The present invention relates to an arrangement of at least two glass panels for a heat insulated oven door of a cooking oven. Further, the present invention relates to a heat insulated oven door for a cooking oven including an arrangement of glass panels. Additionally, the present invention relates to a cooking oven with a heat insulated oven door comprising an arrangement of glass panels.
An oven door of a cooking without any heat insulating devices causes a loss of energy, regardless of said oven door is actively ventilated in order to keep the temperature of the outer surface at a lower level. The loss of energy is very big, if the cooking oven provides a pyrolytic cleaning. The window of the oven door includes one or more glass panels. Said glass panels are heated up by the heat in the oven cavity. This heat is transferred to the surrounding air by convection. The different heat expansions of the components lead to instabilities.
DE 43 25 399 A1 discloses a system of glass panels. The intermediate spaces between said glass panels may be evacuated. The edge bond of the glass panel is vacuum-sealed. The system of glass panels is self-supporting.
DE 36 25 244 A1 discloses an oven door with two glass panels and an intermediate space between them. Said intermediate space comprises a vacuum and a cooling fluid.
US 2002/0007829 A1 discloses an insulating glass door for a cooking oven. The glass door comprises an interspace, which is at least partially filled with inert gas.
It is an object of the present invention to provide an improved arrangement of glass panels for a heat insulated oven door, wherein the instabilities by heat expansion is reduced.
The object of the present invention is achieved by the arrangement of at least two glass panels for a heat insulated oven door according to claim 1.
According to the present invention the silicone sealing and/or the glass solder, respectively, are adapted to the behaviour of the glass panels at high temperatures, so that motions of the glass panels due to heat expansion and/or gas pressure are compensated.
The main idea of the present invention is the properties of the silicone sealing and/or the glass solder, respectively, at high temperatures. For example, the silicone sealing maintains its elastic properties at high temperatures. Further, the structure of the glass solder may by adapted to the neighbored glass panels in order to compensate the different heat expansions of said glass panels.
According to a preferred embodiment of the present invention the large-area sides of the glass panels have the same sizes.
According to a first embodiment of the invention, the silicone sealing can be made of silicone foam. A silicone foam has important advantages when arranged according to the present invention in a suitable way to fill and seal the boarder of an intermediate space between two neighbouring glass panels of a heat insulated oven door of a cooking oven, wherein said intermediate space can be preferably filled with an inert gas, such as for example Argon.
An inner glass panel that faces the oven cavity can become very hot and its neighbouring glass panel that faces towards the outside can have a much lower temperature such as almost room temperature. Now, it has been found surprisingly that a silicone foam can tolerate better than any non-foamed silicone sealings of the prior art a temperature gradient between two neighbouring glass panels of an oven door. It has been found that a silicone foam sealing does not tear off from neighboring glass panels even after repeated exposure to steep temperature gradients between about 300° C. at the inner glass panel and close to room temperature at the neighbouring glass panel.
It has been found that in principle both, a silicone foam comprising essentially closed pores, or of a silicone foam comprising essentially open pores can be used according to the present invention. Since the closed pores are filled with a gas they will expand the volume of the sealing when heated and thus adapt the spacer to the form of the glass, avoid tearing off the sealing from the glass.
In the case of a silicone foam comprising open pores, the pores can adapt their sizes due to expanding gas that enters with pressure from an intermediate space between two neighbouring glass panels, wherein the intermediate space can be filled with an inert gas according to the present invention. In a preferred execution of the invention, the silicone foam sealing comprising open pores can have a gas barrier on its outside facing side that faces away from the intermediate space between the neighbouring glass panels, in particular when an open pore silicone foam sealing of a comparably small dimension is used. In that way, any loss of an inert gas filling of said intermediate space can be effectively avoided. But also an open pore silicone foam sealing without any gas barrier can be used to seal an intermediate space between two glass panels that is filled with an inert gas, if the sealing is formed as a solid part of sufficient dimensions that consists essentially of silicone foam without any further cavities.
For example, the silicone sealing is formed as an elongated profile strip.
According to a second embodiment of the invention, a heat insulated oven door for a cooking oven is provided that includes three glass panels that are arranged in parallel such that a first intermediate space and a second intermediate space are formed between neighbouring glass panels, wherein the border of the first intermediate space is sealed with a silicone sealing and the border of the second intermediate space is sealed with a glass solder. Said first intermediate space is preferably filled with an inert gas, whereas said second intermediate space is evacuated. Still preferably, said second intermediate space is arranged towards the oven cavity, whereas said first intermediate space faces outwards.
The evacuated second intermediate space that is sealed with glass solder can stand particularly high temperatures when arranged facing directly the oven cavity due to the high thermal stability of the glass solder as such. Yet, glass solder is not stable when used to bridge a large temperature gradient between two neighbouring glass panels that are arranged at an elevated distance from each other. Therefore, the effectiveness of the thermal isolation of a vacuumized arrangement of two glass panels that are sealed by glass solder is lower than that of a gas-filled arrangement of two glass panels.
The present invention has found that an arrangement of three glass panels that comprises a first intermediate space and a second intermediate space, wherein the border of the first intermediate space is sealed with a silicone sealing and the border of the second intermediate space is sealed with a glass solder, said first intermediate space is filled with an inert gas, whereas said second intermediate space is evacuated, and said second intermediate space is arranged towards the oven cavity, whereas said first intermediate space faces outwards provides a particularly high thermal isolation effectiveness and at the same time an enhanced stability of both sealings over time. In fact, said arrangement has been found to provide superior isolation effectiveness and thermal stability even in doors of pyrolytic ovens which comprise a pyrolytic cleaning functionality that heats the oven cavity to a temperature of about 500° C. in order to burn food residues on the inner cavity surface to ashes.
Further, a supporting structure can be arranged in the evacuated intermediate space. This contributes to the stability of the arrangement of glass panels. Because differently to oven doors with glass panel arrangements comprising a sealed and gas-filled intermediate space wherein the gas expands when the oven cavity is heated, the glass panel of an evacuated glass panel arrangement that faces the oven cavity will be pressed towards the outer glass panel during heating, potentially damaging the glass solder and leading in addition to extended contact areas between both glass panels and hence to a reduction of the insulation effectiveness.
For example, the supporting structure includes at least one elongated profile strip. Preferably, the supporting structure is made of silicone foam.
Alternatively, the supporting structure includes a plurality of supporting elements.
For example, the supporting elements are glass beads.
According to another example, the supporting elements may be glass cylinders.
Preferably, the supporting elements can be arranged according a predetermined scheme and form a grid.
Further, the present invention relates to a heat insulated oven door for a cooking oven including an arrangement of glass panels, wherein the oven door includes the arrangement of at least two glass panels mentioned above.
At last, the present invention relates to a cooking oven with a heat insulated oven door comprising an arrangement of glass panels, wherein the oven door includes the arrangement of at least two glass panels mentioned above and/or the cooking oven includes the oven door described above.
Novel and inventive features of the present invention are set forth in the appended claims.
The present invention will be described in further detail with reference to the drawing, in which
The inner glass panel 12 is arranged towards the oven cavity 18. The outer glass panel 14 is arranged behind the front panel 20 of the oven door 10. The front space 22 between the outer glass panel 14 and the front panel 20 of the oven door 10 is open in order to allow an air flow space inside said front space 22, so that the front space 22 forms an air stream channel for cooling an outer portion of the oven door 10. The central glass panel 16 is arranged between the inner glass panel 12 and the outer glass panel 14. In this example, the inner glass panel 12, the outer glass panel 14 and the central glass panel 16 have the same areas and thicknesses.
A first intermediate space 24 is arranged between the outer glass panel 14 and the central glass panel 16 on the one hand, and a further second intermediate space 24′ is arranged between the central glass panel 16 and the inner glass panel 12 on the other hand.
The border of the first intermediate spaces 24 between the outer glass panel 14 and the central glass panel 16 is filled by the silicone sealing 26, so that the silicone sealing 26 encloses said first intermediate space 24. Further, the first intermediate space 24 is filled by the inert gas 28, such as for example Argon.
In contrast, the border of the further second intermediate space 24′ between the central glass panel 16 and the inner glass panel 12 is filled by a glass solder 34. Said glass solder 34 encloses the second intermediate space 24′. The vacuum 30 and the supporting structure are inside the further intermediate space 24′.
The second intermediate space 24′ comprises the supporting structure 32 that includes the plurality of supporting elements. In this example, the supporting elements are small glass cylinders. The bases of the cylinders lie against the glass panels 12 and 16, while the curved surfaces of the cylinders are in the second intermediate space 24′ between the glass panels 12 and 16. The glass cylinders are distributed in the second intermediate space 24′ between the glass panels 12 and 16 according to a predetermined scheme. For example, the glass cylinders are equally distributed and form a grid. The distances between horizontally neighbored glass cylinders and vertically neighbored glass cylinders may be different or equal. Alternatively, the supporting elements may be the small glass beads arranged between the glass panels 12 and 16. The supporting structure allows an increased stability of the inner glass panel 12 and the central glass panel 16 enclosing the vacuum 30 in the second intermediate space 24′.
An inner glass panel 12 is arranged towards an oven cavity 18. An outer glass panel 14 is arranged behind a front panel 20 of the oven door 10. There is a front space 22 between the outer glass panel 14 and the front panel 20 of the oven door 10. Preferably, the front space 22 is open in order to allow an air flow space inside said front space 22. Thus, the front space 22 may be provided as an air stream channel for cooling an outer portion of the oven door 10.
A central glass panel 16 is arranged between the inner glass panel 12 and the outer glass panel 14. In this example, the inner glass panel 12, the outer glass panel 14 and the central glass panel 16 have the same areas and thicknesses. A first intermediate space 24 is arranged between the outer glass panel 14 and the central glass panel 16. In a similar way, a further second intermediate space 24′ is arranged between the central glass panel 16 and the inner glass panel 12. In this example, said intermediate spaces 24, 24′ have the same thicknesses. Further, the glass panels 12, 14 and 16 and the intermediate spaces 24, 24′ have about the same thicknesses.
The borders of the intermediate spaces 24, 24′ are filled by a silicone sealing 26 in each case, so that the silicone sealings 26 enclose the corresponding intermediate spaces 24, 24′. Moreover, the intermediate spaces 24, 24′ are filled by an inert gas 28, such as for example Argon.
The inner glass panel 12 is arranged towards the oven cavity 18. The outer glass panel 14 is arranged behind the front panel 20 of the oven door 10. There is the open front space 22 between the outer glass panel 14 and the front panel 20 of the oven door 10, in order to allow the air flow inside said front space 22 for cooling the outer portion of the oven door 10.
A single intermediate space 24″ is arranged between the inner glass panel 12 and the outer glass panel 14. In this example, the single intermediate spaces 24″ has about the same thickness as the glass panels 12 and 14. The border of the single intermediate space 24″ is filled by the silicone sealing 26, so that the silicone sealing 26 encloses said single intermediate space 24″. Further, the single intermediate space 24″ is filled by the inert gas 28, such as for example Argon.
The inner glass panel 12 is arranged in front of the oven cavity 18. The outer glass panel 14 is arranged behind the front panel 20 of the oven door 10. There is also the open front space 22 between the outer glass panel 14 and the front panel 20 of the oven door 10, in order to allow the air flow inside said front space 22 for cooling the outer portion of the oven door 10.
A single intermediate space 24″ is arranged between the inner glass panel 12 and the outer glass panel 14. In this example, the single intermediate space 24″ has also about the same thickness as the glass panels 12 and 14. The border of the single intermediate space 24″ is filled by the silicone sealing 26, so that the silicone sealing 26 encloses said single intermediate space 24″. In this embodiment, a vacuum 30 is inside the single intermediate space 24″. Further, a supporting structure 32 is arranged in the single intermediate space 24″. Said supporting structure 32 allows an increased stability of the inner glass panel 12 and the outer glass panel 14 enclosing the vacuum 30 in the single intermediate space 24″.
The supporting structure 32 includes a plurality of supporting elements. In this example, said supporting elements are small glass beads. The glass beads are arranged between the glass panels 12 and 14. The glass beads are distributed in the single intermediate space 24″ according to a predetermined scheme. For example, the glass beads are equally distributed and form a grid. The distances between horizontally neighbored glass beads and vertically neighbored glass beads may be different or equal. Alternatively, the supporting elements may be small glass cylinders. In this case, the bases of the cylinders lie against the glass panels 12 and 14, while the curved surfaces of the cylinders are in the single intermediate space 24″.
The inner glass panel 12 is arranged in front of the oven cavity 18. The outer glass panel 14 is arranged behind the front panel 20 of the oven door 10. A single intermediate space 24″ is arranged between the outer glass panel 14 and the inner glass panel 12. There is also the open front space 22 between the outer glass panel 14 and the front panel 20 of the oven door 10, in order to allow the air flow inside said front space 22 for cooling the outer portion of the oven door 10.
The border of the single intermediate space 24″ between the outer glass panel 14 and the inner glass panel 12 is filled by the glass solder 34. Said glass solder 34 encloses the single intermediate space 24″. The vacuum 30 and the supporting structure 32 are inside the single intermediate space 24″. The supporting structure allows an increased stability of the inner glass panel 12 and the outer glass panel 14 enclosing the vacuum 30 in the single intermediate space 24″.
The supporting structure 32 includes the plurality of supporting elements arranged between the glass panels 12 and 14. In this example, said supporting elements are small glass beads again. The glass beads are distributed in the single intermediate space 24″ according to a predetermined scheme. For example, the glass beads are equally distributed and form a grid. The distances between horizontally neighbored glass beads and vertically neighbored glass beads may be different or equal. Alternatively, the supporting elements may be also small glass cylinders. In this case, the bases of the cylinders lie against the glass panels 12 and 14, while the curved surfaces of the cylinders are in the single intermediate space 24″.
The first, second and/or single intermediate spaces 24, 24′ or 24″ with vacuum or inert gas reduce the heat conductivity of the arrangement of glass panels 12, 14 and/or 16. The temperature gradient at the glass panels 12, 14 and/or 16 is reduced. The cooking results are improved, since uneven browning is prevented. The energy consumption is lower, since the heat conductivity is reduced. The arrangement of the glass panels 12, 14 and/or 16 can easily be mounted into the oven door 10. When the oven door 10 is closed, then the acoustic characteristics are improved by the arrangement of the glass panels 12, 14 and/or 16.
Further, the thermal impact and the pressure impact on the silicon sealing are reduced. The silicone sealing 26 as well as the glass solder 34 are adapted to the thermal behaviour of the glass panels 12, 14 and/or 16. The silicone sealing 26 may be made of silicone foam, so that the stability is improved, when the glass panels 12, 14 and/or 16 are deformed at high temperatures. In particular, the glass solder 34 can compensate the different heat expansions of the glass panels 12, 14 and/or 16.
Unlike double or triple window panes as used for buildings, the glass panels 12, 14 and 16 do not require any drying agents, e.g. a molecular sieve, in the intermediate spaces 24.
The glass panels 12, 14 and 16 as well as the glass panels 14 and 16 with the solder 34 have been tempered. In order to prevent an outgassing of the silicone sealing 26, the supporting structure 32 or other spacers, the tempering has been performed for a relative long time.
If low-energy panels are used, then preferably a scavenger is applied in order to absorb highly volatile components. For example, diatomaceous earth is used as scavenger.
Although illustrative embodiments of the present invention have been described herein with reference to the accompanying drawings, it is to be understood that the present invention is not limited to those precise embodiments, and that various other changes and modifications may be affected therein by one skilled in the art without departing from the scope or spirit of the invention. All such changes and modifications are intended to be included within the scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
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12166565.7 | May 2012 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/059287 | 5/3/2013 | WO | 00 |