapped onto the holding elements. Therefor becomes the elasticity of the heating coil exploited. The heating coil is thereby at the Insulated shell held without another Fixation is necessary.

The heating element is not rigid from the holding elements clamped. This is a heat-dependent expansion of the Heating coil not hindered. This extends the Lifespan of the heating coil.

The holding elements are only on with the heating coil practically negligible contact areas. they hinder the free heat radiation of the heating coil Not. This results in a high degree of efficiency Heating coil.  

The holding elements are also suitable for heating coils thin heating wire with a small slope.

In a preferred embodiment of the invention, the Projection on its side facing away from the neck straight or curved guide slope. At the The heating coil wire can be slid on the heating coil of this guide slope until it is under the Head start snaps. This is the laying of the Heating coil simplified.

Advantageous refinements of the invention result from the subclaims and the following description of embodiments. The drawing shows:

Fig. 1 is a partial view of a radiant heater in section,

Fig. 2 to 8 further embodiments of holding elements and

Fig. 9 shows another embodiment of the invention in partial section.

An insulating shell ( 2 ) is placed on a tin pot base ( 1 ). This consists, for example, of aluminum silicate fibers. A groove ( 4 ) for receiving a heating coil ( 5 ) is preformed on the surface ( 3 ) of the insulating shell ( 2 ). The surface ( 3 ) can also be flat.

A multiplicity of holding elements ( 7 ) are pressed into the insulating shell ( 2 ) at the base ( 6 ) of the channel ( 4 ), one of which is shown in the figures.

The holding element ( 7 ) has one or more foot parts ( 8 ) which are stuck in the material of the insulating shell ( 2 ). A neck ( 9 ) adjoins the foot parts ( 8 ) and projects beyond the surface ( 3 ) or the base ( 6 ) of the insulating shell ( 2 ). A hook-like projection ( 10 ) is formed on the neck ( 9 ). This has a guide bevel ( 11 ) on its side facing away from the neck ( 9 ), in the exemplary embodiments this is straight. However, it can also be designed in an arc shape.

The holding elements ( 7 ) of FIGS. 1 to 5 are metallic stamped parts. They can also be formed from molded ceramic parts.

In the embodiments of FIGS. 1, 3, 4 and 5 of the neck are provided (9) projections (10) with guiding slopes (11) on both sides. In the embodiment according to FIG. 2, the hook-like projection ( 10 ) and the guide bevel ( 11 ) are only formed on one side of the neck ( 9 ).

In the exemplary embodiments according to FIGS. 1 and 4, the foot parts ( 8 ) have expansion bevels ( 12 ). This ensures that the foot parts ( 8 ) spread apart when pressed into the material of the insulating shell ( 2 ) (cf. FIG. 1). As a result, the holding element ( 7 ) in the insulating shell ( 2 ) is not only held in a frictional manner, but also in a form-fitting manner.

When Exemplary Embodiment of Fig. 5 of the foot parts are formed (8) barbs (13) at the lower ends. These improve the anchoring of the holding element ( 7 ) in the material of the insulating shell ( 2 ) compared to a pure friction fit.

In the exemplary embodiments according to FIGS. 2 and 3, only one foot part ( 8 ) is provided. This is pointed at its end. The foot part ( 8 ) sits frictionally in the insulating shell ( 2 ).

The exemplary embodiments according to FIGS. 6, 7 and 8 show holding elements ( 7 ) which are produced as bent wire parts from round wire or square wire. The retaining element (7) of Fig. 6 on one side has the hook-like projection (10) and the guide slope (11) on the neck (9). In contrast, in the exemplary embodiments according to FIGS. 7 and 8 the hook-like projection ( 10 ) and the guide bevel ( 11 ) are provided on both sides of the neck ( 9 ). In the design of the foot parts ( 8 ) according to FIGS. 6 and 7, the above-mentioned expansion will result when pressed into the insulating shell ( 2 ).

The holding elements ( 7 ) according to FIGS. 1 to 8 are pressed from the surface ( 3 ) into the insulating shell ( 2 ). In Fig. 9 a holding element ( 7 ) is shown, which is pressed from the bottom through the insulating shell ( 2 ), so that here again his neck ( 9 ) with the hook-like projection ( 10 ) and the guide bevel ( 11 ) Surface ( 3 ) protrudes. On the foot part ( 8 ) a cross piece ( 14 ) is formed which has tips ( 15 ) which engage in the material of the insulating shell ( 2 ) and which serve as an anti-rotation device to ensure that the hook-like projection ( 10 ) has a wire area ( 5 ') the heating coil ( 5 ) engages. The holding element ( 7 ) according to FIG. 9 can be produced as a stamped part, as a turned part or as a molded part.

In the exemplary embodiment according to FIG. 9, an insulating disk ( 16 ) is provided between the tin pot base ( 1 ) and the insulating shell ( 2 ). This is necessary if the holding element ( 7 ) consists of metal in order to avoid that the holding element ( 7 ) touching the heating coil ( 5 ) forms a short circuit to the bottom of the tin pot ( 1 ). If the holding element ( 7 ) is a ceramic molded part, the insulating washer ( 16 ) can be omitted.

If the holding element ( 7 ) is a rotationally symmetrical rotating part, the cross piece ( 14 ) forms a disk. The tips ( 15 ) can be omitted, since the projection ( 10 ) from the wire area ( 5 ') can then be gripped under in each rotational position of the holding element ( 7 ). The holding element designed in this way can also be formed by a ceramic molded part with a wedge-shaped tip.

The holding elements ( 7 ) are attached to the insulating shell ( 2 ) before the heating coil ( 5 ) is laid, for example shot into it. The heating coil ( 5 ) is then placed on and pressed onto the holding elements ( 7 ). A wire area ( 5 ') close to the surface ( 3 ) can slide along the guide bevels ( 11 ). Due to the resilient properties of the heating coil ( 5 ), the wire area ( 5 ') receives a certain bias. As soon as he leaves the guide slope ( 11 ) in question, he snaps under the projection ( 10 ). The heating coil ( 5 ) is fixed in the end on a variety of wire areas ( 5 ') between the projections ( 10 ), the necks ( 9 ) and the surface ( 3 ) or the base ( 6 ).

Claims (8)

1. Radiant heater for glass ceramic hot plates, a heating coil being fixed on an insulating shell by means of holding elements which sit with foot parts in the insulating shell, characterized in that the holding element ( 7 ) projects from the surface ( 3 , 6 ) of the insulating shell ( 2 ) neck ( 9 ) and that a protruding hook-like projection ( 10 ) is formed on the neck ( 9 ) which engages over the heating coil wire ( 5 '). 2. Radiant heater according to claim 1, characterized in that the projection ( 10 ) on its side facing away from the neck ( 9 ) has a straight or curved guide bevel ( 11 ). 3. Radiant heater according to claim 1 or 2, characterized in that the projection ( 10 ) and optionally the guide slope ( 11 ) is provided on both sides of the neck ( 9 ). 4. Radiant heater according to one of the preceding claims, characterized in that the holding elements ( 7 ) on the base ( 6 ) of a channel ( 4 ) for the heating coil ( 5 ) are provided. 5. Radiant heater according to one of the preceding claims, characterized in that the holding element ( 7 ) has two foot parts ( 8 ). 6. Radiant heater according to one of the preceding claims, characterized in that the holding element ( 7 ) from the surface ( 3 ) is pressed into the insulating shell ( 2 ) and an expansion bevel ( 12 ) is formed on the foot part ( 8 ). 7. Radiant heater according to one of the preceding claims 1 to 6, characterized in that the holding element ( 7 ) from the surface ( 3 ) is pressed into the insulating shell ( 2 ) and barbs ( 13 ) are formed on the foot part ( 8 ). 8. Radiant heater according to one of the preceding claims 1 to 4, characterized in that the holding element ( 7 ) is inserted from the underside through the insulating shell ( 2 ) and has a cross piece ( 14 ) on the underside.