EP3623521A1 - Washing machine, method and control device for operating a washing machine - Google Patents

Abstract

The invention relates to a washing machine (100). The washing machine (100) comprises a tub (102) with a washing drum (104), a water inlet (106) for introducing fresh water into the washing machine (100), a water outlet (108) for draining liquid from the tub (102), a tank (110) for storing liquid from the tub (102), a line (112), a tub pump (114) and a tank valve (116). The line (112) has a first connection (120) to the tub (102). In addition, the line (112) has a second connection (122) to the tank (110) and a third connection (124) to the water drain (108). The line (112) also has a branch (130) which is shaped to connect the first connection (120) to the second connection (122) and the third connection (124). The drain pump (114) is designed to pump liquid in response to a pump signal via the first connection (120) in the direction of the branch (130). The tank valve (116) is arranged between the branch (130) and the second connection (122) and is designed to enable a flow between the branch (130) and the tank (110) in response to an opening signal. In addition, the tank valve (116) is designed to block a flow between the branch (130) and the tank (110) in response to a closing signal.

Description

The invention relates to a washing machine, a method and a control device for operating a washing machine.

Global warming is leading to ever higher requirements for low energy consumption in household appliances. This means that energy and water saving measures are becoming increasingly important, so that smaller and smaller savings measures are also an option.

The EP000000287990A2 describes a storage of liquid from a washing process of a washing machine and a re-supply of the stored liquid at a later time.

The object of the invention is to provide an improved washing machine, an improved method and an improved control device for operating a washing machine.

According to the invention, this object is achieved by a washing machine, a method and a control device for operating a washing machine with the features or steps of the main claims. Advantageous refinements and developments of the invention result from the following subclaims.

The advantages achievable with the invention are that water and energy can be saved when using a washing machine by storing liquid from one wash cycle and using it in a subsequent wash cycle. It is advantageously possible to meet the requirements for activating detergent with temperature, and the resulting effects on hygiene, stain removal and cleanliness with minimal use of energy. This advantageously conserves resources and contributes to global warming. The approach described enables energy-saving storage and reuse of water from a washing process. In addition, residual heat of the stored liquid can be used, or space heat can be used by means of the tank arranged in the water drain, which makes it easier to meet the requirements of new energy labels.

Even if the approach described is described with the aid of a household appliance, the approach described here can also be used in connection with a commercial or professional device, for example a medical device, such as a cleaning or disinfection device, a small sterilizer, a large-scale disinfector or a container washing system.

A washing machine is presented. The washing machine comprises a tub with a washing drum, a water inlet for introducing fresh water into the washing machine, a water outlet for draining liquid from the tub, a tank for storing liquid from the tub, a line, a tub pump and a tank valve. The line has a first connection to the tub. In addition, the line has a second connection to the tank and a third connection to the water drain. In addition, the line has a branch which is shaped in order to connect the first connection to the second connection and the third connection. The drain pump is designed to pump liquid in response to a pump signal via the first connection in the direction of the branch. The tank valve is arranged between the branch and the second connection and is designed to enable a flow between the branch and the tank in response to an opening signal. The tank valve is also designed to block a flow between the branch and the tank in response to a closing signal.

The washing machine can be, for example, an automatic washing machine or a combined washer-dryer. The washing drum can be rotatably arranged in the tub. The tub can be made of stainless steel or plastic, for example. The water inlet can be connected or connected to a tap water connection. The water drain can be a hose or a pipe with a connection to a drain. The liquid can be understood as tap water with or without detergent. The tank can be made of a thermally conductive material, for example stainless steel or a plastic with good thermal conductivity, in order to allow the heat input. The line can be shaped as a metal tube. The branch can be formed as a fork in the line. [BR1]

As a rule, the temperature of a room in which the washing machine is operated is higher than the temperature of the incoming water. Using the tank, this temperature difference can be optimally used to save energy. In order to use an ambient heat of the installation area of the washing machine to heat water for a washing process of the washing machine, it is possible to switchably couple the tank to the water inlet of the washing machine via the line and the tank valve. The water temperature in the tank can approach the ambient temperature.

According to one embodiment, the branch can be designed to have a lower hydraulic resistance in the direction of the second connection than in the direction of the third connection. For this purpose, the branch can have a cross section, for example, which favors a flow of liquid in the direction of the second connection. For this purpose, the branch can, for example, have a triangular indentation opposite the second connection, which directs the liquid in the direction of the second connection. This is advantageous in order to ensure that the tank is filled before excess liquid flows in the direction of the drain. The tank can advantageously be filled quickly and efficiently.

According to one exemplary embodiment, the washing machine can also have a first vent valve which is designed to enable the line to be vented. In addition, the washing machine can have a second vent valve, which is designed to enable venting of the tank. The line and the tank can advantageously be vented by opening the first and the second vent valve. This is advantageous in order to be able to carry out the pumping efficiently without impairing the air in the line or in the tank.

According to one embodiment, the first vent valve and the second vent valve can each have a vent opening and a vent interior. In addition, the first vent valve and the second vent valve can each be designed to close the vent opening when the interior of the vent is flooded. When the line or the tank are completely filled with liquid, a ball in the ventilation interior of the respective ventilation valve can be driven upwards by the buoyancy of the liquid in order to close the ventilation opening. For this purpose, the sphere can have a lower density than water. Venting of the line and the tank can advantageously be implemented in this way simply and inexpensively.

In addition, a heating element can be arranged in the tub according to one embodiment. The heating element can be arranged below a liquid level when the tub is filled with a first amount of liquid. A tank volume of the tank can correspond to the first amount of liquid. The heating element can be a tubular heater, for example. Advantageously, liquid held in the tank can thus flow in the direction of the tub by opening the tank valve and completely flow around the heating element. This is advantageous if the liquid stored in the tank is heated for thermal activation during a washing process.

This approach also introduces a method of operating a washing machine. The method has a step of providing, a step of sending and a step of issuing. In the step of providing, the pump signal and the opening signal are provided to conduct liquid from the tub into the tank. In the sending step, the pump signal and the closing signal are sent to direct liquid from the tub to the water drain. In the dispensing step, the opening signal is output in order to conduct liquid from the tank into the tub. The tank can thus advantageously be filled with liquid from the tub. In addition, the tank valve can block the flow between the line and the tank when pumping out, in order to pump out liquid in the direction of the water outlet. Blocking the flow prevents liquid pumped back into the tank from flowing back. To empty the tank or to return the liquid to the tub, the tank valve is opened again. Advantageously, filling and emptying of the tank and pumping liquid out of the tub in the direction of the water drain can thus be carried out quickly and efficiently.

According to one embodiment, the steps of providing, sending and additionally or alternatively dispensing can be carried out depending on a detergent signal. The detergent signal represents a detergent dosage and additionally or alternatively a type of detergent for a washing process. Advantageously, the tank can be filled or emptied and the liquid can be pumped out in the direction of the water drainage depending on whether the liquid with the respective ingredients of the detergent is suitable for further use or reuse or not. This is advantageously water-saving and environmentally friendly with regard to the use of chemical detergents.

According to one embodiment, the step of transmitting can also be carried out as a function of a storage time signal. Additionally or alternatively, the step of issuing can also be carried out depending on a storage time signal. The storage time signal represents an average storage time of the liquid in the tank. For example, the storage time of the liquid can be saved each time. For this purpose, for example, an opening or closing of the tank valve can be detected, or the time period between the output of an opening signal and a further opening signal after a closing signal. In this way, depending on the storage time signal, fresh water or liquid from a rinsing process or liquid from a main wash cycle can advantageously be introduced into the tank.

In addition, according to one embodiment, the step of sending can be carried out depending on a dwell signal. The dwell signal represents one Dwell time of the liquid currently stored in the tank in order to discard the liquid stored in the tank depending on the dwell time. This is advantageous in order to prevent the tank from becoming contaminated with bacteria. The residence time signal can also be determined using the detergent signal in order to determine a maximum residence time of the liquid in the tank depending on the contents of the liquid. Additionally or alternatively, the liquid in the tank can be discarded depending on the phase of a washing process from which the liquid originates, whether, for example, fresh water, already heated liquid from a main wash cycle or liquid from a last rinse cycle is introduced into the tank.

The approach presented here also creates a control device which is designed to carry out, control or implement the steps of a variant of a method presented here in corresponding devices. This variant of the invention in the form of a control unit can also be used to achieve the object on which the invention is based quickly and efficiently.

The control device can be designed to read input signals and to determine and provide output signals using the input signals. An input signal can represent, for example, a sensor signal that can be read in via an input interface of the device. An output signal can represent a control signal or a data signal that can be provided at an output interface of the control device. The control device can be designed to determine the output signals using a processing rule implemented in hardware or software. For this purpose, the control device can, for example, comprise a logic circuit, an integrated circuit or a software module and can be implemented, for example, as a discrete component or can be comprised by a discrete component.

Figur 1

eine schematische Darstellung einer Waschmaschine gemäß einem Ausführungsbeispiel, und

Figur 2

ein Ablaufdiagramm eines Verfahrens zum Betreiben einer Waschmaschine gemäß einem Ausführungsbeispiel.

An embodiment of the invention is shown purely schematically in the drawings and is described in more detail below. It shows

Figure 1

is a schematic representation of a washing machine according to an embodiment, and

Figure 2

a flowchart of a method for operating a washing machine according to an embodiment.

In the following description of favorable exemplary embodiments of the present approach, the same or similar reference numerals are used for the elements shown in the different figures and acting in a similar manner, a repeated description of these elements being dispensed with.

Figure 1 shows a schematic representation of a washing machine 100 according to an embodiment. The washing machine 100 comprises a tub 102 with a washing drum 104, a water inlet 106 for introducing fresh water into the washing machine 100, a water outlet 108 for draining liquid from the tub 102, a tank 110 for storing liquid from the tub 102, a line 112, a drain pump 114 and a tank valve 116. The line 112 has a first connection 120 to the tub 102, a second connection 122 to the tank 110 and a third connection 124 to the water outlet 108. In addition, the line 112 has a branch 130, which is formed in order to connect the first connection 120 to the second connection 122 and the third connection 124. The drain pump 114 is designed to pump liquid in the direction of the branch 130 in response to a pump signal via the first connection 120. The tank valve 116 is arranged between the branch 130 and the second connection 122 and is designed to enable a flow between the branch 130 and the tank 110 in response to an opening signal. In addition, the tank valve 116 is designed to block a flow between the branch 130 and the tank 110 in response to a closing signal.

In the exemplary embodiment shown here, the water inlet 106 takes place via a washing-in box 140 of the washing machine 100. In addition to the drain pump 114, the washing machine 100 also includes, for example, a circulation pump 142 which is designed to guide liquid from the tub 102 back into the washing drum 104.

According to one exemplary embodiment, the branch 130 is designed to have a lower hydraulic resistance in the direction of the second connection 122 than in the direction of the third connection 124. For this purpose, the branch 130 has a cross section which favors a flow of liquid in the direction of the second connection 122 . The branch 130 is designed here as a fork in the line 112. The branch 130 optionally has a triangular indentation opposite the second connection 122, which directs the liquid in the direction of the second connection 122.

According to the exemplary embodiment shown here, the washing machine 100 also comprises a first vent valve 150. The first vent valve 150 is designed to enable the line 112 to be vented. The washing machine 100 also includes a second vent valve 152 that is configured to enable the tank 110 to be vented. The vent valves 150, 152 are designed here as ball valves, for example.

The first vent valve 150 and the second vent valve 152 also each have a vent opening and a vent interior. The first vent valve 150 and the second vent valve 152 are each formed when the To close the ventilation opening. To enable flooding of the venting interiors of the venting valves 150, 152, the venting valves 150, 152 each have a flooding opening. The flood opening of the first vent valve 150 is arranged on the side of the first vent valve 150 facing the line 112. The flood opening of the second vent valve 152 is arranged on the side of the second vent valve 152 facing the tank 110. The ventilation openings of the ventilation valves 150, 152 are each arranged opposite the flood opening.

A heating element 160 is arranged in the tub 102 in accordance with the exemplary embodiment shown here. The heating element 160 is arranged below a liquid level 162 when the tub 102 is filled with a first amount of liquid and a tank volume of the tank 110 corresponds to the first amount of liquid.

By actuating the tank valve 116, it is possible to use the liquid stored in the tank 110 in a targeted manner during different process phases of a washing cycle. This allows preheated water to be used, for example, during a main wash while cold water is used for rinsing.

A use of the washing machine 100 shown here is described below by way of example: the tank 110 is connected to the drain system of the washing machine 100. This storage tank, tank 110, is filled and emptied by opening and closing tank valve 116. The empty tank 110 is filled with liquid from a main wash, from a rinse cycle or also with fresh water from the water inlet 106. If the tank 110 is to be filled with fresh water, the liquid is first pumped out of the tub 102 and, optionally, laundry picked up in the drum 104 is spun so that no further water drips off. For this purpose, the drain pump, the drain pump 114, is switched on and the liquid is drained off through the line 112 in the direction of the water drain 108. So that any air in the drain system does not impair pumping, the first vent valve 150 is used to vent at the beginning of the pumping. As soon as there is liquid in the first vent valve 150, the first vent valve 150 closes due to the buoyancy of the ball, which is why the density of the ball is below the density of water. After the liquid, for example water with or without detergent, has been pumped out, fresh water is introduced into the tub 102. The water level is set so that the drum 104 has not yet been reached. The height corresponds to the liquid level 162 shown here. Then the drain pump 114 is switched on. The liquid now flows through line 112 to branch 130 and through tank valve 116 into tank 110. The cross sections of branch 130 and tank valve 116 are designed such that the hydraulic Resistance to tank 110 is less than to water drain 108. In addition, the highest point of tank 110, shown here by marking 164, lies below third connection 124, which is shown by marking 166. It is thereby achieved that the tank 110 is first filled before the excess liquid is drained off through the line 112 and the water drain 108, which is shown here as a drain hose. The second vent valve 152 ensures that the tank 110 is vented when the tank 110 is filled.

As soon as the tank 110 is completely filled with liquid, the second vent valve 152 closes by the ball in the vent interior of the second vent valve 152 being pushed into the sealing seat above the ball by the buoyancy. As soon as the liquid has been pumped out of the tub 102, the tank valve 116 is first closed before the tub pump 114 is switched off, so that the water does not run back into the tub 102 when the tub pump 114 is switched off. The filling of the tank 110 with water from the main wash or from one of the rinse cycles takes place analogously. The liquid in the tub 102 is pumped into the tank 110 with the tub pump 114 when the tank valve 116 is open. The liquid from the main wash is preferably stored if there is a detergent in it from which ingredients can be reused. Otherwise, the liquid from the last rinse is used to fill the tank 110.

The use of the liquid stored in the tank 110 takes place, for example, at the start of a washing program for the water inlet for the main wash. For this purpose, the tank valve 116 is opened after the program starts. The liquid from the tank 110 now runs into the tub 102 and fills it up to the covering of the heating element 160 to just below the drum 104, that is to the liquid level 162. After the water has run in, the tank valve 116 is closed. Depending on how long the liquid has been stored in the tank 110 and on which process phase it comes from, for example from the main wash or from the last rinse cycle, this liquid is now used or discarded. If it is to be discarded, the drain pump 114 is used for pumping. As a rule, the liquid can be reused (recycled). The majority of the detergent from the dispenser box 140 is then washed in with a small additional amount of water.

The thermal activation of the liquid, the wash liquor in the tub 110, now follows when the heating element 160 is switched on. If the level of the liquid reaches the drum 104, the drum 104 is rotated during heating. The information as to whether the drum comes into contact or not is derived from the liquid level and additionally or alternatively from the pressure profile of a pressure sensor that detects the liquid level. derived. The necessary heating time is calculated from a quantity of laundry, a quantity of liquid, a water temperature at the beginning and a temperature to be reached. After the heating time has elapsed, the liquid is passed into the laundry in the drum 104 with the circulation pump 142. The laundry is then moved on in order to distribute the wash liquor as evenly as possible in the laundry. As soon as the thermal washing phase is complete, more water is added. This makes the laundry heavier and the subsequent mechanical washing phase further contributes to the cleaning effect of the washing process.

The following aspects are worth mentioning as main features of a construction of the exemplary embodiment of the washing machine 100 shown here: The tank 110 is arranged in the drain system above the highest liquid level in the tub 102, above the liquid level 162. An inlet of the tank 110 in the form of the tank valve 116 is arranged at the bottom of the tank 110 with respect to an installation direction of the washing machine 100. The tank 110 is coupled to the drain system of the washing machine 100 via the tank valve 116. A lower flow resistance to the tank 110 occurs at the branch 130 than in the direction of the third connection 124 to the further drain system. The tank 110 is aerated and vented by means of the second vent valve 152, designed as a ball valve, with the ball floating through the buoyancy. The tank 110 is dimensioned such that the amount of liquid is sufficient to cover the heating element 160 without an appreciable amount of water coming into the drum 104, so the tub 102 is filled up to the liquid level 162.

Figure 2 FIG. 12 shows a flowchart of a method 200 for operating a washing machine according to an exemplary embodiment. An embodiment of the washing machine described with reference to the previous figure is possible using method 200. The method 200 has a step 205 of providing, a step 210 of sending and a step 215 of issuing. In step 205 of providing, the pump signal and the opening signal are provided to conduct liquid from the tub into the tank. At step 210 of sending, the pump signal and the closing signal are sent to direct liquid from the tub to the water drain. In step 215 of dispensing, the opening signal is issued in order to conduct liquid from the tank into the tub.

According to one exemplary embodiment, the step 205 of providing, the step 210 of sending and additionally or alternatively the step 215 of dispensing are carried out depending on a detergent signal. The detergent signal represents one Detergent dosage and additionally or alternatively a type of detergent for a washing process.

The step 210 of transmitting and the step 215 of issuing are carried out in accordance with an embodiment depending on a storage time signal. The storage time signal represents an average storage time of liquid in the tank.

In addition, step 210 of the transmission is carried out depending on a dwell signal. The dwell time signal represents a dwell time of the liquid currently stored in the tank in order to discard the liquid stored in the tank depending on the dwell time.

The method 200 can also be carried out using a control device which is designed to carry out the steps 205, 210, 215 in corresponding units and to control them additionally or alternatively.

An embodiment of the method 200 can be used to store liquid from the main wash and then to use it again if the detergent used is suitable for this. In addition, the stored liquid can be automatically discarded if it has been stored for too long, ie if a maximum residence time has been reached or exceeded. The stored water is discarded by letting water into the tub, opening and then closing the tank valve and pumping out with the tub pump if the maximum storage time has been exceeded. To do this, step 205 can be carried out so that the liquid flows into the tub, and then step 210 can be carried out to pump the liquid in the direction of the water drain. The storage time of the liquid, i.e. the maximum residence time, can also be determined depending on whether fresh water or the liquid from the main wash or from the last rinse is stored. Depending on the length of an average storage time of a user of the washing machine, it is determined whether fresh water or liquid from the main wash or from the last wash cycle is stored for storage. When thermally activating the liquid in the tub, a quantity of laundry, a liquid temperature at the beginning, an end temperature to be reached, a quantity of liquid and a room temperature are taken into account to determine the heating time.

If an exemplary embodiment comprises a “and / or” link between a first feature and a second feature, this is to be read in such a way that the embodiment according to one embodiment has both the first feature and the second feature and according to a further embodiment, has either only the first feature or only the second feature.

Claims (10)

Washing machine (100), which has the following features: a tub (102) with a washing drum (104); a water inlet (106) for introducing fresh water into the washing machine (100); a water drain (108) for draining liquid from the tub (102); a tank (110) for storing liquid from the tub (102); a line (112) with a first connection (120) to the tub (102) and with a second connection (122) to the tank (110) and with a third connection (124) to the water drain (108), the line (112) has a branch (130) which is shaped to connect the first connection (120) to the second connection (122) and the third connection (124); a drain pump (114) configured to pump liquid in response to a pump signal via the first connection (120) towards the branch (130); and a tank valve (116), which is arranged between the branch (130) and the second connection (122) and is designed to allow a flow between the branch (130) and the tank (110) in response to an opening signal, and is designed to block a flow between the branch (130) and the tank (110) in response to a closing signal. Washing machine (100) according to claim 1, wherein the branch (130) is formed to have a lower hydraulic resistance in the direction of the second connection (122) than in the direction of the third connection (124). Washing machine (100) according to one of the preceding claims, with a first vent valve (150), which is designed to allow venting of the line (112) and with a second vent valve (152), which is designed to vent the tank (110 ) to enable. The washing machine (100) according to claim 3, wherein the first vent valve (150) and the second vent valve (152) each have a vent and a vent interior, and wherein the first vent valve (150) and the second vent valve (152) are each designed to close the vent opening when the interior of the vent is flooded. Washing machine (100) according to one of the preceding claims, wherein a heating element (160) is arranged in the tub (102), the heating element (160) being arranged below a liquid level (162) when the tub (102) with a first amount of liquid is filled, and a tank volume of the tank (110) corresponds to the first amount of liquid. Method (200) for operating a washing machine (100) according to one of the preceding claims, the method (200) comprising the following steps: Providing (205) the pump signal and the opening signal to direct liquid from the tub (102) into the tank (110); Sending (210) the pump signal and the close signal to direct liquid from the tub (102) to the water drain (108); and Outputting (215) the opening signal to conduct liquid from the tank (110) into the tub (102). The method (200) according to claim 6, wherein the steps (205, 210, 215) of providing, transmitting and / or dispensing are carried out depending on a detergent signal, the detergent signal representing a detergent dosage and / or a type of detergent for a washing process. Method (200) according to one of claims 6 or 7, wherein the steps (210, 215) of sending and / or issuing are carried out depending on a storage time signal, the storage time signal representing an average storage time of liquid in the tank (110). A method (200) according to any one of claims 6 to 8, wherein the step (210) of transmitting is carried out depending on a residence time signal, which represents a residence time of the liquid currently stored in the tank (110) to, depending on the residence time, in the Discard tank (110) stored liquid. Control device which is designed to execute and / or to control the steps of the method (200) according to one of the preceding claims in corresponding units.

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