The present invention relates to a dishwasher as defined in the preamble of claim 1.
German Patent Application DE 103 46 964 A1 describes a dishwasher whose walls are provided with an insulation having a variable thermal conductivity. This makes it possible to adjust the thermal insulation layer during the dishwashing operation in such a way that it has a low thermal conductivity and the thermal energy is retained in the washing chamber. On the other hand, during the drying process, the thermal conductivity can be increased so that an inner wall is cooled by removal of thermal energy to then accelerate the removal of moisture by condensation. In order to change the thermal conductivity, hydrogen in a metal hydride lattice is released, the hydrogen then changing the thermal conductivity. The use of such a metal hydride lattice in a thermal insulation layer involves a relatively high degree of complexity, because electrical heating means must be provided for the operation of the thermal insulation layer.
Other commercial dishwashers have a washing chamber surrounded by walls which are thermally insulated by an insulation layer. It is possible, for example, to provide an insulation layer of bitumen. However, the thermal conductivity of such insulation layers cannot be changed. Therefore, the thermal conductivity remains constant, irrespectively of whether the heat should be retained in the washing chamber during the dishwashing operation, or whether, during the drying operation, the heat should be removed from the washing chamber as efficiently as possible so as to cool an inner wall and accelerate the condensation process.
It is, therefore, an object of the present invention to provide a dishwasher which is simple of design yet allows for changing the emission of thermal radiation at least one wall.
This object is achieved by a dishwasher having the features of claim 1. Advantageous embodiments will become apparent from the dependent claims.
In accordance with the present invention, the walls surrounded by an insulation layer are provided on the outside, at least in some regions, with means for changing the emission of thermal radiation. This allows the heat contained in a washing chamber during the dishwashing operation to be retained to the extent possible, while during the drying operation, heat can be removed, at least partly, by an increased level of heat emission. There is no need to change the thermal conductivity of the insulation layer for this purpose. Rather, use is made of differences in the thermal radiation in order to operate the dishwasher as effectively and energy-efficiently as possible. This involves minimizing energy losses during the wash cycle, while increasing the level of heat emission during the drying process.
Therefore, advantageously, means for changing the emission of thermal radiation are provided which allow for a high level of heat emission in a first position and a low level of heat emission in a second position. To this end, a layer which may be selected to be dark in color or reflective may be provided on the outside, at least in some regions. It is known that dark matte surfaces are capable of emitting high levels of heat, while light shiny surfaces emit less heat by radiation. Bitumen, for example, has an emission coefficient of nearly 1, while a shiny surface, such as bitumen coated with aluminum foil, has an emission coefficient of about 0.16. In this connection, tests have shown that a dishwasher provided with coated bitumen uses about 40 Wh less energy for a complete wash cycle (standard wash cycle) than one provided with uncoated bitumen. Thus, the differences in the thermal radiation resulting from a different surface design can also be used for optimizing the process sequence performed in a dishwasher.
In another embodiment of the present invention, tiltable slats are provided on the outside, at least in some regions. These slats may have a reflective surface and be movable from a closed position to an open position so as to produce a change in the emission of thermal radiation. Such a slat curtain may be disposed on a side wall of a dishwasher to be able to change the thermal emission via the respective wall surface. Tilting of the slats may preferably occur during switchover from the cleaning process to the drying process.
In a further embodiment of the present invention, the means for changing the emission of thermal radiation have a layer whose emissivity is variable. In this connection, the layer may be changeable in color, for example, depending on the temperature. It is also possible for the emissivity of the layer to be changed by pulses from a controller. In this connection, the layer can be adjusted in such a way that the emissivity is high at high temperatures, while at slightly lower temperatures, thermal radiation is emitted at a lower rate. This is because, especially shortly before the drying cycle, a particularly high temperature is introduced into the washing chamber, so that then a high level of heat emission is required for the subsequent drying operation.
The present invention will now be explained in greater detail with reference to two exemplary embodiments:
According to a first exemplary embodiment, a dishwasher includes a washing chamber surrounded by walls, the walls including a water-impermeable inner wall and an outer insulation layer of bitumen. At least one wall of the washing chamber has provided thereon a slat curtain having a plurality of tiltable slats, said slats being provided with a reflective surface on one side thereof. During the washing operation, heat emission should be kept to a low level and, therefore, the slats are oriented with their reflective surfaces facing the insulation layer of bitumen. Because of this, the thermal radiation emitted by the dark bitumen is reflected by a suitable color given to the slats or by a coating of aluminum foil. The slats are tilted to facilitate the drying operation, so that the emitted thermal radiation can then pass through between the slats. Behind the slat curtain, there are disposed further units, such as water bags, drying units, or other components, and, therefore, thermal radiation that may be emitted is not immediately reflected by an outer wall. Thus, when the slats are in the closed position, the insulation layer faces a light reflective surface, while in the open position, the slats allow for emission of thermal radiation to facilitate the drying operation.
According to a second exemplary embodiment of the present invention, a dishwasher is provided with a washing chamber surrounded by walls, a coating whose emissivity is variable being provided on the insulation layer on the outside of the walls, at least in some regions. In this connection, the variation can be brought about either directly through the control of the controller (such as by an electric pulse), or indirectly by a reversible change in emissivity occurring above a certain temperature. This may be achieved using colors having a function that is dependent on temperature. For example, the temperature required to cause the color to change may be selected such that the emissivity is low at lower temperatures (low thermal radiation losses) and that, at a predetermined transition temperature, the emissivity is high (high thermal radiation losses). In this manner, it is achieved that, during the normal washing cycle, which is performed at relatively low temperatures, the losses are low, while during the drying step, which is performed at relatively high temperatures, high losses assist the drying process.
Such a coating is preferably composed of polymer microcapsules (about 6 μm in diameter), which are filled with chromophoric components and a medium, it being possible for the medium to be in solid or liquid state. Below the temperature at which the medium changes from the liquid to the solid state, the chromophoric components are in direct contact and the particular color appears. Above the temperature at which the medium changes from the liquid to the solid state, the chromophoric components are no longer in direct contact and the particular color is not visible. This process is reversible, a hysteresis being present between the change from cold to warm and back from warm to cold, so that the temperature at which no color is visible is slightly higher than that at which the color appears again.
The color transition temperature is preferably in a range between 50° and 90°, in particular between 60° and 70°.
Of course, it is also possible to combine the two above-described embodiments, so that both a slat curtain is provided and a coating having a variable emissivity is attached to the insulation layer, at least in some regions.
Number | Date | Country | Kind |
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10 2007 038 266.0 | Aug 2007 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/006066 | 7/24/2008 | WO | 00 | 2/10/2010 |