CN117265829B - Intelligent control method and device for washing machine, washing machine and storage medium - Google Patents

Abstract

The invention provides an intelligent control method and device of a washing machine, the washing machine and a storage medium, wherein the method comprises the steps of identifying the current state of the washing machine, and determining functional components required by the washing machine to maintain the current state; and supplying power to the functional component so that the functional component works according to the setting work logic adapted to the current state. The scheme of the invention not only can further optimize the power supply and power failure control method of the module, the load and the communication circuit according to the actual state of the washing machine, but also can greatly reduce the energy consumption of the whole use process of the washing machine while ensuring the normal operation of the washing machine.

Description

Intelligent control method and device for washing machine, washing machine and storage medium

Technical Field

The invention relates to the technical field of intelligent household appliances, in particular to an intelligent control method and device of a washing machine, the washing machine and a storage medium.

Background

There are two main criteria for measuring power consumption in washing machines: one is an energy efficiency standard, i.e. power consumption per unit time; the other is standby power consumption, i.e., power at standby, such as 0W standby, 0.5W standby, 1W standby, and the like. In order to achieve the energy efficiency standard, many manufacturers of washing machines independently use an energy efficiency mode as a single mode, and reduce the power consumption per unit time by lengthening the washing time, thereby achieving the energy efficiency standard. In order to meet the standby power standard, many current washing machines reach the standard by turning off the relevant load during standby. While current industry approaches like 0W standby or 0.5W standby may save power to some extent, there is no significant reduction in power consumption as a whole.

In order to solve the energy-saving problem, some technologies achieve the purpose of energy saving by switching between a normal mode and a shutdown/sleep mode of a chip; the normal power consumption mode and the low power consumption mode are also realized by switching the frequency of the clock inside the chip. The above-described scheme of mode switching and chip frequency change through the inside of the chip can achieve a certain degree of energy saving in standby, but cannot greatly reduce the energy consumption of the washing machine during the whole use process.

While some schemes can reduce the energy consumption in the standby state to a greater extent, the function of influencing the circuit connection still has greater energy consumption, and the power supply and power failure control method of the module, the load and the communication circuit is not further optimized according to the actual state of the washing machine. Therefore, a method for saving energy and ensuring the washing effect is needed.

Disclosure of Invention

The invention aims to provide an intelligent control method and device for a washing machine, the washing machine and a storage medium, so as to solve the problem of energy consumption of the washing machine in the use process, and further ensure that the energy-saving performance of the washing machine can be greatly improved on the premise of not affecting the washing effect.

According to an aspect of the present invention, there is provided an energy saving control method of a washing machine including a plurality of functional components, each of which is independently powered, the method comprising:

identifying a current state of a washing machine, and determining functional components required by the washing machine to maintain the current state;

and supplying power to the functional component so that the functional component works according to the setting work logic adapted to the current state.

Optionally, the determining the functional components required by the washing machine to maintain the current state includes:

if the current state of the washing machine is a shutdown state, it is determined that the washing machine does not need to operate any functional component modules.

Optionally, the determining the functional components required by the washing machine to maintain the current state includes:

and if the current state of the washing machine is a standby/pause state, determining that the functional components required by the washing machine to maintain the current state comprise a display module and a touch module for interacting with a user.

Optionally, the supplying power to the functional component to make the functional component operate according to the setting operation logic adapted to the current state includes:

supplying power to the display module and the touch module, and judging whether touch operation triggered by a user based on the touch module is received in a first continuous time period;

if yes, responding to the touch operation;

if not, reducing the display brightness of the display module, and continuously monitoring the touch module;

and if the touch operation triggered by the user based on the touch module is not received continuously in a second continuous time period, switching the washing machine to a shutdown state, and cutting off all power supply of the washing machine.

Optionally, the determining the functional components required by the washing machine to maintain the current state includes:

judging whether the washing machine is in a standstill processing stage in the running state or not if the current state of the washing machine is the running state;

if the washing machine is in a static processing stage in an operating state, determining functional components required by the washing machine to maintain the current state as a touch control module and a control chip;

and if the washing machine is in a non-stationary processing stage in the running state, determining functional components required by the washing machine for maintaining the current state according to the specific running stage.

Optionally, when the washing machine is in a quiescence processing stage in an operation state, the supplying power to the functional component to make the functional component operate according to a set operation logic adapted to the current state includes:

the touch control module and the control chip are powered, and the control chip switches the clock frequency to a first set frequency and enters a sleep mode;

the control chip counts the time corresponding to the quiescence processing stage according to the set working logic; after timing is completed, the control chip switches the clock frequency to the second set frequency and exits the sleep mode to enter the normal working mode.

Optionally, when the washing machine is in a non-stationary processing stage in an operating state, the supplying power to the functional component to make the functional component operate according to a set operation logic adapted to the current state includes:

supplying power to the control chip, and switching the clock frequency to a second set frequency by the control chip and keeping the clock frequency in a normal working mode;

and supplying power to the functional components related to the non-stationary processing stage, so that the functional components work according to the set working logic adapted to the current state.

Optionally, the quiescence treatment stage includes a quiescence soak stage and/or a quiescence defoaming stage of the main wash stage;

the non-stationary treatment stage comprises a water inlet stage, other stages except a stationary soaking stage and a stationary defoaming stage in a main washing stage, and a dehydration stage.

According to another aspect of the present invention, there is also provided an energy saving control apparatus of a washing machine, comprising a processor and a memory storing program instructions, the processor being configured to perform the energy saving control method of a washing machine as described in any one of the above, when the program instructions are executed.

According to another aspect of the present invention, there is also provided a washing machine including: the washing machine comprises a washing machine main body and a controller, wherein the controller comprises the energy-saving control device of the washing machine.

According to another aspect of the present invention, there is also provided a computer storage medium storing a computer program which, when executed by a processor, implements the energy saving control method of a washing machine as any one of the above.

The invention provides an intelligent control method and device for a washing machine, the washing machine and a storage medium. The scheme of the invention not only can further optimize the power supply and power failure control method of the module, the load and the communication circuit according to the actual state of the washing machine, but also can greatly reduce the energy consumption of the whole use process of the washing machine while ensuring the normal operation of the washing machine.

Drawings

In order to more clearly illustrate the technical solutions of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a flow chart illustrating an energy saving control method of a washing machine according to an embodiment of the present invention;

fig. 2 illustrates an overall flowchart of an energy saving control method of a washing machine according to an embodiment of the present invention.

Detailed Description

As used herein, the terms "first," "second," and the like may be used to describe elements in exemplary embodiments of the present invention. These terms are only used to distinguish one element from another element, and the inherent feature or sequence of the corresponding element, etc. is not limited by the terms. Unless defined otherwise, all terms (including technical or scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

Those skilled in the art will understand that the devices and methods of the present invention described herein and illustrated in the accompanying drawings are non-limiting exemplary embodiments and that the scope of the present invention is defined solely by the claims. The features illustrated or described in connection with one exemplary embodiment may be combined with the features of other embodiments. Such modifications and variations are intended to be included within the scope of the present invention.

Furthermore, it should be understood that one or more of the following methods or aspects thereof may be performed by at least one control system, control unit, or controller. The terms "control unit", "controller", "control module" or "main control module" may refer to a hardware device comprising a memory and a processor, and the term "washing machine" may refer to a washing device. The memory or computer-readable storage medium is configured to store program instructions, and the processor is specifically configured to execute the program instructions to perform one or more processes that will be described further below. Moreover, it should be appreciated that the following methods may be performed by including a processor in combination with one or more other components, as will be appreciated by those of ordinary skill in the art.

The embodiment of the invention provides an energy-saving control method of a washing machine, which comprises a plurality of functional components, wherein each functional component is independently powered, the functional components can comprise a control chip, a load, a communication circuit and a functional module, the control chip can also comprise a main chip and other chips for assisting the normal operation of the washing machine, and the functional module can comprise a display module (such as a display screen), a communication component, a touch control module, a load detection module and the like, and the embodiment is not limited to the method.

As shown in fig. 1, the energy saving control method of a washing machine according to an embodiment of the present invention may include:

s1, identifying the current state of the washing machine, and determining functional components required by the washing machine to maintain the current state.

And S2, supplying power to the functional component so that the functional component works according to the setting work logic adapted to the current state.

In this embodiment, the states of the washing machine are divided into a stop state, a standby/pause state and an operation state, and the functional components required by different states of the washing machine are different, and the number of the functional components required by the washing machine in different states may be one or more.

1. Shutdown state

If the current state of the washing machine is a shutdown state, it is determined that the washing machine does not need to operate any functional component modules.

In the shutdown state, all loads and circuits of the whole machine are powered off, and a power key is used for supplying power by one key or powering off by one key, so that 0W shutdown is realized during shutdown.

2. Standby/pause state

And if the current state of the washing machine is a standby/pause state, determining that the functional components required by the washing machine to maintain the current state comprise a display module and a touch module for interacting with a user. Further, the step S2 specifically includes: supplying power to the display module and the touch module, and judging whether touch operation triggered by a user based on the touch module is received in a first continuous time period; if yes, responding to the touch operation; if not, the display brightness of the display module is reduced, and the touch control module is continuously monitored. In the standby/pause state, the parameters of the washing machine need to be displayed to the user through the display module, and the touch control module needs to receive the control instruction of the user. If the user does not operate in the first continuous time period, the display brightness can be properly reduced, and energy saving is realized while waiting continuously.

And if the touch operation triggered by the user based on the touch module is not received continuously in a second continuous time period, switching the washing machine to a shutdown state, and cutting off all power supply of the washing machine. The second continuous time period may be greater than the first continuous time period, and may be specifically and often determined according to different washing machine models and specific control logic, which is not limited in the embodiment of the present invention.

Generally, after a user presses a power key to start up, the washing machine enters a standby state, and when in standby, all loads of the washing machine except the display module and the touch module are powered and related communication circuits are not powered; after the user adjusts parameters and starts the whole machine, power supply to related loads and communication circuits is started; when the user does not operate in the continuous T1 time, the frequency of the main control chip is reduced to the lowest settable frequency, and the chip is switched from a normal mode to a sleep/stop/low power consumption mode, so that the standby power of the chip is maintained at 0-0.5W; and when the operation is not performed for the duration T2 (T2 > T1), the standby state is switched to the shutdown state.

3. Run phase

Judging whether the washing machine is in a standstill processing stage in the running state or not if the current state of the washing machine is the running state; if the washing machine is in a static processing stage in an operating state, determining functional components required by the washing machine to maintain the current state as a touch control module and a control chip; and if the washing machine is in a non-stationary processing stage in the running state, determining functional components required by the washing machine for maintaining the current state according to the specific running stage.

The present embodiment divides the operation state of the washing machine into two different states including a quiescence state and a non-quiescence state. The resting state mainly means that the washing machine is in an operating state, but does not need a load or functional components to operate, such as a resting soaking stage and a resting defoaming stage of a main washing stage; the non-stationary state may be a water inlet stage, a dewatering stage, or other stages such as a rinsing stage and a washing stage of the main washing stage.

When the washing machine is in a static processing stage in an operating state, power is supplied to the touch control module and the control chip, and the control chip switches the clock frequency to a first set frequency and enters a sleep mode; the control chip counts the time corresponding to the quiescence processing stage according to the set working logic; after timing is completed, the control chip switches the clock frequency to the second set frequency and exits the sleep mode to enter the normal working mode. The first set frequency may be the lowest frequency of the preset clock frequency, and the second set frequency may be the normal frequency. The sleep mode may be an operation mode set in advance for the control chip in a low power consumption state.

When the washing machine is in a non-stationary processing stage in an operating state, power is supplied to the control chip, and the control chip switches the clock frequency to a second set frequency and is in a normal working mode; and supplying power to the functional components related to the non-stationary processing stage, so that the functional components work according to the set working logic adapted to the current state.

According to the scheme provided by the embodiment of the invention, each load and each module of the washing machine are respectively and independently controlled in power supply and the running state of the split machine is finely controlled. The independent modules, the load and the communication circuit in each stage are used for power supply control, so that the energy consumption of the washing machine can be greatly reduced on the premise of not affecting the washing effect of the washing machine.

Fig. 2 is a flowchart of an overall energy-saving control method of a washing machine according to an embodiment of the present invention, and it can be seen with reference to fig. 2 that, in order to reduce total energy consumption in the whole operation process of the washing machine, each load and module of the washing machine are separately controlled by power supply and refined by the operation state of the split machine. The power supply control of the independent modules, the loads and the communication circuits in each stage is as follows:

(1) And (3) stopping the machine: the power supply key controls the on-off of the power supply of the whole washing machine, all loads, communication circuits and control chips of the washing machine are powered off during the shutdown, and the washing machine is shut down at 0W during the shutdown; when it is determined that the user presses the power key, the washing machine is turned on and enters a standby state/a pause state.

(2) Standby/suspend state: after the user presses the power key to start, the washing machine enters a standby state, and other loads except the display module and the touch control module are powered and related communication circuits are not powered during standby; at this time, the display module and the touch module are mainly used for receiving the input operation instruction of the user. The display module and the touch module can be two independent modules or an integral module, and the touch module can be a touch module in a touch mode or a key module in a key mode.

If the touch module does not detect the user operation touch area in the standby/pause state for the continuous T1 time, the display module reduces the display brightness to a (a% < 1) as the original brightness, and when the touch module is not operated in the user continuous T2 (T2 > T1) time, the washing machine switches the standby/pause state to a shutdown state and switches the whole machine to supply power; when the user needs to use the washing machine again, the user needs to press the power key again to start the washing machine. After the user adjusts parameters and starts the whole machine, power supply to related loads and communication circuits is started; at this time, the whole machine state is switched from the standby/pause state to the operation state.

(3) Quiescence operation phase of the operation state.

The operating state may be classified as a quiescing operating phase or a non-quiescing operating phase. The static operation stage comprises a main washing stage static soaking stage and a static defoaming stage, all loads of the whole machine do not participate in operation in the main washing stage static soaking stage and the static defoaming stage in the running state of the washing machine, only simple stage timing is performed, and when timing time is finished, the completion of the static soaking stage or the static defoaming stage is represented; in this case, the power supply to the individual loads only causes unnecessary power losses. In order to save the electric energy of the stage, other functional modules and communication circuits except the touch module and the main chip are powered off, the main chip switches the clock frequency to the lowest and enters the sleep mode, but at the moment, the main chip still counts the time corresponding to the static soaking stage or the static defoaming stage, and when the counting is completed, the main chip switches the main frequency to the normal frequency and exits the sleep mode.

The touch chip keeps supplying power in the operation stage and mainly receives input operation instructions of a user, such as the user wants to pause and adjust parameters and the like; when the touch module detects a user touch instruction, the main chip switches the main frequency to a normal frequency and exits from the sleep mode, and supplies power to the display module and displays the current corresponding display parameters; when the user pauses and adjusts the parameters, if the continuous T1 time does not operate, the method returns to the step (2), and if the user adjusts the parameters and restarts, the control method is the same as the step (3).

(4) Other phases of operation (non-stationary phases of operation)

When the washing machine goes from the static soaking stage and the static defoaming stage of the step (2) to other stages of the running state, the main chip switches the clock frequency to the normal clock frequency and exits the sleep mode, and simultaneously only the load and the communication circuit related to the stage are supplied with power.

According to the embodiment of the invention, the control is further refined according to the influence modules of the washing machine in specific stages of different states, such as a standby stage, the display module and the touch module are used as instruction input guide of a user in the standby stage, but when the user does not operate for a long time, the brightness of the display module is reduced when the first set time is reached, and when the second set time is not operated, the display module is powered off to enter a shutdown state; in addition, in the static soaking stage and the static defoaming stage in the running state, the display module can be powered off, the touch module is maintained, the frequency of the main chip can be reduced, the chip is switched into the sleep mode, and the timing of the stage is kept.

For example, the display and touch module of the washing machine is kept powered for a long time without operation by the user, the display module is powered when the user does not operate in the operation stage, and the main chip maintains the normal main frequency and consumes a certain amount of energy in the static soaking stage and the static defoaming stage of the operation state of the washing machine. The embodiment performs independent power supply and refined optimization control on loads and circuits in the whole operation process of the washing machine, does not supply power to irrelevant loads, modules and communication circuits, and performs detailed control on the affected modules and loads according to specific conditions at the stage so as to achieve maximum energy conservation.

The embodiment of the invention also provides an energy-saving control device of the washing machine, which comprises a processor and a memory storing program instructions, wherein the processor is configured to execute the energy-saving control method of the washing machine according to the embodiment when executing the program instructions.

The embodiment of the invention also provides a washing machine, which comprises: the washing machine comprises a washing machine main body and a controller, wherein the controller comprises the energy-saving control device of the washing machine.

The embodiment of the invention also provides a computer storage medium, wherein the storage medium stores a computer program, and the computer program realizes the energy-saving control method of the washing machine when being executed by a processor.

According to the scheme, the current state of the washing machine is identified, the functional components required by the washing machine for maintaining the current state are determined, and then power is supplied to the functional components, so that the functional components work according to the set working logic, and the normal work of the washing machine is ensured. The scheme of the invention not only can further optimize the power supply and power failure control method of the module, the load and the communication circuit according to the actual state of the washing machine, but also can greatly reduce the energy consumption of the whole use process of the washing machine while ensuring the normal operation of the washing machine.

The figures and detailed description of the invention referred to above as examples of the invention are intended to illustrate the invention, but not to limit the meaning or scope of the invention described in the claims. Accordingly, modifications may be readily made by one skilled in the art from the foregoing description. In addition, one skilled in the art may delete some of the constituent elements described herein without deteriorating the performance, or may add other constituent elements to improve the performance. Furthermore, one skilled in the art may vary the order of the steps of the methods described herein depending on the environment of the process or equipment. Thus, the scope of the invention should be determined not by the embodiments described above, but by the claims and their equivalents.

While the invention has been described in connection with what is presently considered to be practical, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Claims (9)

1. An energy saving control method of a washing machine, wherein the washing machine includes a plurality of functional components, each of which is independently powered, the method comprising:

identifying a current state of a washing machine, and determining functional components required by the washing machine to maintain the current state; the current state of the washing machine includes a stopped state, a standby/suspended state, and an operating state; the operating state comprises a quiescence treatment stage and a non-quiescence treatment stage, wherein the quiescence treatment stage comprises a quiescence soaking stage and/or a quiescence defoaming stage of the main washing stage; the non-stationary treatment stage comprises a water inlet stage, and other stages except a stationary soaking stage and a stationary defoaming stage in a main washing stage, and a dehydration stage;

supplying power to the functional component so that the functional component works according to the setting work logic adapted to the current state;

the determining functional components required for the washing machine to maintain the current state includes:

judging whether the washing machine is in a standstill processing stage in the running state or not if the current state of the washing machine is the running state;

if the washing machine is in a static processing stage in an operating state, determining functional components required by the washing machine to maintain the current state as a touch control module and a control chip;

and if the washing machine is in a non-stationary processing stage in the running state, determining functional components required by the washing machine to maintain the current state according to the specific running stage of the non-stationary processing stage.

2. The energy saving control method of claim 1, wherein the determining the functional components required for the washing machine to maintain the current state comprises:

if the current state of the washing machine is a shutdown state, it is determined that the washing machine does not need to operate any functional component modules.

3. The energy saving control method of claim 1, wherein the determining the functional components required for the washing machine to maintain the current state comprises:

and if the current state of the washing machine is a standby/pause state, determining that the functional components required by the washing machine to maintain the current state comprise a display module and a touch module for interacting with a user.

4. The energy saving control method according to claim 3, wherein the supplying power to the functional component to cause the functional component to operate in accordance with a set operation logic adapted to the current state includes:

supplying power to the display module and the touch module, and judging whether touch operation triggered by a user based on the touch module is received in a first continuous time period;

if yes, responding to the touch operation;

if not, reducing the display brightness of the display module, and continuously monitoring the touch module;

and if the touch operation triggered by the user based on the touch module is not received continuously in a second continuous time period, switching the washing machine to a shutdown state, and cutting off all power supply of the washing machine.

5. The energy saving control method according to claim 1, wherein said supplying power to the functional module to operate the functional module according to a set operation logic adapted to the current state when the washing machine is in a quietable processing stage in an operation state includes:

the touch control module and the control chip are powered, and the control chip switches the clock frequency to a first set frequency and enters a sleep mode;

the control chip counts the time corresponding to the quiescence processing stage according to the set working logic; after timing is completed, the control chip switches the clock frequency to the second set frequency and exits the sleep mode to enter the normal working mode.

6. The energy saving control method according to claim 1, wherein said supplying power to the functional module to operate the functional module according to a set operation logic adapted to the current state when the washing machine is in a non-stationary processing stage in an operation state comprises:

supplying power to the control chip, and switching the clock frequency to a second set frequency by the control chip and keeping the clock frequency in a normal working mode;

and supplying power to the functional components related to the non-stationary processing stage, so that the functional components work according to the set working logic adapted to the current state.

7. An energy saving control device of a washing machine, characterized by comprising a processor and a memory storing program instructions, the processor being configured to execute the energy saving control method of a washing machine according to any one of claims 1 to 6 when executing the program instructions.

8. A washing machine, comprising: a washing machine main body and a controller including the energy saving control device of the washing machine as claimed in claim 7.

9. A computer storage medium, characterized in that the storage medium stores a computer program which, when executed by a processor, implements the energy saving control method of a washing machine as claimed in any one of claims 1 to 6.