DE1299379B - Electrically heated liquid container - Google Patents

Description

The invention relates to an electrically heated liquid container, in particular kettle, consisting of a pot-like housing, in the bottom an annular groove is formed, and a heater insertable therein, in particular a tubular heater.

In known liquid containers, in particular kettles, is the liquid is heated by a radiator, the bottom side, usually the Exterior facing, is arranged. Find z. B. Radiator use, The one made of a ceramic plate that covers the bottom of the case and has an inlaid heating conductor exist. Tubular heating elements are also used, with the aim of achieving a good one Connection the tubular heating elements are hard-soldered to the housing base. Furthermore are known kettles that have a z. B. have U-shaped tubular heating elements, the one in the interior above the housing base in the manner of a rigidly attached immersion heater is arranged.

It has also been suggested to use a tubular heater which is soldered in the interior in the angle between the housing base and the housing shell is. The overall height is thus low and the space requirement is correspondingly small. Such Structural shapes have the disadvantage that the floor is not even, which is easy to clean of the device, e.g. B. the descaling, made more difficult, and that the soldering manufacturing technology Causes difficulties.

The invention is based on the object of an electrically heated Liquid containers, especially kettles, to create the one possible has a low overall height and the radiator with simple structural measures can be accommodated on the liquid container.

The invention consists in that the groove is stamped outwards on the bottom side has an opening facing the interior of the housing and its depth is larger than the diameter of the tubular heater. So that is the liquid container completed with the inclusion of the radiator against the outside space. An achievable low overall height affects the center of gravity of the filled liquid container cheap, d. that is, the stability of the container is improved.

Because the depth of the groove is greater than the diameter of the tubular heater is, the floor with the inserted tubular heating element against a surrounding the groove Abutment flattened or flattened so that the groove wall the tubular heater encloses to an extent of more than 180 °. After hitting it flat, it lays down Edge of the groove on the tubular heating element, which means that there is no further mechanical means is set in the case back. The result is a level and flat floor surface, because the flattened jacket area of the tubular heater goes into the plane of the Floor area over.

The remaining space between the groove wall and the tubular heating element is filled with a material with good thermal conductivity. Through this structural Measure, the subject matter of the invention is also suitable for heating residues forming liquids, such as B. milk, sauces, etc., as these are no longer in the Penetrate the space formed between the groove wall and the radiator and cause contamination being able to lead. This provides the necessary good heat transfer between the radiator and because the housing is secured. With regard to the choice of the material with good thermal conductivity it has been shown that the inventive design of the gap-like space the use of a soft solder is permitted. This eliminates the use of hard solder materials, which only result in a perfect connection at high temperatures. Hard solder is Difficult to use from a manufacturing point of view because the material of the container and the tubular heating element is thermally stressed.

Despite the use of soft solder, the liquid container is sufficient Requirements for good security against desoldering of the radiator when the device goes dry, because the gap-like space also absorbs the solder maintains a drying temperature above the melting temperature.

In the drawing, the F i g. 1 to 8 in a schematic representation an embodiment of the invention and individual manufacturing steps the production. In the figures, the same parts are provided with the same reference numerals.

FIG. 1 shows a tool for deep drawing, consisting of a die 1 and a punch t assigned to it. The container 3 to be deformed receives the from FIG. 1 in the deep-drawing process. 2 apparent training. The container 3 has an annular groove 4 on the bottom side, ie is formed in the base 6 in the region of the casing 5 of the container 3. The groove 4 is intended to receive a tubular heating element 7 adapted to its shape. The groove 4 is embossed to the outside and accordingly has an opening 12 facing the interior 11. The tubular heating element 7 is inserted into the groove 4 from the interior 11.

In Fig. 3 shows the tubular heating element 7 inserted in the groove 4. The tubular heating element 7 consists of a heating conductor coil 8 and a tube 9 from a Material with good thermal conductivity, e.g. B. Copper. Between the helix 8 and the tube 9 is electrically insulating, preferably granular material 10. How from FIG. 3, the outer diameter a of the tube 9 is smaller than the effective depth b of the groove 4.

As the F i g. 4 shows the bottom 6 with the inserted tubular heating element 7 against an abutment according to Art the die 1 flattened or flattened in such a way that the groove wall 13 the tubular heater 7 engages around to an extent of more than 180 °. When hitting flat the from FIG. 3 noticeable groove edge 14 compressed, thus the tubular heater 7 firmly and immovably.

The flattened surface area of the tube 9 forms with the inner surface 15 of the bottom 6 a level. In between the tubular heater 7 and the groove wall 13 formed notch rings 16 is placed to fill the gap 17 soft solder. As a result of the heating of the tubular heating element 7, the soft solder runs into the space 17 and forms a composite body with good thermal conductivity.

When flattened, the heating conductor coil8 is deformed in such a way that an elliptical cross-section results. In any case, it must be ensured be that the deformation stroke when flattening is limited to a change in the exclude electrical values of the tubular heater.

In the F i g. 5 and 6 is a kettle in plan and elevation schematically shown. The F i g. 7 and 8 show a kettle in a modified version.

The kettle according to FIG. 5 has the advantage of being as long as possible Tubular heating element training. In the interest of small feed-through openings in the housing jacket for the connection ends 18 there is a very small bending radius in the area of these ends necessary. In contrast, the tubular heating element 7 in FIG. 8 larger ones, d. H. more favorable bending radii. Here is the maximum achievable length of the radiator however decreased.

In Fig. 7 shows a base 19 placed under the kettle, which forms the standing surface of the device and protects the storage surface from excessive heating. Flat temperature regulating elements and dry boil protection elements can be installed in the space 20.

Claims (3)

Claims: 1. Electrically heated liquid container, in particular Kettle, consisting of a pot-like housing with a ring-shaped housing in the bottom Groove is formed, and a heater insertable therein, in particular a Tubular heating element, characterized in that the groove is stamped outwards on the bottom side has an opening facing the interior of the housing and its depth is larger than the diameter of the tubular heater. 2. Liquid container after Claim 1, characterized in that the bottom with the inserted tubular heating element is flattened or flattened against an abutment surrounding the groove, in such a way that the groove wall engages around the tubular heating element to an extent of more than 180 °. 3. Liquid container according to claim 1 and 2, characterized in that the remaining Gap between the groove wall and the tubular heater with a good material Thermal conductivity is filled.