Pump with integrated heating element

Abstract

A pump for a dishwasher is configured as an impeller pump having a central water inflow to a rotating impeller for conveying the water in the radial direction out of the impeller into a pump chamber which surrounds the impeller in a ring-like manner and has a heated pump chamber wall on its outer side. Here, the pump has an outlet in the end region of the pump chamber at an axial spacing from the impeller. Heating elements which have a decreasing power output with regard to the area power output in the axial direction of the pump toward the outlet are arranged on the pump chamber wall. An input of energy into the pump chamber can thus be varied and in the process adapted depending on a turbulent or laminar flow.

Claims

1. A pump for a water-conducting domestic appliance such as a dishwasher or a washing machine, said pump being configured as an impeller pump comprising: a central water inflow to a rotating impeller for conveying water in a radial direction out of said impeller into a pump chamber surrounding said impeller in a ring-like manner and being delimited on an outer side by an at least partially heated pump chamber wall, said pump comprising an outlet in an end region of said pump chamber at an axial spacing from said impeller, wherein heating elements are arranged on said pump chamber wall and said heating elements have a decreasing power output with regard to an area power output in an axial direction of said pump toward said outlet, and wherein a plurality of said heating elements run substantially in said axial direction of said pump and, in said axial direction, have a smaller width or a smaller cross section at a start close to said impeller than at an end toward said outlet.

2. The pump as claimed in claim 1, wherein said outlet is in a tangential direction from said pump chamber wall.

3. The pump as claimed in claim 1, wherein said heating elements are film heating elements.

4. The pump as claimed in claim 3, wherein said heating elements are thick film heating elements.

5. The pump as claimed in claim 1, wherein, in the case of said individual heating elements, said width or said cross section increases continuously along said axial direction toward said outlet.

6. A pump for a water-conducting domestic appliance such as a dishwasher or a washing machine, said pump being configured as an impeller pump comprising: a central water inflow to a rotating impeller for conveying water in a radial direction out of said impeller into a pump chamber surrounding said impeller in a ring-like manner and being delimited on an outer side by an at least partially heated pump chamber wall, said pump comprising an outlet in an end region of said pump chamber at an axial spacing from said impeller, wherein heating elements are arranged on said pump chamber wall and said heating elements have a decreasing power output with regard to an area power output in an axial direction of said pump toward said outlet, wherein said heating elements run substantially transversely with respect to said axial direction toward said outlet, a width or a cross section of one said individual heating element remaining unchanged and said width or said cross section of said heating elements which follow one another increasing in said axial direction toward said outlet, and wherein said heating element which is closest to the outlet has a greatest width or a greatest cross section.

7. The pump as claimed in claim 6, wherein said heating elements run substantially transversely with respect to said axial direction toward said outlet in each case so as to surround said pump chamber wall substantially in a ring-like manner.

8. A pump for a water-conducting domestic appliance such as a dishwasher or a washing machine, said pump being configured as an impeller pump comprising: a central water inflow to a rotating impeller for conveying water in a radial direction out of said impeller into a pump chamber surrounding said impeller in a ring-like manner and being delimited on an outer side by an at least partially heated pump chamber wall, said pump comprising an outlet in an end region of said pump chamber at an axial spacing from said impeller, wherein heating elements are arranged on said pump chamber wall and said heating elements have a decreasing power output with regard to an area power output in an axial direction of said pump toward said outlet, and wherein said heating elements run substantially transversely with respect to said axial direction toward said outlet, said spacing of said heating elements from one another increasing in said axial direction toward said outlet.

9. The pump as claimed in claim 8, wherein said heating elements run substantially transversely with respect to said axial direction toward said outlet in each case so as to surround said pump chamber wall substantially in a ring-like manner.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) Exemplary embodiments of the invention are shown diagrammatically in the drawings and will be explained in greater detail in the following text. In the drawings:

(2) FIG. 1 shows a section through a pump according to the invention having a tubular heating device with heating elements on the outer side,

(3) FIGS. 2 to 8 show plan views of alternative heating devices in accordance with FIG. 1 having heating elements which are configured and run in different ways.

DETAILED DESCRIPTION

(4) FIG. 1 shows a pump 11 according to the invention in section, the design of which as a radial pump or impeller pump corresponds substantially to DE 102007017271 A1 mentioned at the outset, to which reference is made in this regard explicitly. It can advantageously be used in a dishwasher or a washing machine. In the left-hand region, the pump 11 has a pump housing 12 with an inlet 13, an outlet 14 and a pump chamber 16. A customary impeller 18 is arranged as rotor or pump impeller close to a pump chamber bottom 17. It is driven by a pump motor 20 which is not described in greater detail. By way of rotation of the impeller 18, fluid is sucked in at the inlet 13 in the axial direction along the longitudinal center axis L (shown using a dashed line) of the pump 11 and is then ejected by the impeller 18 in the radial direction. The fluid is then brought into circulation in the pump chamber 16 and circulates and finally exits from the pump 11 at the outlet 14. To this end, it has an axial flow component in addition to the circulating movement component of the fluid.

(5) The pump chamber 16 is delimited or formed to the outside substantially by a metallic carrier tube 24, and heating elements 26 are provided on its outer side on an insulating layer 25, with the result that a heating device 22 is formed. The carrier tube 24 is arranged sealingly in the pump housing by means of seals or sealing rings 21.

(6) FIG. 2 shows an enlarged plan view of a first embodiment of a heating device 22a in accordance with FIG. 1. It can be seen how heating elements 26a are provided on the carrier tube 24 or on its outer side on an insulating layer 25. The heating elements 26a are all of identical configuration and run in the direction of the axial flow component S of the water in the pump chamber 16 in accordance with FIG. 1. Here, the heating elements 26a not reach quite as far as the lower and the upper edge of the carrier tube 24, with the result that the carrier tube 24 can be installed satisfactorily with the sealing rings 21 in accordance with FIG. 1.

(7) The heating elements 26a have starting regions 28a which are tapered toward the bottom and, after approximately one third of the length, have achieved a width which they then retain as far as upper end regions 30a. The thickness of the heating elements 26a which are configured as thick film heating elements is identical everywhere here. Here, a pronounced increase in the power output or the thermal energy which is generated is achieved as a result of the reduction in the width at the lower end of the starting regions 28a, which width is, in particular, less than half the main width and once again runs as far as the upper end regions 30a. A transition of the abovementioned turbulent flow of the conveyed water in the pump chamber 16 outside the impeller 18 on the inner side of the heating device 22 into a laminar flow is indicated on the right next to the heating device 22a by way of a dashed line. However, the transition is not as sudden or abrupt as indicated by the dashed line, but rather assumes a defined region, in which the flow gradually changes from turbulent to laminar.

(8) The transition therefore runs somewhat above that region, from which the heating elements 26a have reached a constant width or their width and therefore their heating power output no longer change. This means that there is a lower area power output in the region of the laminar flow than in the region of the turbulent flow. Moreover, the area power output in the region of the laminar flow is substantially constant in the direction of the axial flow component.

(9) It can be seen from FIG. 2 that more heating power output is provided or more heat is generated on account of the tapered starting regions 28a in the lower region of the heating device 22a. Here, in particular, the heating power output can be at least twice that in the upper region close to the end regions 30a, and the area power output can therefore also be virtually double.

(10) In the further alternative of a heating device 22b according to FIG. 3, the heating elements 26b are configured in such a way that they become continuously wider in their longitudinal course along the flow direction S from lower starting regions 28b as far as upper end regions 30b which lie in each case on contacts 33 on the carrier 24 or the insulating layer 25. Here, the smallest width in the lower starting region 28b and the greatest width in the upper end region 30b correspond approximately to those from FIG. 2. It can also be seen in FIG. 3 that the area power output is greater in the lower region of the heating device 22b than in the upper region, the area power output as it were decreasing substantially continuously or uniformly along the axial flow component S, whereas this took place in FIG. 2 just below the dashed transition from the turbulent flow to the laminar flow with a jump or rather in a jump-like manner.

(11) Further variants of the course of the width of the heating elements 26 according to FIGS. 2 and 3 which are not shown in part are readily conceivable to a person skilled in the art. Thus, instead of widening continuously, they can also become wider in a jump-like manner. A combination of uniform and jump-like widenings can also be provided. Uniform widenings are considered, however, to be more advantageous with regard to stream flow and power output generation.

(12) In the further alternative of a heating device 22c according to FIG. 4, the heating elements 26c then do not run along or in the direction of the axial flow component S, but rather perpendicularly with respect thereto, that is to say in the circumferential direction on the carrier tube 24. It can be seen here that the heating elements 26c are considerably narrower in the lower end than the heating elements 26c at the upper end, that is to say the width of the heating elements 26c increases in the direction S in each case from one heating element to the next. The heating elements 26c according to FIG. 4 are in each case at the same spacing from one another.

(13) Overall, the width of the lowermost heating element 26c is less than half the uppermost heating element 26c. A heating power output which decreases in each case is therefore also provided here as a result of the width of the heating elements 26c which increases toward the top. As a consequence, in a similar manner as for the heating devices according to FIGS. 2 and 3, the area power output in the lower region is considerably higher than in the upper region, in particular is at least twice as high. Here, the increase in the width of the heating elements 26c from the bottom to the top along the axial flow component S can be uniform, for example by in each case from 20% to 30%.

(14) In the further exemplary embodiment of a heating device 22d according to FIG. 5, six heating elements 26 are provided, as has otherwise already also been provided in the heating device 22c according to FIG. 4. Here, the lowermost three heating elements 26d have the same width.

(15) Two heating elements 26d which are considerably wider than the lower three, in particular are approximately twice as wide, are provided above the transition (shown using a dashed line) from the turbulent to the laminar flow. Above this, a heating element 26d is provided which in turn is considerably narrower, in particular is approximately as narrow as the lower three heating elements 26d.

(16) In this way, in the heating device 22d according to FIG. 5, the heating power output of the individual heating elements 26d and therefore, on account of the respectively identical spacing from one another, the area power output in the lower region of the heating device 22d is therefore once again considerably greater than in the upper region, in a similar manner to FIG. 4. Here, however, it has no or only a small change along the axial flow component S in the lower region. The change is then rather jump-like above the transition which is shown using a dashed line, namely in the direction of approximately halving of the area power output.

(17) Toward the very top at the upper end of the heating device 22d, the area power output then rises once again as a result of the narrower uppermost heating element 26d which once again ensures an increased area power output in the uppermost region. It can be seen from FIG. 1 that this is as close as possible to the outlet 14 from the pump 11, with the result that an attempt is made here finally once again to introduce as much heat as possible into the conveyed water. Here, the flow can also change again from laminar to rather turbulent, with the result that an increased heat transfer is possible.

(18) Unlike FIG. 4, FIG. 5 also shows the electrical contact of the heating elements 26d via the two contacts 33d. The contacts 33d are elongate strips as contact fields, advantageously made from highly electrically conductive material such as for example silver conductive paste or the like. All the heating elements 26d are therefore connected in parallel, which also applies to the embodiments of FIGS. 4, 6 and 7. The heating elements 26 of the heating devices 22a and 22b from FIGS. 2 and 3 were after all connected in series. However, the thickness and composition of the heating elements are also in each case identical or constant in the heating devices according to FIGS. 4 to 7.

(19) In a further alternative of a heating device 22e according to FIG. 6, the respective heating elements 26e are in turn at the same spacing from one another. Two lower heating elements 26e have the same width and reach approximately up to the transition which is shown using a dashed line. Two heating elements 26e which are arranged above the latter are considerably wider, in particular are approximately twice as wide. Although there are therefore only two types or widths of heating elements 26e here with in each case a different power output, since the area power output is once again considerably smaller in the upper region of the heating device 22e on account of the lower heating power output which is provided than in the lower region, the result here is also the effect according to the invention of an area power output which becomes lower in the axial direction along the flow direction S of the pump 11 toward the outlet 14.

(20) FIG. 7 shows a further alternative of a heating device 22f having heating elements 26f which once again are all at a constant spacing from one another. Two lower heating elements 26f correspond in terms of width to those of the heating device 22e from FIG. 6, and they reach as far as approximately the transition which is shown using a dashed line between the turbulent and laminar flow. A wide heating element 26f is arranged above this, and a heating element 26f which is once again narrow is also arranged above that. In view of the previous explanations, it is clear here that the area power output in the lower region is relatively great, and then the area power output decreases in the region of the wide heating element 26f above the transition which is shown using a dashed line, in order then to increase once more toward the top. A similar effect can therefore be achieved here as in the heating device 22d according to FIG. 5 which has already been explained above.

(21) FIG. 8 shows a further alternative of a heating device 22g. Here, five heating elements 26g are provided which are in each case equally wide, but the spacing of which from one another becomes greater in each case, that is to say increases, along the axial flow component S. Although all the heating elements 26g therefore generate the same heating power output, the area power output is at any rate increased according to the invention in the direction S as a result of the respectively increasing spacing from one another. This takes place in a relatively uniform manner, since the spacings also, as it were, become uniformly greater, for example increase in each case by from 20% to 30%. It can be seen that the illustration of FIG. 8 is approximately an inverted illustration of that from FIG. 4, where the individual heating elements 26c in each case became uniformly wider, whereas the spacings between them remained identical.