EP1651919A1 - Method for operating an appliance comprising at least one sub-program step "drying" - Google Patents

Abstract

The invention relates to a method for operating an appliance comprising at least one sub-program step "drying", which permits appliances comprising at least one sub-program step "drying" to be operated in the most economic manner possible and permits the efficient drying of items with a minimum energy consumption. To achieve this, during the sub-program step(s) "drying", air is conducted from a treatment chamber via a conduit system, in which at least one Peltier element is located, and said air is then recirculated to the chamber. During its passage through said conduit system, the air is cooled, moisture is removed and the air is subsequently reheated.

Description

 Method for operating a device with at least one partial program step "drying"

The invention relates to a method for operating a device with at least one sub-program step "drying", as it is e.g. is used in tumble dryers, dishwashers, dishwashers, shoe dryers etc.

Different methods are known for drying items to be washed in a dishwasher, for example. For example, the items to be washed can be dried by self-heating if the washing liquid is heated in a sub-program step "rinse-off" and thus the hot, rinsed items are self-drying due to the inherent heat of the items to be washed during the drying process the sub-program step "final rinse" heated to a certain temperature and applied to the items to be washed using spray devices. Due to the relatively high temperature of the rinsing liquid in the part program step "clear rinsing" of usually 65 ^C C to 75 ° C is achieved that a sufficiently large amount of heat is transferred to the items to be washed so that the adhesive on the ware water through the stored in the dishes heat evaporated.

In other known methods for drying the dishes in dishwashers, a separate heating source, e.g. a hot air blower, used to heat the moist air mixture during the drying process so that the air in the washing container can absorb a larger amount of moisture.

Dishwashers are known in which the moist air is discharged to the outside. This is disadvantageous because the surrounding kitchen furniture is damaged.

Therefore, further methods are known in which, before being discharged, the moist air is passed over condensation surfaces on which the moisture condenses. This condensed water is either fed into the rinsing tank or into special collecting tanks. A method for operating a dishwasher is known from DE 30 21 746 A1, in which a heat exchanger connected to the washing container in a heat-conducting manner is fed with cold fresh water during a “drying” sub-program step. This creates a condensation surface on the inside of the washing container, on which The moisture condenses and the resulting condensed water remains in the rinsing container. As the temperature difference between the moist air and the fresh water filled in is relatively small and the quantity of fresh water heats up continuously, there is the disadvantage that the condensation of the moist air takes a long time and is steadily lower, so that the outlet of moist air from the dishwasher rises and the duration of the sub-program step "drying" is long, with a moderate drying result.

A disadvantage of the heating systems according to the prior art described above is that the heating of the rinsing liquid is associated with a high energy requirement and the required thermal energy has to be generated anew for each heating phase by means of the electrical heating elements. Likewise, the known heating systems have the disadvantage that the heating of the rinsing liquid in the sub-program step "rinse-off" and the processes in the sub-program step "drying" are themselves associated with a high energy requirement and the required thermal energy is lost after the drying process.

The object of the present invention is therefore to provide a method with which it is possible to operate devices of the type mentioned at the outset as economically as possible, to dry the material to be dried efficiently and to keep the associated energy expenditure as low as possible.

This object is achieved by the method according to the invention with the features according to claim 1. Advantageous developments of the present invention are characterized in the subclaims.

In the method according to the invention for operating a device with at least one sub-program step "drying", in the at least one sub-program step "drying", air is extracted from a treatment room out of it via a line system in which at least one Peltier element is arranged and back into it passed, the air being cooled during the passage, thereby removing moisture from it and then heating it again.

A Peltier element is a heat pump with which heat is extracted from one area - this is cooled down - and transported to another area - which is heated. By using a Peltier element, heating of the material to be treated, which is significantly less than in the prior art, is only necessary, e.g. in dishwashers in the sub-program step "rinse aid". This means a significant energy saving. By cooling the air, its moisture absorption capacity is reduced and the moisture content of the air precipitates as condensate. By heating the air, its moisture absorption capacity is increased each time it is passed through the line system, With the closed air system, an exchange of polluted air from the environment is completely ruled out, thus preventing the treated material from being contaminated back. The present invention provides a method with which it is possible to operate devices of the type mentioned at the outset as economically as possible, to dry the material to be dried efficiently and to keep the associated energy expenditure as low as possible.

According to a preferred feature of the invention, the air is conveyed by means of a blower, which makes it easier to control the use of the Peltier element.

According to a further preferred feature of the invention, the air is cooled by means of the Peltier element. The actual function of a Peltier element, cooling with removal of the absorbed thermal energy, is thus used in accordance with the method according to the invention. By cooling the air, its moisture absorption capacity is reduced and the moisture content of the air precipitates as condensate.

According to a further preferred feature of the invention, the air is heated by means of the Peltier element. The further function of the already existing Peltier element is thus taken up - the transported heat when cooling the moist air and during Condensation of moisture from the moist air - used for further energy saving.

According to an advantageous embodiment of the invention, the air is heated by means of a heater. If the heating of the air by the Peltier element is not sufficient, the air is additionally heated with a heater to ensure the drying function. Despite the additional energy consumption for heating, an energy saving is achieved compared to the previously described prior art.

According to a further advantageous embodiment of the invention, the air is directed past a condenser. If the removal of moisture from the air is not sufficient due to the cooling by the Peltier element, the air is additionally directed past a condenser to ensure the drying function, which performs the lack of moisture removal.

The invention is explained below using an exemplary embodiment of a method in a dishwasher.

The method according to the invention for operating a device with at least one partial program step "drying" is carried out in the exemplary embodiment explained in a dishwasher. As is known, a dishwasher has a rinsing method whose program sequence consists of at least one sub-program step "pre-rinse", a sub-program step "cleaning", at least one sub-program step "intermediate rinsing", a sub-program step "rinsing" and a sub-program step "drying". According to the invention, in the exemplary embodiment explained, in the at least one sub-program step "drying", air is passed out of a treatment room out of it via a line system in which at least one Peltier element is arranged and back into it, the air being cooled during the passage and thereby moisture withdrawn and then heated again.

In the exemplary embodiment, the treatment room of the dishwasher - the washing container - is equipped with an outlet in the upper region of the washing container. From this outlet leads an air line to a blower and from the blower to the Peltier element.

As is known per se, a Peltier element is a heat pump with which heat is extracted from one area - this is cooled - and transported to another area - which is heated, the heat being produced at high speed and in large quantities by one part - the so-called “cold side” "- of the Peltier element to the other part - the so-called" warm side "- of the Peltier element. If the introduced moist air is directed to the "cold side" of the Peltier element, it cools the moist air and thus reduces the moisture absorption capacity of the moist air, as a result of which the moisture contained in the moist air condenses. The "cold side" of the Peltier element thus extracts the heat (sensitive heat) from the moist air and also absorbs the heat of condensation (latent heat) and transports the heat to the other part - for "heating" the Peltier element.

In the exemplary embodiment, a further air line leads from the "cold side" of the Peltier element to the "warm side" of the Peltier element and from there to an inlet located in the lower region of the rinsing container.

If the dry air now reaches the "warm side" of the Peltier element, the air is heated by it.

The heated air introduced into the rinsing tank is now much drier and therefore has a high moisture absorption capacity. It rises in the washing compartment and absorbs the residual moisture in the items to be treated - the items to be washed. As already described above, it is now fed back to the line system.

Through the use of a Peltier element, only a much lower heating of the goods to be treated is required than in the prior art, in the exemplary embodiment described for dishwashers in the sub-program step "rinse aid" about 50 ° C., possibly even lower. This means an essential one By cooling the air, its moisture absorption capacity is reduced and the moisture content of the moist air precipitates as condensate the heating of the air increases its moisture absorption capacity each time it is passed through the line system, which leads to an improvement in the drying result and / or a reduction in the drying time. With the closed air system, an exchange of polluted air from the environment is completely ruled out, thus preventing the treated goods from becoming dirty again.

If the removal of moisture from the air is not sufficient due to the cooling by the Peltier element, the air is additionally directed past a condenser to ensure the drying function, which performs the lack of moisture removal. The condenser can be arranged in the flow direction of the air before or after the “cold side” of the Peltier element, in the exemplary embodiment described it is arranged after the “cold side” of the Peltier element.

If the heating of the air by the Peltier element is not sufficient, the air is additionally heated with a heater to ensure the drying function. In the exemplary embodiment described, the heater is arranged shortly before the treated air is admitted to the rinsing container. Despite the additional energy consumption for heating, an energy saving is achieved compared to the previously described prior art.

The present invention provides a method with which it is possible to operate devices of the type mentioned at the outset as economically as possible, to dry the material to be dried efficiently and to keep the associated energy expenditure as low as possible.

Claims

claims

1. A method for operating a device with at least one sub-program step "drying", characterized in that in the at least one sub-program step "drying" air from a treatment room out of this via a line system in which at least one Peltier element is arranged and back into this is passed, the air being cooled during the passage, thereby removing moisture from it and then heating it again.

2. The method according to claim 1, characterized in that the air is conveyed by means of a blower.

3. The method according to claim 1 or 2, characterized in that the air is cooled by means of the Peltier element.

4. The method according to claim 1 or 2, characterized in that the air is heated by means of the Peltier element.

5. The method according to claim 1 or 2, characterized in that the air is heated by means of a heater.

6. The method according to any one of the preceding claims, characterized in that the air is conducted past a condenser.