KR20230118837A - How Water Handling Electrical Devices Work and Water Handling Electrical Devices - Google Patents

Abstract

The present invention relates to a method of operating a water handling electrical device comprising a dosing device designed to add at least one of a water receiving element, an electrochemical cell, and a conductivity transmitter-containing washing and cleaning means to an electrochemical cell, the method comprising: a) delivering water to the electrochemical cell; b) adding at least one of the conductivity transmitter-containing washing and cleaning means to the electrochemical cell or to the water flowing through it; c) determining the conductivity of the fluid in the electrochemical cell subsequent to steps a) and b); and d) setting the determined conductivity to a predetermined conductivity. The invention also relates to a corresponding water handling electrical device.

Description

How Water Handling Electrical Devices Work and Water Handling Electrical Devices

The present invention relates to a method of operating a water-bearing electrical apparatus and to a water-bearing electrical apparatus.

WO2018226706A1 describes a heating device that can be connected to a water handling electrical device to provide hot water. This heating unit is designed as an instantaneous water heater and has a water reservoir, cold water connection, inlet and outlet, pump and hot water return. However, this system is complex and requires a lot of installation space.

Accordingly, the present invention aims to provide a water handling electric device and a method of operating the water handling electric device which are simple and require a small installation space.

According to the present invention, this object is achieved by a method having the features of claim 1 and a water handling electric device having the features of claim 9. Advantageous embodiments and developments of the invention can be found in the dependent claims below.

In addition to reduced system complexity and reduced footprint, an advantage achievable with the present invention is that standardized conditions are provided for operating the electrochemical cell. Standardized conditions are achieved by setting the conductivity of the liquid in the electrochemical cell to a predetermined conductivity.

Since water has different conductivity from region to region, heating the water generally has to be done with different parameters. To compensate for this, design effort is increased, eg required electrode area and control effort. The present invention solves this problem by setting the conductivity of the fluid in the electrochemical cell to a predetermined conductivity, which eliminates or at least minimizes such design and control efforts because the electrochemical cell can always operate under the same conditions. This water handling electric device is designed to be compact.

The present invention relates to a water handling electrical system comprising a dosing device designed to meter at least one of a water receiving element, an electrochemical cell, and a conductivity transmitter-containing washing and cleaning means into an electrochemical cell. It relates to how the device works, which method

a) delivering water to the electrochemical cell;

b) adding at least one of the conductivity transmitter-containing washing and cleaning means to the electrochemical cell or to the water flowing through it;

c) determining the conductivity of the fluid in the electrochemical cell subsequent to steps a) and b); and

d) setting the determined conductivity to a predetermined conductivity.

The power required to heat a liquid depends on the conductivity of the liquid to be heated. By supplying at least one of water and a conductivity transmitter-containing washing and cleaning means to adjust the electrical conductivity or conductivity of the liquid to a predetermined conductivity, the electrochemical cell is configured to have the same conductivity regardless of the conductivity or electrical conductivity of the water supplied to the electrochemical cell. conditions can be operated. This system is particularly advantageous in regions where the water hardness is low and the conductivity value of the water is low.

Preferably, drinking water is supplied to the electrochemical cell T in step a). The conductivity of drinking water varies from region to region.

In a preferred embodiment, step d) comprises

- comparing the determined conductivity with the predetermined conductivity; and

- delivering water to the electrochemical cell if the determined conductivity is greater than the predetermined conductivity, and metering at least one of the conductivity transmitter-containing cleaning and cleaning means into the electrochemical cell if the determined conductivity is less than the predetermined conductivity. do.

This means that the determined conductivity can be easily adjusted to the predetermined conductivity of the liquid present in the electrochemical cell.

Preferably, step c) has the steps of applying a predetermined voltage to the electrochemical cell, measuring the current flow in the electrochemical cell, and determining the conductivity based on the measured current flow. This makes it easy to determine the conductivity of the liquid in the electrochemical cell.

Preferably, the electrochemical cell is designed for an operating region higher than the conductivity present at water hardness greater than 14 °dH, more preferably greater than 17 °dH, even more preferably greater than 21 °dH. The predetermined conductivity is preferably stored in the water handling electrical device.

In a preferred embodiment, when the determined conductivity is equal to the predetermined conductivity, the electrochemical cell is started to heat the liquid therein. An electrochemical cell is started, for example, by applying an AC voltage to its electrodes. Preferably, liquid is directed from the electrochemical cell to the water receiving element during and/or after heating. There, the liquid can wash and/or clean at least one of the water receiving element and objects located therein.

Preferably, the fluid is passed from the electric cell to the water receiving element and from there back to the electric cell to be circulated through the electric cell and the water receiving element. In a preferred embodiment, during and/or after heating the fluid in the electrochemical cell, the fluid is circulated from the first region of the water receiving element through the electrochemical cell to the second region of the water receiving element. This further enhances the cleaning and/or cleaning performance of the liquid.

Preferably, steps c) and d) are performed while heating the liquid in the electrochemical cell. This ensures that the electrochemical cell is operated under constant conditions during heating.

In a preferred embodiment, the conductivity transmitter-containing means is selected from at least one of the group consisting of alkali carriers, inorganic or organic acids, salts of organic acids, phosphates, surfactants, and mixtures thereof. The conductivity transmitter-containing means may constitute part of a cleaning and/or cleaning means, at least one of which further contains, for example, at least one of a cleaning and cleaning-active substance. The cleaning and/or cleaning means may alternatively consist of conductivity transmitter-containing means. The conductivity produced by the conductivity transmitter is higher than the conductivity of water that can be used to dilute one of the conductivity transmitter-containing cleaning and rinsing means.

The present invention also relates to a water handling electrical device, which water handling electrical device comprises:

- a water receiving element;

- an electrochemical cell,

- a dosing device designed to add to the electrochemical cell or to the water flowing through it at least one of the cleaning and rinsing means containing the conductivity transmitter, and

- a control device configured to perform a method according to one or more of the foregoing embodiments.

An electrochemical cell has electrodes in the form of an anode and a cathode to which a voltage can be applied. Preferably, the electrochemical cell is designed to heat the fluid therein when AC voltage is applied to the anode and cathode.

Preferably, the water handling electric device is designed as a washing machine or dishwasher.

Preferably, the device further has a circulation system designed to deliver water from the first region of the water receiving element through the electrochemical cell to the second region of the water receiving element.

Embodiments of the present invention are shown only schematically in the drawings and are described in more detail below.
1 shows a partial flow diagram of a method according to the invention.

1 shows a partial flow diagram of a method according to the invention. The method is performed in a water handling electrical device having an electrochemical cell in which water is introduced and at least one of the conductivity transmitter-containing cleaning and cleaning means is metered such that the liquid is present in the electrochemical cell. In step (1), the conductivity value of the liquid present in the electrochemical cell is determined from at least one of water and a conductivity transmitter-containing cleaning and cleaning means. Subsequently, step (2) is performed in which the determined conductivity is compared with a predetermined conductivity.

In result (3), if the determined conductivity is greater than the predetermined conductivity, water is introduced into the electrochemical cell to adjust the conductivity of the liquid to the predetermined conductivity.

If, in result (5), the determined conductivity is equal to the predetermined conductivity, then in step (6) the electrochemical cell is operated to heat the liquid therein. In result (7), if the determined conductivity is less than the predetermined conductivity, in step (8) at least one of the conductivity transmitter-containing cleaning and cleaning means is metered into an electrochemical cell to adjust the conductivity of the liquid to the predetermined conductivity. do. After steps (4, 6, 8), step (1) may be performed again.

Claims (10)

A method of operating a water handling electrical device comprising a dosing device designed to add at least one of a water receiving element, an electrochemical cell, and a conductivity transmitter-containing washing and cleaning means to said electrochemical cell, comprising the steps of:
a) delivering water to the electrochemical cell;
b) adding the conductivity transmitter-containing wash and wash means to the electrochemical cell or to the water flowing through it;
c) determining the conductivity of the fluid in the electrochemical cell subsequent to steps a) and b); and
d) setting the determined conductivity to a predetermined conductivity.
2. The method of claim 1, wherein step d)
- comparing said determined conductivity with said predetermined conductivity; and
- delivering water to the electrochemical cell if the determined conductivity is greater than the predetermined conductivity, and at least one of the conductivity transmitter-containing washing and cleaning means if the determined conductivity is less than the predetermined conductivity; and metering the chemical cell or the water flowing through it.
3. The method of claim 1 or 2, wherein step c) comprises applying a predetermined voltage to the electrochemical cell, measuring a current flow in the electrochemical cell, and determining the conductivity based on the measured current flow. A method comprising the steps of:
4. The electrochemical cell according to any one of claims 1 to 3, wherein the electrochemical cell exhibits a conductivity present at water hardness greater than 14°dH, more preferably greater than 17°dH, even more preferably greater than 21°dH. A method characterized in that it is designed taking into account the operating area in excess.
5. A method according to any one of claims 1 to 4, characterized in that when the determined conductivity is equal to the predetermined conductivity, the electrochemical cell is operated in such a way that the liquid therein is heated.
6. The method of claim 5, wherein during and/or after heating the liquid in the electrochemical cell, the liquid flows from the first region of the water receiving element through the electrochemical cell to the second region of the water receiving element. A method characterized by being circulated.
7. Method according to claim 5 or 6, characterized in that steps c) and d) are performed while heating the liquid in the electrochemical cell.
According to any one of claims 1 to 7,
wherein the conductivity transmitter-containing means is selected from at least one of the group consisting of alkali carriers, inorganic or organic acids, organic acid salts, phosphates, surfactants, and mixtures thereof.
As a water handling electrical device,
- a water receiving element;
- an electrochemical cell;
- a dosing device designed to add to said electrochemical cell at least one of a conductivity transmitter-containing washing and cleaning means;
- A water handling electric device, characterized in that it comprises a control device configured to carry out the method according to any one of claims 1 to 8.
A water handling electrical device characterized in that it is designed as a washing machine or dishwasher.

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