EP4003108A1

EP4003108A1 - Beverage maker and method for operating a beverage maker

Info

Publication number: EP4003108A1
Application number: EP20743683.3A
Authority: EP
Inventors: Oliver Schneider
Original assignee: WMF GmbH
Current assignee: WMF GmbH
Priority date: 2019-07-30
Filing date: 2020-07-21
Publication date: 2022-06-01
Also published as: DE102019211272A1; WO2021018666A1; US20220273133A1

Abstract

A beverage maker and a method for operating a beverage maker are provided. The beverage maker is characterized in that its discharge channel has a sensor suitable for detecting a cleaning agent in water. Moreover, the beverage maker contains a control unit configured to receive measured values from the sensor and to take the received measured values as a basis for regulating a water intake from the water source. The method according to the invention accordingly involves a water intake from the water source being regulated on the basis of the measured values from the sensor in the discharge channel. After the beverage maker has been cleaned with cleaning agent, it is possible to ensure that only an amount of water necessary for removing remaining cleaning agent safely from the beverage maker is used for flushing and an unnecessarily large amount or too small an amount of water is not used for flushing. This results in economic and ecological advantages.

Description

Beverage maker and method for operating a beverage maker

A beverage maker and a method for operating a beverage maker are provided. The beverage maker is characterized in that its drainage channel has a sensor which is suitable for detecting a cleaning agent in water. In addition, the beverage maker contains a control unit which is configured to receive measured values from the sensor and to regulate the withdrawal of water from the water source based on the received measured values. In the method according to the invention, water withdrawal from the is accordingly regulated

Water source based on the readings from the sensor in the drainage channel. After cleaning the beverage maker with cleaning agent, it can be ensured that rinsing is only done with an amount of water that is necessary to safely remove remaining cleaning agent from the beverage maker and that it is not rinsed with too much or too little water. This results in economic and ecological advantages. In order to ensure operational readiness and beverage quality in coffee machines, especially in fully automatic coffee machines, components of these machines that come into contact with the ingredients for the beverages or the finished beverages require cyclical cleaning processes. The drinks are usually coffee, but also milk and milk foam, hot chocolate, syrup and / or sugar. In addition, descaling of the hot water and steam generator is necessary with these beverage makers.

There are different cleaning agents and descaling agents for the different paths such as coffee, milk, hot chocolate, syrup, hot water or steam. These are introduced into the respective system or into the respective path in a cleaning mode in solid or liquid form (optionally concentrated form). There, solid detergents are either dissolved or can be diluted to the required concentration in dissolved form. The cleaning agents are then passed through the components and lines of the beverage maker to be cleaned. The exposure times required for an optimal cleaning result are known in the prior art. In addition, it is known in the prior art to pass the cleaning agent several times through the components or lines of the beverage maker in order to achieve a better cleaning result.

At the end of the cleaning process, the cleaning agent is discharged from the beverage maker and the components and lines that have come into contact with the cleaning agent are rinsed until all cleaner residues have been safely removed from the beverage maker. It is known in the art to carry out the rinsing with cold water or with hot water up to steam. The water vapor offers the advantage of disinfection and the possibility of blowing empty the lines of the beverage maker. In the case of commercial beverage makers, the rejection usually takes place via a central drain of the machine, which is connected to the drain of the house installation.

The required amount of rinse water to completely remove the detergent The process of removing a beverage maker can vary from one beverage maker to another or from cleaning cycle to cleaning cycle (depending on how dirty the coffee machine is). For example, a little-used beverage maker has hardly any residues or deposits on the surfaces of the lines and components to be rinsed, on which cleaning agent can adhere. With such a beverage maker, less rinse water is required than with a frequently used beverage maker, the lines and components of which have more residues or deposits on which cleaning agents can adhere. It is similar with decalcifying, as lime partially neutralizes the decalcifying agent.

In order to be able to ensure a complete rinsing of the cleaning agent in all conceivable operating situations (e.g. accidental overdosing of cleaning agent or accumulation of cleaning agent residues in dead spaces and / or poorly perfused areas), it is customary with beverage makers from the prior art to use an excessively large amount to use rinsing liquid in order to exclude any risk to the users of the beverage maker from residues of detergent in the beverage maker. In many cases, a multiple of the amount actually required for rinsing is used, which can unnecessarily increase the time until the next drink is dispensed and, due to the unnecessarily high water consumption, is neither economical nor ecological.

Based on this, it was the object of the present invention to provide a beverage maker which enables the amount of rinse water to be reduced and at the same time can ensure that the user is not exposed to any safety risk from residual detergent in the beverage maker.

The object is achieved by the beverage maker with the features of claim 1 and by the method with the features of claim 9. The dependent claims show advantageous developments.

According to the invention, a beverage maker is provided, comprising a) a water source; b) a heating device (preferably a heating device selected from the group consisting of hot water boiler, steam boiler, flow heater, heat exchanger and combinations thereof);

c) a beverage outlet;

d) a drip tray below (i.e. in the direction of gravity) the beverage outlet;

e) a beverage channel which fluidly connects the water source with the beverage outlet;

f) a sequence that is not identical to the beverage outlet; and g) a drain channel which fluidly connects an interior of the drip tray to the drain;

characterized in that the drainage channel has a sensor which is suitable for detecting a cleaning agent in water, and the beverage maker contains a control unit which is configured to receive measured values from the sensor and, based on the received measured values, to draw water from the water source to regulate.

In the beverage maker presented here, the sensor for detecting a cleaning agent is located in the drainage channel, i.e. in a channel between the drip tray and the drain. A residual concentration of cleaning agent at the end of a cleaning process (e.g. an automatically running cleaning program) can therefore be recorded directly upstream of the drain, i.e. at the last location of cleaning agent in the beverage maker. This ensures that the supply of rinsing water from the water source of the beverage maker in the direction of the detergent outlet is only stopped when the measured value on the sensor (limit value) falls below a certain value.

This feedback control makes it possible to rinse only with the exactly necessary amount of water in order to completely remove the cleaning agent from the beverage maker or to lower its residual concentration in the beverage maker to a value that is harmless for users of the beverage maker. The beverage maker can thus ensure that there is no danger for the user of the beverage operator from residual cleaning agent in the beverage maker. Compared to cleaning methods in the prior art, which for safety reasons rinse with an unnecessarily large amount of water at the end of the cleaning cycle, the use of the beverage maker according to the invention results in a significant saving in water. This has economic advantages for the user or operator of the beverage maker, since less water is consumed and the times until the next possible drink can be dispensed ("dead times") are shortened. The lower water consumption has ecological advantages for the environment, which are becoming more and more important, especially with a rising trend towards water scarcity in more and more regions of the world.

The sensor can be located at any point on the drainage channel, i.e. at any point on the route between the drain and the drip tray. The sensor is preferably arranged at an inlet opening in the drainage channel. The sensor is particularly preferably arranged at an inlet opening from the interior of the drip tray into the drainage channel. Furthermore, the sensor is particularly preferably arranged at an inlet opening from a connecting channel into the drainage channel, the connecting channel fluidically connecting the beverage channel to the drainage channel. The sensor is very particularly preferably arranged downstream of the (respective) inlet opening.

The closer the sensor is to the outlet of the beverage maker, the better it can be ensured that the remaining cleaning agent has completely left the drainage channel of the beverage maker during a rinsing process or that the remaining concentration of cleaning agent is below a certain threshold value, i.e. it is harmless.

In a further preferred embodiment, the drainage channel is fluidically connected to the beverage channel upstream of the sensor via at least one connecting channel. The at least one connection channel is preferably connected to the beverage channel downstream of the heating device of the beverage maker, the heating device preferably being selected from the group consisting of hot water boiler, steam boiler, continuous flow heater, heat exchanger and combinations thereof. In addition, the at least one connection channel can be downstream of a brewing unit for the beverage kebereiters be connected to the beverage channel. Apart from this, the at least one connecting channel can be connected to the beverage channel downstream of a mixer of the beverage maker. It is also possible that the at least one connecting channel is connected to the beverage channel downstream of a milk frothing device of the beverage maker. Furthermore, the at least one connecting channel can be connected to the beverage channel upstream of the beverage outlet. A valve (eg two-way valve) can be arranged at the connection points with the beverage channel. The advantage of these embodiments is that when the beverage maker is cleaned, all the components in the beverage channel of the beverage maker do not necessarily have to be completely cleaned, but rather individual components (e.g. only the heating device) can be cleaned, which saves cleaning agents and reduces cleaning time ("Dead time") can shorten.

Another advantage of the connection channel (preferably of several such connection channels) in the beverage maker is that when cleaning the individual components, the cleaning agent does not have to be dispensed via the beverage outlet. For example, an acidic cleaning agent (e.g. a decalcifying agent) has a certain caustic effect, which can pose a safety risk if such a cleaning agent is dispensed via the beverage outlet (e.g. risk of chemical burns due to the agent splashing at the outlet and / or mistaking the agent a drink by a user of the drink maker).

In a preferred embodiment, the at least one connecting channel of the beverage maker has at least one further sensor which is suitable for detecting a cleaning agent in water, the control unit being configured to receive measured values from the at least one further sensor and based on the received ones Measured values to regulate water withdrawal from the water source. The advantage of this embodiment is that, in the case of simultaneous cleaning of several components of the beverage maker, it can be monitored at the same time whether cleaning agent can actually pass through each individual component and when a harmless level of cleaning agent is reached during rinsing (with water) for each individual component . The at least one further sensor of the beverage is already arranged at an inlet opening of the beverage channel in the connecting channel. The at least one further sensor is particularly preferably arranged upstream of the inlet opening of the connecting channel into the drainage channel.

The control unit can be configured to stop the removal of liquid from the water reservoir when the measured values from the sensor, optionally also from at least one further sensor (in at least one connecting channel), fall below a certain limit value.

Furthermore, the control unit can be configured to regulate a liquid withdrawal from the detergent reservoir based on the measured values from the sensor, optionally also based on the measured values from at least one further sensor (in at least one connecting channel), in particular such that the liquid withdrawal from the cleaning Medium reservoir is reduced or stopped when the measured values from the sensor, optionally also from at least one further sensor, exceed a certain limit value.

The beverage maker can contain a display unit and / or a memory unit, wherein the control unit is preferably configured to cause the values measured by the sensor, optionally also by at least one further sensor (in at least one connection channel), to be exceeded and / or fallen below To present measured values on the display unit and / or to store them on the memory unit, particularly preferably as a function of the measured values as a successful cleaning process or as a faulty cleaning process. The advantage here is that the cleaning process is visualized and documented and thus signals to the user and maintenance staff whether a cleaning process was successful.

If a cleaning program is started on the beverage maker and the measured value of the sensor then falls below a predetermined threshold value, the control unit can be configured to display a request on a display unit of the beverage maker to supply cleaning agent to the beverage maker and / or to store the beverage on a storage unit. kebereiters to save an underdosage of detergent during a cleaning program as an event. Optionally, the control unit can be configured to additionally restrict the operability of the beverage maker, preferably the possibility of dispensing a beverage.

The control unit can also be configured to show the message that a cleaning program is being carried out on a display unit of the drink maker and / or on a memory unit when a cleaning program is started on the beverage maker and the measured value of the sensor is then in a predetermined value range of the beverage maker to save the correct dosage of cleaning agent during a cleaning program as an event.

If a cleaning program is started on the beverage maker and the measured value of the sensor then exceeds a predetermined threshold value, the control unit can also be configured to display a request on a display unit of the beverage maker not to supply and / or open any cleaning agent to the beverage maker a storage unit of the beverage maker to store an overdose of cleaning agent as an event during a cleaning program. Optionally, the control unit can be configured to additionally restrict operability of the beverage maker, preferably the ability to dispense a beverage.

The sensor of the beverage maker, optionally at least one further sensor of the beverage maker, can be selected from the group consisting of conductivity sensor (“conductivity” refers to the electrical conductivity), pH value sensor, capacitive sensor and combinations thereof it is a conductivity sensor.

According to the invention, a method for operating a beverage factory is also provided, comprising the steps

a) Providing a beverage maker containing a water source, a heating device, a beverage outlet, a drip tray below the beverage outlet, a beverage channel connecting the water source fluidically to the beverage outlet, a beverage channel not connected to the beverage outlet outlet identical drain, and a drain channel which fluidly connects an interior of the drip tray with the drain and which has a sensor for detecting a cleaning agent in water, and b) recording measured values of the sensor;

c) receiving measured values of the sensor from a control unit of the beverage maker; and

d) Regulation of a water withdrawal from the water source by the control unit, the regulation being based on the measured values received from the control unit.

The closer the sensor is to the outlet of the beverage maker, the better it can be ensured that the remaining cleaning agent has completely left the drainage channel of the beverage maker during a rinsing process or that the remaining concentration of cleaning agent is below a certain threshold value, i.e. is harmless.

In a preferred embodiment, the outflow channel is fluidically connected to the beverage channel upstream of the sensor via at least one connecting channel. The at least one connecting channel is preferably connected to the beverage channel downstream of the heating device of the beverage maker, the heating device preferably being selected from the group consisting of hot water boiler, steam boiler, flow heater, heat exchanger and combinations thereof. In addition, the at least one connecting channel can be downstream of a brewing unit of the beverage maker be connected to the beverage channel. Apart from that, the minimum At least one connecting channel can be connected to the beverage channel downstream of a mixer of the beverage maker. It is also possible that the at least one connecting channel is connected to the beverage channel downstream of a milk frothing device of the beverage maker. Furthermore, the at least one connecting channel can be connected to the beverage channel upstream of the beverage outlet. A valve (eg two-way valve) can be arranged at the connection points with the beverage channel.

In a further preferred embodiment, the at least one connection channel of the beverage maker has at least one further sensor that is suitable for detecting a cleaning agent in water, the control unit being configured to receive measured values from the at least one further sensor and based on the received measurements evaluate to regulate water withdrawal from the water source.

The at least one further sensor of the beverage is already arranged at an inlet opening of the beverage channel in the connecting channel. The at least one further sensor is particularly preferably arranged upstream of the inlet opening of the connecting channel into the drainage channel.

The method can be characterized in that the control unit stops the liquid withdrawal from the water reservoir of the beverage maker when the measured values from the sensor, optionally also from at least one further sensor (in at least one connecting channel), fall below a certain limit value.

In the method, the control unit, based on the measured values from the sensor, optionally also from at least one further sensor (in at least one connecting channel), can regulate a liquid withdrawal from the detergent reservoir, in particular such that the liquid withdrawal from the detergent reservoir is reduced or reduced stops when the measured values from the sensor, optionally also from at least one further sensor (in at least one connection channel), exceed a certain limit value. The beverage maker can contain a display unit and / or a memory unit or be equipped with this, the control unit causing the sensor, optionally at least one further sensor (in at least one connection channel) to fall below and / or exceed the values. to display measured values on the display unit and / or to store them on the storage unit, particularly preferably depending on the measured values as a successful cleaning process or as a faulty cleaning process.

The method can be characterized in that when a cleaning program is started on the beverage maker and the measured value of the sensor then falls below a predetermined threshold value, the control unit causes a request to be displayed on a display unit of the beverage maker to supply cleaning agent to the beverage maker and / or to store an underdosage of cleaning agent as an event on a storage unit of the beverage maker during a cleaning program. Optionally, the control unit can also cause an operability of the beverage maker to be restricted, preferably to restrict the possibility of dispensing a beverage.

The method can further be characterized in that when a cleaning program is started on the beverage maker and the measured value of the sensor is then in a predetermined value range, the control unit causes the message to be displayed on a display unit of the beverage maker that a cleaning program is being carried out and / or to store a correct dosage of cleaning agent on a storage unit of the beverage maker during a cleaning program as an event.

The method can also be characterized in that if a cleaning program is started on the beverage maker and the measured value of the sensor then exceeds a predetermined threshold value, the control unit causes a request to be displayed on a display unit of the beverage maker not to feed any cleaning agent to the beverage maker and / or to store an overdosing of cleaning agent as an event on a storage unit of the beverage maker during a cleaning program. Optionally, the control unit can also cause to restrict usability of the beverage maker, preferably to restrict the possibility of dispensing a beverage.

The sensor, optionally at least one further sensor of the beverage maker, can be selected from the group consisting of conductivity sensor ("conductivity" means electrical conductivity), pH value sensor, capacitive sensor and combinations thereof. The sensor is preferably a conductivity sensor.

In a preferred embodiment, the method is characterized in that it is carried out with a beverage maker according to the invention.

The subject according to the invention is intended to be explained in more detail with reference to the following figure and the following example, without wishing to restrict it to the specific embodiments shown here.

FIG. 1 shows a schematic representation of the fluidic lines in a beverage maker according to the invention. The beverage channel 4 connects the water source 1 (e.g. a water connection) fluidly with the beverage outlet 2. Inside the beverage channel 4 in this embodiment are a heating device comprising a hot water boiler 8 and a steam boiler 8 ^' , a brewing unit 9, a mixer 10 and a milk frother - Device 11 arranged. The milk frothing device is fluidically connected to a milk source 12 and an air source 13. Fluid (e.g. coffee) that is not caught by a vessel (e.g. a cup) on the drip tray 3 enters an interior of the drip tray 3. The interior of the drip tray is fluidically connected via a drain channel 6 to the drain of the beverage maker. The sensor S for detecting cleaning agent in water, which can be a conductivity sensor, is arranged within the drainage channel 6. In this embodiment, the beverage maker has four connecting channels 7 which fluidically connect the beverage channel 4 to the drainage channel 6 at different points (e.g. downstream of the hot water boiler 8 and steam boiler 8 ^' on the one hand and downstream of the Milchaufschäumvorrich device 11 on the other hand). The sensor S is downstream of that introduction of a connecting channel 7 into the Arranged drain channel 6, which is located closest to the drain 6. Each of the connecting channels here has a further sensor S ^' which is suitable for detecting a cleaning agent in water. The further sensors S ^{′ of} the respective connection channels are arranged upstream of the inlet opening of the respective connection channel 7 into the outlet channel 6. The control unit of the beverage maker (not shown) is configured to receive measured values from the sensor S of the beverage maker and from the at least one further sensor S ^' and to regulate water withdrawal from the water source based on the received measured values.

Example 1 - The electrical conductivity of various cleaning agents recorded by the sensor

In this example, a conductivity sensor was used as the sensor. The conductivity at the sensor was recorded as a function of rinsing with water or certain cleaning agent mixtures (see table).

Table: Conductivity values recorded by the sensor depending on the cleaning agent used in a cleaning program. Water is the control (= no cleaning agent).

The data shown in the table show that the individual tested cleaning agents show a clear difference in electrical conductivity to the electrical conductivity of water from the water source. As a result, the sensor can be used to detect whether there are any cleaning agent residues in the beverage maker. Due to the conductivity characteristic of each tested cleaning agent, an overdosing or underdosing of the one used can also be avoided Record cleaning agents.

The water coming from the water source can have different conductivity values depending on the region or water supplier. If the conductivity is higher than the conductivity specified in the table above, the conductivity for the mixture of the water with the respective cleaning agent specified in the table above should also be higher. The conductivity value given in the table for the water used is therefore not to be regarded as an absolute value which, in the case of every conceivable water, stands for the situation that the beverage maker is free from cleaning agent residues. Rather, the conductance value for water is a reference value that must be determined by every beverage maker depending on its respective water source and via which the other values are calibrated. In this case, the difference between the conductivity value recorded by the sensor and the reference value of water gives the level of residual cleaning agent at the point in the beverage maker where the sensor is located.

The user can be informed about an overdosing and / or underdosing of cleaning agent, for example with the aid of a display unit of the beverage maker.

List of reference symbols

1: water source (e.g. water connection or water tank);

2: beverage outlet;

3: drip tray;

4: beverage channel;

5: process;

6: drainage channel;

7: at least one connection channel;

8: hot water boiler;

8 ^' : steam boiler;

9: brewing unit;

10: mixer;

11: milk frother;

12: source of milk; 13: air source;

S: sensor

S ^' : at least one other sensor.

Claims

1. Beverage maker containing

a) a water source;

b) a heating device;

c) a beverage outlet;

d) a drip tray below the beverage outlet;

e) a beverage channel, which fluidly connects the water source with the Ge beverage outlet;

f) a sequence that is not identical to the beverage outlet; and

g) a drain channel which fluidly connects an interior of the drip tray with the drain;

2. Beverage maker according to one of the preceding claims,

characterized in that the sensor is arranged at an entry opening into the drainage channel, preferably at an entry opening from the interior of the drip tray into the drainage channel and / or from a connecting channel that connects the beverage channel with the drainage channel into the drainage channel, the sensor being particularly is preferably arranged downstream of the inlet opening.

3. Beverage maker according to one of the preceding claims,

characterized in that the discharge channel upstream of the Sors is fluidically connected to the beverage channel via at least one connection channel, the at least one connection channel being preferred

i) downstream of the heating device of the beverage maker is connected to the beverage channel, wherein the heating device is preferably selected from the group consisting of hot water boiler, steam boiler, flow heater, heat exchanger and combinations thereof; and or

ii) downstream of a brewing unit of the beverage maker is connected to the beverage channel; and or

iii) downstream of a mixer of the beverage maker is connected to the Ge beverage channel; and or

iv) downstream of a milk frothing device of the beverage rider is connected to the beverage channel; and / or v) is connected to the beverage channel upstream of the beverage outlet.

4. Beverage maker according to the preceding claim, characterized in that the at least one connecting channel of the Ge beverage maker has at least one further sensor which is suitable for detecting a cleaning agent in water, the control unit being configured to send measured values from the at least one further sensor and to regulate a water withdrawal from the water source based on the received measured values, the at least one further sensor preferably being arranged at an inlet opening of the beverage channel in the connecting channel and particularly preferably upstream of the inlet opening of the connecting channel in the drainage channel .

5. Beverage maker according to one of the preceding claims,

characterized in that the control unit is configured to stop the withdrawal of liquid from the water reservoir when the measured values from the sensor, optionally also from at least one further sensor, fall below a certain limit value, wherein the control unit is preferably configured to regulate a liquid withdrawal from the detergent reservoir based on the measured values from the sensor, optionally also based on the measured values from at least one further sensor, in particular such that the liquid withdrawal from the detergent reservoir is reduced or stopped is when the measured values from the sensor, optionally also from at least one further sensor, exceed a certain limit value.

6. Beverage maker according to one of the preceding claims,

characterized in that the beverage maker contains a display unit and / or a storage unit, the control unit preferably being configured to cause the measured values measured by the sensor, optionally also by the at least one further sensor, to be exceeded and / or fallen below on the Display unit and / or store it on the memory unit, particularly preferably as a successful cleaning process or as a faulty cleaning process as a function of the measured values.

7. Beverage maker according to one of the preceding claims,

characterized in that the control unit is configured to start a cleaning program on the beverage maker and then the measured value of the sensor

i) falls below a predetermined threshold value, a request to supply the beverage maker with cleaning agent on a display unit of the beverage maker and / or to store an underdosing of cleaning agent on a storage unit of the beverage maker as an event during a cleaning program, optionally also an operability of the beverage maker, prefer to limit the ability to dispense a drink; and or

ii) is in a predetermined range of values to show on a display unit of the beverage maker the message that a cleaning program is being carried out and / or on a storage ch unit of the beverage maker to store a correct dosage of cleaning agent during a cleaning program as an event; and or

iii) exceeds a predetermined threshold value, to display a request on a display unit of the beverage maker not to supply any cleaning agent to the beverage maker and / or to store an overdosing of cleaning agent as an event on a storage unit of the beverage maker during a cleaning program, optionally also an operability of the beverage maker, prefers to limit the ability to dispense a drink.

8. A method for operating a beverage maker, comprising the steps a) providing a beverage maker containing a water source, a heating device, a beverage outlet, a drip tray below the beverage outlet, a water source fluidly connecting the beverage outlet with the beverage channel, one not with the outlet identical to the beverage outlet, and an outlet channel which fluidly connects an interior of the drip tray with the outlet and which has a sensor for detecting a cleaning agent in water, and b) recording measured values of the sensor;

d) Regulation of a water withdrawal from the water source by the control unit, the regulation being carried out based on the measured values received from the control unit.

9. The method according to claim 8, characterized in that the sensor is arranged at an inlet opening in the drainage channel, before given to an inlet opening from the interior of the drip tray into the drainage channel and / or from a connecting channel that connects the beverage Kekanal connected to the drainage channel, in the drainage channel, wherein the sensor is very particularly preferably arranged downstream of the inlet opening.

10. The method according to any one of claims 8 or 9, characterized in that the drainage channel upstream of the sensor is fluidically connected to the beverage channel via at least one connection channel, the at least one connection channel preferably i) downstream of the heating device of the beverage maker with the beverage channel is connected, wherein the heating device is preferably selected from the group consisting of hot water boiler, steam boiler, flow heater, heat exchanger and combinations thereof; and or

11. The method according to the preceding claim, characterized in that the at least one connection channel of the beverage rider has at least one further sensor which is suitable for detecting a cleaning agent in water, the control unit being configured to receive measured values from the at least one further sensor to receive and based on the received measured values to regulate a water withdrawal from the water source, the at least one further sensor preferably being arranged at an inlet opening of the beverage channel in the connecting channel and particularly preferably upstream of the inlet opening of the connecting channel in the drainage channel.

12. The method according to any one of claims 8 to 11, characterized in that the control unit stops the liquid withdrawal from the water reservoir of the beverage maker when the measured values from the sensor, optionally also from at least one further sensor, fall below a certain limit value, wherein preferably by the control unit, based on the measured values from the sensor, optionally also from at least one further sensor, a liquid withdrawal from the detergent reservoir is regulated, in particular such that the liquid withdrawal from the detergent reservoir is reduced or stopped when the measured values from the sensor, optionally also by at least one further sensor, exceed a certain limit value.

13. The method according to any one of claims 8 to 12, characterized

indicates that the beverage maker contains a display unit and / or a memory unit or is equipped with this, the control unit causing the measured values measured by the sensor, optionally by at least one further sensor, to be exceeded on the display unit represent and / or store on the storage unit, particularly preferably depending on the measured values as a successful cleaning process or as a faulty cleaning process.

14. The method according to any one of claims 8 to 13, characterized

indicates that when a cleaning program is started on the beverage maker and the measured value of the sensor is thereupon

i) falls below a predetermined threshold value, the control unit causes a request to be displayed on a display unit of the beverage maker to supply cleaning agent to the beverage maker and / or to store an underdosage of cleaning agent on a storage unit of the beverage maker during a cleaning program as an event, optionally also one To restrict usability of the beverage maker, preferably restrict the ability to dispense a drink; and or ii) lies in a predetermined value range, the control unit causes the message to be displayed on a display unit of the beverage maker that a cleaning program is being carried out and / or a correct dosage of cleaning agent during a cleaning program as an event on a storage unit of the beverage maker to save; and or

iii) exceeds a predefined threshold value, causes the control unit to display a request on a display unit of the beverage maker not to supply any cleaning agent to the beverage maker and / or on a storage unit of the

Beverage maker to save an overdosing of cleaning agent during a cleaning program as an event, optionally also to restrict operability of the beverage maker, preferably to restrict the possibility of dispensing a drink.

15. The method according to any one of claims 8 to 14, characterized

indicates that the method is carried out with a beverage maker according to one of claims 1 to 7.