EP2315547A2 - Method for operating a water-carrying household appliance - Google Patents

Abstract

The invention relates to a method for operating a water-carrying household appliance, especially a dishwasher or a tumble dryer, comprising a plurality of successive partial program steps, a first medium being heated at least temporarily by a first heating element (24) in at least one partial program step, and the product to be treated then being heated by being subjected to the heated first medium. According to the invention, when the first heating element (24) is inactive, a second medium is at least temporarily heated by a second heating element (23) and the product to be treated is heated by the heated second medium.

Description

 Method for operating a water-conducting household appliance

The invention relates to a method for operating a water-conducting domestic appliance, in particular for a dishwasher or a washer-dryer according to the preamble of claim 1.

From DE 10 2005 004 089 A1 a method for operating a water-conducting domestic appliance, i. a dishwasher known. As a drying system, a sorption device with reversibly dehydratable material is provided, which extracts a quantity of water in a drying step of the air to be dried and stores them. In a subsequent cleaning step, a regeneration process or a desorption is then carried out, in which an air stream flowing through the desiccant is heated by means of an air heater. With the heated air stream, the amount of water stored in the drying agent is released as hot steam and returned to the washing and heated to be cleaned items. However, this type of heating is time consuming.

It is therefore an object of the invention to provide a method for operating a water-conducting household appliance that allows a reduction of the time required.

The invention is based on a method for operating a water-conducting domestic appliance, in particular for a dishwasher or a washer dryer, comprising a plurality of successive partial program steps, of which in at least one partial program step at least temporarily heated a first medium with a first heating element and treated by loading with the heated first medium is heated.

According to the invention, when the first heating element is inactive, at least temporarily a second medium is heated with a second heating element and the material to be treated is heated with the heated second medium. In this case, a higher performance of the second heating element allows to accelerate the heating process. Furthermore, it is ensured that the power consumption remains below a maximum power consumption of the water-conducting household appliance. The maximum power consumption is determined by the maximum power capacity of the home-side Supply network limited that the power supply of the water-bearing household appliance is used with electrical energy. A power consumption of the water-conducting household appliance exceeding the maximum power capacity of the home-side supply network leads to an overload of the home-side supply network with the result that fuse elements, such as fuses or circuit breakers, trigger and a further energy supply is prevented. This ensures uninterrupted operation of the water-conducting household appliance.

It is further preferably provided that the first medium is a gaseous medium and the second medium is a liquid medium. This reduces the higher

Heat capacity of the liquid medium, the heating time. The heating of the gaseous medium can be carried out by an electric air heater, for example. Supported by a fan blower for circulating the gaseous medium. The heating of the liquid medium can be done by a water heater, for example. Supported by circulating pump for circulation of the liquid medium.

In a first, preferred embodiment it is provided that in the subprogram step, at least temporarily, only a first medium is heated only with the first heating element and only a second medium, at least temporarily, with the second heating element.

In a further, preferred embodiment it is provided that in a first partial program step, at least temporarily, a first medium is heated only with the first heating element and, in a second partial program step, at least temporarily with only the second heating element.

Thus, there is only an alternating or alternating operation of the two heating elements, either during a partial program step or in at least two partial program steps. This ensures that it can not overheat within the water-bearing household appliance by at least temporarily simultaneous operation of the two heating elements with the result eg. Damage to one of the two heating elements and / or a sorption with reversibly dehydratable material, eg. Zeolite. It is preferably provided that in a part program step treated material is subsequently subjected to a second medium. This may be a pre-rinsing step with which, for example, in the case of a dishwasher coarse soiling is removed from the treatment or ware, or a cleaning step with detergent addition to remove stubborn dirt.

Furthermore, it is preferably provided that at least one exchange of a medium, for example of rinsing liquor, takes place between two partial program steps. It sets a mixing temperature, which is between the temperature of the liquid medium and the temperature of the item to be treated after the first part program step. The temperature difference to be overcome between the mixing temperature and the maximum temperature to be reached in the purification step is correspondingly lower, so that correspondingly less energy has to be expended.

Furthermore, it is preferably provided that a cleaning agent is added in a part program step designed as a cleaning step for the purpose of cleaning articles to be treated.

In addition, it is preferably provided that prior to the cleaning step, a partial program step designed as a pre-rinsing step for cleaning articles to be treated is carried out without addition of detergent, so that the pre-rinse step is carried out immediately before the cleaning step in which higher temperatures are achieved than in the pre-rinse step.

It is preferably provided that during the cleaning step, a Nachwaschphase is performed while the material to be treated is heated by exposure to the second heating medium heated by the second heating medium.

In a further embodiment, it is preferably provided that a partial program step is formed as a rinsing step with heating of rinsing liquor, in which expansion agents are added. It is further provided that, before the rinsing step, a partial program step designed as an intermediate rinsing step is carried out for cleaning treated items without adding detergent, so that the intermediate rinsing step is carried out immediately before the rinsing step in which higher temperatures are achieved than in the intermediate rinsing step.

It is further preferably provided that the last partial program step, a drying step is performed, is absorbed in the second medium of a reversibly dehydratable material. Thus, liquid stored in the reversible dehydrogenatable material is available again for a new treatment cycle.

It is preferably provided that during a partial program step, the reversibly dehydratable material is at least partially desorbed, so that subsequently the reversibly dehydratable material is receptive again.

In the following, two embodiments of the invention will be described with reference to the attached figures.

Show it:

1 is a schematic block diagram of a dishwasher for carrying out a rinsing method according to the first embodiment,

2 is a temperature-time diagram for illustrating a Spülprogrammab- run in a first energy-saving rinse mode,

FIG. 3 is a timing chart showing only the cleaning step for illustrating a purging process in the second time-saving purging mode according to the first embodiment; and FIG

Fig. 4 is a diagram corresponding to FIG. 3 according to the second embodiment. In Fig. 1 is shown as an exemplary embodiment of a water-conducting household appliance, a dishwasher with a washing container 1, in which not shown, to be cleaned dishes in dish racks 3, 5 can be arranged. In the washing container 1 shown, two spraying arms 7, 9 provided in different spraying levels are arranged by way of example as spraying devices, via which the washware to be cleaned is supplied with washing liquid. In the Spülbehälterboden a pump pot 11 is provided with a circulating pump 13, which is connected via feed lines 14, 15 fluidly connected to the spray arms 7, 9. The sump 11 is also connected via connecting pieces with a fresh water supply line 16 coupled to the water supply network and with a discharge line 17 in which a sump pump 18 for pumping out the rinsing liquid from the rinsing container is arranged.

The rinsing container 1 has in its upper region an outlet opening 19, which is connected via a line 21 with a drying device designed as sorption device 22. In line 21 to the sorption 22 an air blower 27 and a heating element 24 are connected. The sorption device 22 contains as drying agent a reversibly dehydratable material, such as zeolite, with which in a drying step T air is dried. For this purpose, a high-humidity laden air flow is directed by the air blower 27 from the washing container 1 through the sorption 22. The zeolite provided in the sorption device 22 absorbs the moisture of the air and the comparatively dry air is returned to the washing container 1 again.

The amount of water m ₂ stored in the zeolite in the drying step T can be released again in a regeneration process, ie during desorption, by heating the desiccant of the sorption device 22. For this purpose, by means of the blower 27, a heated by the heating element 24 to very high temperatures air flow through the sorption 22, with which the stored water in the zeolite is released as hot water vapor and recycled back into the washing compartment 1.

FIG. 2 shows a temporal program sequence with the individual partial program steps of a rinse cycle, namely pre-rinsing V, cleaning R, intermediate rinsing Z, rinsing K and drying T 1. The regeneration process described above in the sorption device 22 takes place in the temperature-time profile shown in FIG. 2 in the time interval Δt _R. The indicated in Fig. 2 part program steps are controlled by a control device 25 by appropriate control of the circulation pump 13, the drain pump 18, the air blower 23, the drying device 22 and other control components.

The regeneration process .DELTA.t _R starts according to FIGS. 2 and 3 at the beginning of the cleaning step R at time t ₀ . In the regeneration process .DELTA.t _R stored in the drying agent amount of water m _{2 is returned} as water vapor in the washing compartment 1. This amount of water m ₂ was removed in the drying step T of the previous rinse during an adsorption Δt _A to be dried, laden with moisture airflow. The total amount of rinsing liquid M _ιSt provided in the cleaning _step R thus results from a fresh water quantity rrη supplied via the fresh water line 16 and the quantity of water m ₂ recycled in the regeneration process Δt _R.

During the heating-up phase Δt _H taking place at the beginning of the cleaning step R, heating is first carried out during the regeneration process Δt _R by means of the second heating element 24, ie the air heating with which the one heating power Q _{2 is introduced} into the washing compartment 1. Subsequently, a heating power Q _{1 is introduced} into the washing container 1 with the first heating element 23, ie the water heater. The heating power Q _{1 of} the water heater 23 may be about 2,200 W, while the heating power Q _{2 of} the air heater 24 is only in the order of 1,400 W.

As is apparent from Fig. 2, in the heating phase .DELTA.t _H, the heating of the rinsing liquid initially only by means of the released in the regeneration operation .DELTA.t _R water vapor, the rinsing liquid with the heating power Q ₂ to a temperature T ₁ from here example about 40 ⁰ C. can warm up. Only after the end of the regeneration process .DELTA.t _R , the water heater 23, which operates with significantly greater heating power Q ₁ , is switched on. Due to the water heater 23 switched on only after the end of the regeneration process Δt _R , thermal damage to the desiccant in the sorption device can be avoided. By means of the activated water heater 23 the temperature of the rinsing liquid is further increased from the temperature T ₁ of 40 ⁰ C to the cleaning temperature T _R , which may be here by way of example at 51 ⁰ C.

In the first mode of operation shown in FIG. 2, therefore, the heat Q ₂ released during the regeneration process Δt _R for heating the rinsing liquid m _{is used} in an energy-saving manner during the heating phase Δt _H.

As is further apparent from Fig. 1, the control device 25 is in signal communication with a changeover switch 26 which is manually operable by the user. Upon actuation of the changeover switch 26, the user can switch over from the first, energy-saving rinse mode described above with reference to FIG. 2 to a second rinse mode described below.

In the second rinsing mode, the rinsing liquid quantity is heated in the cleaning step R in a heating phase Δt _H i which is reduced in time compared to the first rinsing mode, as shown in FIG. FIG. 3 shows the heating phase Δt _{H of} both the first purge mode (in dashed line) and the second purge mode (solid line). As is apparent from Fig. 3, in the second rinse mode, the regeneration process .DELTA.t _{R is brought} forward in time. Ie. the regeneration process .DELTA.t _R starts here already during the Vorpülschrittes V and temporally superimposed on the start time t _{0 of} the cleaning step R. Due to the temporally advanced regeneration process .DELTA.t _R , the water heater 23 operating at much higher heat output Q ₁ already earlier with the heating of the washing liquid in the washing begin without this is to be feared thermal damage to the foreseen in the sorption 22 zeolite.

In this way, the cleaning temperature T _{R is} reached accelerated in the second rinse mode, whereby accordingly, the cleaning step R _{1 can} already be terminated at a preferred time t _E1 . With a suitable temporal position of the regeneration process with respect to the starting time t _{0 of} the cleaning step R, the start of the water heater 23 - alternatively to the embodiment shown - even with the start time t _{0 of} the cleaning step R ₁ done. Namely, at the beginning of the heating phase, the water heater 23 initially heats only the rinsing liquid in the rinsing container 1 and only with a time delay the air. It therefore exists at the beginning of the heating phase Δt _H i no danger that an excessively heated air flow during the regeneration process .DELTA.t _R reach the sorption 22 and can damage the zeolite thermally.

FIG. 4 describes a rinsing method performed during the second rinse mode in accordance with the second exemplary embodiment. In contrast to Fig. 3 finds the

Regeneration process .DELTA.t _R completely outside the heating phase .DELTA.t _H instead. In addition, the regeneration process .DELTA.t _R in mutually separated regeneration segments

Δ. _RI , .DELTA.t _R2 divided, the example in FIG. 4 are approximately equal in time. As can be seen from FIG. 4, the first regeneration segment Δt _R1 already takes place in the pre-rinse step V. The second regeneration segment Δt _R2 then starts after the heating phase Δt _H during the post-washing period N.

LIST OF REFERENCE NUMBERS

1 washing container

3 crockery basket

5 crockery basket

7 spray arm

9 spray arm

11 pump pot

13 circulation pump

14 supply line

15 supply line

16 fresh water supply line

17 drain line

18 lye pump

19 outlet opening

21 line

22 drying device

23 heating element

24 heating element

25 control device

26 switches

27 air blowers

29 temperature sensor

V prewash

R Cleaning

Z intermediate rinse

K rinse

T drying

TR cleaning temperature

Δt _A adsorption process

Δt _H heating phase

Δt _R regeneration process

ITl ₁ amount of fresh water supplied m ₂ recycled amount of water m _ιst rinsing fluid

Q ₁ heating power

Q ₂ Heating power to start time of the cleaning step R t _E End time of the cleaning step R

Claims

A method for operating a water-conducting domestic appliance, in particular for a dishwasher or a washer-dryer, which comprises a plurality of successive partial program steps, of which at least one

Part program step at least temporarily heated a first medium with a first heating element (24) and material to be treated is heated by exposure to the heated first medium, characterized in that at least temporarily a second medium with a second heating element (23) heated at inactive first heating element (24) and the material to be treated is heated with the heated second medium.

2. A method for operating a water-conducting household appliance according to claim 1, characterized in that the first medium is a gaseous medium and the second medium is a liquid medium.

3. A method for operating a water-conducting household appliance according to claim 1 or 2, characterized in that in the partial program step at least temporarily only with the first heating element (24) a first and with the second heating element (23) at least temporarily only a second medium is heated.

4. A method for operating a water-conducting household appliance according to claim 1, 2 or 3, characterized in that in a first part program step at least temporarily only with the first heating element (24) a first and in a second partial program step at least temporarily only with the second heating element

(23) a second medium is heated.

5. A method for operating a water-conducting household appliance according to one of claims 1 to 4, characterized in that in a part program step treated with a second medium is subsequently applied.

6. A method for operating a water-conducting household appliance according to one of claims 1 to 5, characterized in that between two Part program steps at least one exchange of a medium, in particular a second medium takes place.

7. A method for operating a water-conducting household appliance according to one of claims 1 to 6, characterized in that in a trained as a cleaning step program step for the purification of a treated material

Cleaning agent is added.

8. A method for operating a water-conducting household appliance according to claim 7, characterized in that prior to the cleaning step designed as a pre-rinsing part program step for cleaning of items without

Detergent addition is performed.

9. A method for operating a water-conducting household appliance according to 8 or 9, characterized in that during the cleaning step, a Nachwaschphase is carried out while the material to be treated by

Loading with heated by the second heating element (24) second medium is heated.

10. A method for operating a water-conducting household appliance according to one of claims 1 to 9, characterized in that a partial program step as

Rinsing step is formed with heating of wash liquor are added to the relaxation means.

11. A method for operating a water-conducting household appliance according to claim 10, characterized in that before the final rinse step designed as an intermediate rinse step part program step for cleaning of items to be treated is carried out without detergent addition.

12. A method for operating a water-conducting household appliance according to any one of claims 1 or 11, characterized in that as the last part program step, a drying step is performed, is absorbed in the second medium of a reversibly dehydratable material.

13. A method for operating a water-conducting household appliance according to one of claims 1 to 12, characterized in that during a partial program step, the reversibly dehydratable material is at least partially desorbed.