NO120032B - - Google Patents

Description

Device for electrically heated vessels.

The present invention relates to electrically heated vessels.

The invention has an important application in washing machines. However, it should be pointed out that the invention can be used quite generally for electrically heated vessels, e.g. for heating gases, liquids or solids with low melting points, such as wax, solder or type metal.

In the past, such vessels have been provided either with a heating flask, which is often unsatisfactory from a practical point of view, or with a tubular heating element which is fastened to the outside of the vessel. The latter device, where the contact surface between the heating element and the tub is small, requires a considerable length of the element to be able to provide the necessary heat load and in some cases, especially where the tubs are small, a sufficient length of the heating element cannot be clamped onto the tub as a whole taken.

It has been proposed to use heating elements in the form of flat bands or simple tubes in circumferential grooves on the outside of the vessel's walls and to clamp the elements firmly in this position.

According to the invention, an electrically heated vessel is provided with an electric heating element of the tubular armored type placed in one or more channels, grooves or the like in the wall of the vessel, which heating element usually consists of a tubular armature isolated from the current-carrying heating wire by means of suitable insulating material, characterized by an outer cover formed of two parts, at least one of which is provided with a longitudinal channel, which parts enclose the reinforcement inside the channel or channels, and are connected to each other, so that a tubular sheathing for the reinforcement in good, heat-conducting contact with it. Good thermal contact between the tube-shaped enclosure(s) can also be achieved in the aforementioned grooves, channels or the like. With the device according to the invention, a relatively large surface of the tubular reinforced heating element is placed in contact with the vessel, so that a relatively short heating element can be used.

Appropriately, a heat reflector made of e.g. aluminium, which is preferably surface-treated in a suitable way, can be placed close to the tubular heating element and can enclose this, so that the reflector together with the vessel forms an enclosure containing the heating element.

The channel or channels or grooves or the like may suitably extend circumferentially around the vessel. With the latter device, clamping devices which clamp the end of the heating element towards each other can be advantageously used, thereby keeping the heating element in good thermal contact with the vessel despite thermal expansion of the heating element.

An embodiment of the invention will now be described as an example with reference to the drawing, applied to a cylindrical vessel, e.g. a washing machine. Fig. 1 shows part of the vessel and the heating element in partial section. Fig. 2 shows a detail with the clamping devices seen from above,

fig. 3 shows the clamping device seen from the side and in the direction of the arrow in fig. 2, and

fig. 4 and 5 show broken pieces of an alternative arrangement seen respectively from above and from the side.

With reference to fig. 1, the heating element 1 is an elongated, electric resistance heating element of the reinforced tubular type, which is enclosed by an outer metal casing 1a. The heating element consists of a resistance element lb, electrically isolated from the surrounding metal reinforcement lc by means of material ld which is electrically insulating but thermally conductive. The wrapping let be-

consists of two narrow metal strips 3, with a straight longitudinal channel with a semicircular or essentially semicircular

met execution, pressed or rolled in strips

lean from one end to the other. The innermost strip is attached to the surface of the casing lc with this placed in the recess in the strip. The outer strip is placed on the casing to complete the reinforcement la. The strips are connected to each other by welding on each side of the casing, so that together they form a tubular capsule. This build-up of the heating element provides surfaces 5a and 5b on the reinforcement and these surfaces stretch

occurs continuously along the entire length of the element, and on both sides of it.

The hollow cylindrical vessel is shown at 6

and is provided with a channel or a groove 7

of essentially semicircular cross-

section, and the channel or groove extends around the periphery of the vessel. This channel or groove can be designed in the vessel on a rest

in any appropriate way, such as e.g. by a rotation process or in the event that the vessel comprises a thick-walled casting, as it e.g. used for melting

ning of metal, the channel or groove can be cast or machined into the vessel.

The tubular reinforced heating element is placed with the outer surface of one of the semicircular channels 4 of the cover in good thermal contact with the channel or groove and with the extended surface 5b of the cover in good heat-conducting contact with the wall 8

of the vessel close to the channel or track.

The heating element and adjacent parts of the vessel are enclosed by a reflector 9 which has a channel shape or U-shaped cross-section, and the reflector together with the outer wall of the vessel forms a complete enclosure of the said heating element in order to thereby reduce heat loss by radiation and flow,

as described above. The reflector can be made of aluminum which is suitably surface treated for protection.

In fig. 2 and 3, the ends of the heating element are clamped against each other by means of clamping devices 10 which comprise two bolts 11a and 11b which protrude through holes

ler at 12 in the extended surfaces 5a and 5b of the heating element at each of the ends 13a and 13b, each of said ends being bent outwards so that they extend parallel to each other.

The bolt heads 15a and 15b abut

the extended surface 5a of the outer cover at the end 13a of the heating element. Coil springs 16a and 16b are held in compression between washers 17a and 17b which in turn are held in position by nuts 18a and 18b as well as locking nuts 19a and 19b which are screwed onto the bolts, and a clamping plate 20 which is common to both bolts and which by means of distance -pieces 21a and 21b are kept at a distance from the extended surface at the end 13b of the heating element.

Preferably, however, the bolts can

as shown in fig. 4 and fig. 5 poke through holes at 12a in angle bracket parts 22a and 22b which have ears 22c where the ears are welded to each end of the heating element.

With the preferred arrangement, the ends of the heating element follow the circumference of the cylindrical vessel.

More than one channel or groove can be arranged in the vessel and the tubular reinforced element can comprise a cover which is

Synthesized with more than one tubular enclosure each containing a separate heating element.

Claims (5)

1. Electrically heated tub, supplied with an electric heating element of the tubular reinforced type, placed in one or more channels, grooves or the like in the wall of the vessel, which heating element usually consists of a tubular reinforcement isolated from the current-carrying heating wire, by means of suitable electrical insulation material, characterized by a outer cover, formed of two parts, of which at least one is provided with a longitudinal channel, which parts enclose the reinforcement inside the channel or channels, and are connected to each other, so that a tubular casing is formed for the reinforcement in good, heat-conducting contact with this one. 2. Electrically heated vessel as specified in claim 1, characterized in that both parts forming the cover are provided with channels, the channel in one part being flush with the channel in the other part, so that these parts together form the tubular casing for the reinforcement. 3. Electrically heated vessel as stated in claim 1, characterized in that a heat reflector is placed close to the tubular heating element and encloses it. 4. An electrically heated vessel as set forth in claim 1 or 3, wherein the channel or channels, groove or grooves or the like, extend circumferentially around the vessel with clamping means that clamp the ends of the heating element against each other to keep the heating element in intimate thermal contact with the vessel, characterized in that the end parts of the heating element are bent out radially in relation to the vessel, and that the clamping devices work between these parts. 5. Electrically heated vessel as stated in claim 4, characterized in that the clamping device comprises two bolts, one on each side of the heating element, which bolts line passes through the projecting ends of said extended surfaces of the cover, as well as through coil springs which enclose the bolts, each of which is held in compression between a nut which is screwed onto the bolt and a clamping plate which is common to both bolts.