EP1833353A1

EP1833353A1 - Dishwashing machine equipped with a sorption drying device

Info

Publication number: EP1833353A1
Application number: EP05808030A
Authority: EP
Inventors: Helmut Jerg; Kai Paintner
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2004-12-09
Filing date: 2005-10-20
Publication date: 2007-09-19
Anticipated expiration: 2025-10-20
Also published as: JP4659042B2; KR20070085898A; US8459278B2; JP2008522687A; PL2946715T3; RU2404702C2; RU2007120227A; WO2006061287A1; US20070295373A1; EP2946715A2; AU2005313473B2; BRPI0518518A2; DE102005004096A1; PL1833353T3; US20120240965A1; EP2946715A3; EP1833353B1; EP2946715B1; AU2005313473A1

Abstract

The invention relates to a dishwashing machine equipped with a washing compartment and with devices for washing dishes using a washing solution as well as with a sorption drying device (1), which is connected to the washing compartment in an air-conducting manner and which comprises a heater (6) as well as a sorption column (3) containing reversibly dehydratable material (4). The sorption column is placed inside a housing (9) having an air inlet (13) and an air outlet (7), and the heater (6) is placed in the immediate vicinity of the air inlet (13) of the sorption column (3).

Description

Dishwasher with a Sorptionstrockenvorrichtung

The invention relates to a dishwasher with a rinsing container and devices for rinsing dishes by means of rinsing liquor and with a Sorptionstrockenvorrichtung which is air-conductively connected to the rinse tank by circulating air and has a heater and a sorbent column with reversibly dehydratable material, wherein the sorbent in a housing with an air inlet and an air outlet is arranged.

According to DE 103 53 774 and / or DE 103 53 775 of the Applicant, reversibly dehydratable material is heated to very high temperatures for desorption. The stored liquid in this case exits as hot water vapor. Through the management of

Air through the sorption and an optionally existing line is the

Steam is passed into the rinsing tank and also the air in the rinsing tank heated. The

Introduction of the hot water vapor and the heated air in the washing during a partial program step with rinsing liquid to be heated in the

Treatment room is largely sufficient to the treatment liquid and / or the

To heat dishes sufficiently. Thus, if necessary, can be largely dispensed with a further heating, and the energy used for desorption can be almost completely used for heating the rinsing liquor and / or the dishes except for the energy needed to overcome the binding forces between water and reversibly dehydratable material , In addition to energy savings, this ensures efficient cleaning of the items to be washed.

EP 0 358 279 B1 discloses a device for drying dishes in a domestic dishwasher, in which the rinsing liquor is conveyed through an outside of the dishwasher

Rinsing container arranged heaters, preferably an electric water heater is heated, wherein a largely closed drying system is provided in the air from the washing through a regenerable by heating

Drying device and circulated from this back into the washing. In this case, the drying device consists of a heater in thermal contact with the heater

Dry container, which is filled with a moisture adsorbing desiccant. By connecting the drying container with the heating of the rinsing liquor Any existing heater results in the immediate operation of the dryer after the flushing process. The desiccant is hereby placed at least partly as a jacket around the heating elements of the heater, so that the desiccant can be heated in the drying container during each heating process and thus dried.

The drying container is formed as a double-walled hollow cylinder in which the dry material is stored. The arrangement of the inlet and outlet ports for connection to the closed air system takes place in a diagonally opposite arrangement. This results in the disadvantage of a relatively high flow resistance, so that the fan provided for the promotion of the air flow must be operated with very high power. This is negative in terms of noise and energy consumption noticeable.

Due to the structural design of the Sorptionstrockenvorrichtung, which causes an inhomogeneous heat input into the dry material, the desorption is time consuming and can also lead to local overheating of the desiccant and thus to its irreversible damage. The desorption is also difficult because the heater is located in the center of the double-walled hollow cylinder and a radial propagation of the heat to the desiccant close to the outer hollow cylinder wall is hardly possible due to the axially flowing air flow.

The object of the present invention is therefore to provide a dishwasher, in which the dry material contained in a Sorptionstrockenvorrichtung is evenly heated for the purpose of desorption.

This object is achieved with a dishwasher according to the features of claim 1. Advantageous embodiments will be apparent from the dependent claims.

In the dishwasher according to the invention with a washing container and devices for rinsing dishes by means of rinsing liquor and with a Sorption drying apparatus, which is air-conductively connected to the washing container by circulating air and has a heating and a sorption column with reversibly dehydratable material, the sorption column is arranged in a housing with an air inlet and an air outlet, wherein the heater is arranged in the flow direction of the air in front of the air inlet , As a result, evenly heated air is introduced into the sorption column.

In a preferred embodiment, the heating in the region of the air inlet of the sorption column, d. H. in the immediate vicinity of the air inlet, arranged. The advantage of this procedure is that the air is heated at the inlet of the sorption column, preferably outside of it, whereby this uniformly hot air is supplied and this hot air is passed through the sorption column. Overheating of the reversibly dehydratable material of the sorption column during desorption is excluded. This is especially true when the heater is located outside the housing. Due to the immediate spatial proximity of the heater to the air inlet of the sorption column is further ensured that the energy used to heat the air flow energy can be passed to the reversibly dehydratable material with the best possible efficiency, since a cooling of the air flow due to the immediate proximity is avoided.

In a preferred embodiment, the housing has a base area having the air inlet and a cover area having the air outlet. This advantageously ensures a low flow resistance within the sorption column, since the air can be conducted "straight" through the housing of the sorption column.

In a further expedient embodiment, the base surface and / or the top surface are at least partially formed as a sieve, so that the air inlet and / or the air outlet is or are formed by the sieve surface. In addition to a fixation of the reversibly dehydratable material within the sorption column, the flow resistance of the air stream guided through the sorption column can be kept low as a result. - A -

In a further expedient embodiment, the heater and the air inlet are arranged at least partially overlapping. The degree of overlap between the heater and the air inlet of the housing of the sorption column is determined essentially by the type and the power available from a heater.

It may be provided according to another embodiment, to arrange the heater in the immediate vicinity of the air inlet of the sorption column inside the housing of the sorption column. To avoid local overheating, it is advantageous in this case to arrange the heater with the largest possible surface area within the sorption column, wherein the specific power per area can be dimensioned so small that local overheating of the reversibly dehydratable material can not occur.

In a further expedient embodiment, the housing has a heat-insulated housing jacket. This can be formed for example by a double wall. Alternatively or additionally, for example, a heat insulation may be applied to the outside of the housing shell. Furthermore, it is conceivable to form a vacuum in the gap formed between the double wall in order to obtain the best possible insulation to the outside. By providing a heat insulation on the housing shell, which preferably forms the largest part of the surface of the sorption column, it is ensured that the energy expended by the heating can be used as best as possible for the desorption of the reversibly dehydratable material.

In a further expedient embodiment, the height of the housing shell is smaller than the width or the diameter of the base and top surfaces. Generally speaking, this means that the length to be flowed through by the air flow is less than the maximum width or the diameter of the base and top surfaces. This results in advantage with a low flow resistance, so that the performance of the fan or the speed of the fan can be made low. A particularly preferred arrangement here is a cylindrical configuration of the housing of the sorption column, since with this geometric shape a particularly homogeneous flow through the

Air flow is guaranteed. In a further expedient embodiment, the sorption drying device has a fan with a fan housing for generating an air flow, which is arranged in spatial proximity in front of the air inlet of the housing of the sorption column. This makes it possible to integrally form the fan housing and the housing of the sorption column, so that an overall compact unit is provided, which takes up only a small space in the dishwasher.

In a variant, the blower can be arranged as an axial blower in front of the inlet of the housing of the sorption column. In another variant, the fan is arranged as a radial fan laterally of the inlet of the housing of the sorption column. Which variant is preferable to choose, results essentially from the spatial arrangement of the Sorptionstrockenvorrichtung in the dishwasher and the prevailing space conditions.

The heater used for desorption can be designed as a wire heater, as a tubular heater, as a ceramic heater or in PTC technology.

In an advantageous embodiment, the heater is integrated into the fan housing. This can be particularly easily realized, especially when using a heater in PTC technology, since the resistance layer or layers can be applied to the inside of the housing. Another advantage of using a PTC heater is the ease of fabrication since the layers can be applied by a printing process. Furthermore, the heating power regulates itself over the prevailing temperatures in the heating sections by itself, so that overheating is inherently precluded. By appropriate arrangement or interconnection of individual layer sections, moreover, a heater with several heating powers can be realized.

In a further expedient embodiment, the blower, the heater and the housing of the sorption column are formed as a unit, so that there is an overall compact Sorptionstrockenvorrichtung.

In a further embodiment, the sorption column is used on the one hand for drying the dishes and on the other hand for the desorption of the sorption column Heat energy for at least partially used for heating the rinsing water in the washing and / or the dishes. In addition to this feature, all further features from DE 10353774 and / or DE 10353775 of the applicant can be included in further embodiments.

In a further dishwashing machine according to the invention with a rinsing container and devices for rinsing crockery by means of rinsing liquor and with a Sorptionstrockenvorrichtung which is air-conductively connected to the rinse tank by circulating air and has a heater and a sorbent column with reversibly dehydratable material, the sorbent in a housing with an air inlet and an air outlet, wherein the heater is disposed inside or on the housing of a blower.

The invention will be explained in more detail with reference to several embodiments. Show it:

1a, b, a first embodiment of a usable in a dishwasher according to the invention sorption drying device,

2a, b, a second embodiment of a usable in a dishwasher according to the invention sorption drying device,

3a, b, a third embodiment of a usable in a dishwasher according to the invention sorption drying device,

4 shows a fourth exemplary embodiment of a sorption drying device that can be used in a dishwasher,

Fig. 5 shows a fifth embodiment of a in an inventive

Dishwasher usable Sorptionstrockenvorrichtung, and

Fig. 6 shows a sixth embodiment of a in an inventive

Dishwasher usable Sorptionstrockenvorrichtung. A dishwasher according to the invention, not shown in detail in the figures, usually has a washing container, are arranged in the baskets for the classification of items to be washed. In all embodiments of the dishwasher according to the invention, the drying of the dishes is preferably carried out as described in DE 10353774 and / or DE 1035375 of the applicant. The content of the applications DE 10353774 and / or DE 1035375 is thus included, as far as appropriate, in this application. Furthermore, a sorption drying device 1 connected in air-conducting manner to the washing container is provided, which is connected in an air-conducting manner to the washing container and a heater 6, a blower 2 and a sorption column 3 with reversibly dehydratable material, eg. As zeolite having. The sorption column is, as explained above, used both for drying and for heating air conducted through.

In the figures explained in more detail below, various embodiments of such Sorptionstrockenvorrichtungen are shown.

FIG. 1 shows a first exemplary embodiment, which represents the sorption drying device 1 in a sectional side view (FIG. 1 a) and a view from below (FIG. 1 b). The sorption drying apparatus 1 has a radial fan 2 with a propeller 11 in a housing 8, via whose inlet 12 air is drawn in, compressed and fed to the sorption column 3 via a heater 6 designed as a wire heater. The sorption column 3 is formed in a housing 9 which has a cylindrical shape. A wall 10, also referred to as housing jacket, is provided with an insulation, which may be formed for example in the form of a thermal insulation or a double wall with or without vacuum.

The base 6 facing the heater 6 forms an inlet 13 of the sorption column 3, which is preferably designed as a sieve for fixing the reversibly dehydratable material 4 of the sorption column 3 arranged in the housing 9. While the air inlet 13 extends over the entire base area in the exemplary embodiment, an air outlet 7 of the sorption column, arranged in the center of the base area, takes by way of example only a small area section. Due to the size of the air outlet 7, on the one hand, the flow resistance of the passed through the sorption column 3 Air and their exit velocity set in the washing. The airway is indicated by the arrows A, B and C.

The heater 6 designed as a wire heater is arranged at least partially with the air inlet 13 overlapping outside of the air inlet of the sorption column. Contrary to the drawing, the wire heater could be formed completely overlapping below the air inlet 13. How big the wire heater is made and which part of the air intake covers it depends essentially on the power dissipated by the wire heater. Due to the outside, but in close proximity to the air inlet 13, arranged heater 6, there is the effect that the air routed through the heater away until the entry into the Sorptioskolonne 3 can not or at least not significantly cool, so that an effective heat and Desorption of reversibly dehydratable material is ensured. On the other hand - with possibly too high power output of the heater - no local overheating of reversibly dehydratable material occur.

In addition to the geometrical dimensions of the housing 9 of the sorption column 3, the flow resistance of the air passed through it is determined by the diameter of the spherical reversibly dehydratable material 4. When determining the diameter of the reversibly dehydratable material, a tradeoff must be made between the desired surface area of this material and the resulting direct flow resistance. It has proved to be advantageous spherical formed reversibly dehydratable material with a diameter of 2.5 to 5 mm.

FIG. 2 shows a second embodiment of a sorption drying device 1 for use in a dishwasher according to the invention. FIG. 2a shows a sectional side view, FIG. 2b a view from below. The relative arrangement of blower housing 8, heater 6 and housing 9 of the sorption column corresponds to the embodiment described in connection with FIG. In contrast to the previous example, the heating is predominantly formed as a tubular heater (for example in the form of a wire or belt heater), which now extends over the entire surface of the air inlet 13. Disadvantage of a tubular heater is the need for a very high heat output or a very high fan speed. Should the Sorptionstrockenvorrichtung be used simultaneously for heating treatment liquid in the interior of the washing by hot air or hot steam is introduced into the washing, this type of heating is optionally not suitable for reasons of time.

Figure 3 shows a third embodiment, the constructive structure also corresponds to the example described in connection with FIG. FIG. 3a shows a sectional side view, FIG. 3b a view from below. In contrast, the heater is now designed as a ceramic heater (so-called honeycomb heater), which has a greater robustness than a wire heater. A disadvantage of such a heating type, however, is the greater pressure loss when flowing through the heater 6, so that the blower 2 must be operated at a higher speed.

Figures 4 and 5 show further embodiments in which the heater is formed in the interior of the sorption column 3. To avoid a very high power density, the heater preferably extends over a large length over the entire interior of the sorption column 3. Such a variant has the advantage that the fan 2 both as a radial fan (Fig. 4) and as an axial fan (Fig ) can be formed. In this case, it is possible, in particular in the variant shown in FIG. 4, to carry out the air duct designated by the reference numeral 14 with a very small height h, resulting in a more compact arrangement. Of course, the variant shown in FIG. 5 can also be realized with the types of heating mentioned in the preceding exemplary embodiments, with a larger construction volume possibly having to be accepted.

In the sixth exemplary embodiment illustrated in FIG. 6, a PTC heater, which is arranged in the interior of the housing 8 of the blower 2, is shown as the heater. For example, the PTC layer can be applied to the inside of the housing 8 by a printing process. The advantage of a PTC heater is that the heating power is controlled on its own by the temperature prevailing in the PTC layer. In a corresponding manner, the air channel 14 can be made very small, which also results in a compact Sorptionstrockenvorrichtung. In all the variants described above, it is particularly advantageous possible to form blower 2, heater 6 and sorption column 3 to form an integral unit, in particular to carry out their housing in one piece. As a result, on the one hand, a very simple installation of the sorption drying device in the dishwasher is possible, on the other hand, the structural dimensions can be kept low.

With the present invention, a dishwasher is provided, with which it is possible to efficiently clean and dry the dishes located in the washing container, and to keep the associated energy consumption as low as possible. Furthermore, a simple assembly is guaranteed, which allows a cost-effective manufacturing process.

LIST OF REFERENCE NUMBERS

1 sorption drying device

2 blowers

3 sorption column

4 reversibly dehydratable material

6 heating element

7 outlet

8 housing

9 housing

10 housing wall

11 propellers

12 inlet

13 inlet

14 air duct

A ₁ B ₁ C airway h altitude

Claims

claims

1. Dishwasher with a rinse tank and devices for rinsing dishes by rinsing liquor and with a Sorptionstrockenvorrichtung (1), which is air-conductively connected to the rinse tank by circulating air and a heater (6) and a sorption column (3) with reversibly dehydrierbarem

Material (4), wherein the sorption column (3) in a housing (9) with an air inlet (13) and an air outlet (7) is arranged, characterized in that the heater (6) in the flow direction of the air in front of the air inlet ( 13) of the sorption column (3) is arranged.

2. Dishwasher according to claim 1, characterized in that the heater (6) in the region of the air inlet (13) of the sorption column (3) is arranged.

3. Dishwasher according to claim 1 or 2, characterized in that the housing (9) has an air inlet (13) having base and a the air outlet (7) having top surface.

4. Dishwasher according to claim 3, characterized in that the base surface and / or the top surface are at least partially formed as a sieve, so that the air inlet (13) and / or the air outlet (7) is formed by the screen surface or are.

5. Dishwasher according to one of the preceding claims, characterized in that the heater (6) and the air inlet (13) are arranged at least partially overlapping.

6. Dishwasher according to one of the preceding claims, characterized in that the heater (6) in the immediate vicinity of the air inlet (13) of the sorption column (3) in the interior of the housing (9) of the

Sorption column is arranged.

7. Dishwasher according to one of the preceding claims, characterized in that the housing (9) has a thermally insulated housing shell (10).

8. Dishwasher according to claim 7, characterized in that the height of the housing shell (10) is smaller than the largest width or the diameter of

Base and top surface is.

9. Dishwasher according to one of the preceding claims, characterized in that the Sorptionstrockenvorrichtung (1) comprises a fan (2) with a fan housing (8) for generating an air stream, which in close proximity to the air inlet (13) of the housing of the sorption column ( 9) is arranged.

10. Dishwasher according to claim 9, characterized in that the fan (2) as an axial fan in front of the inlet (13) of the housing

Sorption column is arranged.

11. Dishwasher according to claim 9, characterized in that the fan (2) is arranged as a radial fan laterally of the inlet (13) of the housing of the sorption column.

12. Dishwasher according to one of claims 1 to 11, characterized in that the heater (6) is designed as a wire heater, tubular heater, ceramic heater or in PTC technology.

13. Dishwasher according to one of claims 1 to 9, characterized in that the heater (6) in the fan housing (8) is integrated.

14. Dishwasher according to one of claims 8 to 13, characterized in that the fan (2), the heater (6) and the housing (9) of the

Sorption column are formed as a unit.

15. Dishwasher according to one of the preceding claims, characterized in that the sorption column (3) on the one hand for drying the dishes and on the other hand for desorption of the sorption (3) used thermal energy for heating the rinsing tank located in the rinsing liquor and / or the dishes at least partially is used.

16. Dishwasher with a rinsing container and devices for rinsing dishes by rinsing liquor and with a Sorptionstrockenvorrichtung (1), which is air-conductively connected to the rinse tank by circulating air and a heater (6) and a sorption column (3) with reversibly dehydrierbarem material (4 ), wherein the sorption column (3) in a housing (9) with an air inlet (13) and an air outlet (7) is arranged, characterized in that the heater (6) inside or on the housing 8 of a blower (2) is arranged.

17. Dishwasher according to claim 16, characterized in that the sorption column (3) on the one hand for drying the dishes and on the other hand for desorption of the sorption (3) used thermal energy for heating the rinse tank located in the rinsing and / or the dishes is at least partially used ,