EP1340021A1

EP1340021A1 - Oven

Info

Publication number: EP1340021A1
Application number: EP01998771A
Authority: EP
Inventors: Wolfgang Schnell; Klaus Rabenstein; Klemens Roch; Michael Wagner; Rainer Lebacher; Christine Thaller; Robert Hasslberger; Hans Lappat; Peter Lohner
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2000-11-29
Filing date: 2001-11-16
Publication date: 2003-09-03
Anticipated expiration: 2021-11-16
Also published as: EP1340021B1; US20040107955A1; DE10059167A1; AU2002217040A1; WO2002044620A1; ATE324558T1; US20070240701A9; DE50109645D1; ES2262708T3

Abstract

The invention relates to an oven comprising a sealing element ( 2 ) that, for sealing an oven door, rests only against a cool area ( 14 ) of an oven flange ( 4 ) without contacting the hot area ( 12 ) of the oven flange. Both areas ( 12, 14 ) are thermally isolated ( 10 ) from one another

Description

oven

The invention relates to an oven, in particular one with pyrolysis operation for self-cleaning, according to the preamble of claim 1.

Accordingly, the invention relates to an oven containing an oven flange which extends like a frame around the loading opening of a baking space and has a heat decoupling area which thermally decouples a "hot area" adjacent to the loading opening and a "cold area" further away from the loading opening; a sealing element fastened to the oven flange and sealingly in contact with it, against which an oven door bears when the door is closed to seal the oven against the outside of the oven.

An oven of this type is known from DE utility model G 91 06 860.6. For attaching a high temperature resistant material such. B. glass fiber material, existing seal on the oven or its door plug-in clips are provided which are hooked on the one hand on a wire core which extends axially through the seal, and on the other hand can be locked in openings in the oven or on the door. The seal lies in a bead, in the base of which the openings are formed.

From DE 197 05 697 A1 an oven is known in which an intermediate space is formed between a muffle wall of the baking space and a front frame of the muffle wall, which forms a heat decoupling gap between these two parts. The intermediate space is sealed with a seal made of a heat-insulating material, which rests on the front frame and on the muffle wall and has a wing-like sealing part, as seen in cross section, against which the furnace door can be placed tightly. The seal is made of a high-temperature resistant material so that it is not damaged by the high temperatures in the baking chamber.

The temperatures generated in the baking room for baking, roasting, grilling and the like normally do not exceed 280 ° C. In pyrolysis operation for Self-cleaning of the baking chamber, in which dirt residues are burned by high temperatures, the pyrolysis temperature can be up to over 400 ° C. A currently known sealing material that can withstand these temperatures is, for example, a glass fiber braid. This is not only expensive, but also has the disadvantages that it has a poor sealing effect, can soak up grease and steam parts of the baking chamber, can also harden, looks bad, and cannot be cleaned adequately. This is in contrast to seals, which are made of silicone, for example, but are not as resistant to high temperatures, but only withstand temperatures up to a maximum of about 280 ° C.

To save energy, the oven flange is thermally decoupled from the oven (oven muffle) through a gap, through a plurality of slots or other openings, and / or through grooves or beads. So that on the one hand these thermal decoupling means are not visible to the customer and on the other hand the oven is sealed, they are located behind the door seal, in special embodiments on the basis of a groove or bead that extends around the loading opening and which itself also acts as a thermal decoupling means. Due to the thermal decoupling, a strong temperature jump occurs at the decoupling point. On the oven side, the temperatures are very high, in particular during pyrolysis, for example higher than 310 ° C. This temperature is too high for a silicone gasket lying against this surface, so that, according to the prior art, only a fiberglass gasket can be used.

The invention is intended to achieve the object of designing the sealing arrangement between the baking chamber and the oven door in such a way that it is less dirt-absorbing and easier to keep clean, and nevertheless has a good sealing effect for sealing the baking chamber air against the outside of the baking chamber and looks optically acceptably good ,

This object is achieved according to the invention by the features of claim 1.

According to the invention, a silicone seal can be used for the first time in a pyrolysis device because the seal does not contact the hot area of the oven flange. Further features of the invention are contained in the subclaims.

The invention will in the following reference to the drawings based on preferred

Embodiments described as examples. Show in the drawings

1 shows a cross section along the plane I-1 of FIG. 4 of an oven seal according to the invention,

2 is a perspective view of a corner hook for fastening a corner section of the sealing element shown in FIG. 1,

3 is a perspective view of a center hook for fastening the sealing element shown in FIG. 1 on a straight section between corner sections of the sealing element of FIG. 1,

Fig. 4 schematically shows a front view of an oven according to the invention, Figures 5 to 9 different embodiments of an oven seal according to the

Invention seen along the plane V-V of Fig. 4,

10 shows a further embodiment of an oven seal according to the invention along the plane I-1 of FIG. 4,

11 is a perspective view of a fastening element for fastening the sealing element shown in FIG. 10 to an oven end face or an oven flange, FIG. 12 schematically shows a further embodiment of an oven seal according to the invention in the plane XII-XII of FIG. 13, FIG. 13 schematically shows a front view of an oven according to the invention, which is shown schematically without an oven door.

The oven seal according to the invention, shown broken off in cross section in FIG. 1, has a sealing element 2 which extends on a front side of the oven, hereinafter referred to as the oven flange 4, frame-like around the loading opening 6 of a baking chamber 8 and has a heat decoupling area 10. The heat decoupling region 10 thermally decouples a “hot region” 12 (hot side) adjacent to the loading opening 6 from a “cold region” 14 (cold side) that is further away from the loading opening 6. The heat decoupling area 10 preferably extends around the entire loading opening 6 and can pass through an uninterrupted gap in the oven flange 4, through at least one groove or corrugation or, according to FIGS. 1 and 4, through a successive plurality of slots or openings 10 around the Feed opening 6 may be formed around.

The sealing element 2 is arranged only in contact with the cold area 14 of the oven flange 4 without it contacting the hot area 12.

The sealing element 2 is fastened to the round flange corners 16-1, 16-2, 16-3, 16-4) by corner hooks 18 and to the straight sections of the oven flange 4 by middle hooks 20, each of which has at least one through the slots 10 of the heat decoupling area have hooked end 18-0, 18-1 or 20-1 and an end attached to the sealing element 2 18-2 or 20-2, which is preferably integrated in the sealing element 2, for example when producing the sealing element in an injection molding process or a Extrusion process or by vulcanization.

The sealing element 2 consists of an easily cleanable, optically acceptable good-looking material that is largely insensitive to oven contamination, for example silicone, which has a temperature resistance of up to approximately 280 ° C.

The fastening elements 18 and 20 are preferably made of metal and are therefore much more heat-resistant than the sealing element 2.

The openings 10 forming the heat decoupling area can be formed in a surface area or in a groove or bead 22 which is embossed in the direction away from an oven door 24 into the oven flange 4 and also serves as a heat decoupling means. From the oven door 24, only a glass pane 26 of a viewing window of the oven door 24 is shown, which in the closed state rests against a wing-like sealing projection 28 of the sealing element 2 and this sealing element 28 is resilient from a position 28-1 shown in broken lines to the position shown in solid lines bends. The sealing projection 28 extends approximately over the entire width of the bead 22 from the cold region 14 at a distance through the openings 10 of the heat decoupling region to over the hot region 12 and is at a distance from this hot region 12.

The sealing element 2 has a contact with the cold region 14 Sealing section 2-1 and an intermediate sealing section 2-2, which extends in the direction from the cold area 14 over the openings 10 to over the hot area 12, which is located between the hot area 12 and the sealing projection 28 and by a poorly heat-conducting support 30 is supported on the hot area 12 and is kept at a distance from the hot area 12. The support 30 can be made of metal, but preferably also consists of a sealing material, which, however, has a substantially higher temperature resistance than the sealing element 2, the temperature resistance being so high, for example above 350 ° C., that it is due to the hot temperatures of the hot area 12 is not damaged during pyrolysis operation. The support 30 is preferably a glass fiber fabric strand which extends parallel to the sealing element 2 and is preferably fastened to it, for example by gluing or by vulcanization or by simultaneous production together with the sealing element 2, for example in the injection molding process or in the extrusion process. The intermediate sealing section 2-2 not only covers the openings 10, but preferably the entire bead 22.

5 to 13 corresponding parts with the same reference numerals as in Figs. 1 to 4 are designated.

5, the sealing element 2 lies on a support 30, which consists of sealing material and lies on the base of the bead 22. A fastening element 40 extends through the support 30 into the sealing element 2. The sealing element 2 and the support 30 can be inseparably connected to one another by vulcanization or joint production in the extrusion process or the like.

6, the sealing element 2 is fastened to a support 30 in a manner similar to that in FIG. 5. The support 30 is a sealing element, for example a glass fiber braid strand, which lies in the bead 22 and contains a core wire 32, around which plug-in clips 40 are looped, the end sections of which are distant from the core wire 32 can be inserted through the openings 10, which form the heat decoupling region, and spread apart elastically behind them and thus form fastening elements for the sealing element 2. 7 shows a fastening element 2 with a sealing projection 28 and an expansion plug 42 suspended in the sealing element 2 as a fastening element. The fastening element 42 has a support projection 44 which is supported on the hot region 12 by means of sealing material 45.

The sealing element 2 from FIG. 8 is held against the cold area 14 by a spring clip-like fastening element 46 and at the same time is kept at a distance from the hot area 12. As shown in FIG. 8, a further sealing element 49, which consists of more heat-resistant sealing material than the one sealing element 2, can be arranged on the rear side of the oven flange 4.

FIG. 9 is similar to FIG. 7. However, the support 44 lies directly against the hot area 12.

In the embodiment according to FIG. 10, the sealing element 2 is fastened to the oven flange 4 by a plurality of fastening elements 50, which have an end 50-1 which is plugged onto the sealing element 2 and an end 50-2 which is pushed through the openings 10 and is elastically spread behind it , The fastening elements 50 hold the sealing element 2 in contact with the cold area 14 and at a distance from the hot area 12 of the oven flange 4. FIG. 11 shows such a fastening element 50 in perspective.

In the embodiment according to FIGS. 12 and 13, the bead 22 is covered by a plurality of heat-resistant cover elements 52 arranged one after the other, which are preferably attached to the metal, e.g. B. stainless steel to avoid contamination of the bead 22 by food and to improve the visual appearance. The cover elements 52 can at the same time be used as fastening elements for the sealing element 2 and for this purpose, for example, have an arm projecting through the openings 10 or, according to FIG. 12, can be fastened to the oven flange 4 by additional fastening elements 56 which protrude through the openings 10, so that the Sealing element 2 is connected by the cover element 52 to the fastening elements 56 and is held by these on the oven flange 4. 13 schematically shows the front of an oven 60 without the sealing element 2 and without an oven door.

"Sealing element" or "seal" here means a sealing material which is resilient and insulates the baking chamber 8 from the outside environment both thermally and with respect to the baking chamber steam.

Claims

claims

1. oven, especially those with pyrolysis operation, containing one

Oven flange (4), which extends like a frame around the loading opening (6) of a baking chamber (8) and has a heat decoupling area (10) which has a "hot area" (12) adjacent to the loading opening (6) and one further away from the loading opening relative to this "cold area" (14) thermally decoupled from each other, and a sealing element (2) attached to the oven flange (4) and sealingly attached to it, on which an oven door in the closed

Door condition is sealed, characterized in that the sealing element (2) is arranged adjacent to the cold area (14) of the oven flange (4) without contacting the hot area (12).

2. Oven according to claim 1, characterized in that the

Sealing element (2) at least partially covers fastening means (20; 40; 42; 46; 50; 52; 56) with which it is attached to the oven flange (4).

3. Oven according to claim 2, characterized in that the sealing element (2), seen in cross section, one from the cold area

Direction to the hot area, at a distance over a part of this, extending sealing wing (28) which at least partially covers the fastening means and which is the sealing part to be contacted by the oven door.

4. Oven according to one of the preceding claims, characterized in that a support (30; 44; 45; 46; 50-1; 52) is provided, which consists of a more heat-resistant material than the sealing element (2) and which the sealing element, in addition to its installation on the cold area (14), on the oven flange (4) on one closer to the hot one

Supported area (12) and / or at the hot area and keeps there at a distance.

5. Oven according to claim 4, characterized in that the support is a second sealing element (30), which consists of a more heat-resistant material than the one sealing element (2), preferably made of glass silk sealing material.

6. Oven according to claim 5, characterized in that the two sealing elements (2,30) are made together in the extrusion or injection molding process and together form a sealing body unit.

7. Oven according to claim 4, characterized in that the support (44) consists of at least one fastening element (42; 46; 50; 52) with which the sealing element (2) is fastened to the oven flange (4).

8. Oven according to one of the preceding claims, characterized in that in the sealing element (2) fastening means (20; 40;

42; 46; 52) and / or support means (44; 46; 52) are integrated, in particular cast, injected or vulcanized, with which the sealing element (2) is fastened to the oven flange (4) and / or kept at a distance from the hot area (12) becomes.

9. Oven according to one of the preceding claims, characterized in that the heat decoupling area (10) is covered by a metal cover (52), preferably made of stainless steel.

10. Oven according to claim 9, characterized in that the

Metal cover (52) is formed by fastening means for fastening the sealing element (2) to the oven flange (4).