CN115429187A - Integrated cooker, control method thereof and computer-readable storage medium - Google Patents

Abstract

The invention discloses a control method of an integrated cooker, which comprises the following steps: when the integrated stove is in a drying mode, controlling the air conditioning module to be started; the air conditioning module is controlled to blow cold air after heat exchange of the evaporator to the storage rack in the opening process of the air conditioning module so as to dry objects on the storage rack. The invention also discloses an integrated cooker and a computer readable storage medium. The invention aims to dry objects such as tableware in an integrated kitchen range, avoid breeding bacteria and protect the health of users.

Description

Integrated cooker, control method thereof, and computer-readable storage medium

Technical Field

The invention relates to the technical field of kitchen appliances, in particular to a control method of an integrated cooker, the integrated cooker and a computer readable storage medium.

Background

An integrated kitchen range is kitchen equipment integrating functions of smoke exhaust, a kitchen range, a dining cabinet and the like, and is widely applied to daily life.

At present, the user can place it in the dining cabinet of integrated kitchen after clean tableware, can remain moisture on the tableware, and moisture does not breed the bacterium easily for a long time, causes harmful effects to user's health.

Disclosure of Invention

The invention mainly aims to provide a control method of an integrated cooker, the integrated cooker and a computer readable storage medium, aiming at drying objects such as tableware in the integrated cooker, avoiding breeding bacteria and protecting the health of a user.

In order to achieve the above object, the present invention provides a control method of an integrated cooker, the integrated cooker including an air conditioning module and a shelf, the control method of the integrated cooker including the steps of:

when the integrated stove is in a drying mode, controlling the air conditioning module to be started;

the air conditioning module is controlled to blow cold air after heat exchange of the evaporator to the storage rack in the opening process of the air conditioning module so as to dry objects on the storage rack.

Optionally, the step of controlling the air conditioning module to blow cold air after heat exchange of the evaporator to the storage rack comprises:

acquiring the humidity of the area where the commodity shelf is located;

determining a target air supply wind shield of the air conditioning module according to the humidity;

and controlling the air conditioning module to blow cold air subjected to heat exchange of the evaporator to the storage rack according to the target air supply gear.

Optionally, the step of determining a target air supply windshield of the air conditioning module according to the humidity comprises:

when the humidity is in a first humidity interval, determining a first wind shield as the target air supply wind shield;

when the humidity is in a second humidity interval, determining a second wind shield as the target air supply wind shield;

when the humidity is in a third humidity interval, determining a third wind shield as the target air supply wind shield;

the humidity in the first humidity interval is smaller than the humidity in the second humidity interval, the humidity in the second humidity interval is smaller than the humidity in the third humidity interval, the first windshield is smaller than the second windshield, and the second windshield is smaller than the third windshield.

Optionally, according to target air supply gear control air conditioning module blows to with the cold wind after the evaporimeter heat transfer after the step of supporter, still include:

acquiring humidity change parameters and temperature of an area where the commodity shelf is located in the process that the air conditioning module runs by the target air supply wind shield;

in a target rotating speed interval, determining a target operating rotating speed of a fan corresponding to the commodity shelf according to the humidity change parameter and the temperature;

controlling the fan to operate according to the target operation rotating speed so as to drain moisture in the area where the commodity shelf is located;

and the exhaust air speed corresponding to the target running rotating speed is less than the air supply air speed corresponding to the target air supply gear.

Optionally, the control method of the integrated cooker further includes:

when the integrated cooker is in the drying mode, acquiring a target drying rate corresponding to the drying mode;

if the target drying rate is larger than a set rate threshold value, executing the step of controlling the air conditioning module to be started;

and if the target drying rate is less than or equal to the set rate threshold, controlling an exhaust fan corresponding to the commodity shelf to be started, and exhausting moisture in the area where the commodity shelf is located when the exhaust fan is started.

Optionally, the step of controlling the exhaust fan corresponding to the article rack to be turned on includes:

determining a target operation wind gear of the exhaust fan according to the weight of the object in the commodity shelf;

and controlling the exhaust fan to be started according to the target operation wind gear.

Optionally, the step of determining a target operating windshield of the exhaust fan according to the object weight comprises:

when the weight of the object is greater than or equal to a first set weight threshold value, determining a first operation wind gear as the target operation wind gear;

when the weight of the object is smaller than the first set weight threshold value, determining a second operation wind gear as the target operation wind gear;

the first operating gear is greater than the second operating gear.

Optionally, the step of obtaining the target drying rate corresponding to the drying mode includes:

acquiring the current weight of the object in the commodity shelf;

when the object weight is greater than a second set weight threshold, determining that the target drying rate is greater than the set rate threshold;

when the object weight is less than or equal to the second set weight threshold, determining that the target drying rate is less than or equal to the set rate threshold.

Furthermore, in order to achieve the above object, the present application also proposes an integrated cooker, including:

an air conditioning module;

the storage rack is used for placing objects to be dried;

a control device, the air conditioning module with the control device is connected, the control device includes: memory, a processor and a control program of an integrated cooker stored on the memory and executable on the processor, which when executed by the processor implements the steps of the method of controlling an integrated cooker as defined in any one of the above.

Further, in order to achieve the above object, the present application also proposes a computer-readable storage medium having stored thereon a control program of an integrated cooker, which when executed by a processor, implements the steps of the control method of the integrated cooker as recited in any one of the above.

According to the control method of the integrated cooker, in the drying mode of the integrated cooker, cold air formed by heat exchange in the opening process of the air conditioning module is blown to the storage rack to dry objects on the storage rack, so that when the objects such as tableware are placed on the storage rack, moisture on the surface of the storage rack can be rapidly eliminated, bacteria breeding is avoided, and the objects such as the tableware in the integrated cooker are dried, so that the health of a user is protected.

Drawings

FIG. 1 is a schematic structural view of an embodiment of an integrated cooker according to the present invention;

FIG. 2 is a schematic diagram of a hardware structure involved in the operation of an embodiment of the integrated cooker of the present invention;

fig. 3 is a schematic flow chart illustrating a control method of an integrated cooker according to an embodiment of the present invention;

fig. 4 is a schematic flow chart of another embodiment of a control method of an integrated cooker according to the present invention;

fig. 5 is a flowchart illustrating a control method of an integrated cooker according to another embodiment of the present invention.

The implementation, functional features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The main solution of the embodiment of the invention is as follows: when the integrated stove is in a drying mode, controlling the air conditioning module to be started; and in the opening process of the air conditioning module, controlling the air conditioning module to blow cold air after heat exchange of the evaporator to the storage rack so as to dry objects on the storage rack.

Because among the prior art, the user can place it in the dining cabinet of integrated kitchen after clean tableware, can remain moisture on the tableware, and moisture does not dry for a long time and breeds the bacterium easily, causes harmful effects to user's health.

The invention provides the solution, and aims to dry objects such as tableware in an integrated kitchen range and avoid breeding bacteria so as to protect the health of users.

The embodiment of the invention provides an integrated cooker. The integrated cooker is embodied as an integrated device integrated with a cooking module (such as a hob 2, a microwave oven and/or an oven, etc.) and with other kitchen appliance function modules (such as a smoke evacuation module, a dish sterilization module, a dish drying module and/or the like).

In this embodiment, referring to fig. 1, the integrated cooker includes a housing 1, a cooking bench 2, a smoke exhaust module, an air conditioning module 4, a rack 5, and the like. The cooking bench 2, the smoke exhaust module, the air conditioning module 4 and the storage rack 5 are integrally installed on the shell 1. Be equipped with two at least installation chambeies of divided in the casing 1, smoke exhaust module and air conditioning module 4 install respectively in the installation intracavity of difference, and the air current passageway in the air current passageway of smoke exhaust module and the air conditioning module 4 can keep apart each other, also can be equipped with the vent, sets up the bypass valve at the vent to according to actual control demand intercommunication or cut off two air current passageways. In addition, the housing 1 may be provided with another mounting cavity for mounting a shelf. Specifically, the mounting cavity for mounting the rack may be an open cavity (a cavity communicating with an indoor environment), or may be a cavity in which an opening is closed by a cover (the cover may be specifically configured to open or close the cavity).

An air vent can be arranged between the installation cavity where the air conditioning module 4 is located and the installation cavity where the storage rack is located, the air vent can be arranged on a valve, and the valve can be used for opening or closing the air vent. Specifically, when the vent is opened, the air after heat exchange of the air conditioning module 4 can enter the cavity where the shelf is located from the vent; when the vent is closed, the air after the heat exchange of the air conditioning module 4 can not enter the cavity where the commodity shelf is located from the vent. Specifically, the valve may be controlled to open the vent when the integrated cooker is in a dry mode.

Further, in this embodiment, an exhaust fan may be disposed in the cavity where the rack is located, and the exhaust fan is specifically configured to exhaust air in the cavity where the rack is located out of the cavity (for example, an indoor environment or an outdoor environment). Specifically, the cavity where the storage rack is located is provided with an exhaust port, the exhaust port and the air vent are two different air ports, and the exhaust port can be communicated with an indoor environment, also can be communicated with an outdoor environment, and even can be communicated with an installation cavity where the air conditioning module 3 is located.

The cooking bench 2 is specifically used for installing a cooking appliance, and the cooking appliance can be a module integrally installed on an integrated cooking stove and also can be installed by a user based on self requirements.

The smoke exhaust module is specifically used for exhausting indoor oil smoke outdoors. The casing 1 is provided with an indoor smoke outlet and a smoke outlet, the smoke exhaust module comprises a smoke exhaust air channel and a smoke exhaust fan arranged in the smoke exhaust air channel, and the smoke exhaust air channel is communicated with the indoor smoke outlet and the smoke outlet. The smoke outlet can be directly communicated with the outdoor environment, can also be communicated with an oil fume purification device, can also be communicated with an exhaust channel of the air conditioning module 4, and the like. The number of indoor smoke exhaust ports may be one or more than one.

In this embodiment, the smoke exhaust fan is a fan with different rotation speed gears. When the smoke exhaust fan operates at different rotating speed gears, the operation wind gears of the smoke exhaust fan are different, and the amount of oil smoke sucked from indoor air in unit time by the smoke exhaust module is different. The larger the rotating speed gear of the smoke exhaust fan is, the larger the running gear of the smoke exhaust fan is, the larger the amount of oil smoke sucked in unit time is; and vice versa. In other embodiments, the smoke exhaust fan may also be a constant speed fan.

The indoor smoke outlet of the smoke exhaust module can be provided with a smoke exhaust valve or a flow guide piece, and the smoke exhaust valve or the flow guide piece is used for controlling the opening or closing of the indoor smoke outlet. Furthermore, the opening degree of the smoke exhaust valve or the position of the flow guide piece can be adjusted, and the air quantity sucked by the smoke exhaust module from the indoor environment is different under different opening degrees or different flow guide positions.

The air conditioning module 4 includes a refrigerant circulation circuit, and the refrigerant circulation circuit includes a compressor, a first heat exchanger, a throttling device and a second heat exchanger that are connected in sequence. A first air cavity and a second air cavity which are isolated are arranged in the installation space of the air conditioning module 4 in the shell 1, and the shell 1 is provided with an air outlet and an air return inlet which are communicated with the first air cavity, and an air inlet and an air outlet which are communicated with the second air cavity. The number of air outlets, air returns, air vents and/or air inlets may be one or more than one. In this embodiment, the indoor exhaust port of the exhaust module is disposed above the air outlet of the air conditioning module 4.

In this embodiment, the casing 1 is further provided with a fresh air inlet communicated with the first air cavity, and the outdoor air can enter the first air cavity from the fresh air inlet. The air return inlet and the fresh air inlet are respectively provided with a valve for controlling the opening or the closing of the air return inlet and the fresh air inlet.

First wind chamber is located to first heat exchanger, is equipped with air supply fan in the first wind chamber, and when air supply fan operation, air supply fan drive room air enters into first wind intracavity from return air inlet and/or new trend import, sends into indoor environment from the air outlet after the heat transfer of first heat exchanger. In this embodiment, the air supply fan is a fan having different rotational speed gears. When the air supply fan operates at different rotational speed gears, the air conditioning module 4 has different air outlet gears, and the air quantity sent into the indoor environment in unit time by the air conditioning module 4 is different. The larger the gear of the rotating speed is, the larger the air outlet gear of the air conditioning module 4 is, the larger the amount of oil smoke sucked by the air conditioning module 4 in unit time is; and vice versa. In other embodiments, the supply fan may also be a constant speed fan.

The second heat exchanger is arranged in the second air cavity, the exhaust fan is arranged in the second air cavity, when the exhaust fan operates, the exhaust fan drives external air to enter the second air cavity from the air inlet, and the external air is exhausted out of the outdoor environment from the air outlet after heat exchange of the second heat exchanger. The second air cavity and the air outlet can be connected through an air outlet channel. The exhaust port and the smoke outlet in the smoke exhaust module can be a common air port.

The air outlet of the air conditioning module 4 may be provided with a wind guide, and when the wind guide operates at different wind guide positions, the wind outlet direction and/or the wind outlet volume of the air outlet of the air conditioning module 4 are different.

When the air conditioning module 4 operates in a refrigerating mode, the first heat exchanger is an evaporator, the second heat exchanger is a condenser, and indoor air can be cooled through the first heat exchanger. When the air conditioning module 4 is in heating operation, the first heat exchanger is a condenser, the second heat exchanger is an evaporator, and the temperature of the indoor air can be increased through the first heat exchanger.

The air conditioning module 4 may be a heat pump module for independent refrigeration, a heat pump module for independent heating, or a heat pump module with a refrigeration and heating switching function. When the air conditioning module 4 is a heat pump module having a cooling and heating switching function, the refrigerant circulation circuit includes a four-way valve connecting the compressor exhaust port, the compressor return port, the first heat exchanger, and the second heat exchanger, in addition to the above components. When the four-way valve operates at the first valve position, the air conditioning module 4 operates in a refrigerating mode; when the four-way valve operates at the second valve position, the air conditioning module 4 performs heating operation.

The cavity that the supporter was located can communicate with first wind chamber and/or second wind chamber to make the air after one of first heat exchanger and the heat transfer of second heat exchanger accessible supporter locate the cavity and enter into the supporter in the cavity between the wind chamber, with the object on the dry supporter.

Further, referring to fig. 2, the integrated cooker further includes a weight detection module 5, and the weight detection module 5 is specifically used for detecting the weight of an object placed on the rack. In this embodiment, the weight detecting module 5 is disposed at the bottom of the rack, such as a pressure sensor, and determines the weight of the object placed on the rack according to the pressure data formed by gravity on the pressure sensor. In addition, in other embodiments, the weight detecting module 5 may also be disposed above the rack, for example, the elastic sensor is connected to the rack through an elastic member, a change in weight of an object placed on the rack may cause elastic deformation of the elastic member, and the detection data of the elastic sensor represents the elastic deformation of the elastic member, so as to determine the weight of the object placed on the rack according to the detection data of the elastic sensor.

Further, referring to fig. 2, the integrated cooker further includes a humidity sensor 6, and the humidity sensor 6 is specifically used for detecting the humidity of the area where the article placing shelf is located. In this embodiment, the humidity sensor 6 is disposed on the wall of the cavity where the rack is located.

Further, the integrated cooker further comprises a control device. Referring to fig. 2, the air conditioning module 4, the exhaust fan 3, the weight detection module 5, and the humidity sensor 6 are all connected to the control device, and the control device may be configured to control operations of the air conditioning module 4 and the exhaust fan 3, and may also be configured to obtain data measured by the weight detection module 5 and the humidity sensor 6.

The control device includes: a processor 1001 (e.g., CPU), memory 1002, etc. The memory 1002 may be a high-speed RAM memory or a non-volatile memory (e.g., a disk memory). The memory 1002 may alternatively be a storage device separate from the processor 1001.

Those skilled in the art will appreciate that the configuration of the device shown in fig. 2 is not intended to be limiting of the device and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components.

As shown in fig. 2, an integrated cooker control program may be included in the memory 1002, which is a kind of computer-readable storage medium. In the apparatus shown in fig. 2, the processor 1001 may be configured to call an integrated cooker control program stored in the memory 1002 and perform operations of the relevant steps of the integrated cooker control method in the following embodiments.

The embodiment of the invention also provides a control method of the integrated cooker, which is used for controlling the integrated cooker.

Referring to fig. 3, an embodiment of a control method of an integrated cooker according to the present application is provided. In this embodiment, the control method of the integrated cooker includes:

step S10, when the integrated stove is in a drying mode, controlling the air conditioning module to be started;

the integrated kitchen can be divided into a plurality of operation modes according to different functions required to be realized, such as a smoke exhaust mode, a disinfection mode, a dehumidification mode, an oil fume purification mode, a defrosting mode and the like. Wherein, under the dry mode, the object of integrated kitchen on with dry supporter is the purpose operation.

The operation mode can be determined by acquiring a mode control command input by a user, a mode starting command generated based on monitored environmental parameters, and current operation parameters of the integrated cooker. The drying mode can be started by inputting an instruction by a user, and the drying instruction can be automatically generated to start the drying mode when the weight of an object placed on the storage rack is monitored to be larger than or equal to a set threshold value.

The air conditioning module can be operated in a refrigerating mode or in a heating mode after being started, and when the air conditioning module is operated in the refrigerating mode, cold air is fed into the indoor environment to reduce the air temperature in the space and the air humidity of the indoor environment. When the air conditioning module is in heating operation, hot air is fed into the indoor environment to improve the air humidity in the space. In the drying mode, the heat exchange operation state of the air conditioner module can be a preset fixed state or a state selected according to the indoor heat exchange requirement.

Specifically, when the air vent is arranged between the air cavity where the first heat exchanger of the air conditioning module is located and the cavity where the article shelf is located, and the air vent is not arranged between the air cavity where the second heat exchanger is located and the cavity where the article shelf is located, the air conditioning module can be operated in a refrigerating mode. When the air vents are arranged between the air cavity of the second heat exchanger of the air conditioning module and the cavity of the storage rack, and the air vents are not arranged between the air cavity of the first heat exchanger and the cavity of the storage rack, the air conditioning module can be operated in a heating mode. When the air vent is arranged between the air cavity where the first heat exchanger of the air conditioning module is located and the cavity where the commodity shelf is located, and the air vent is arranged between the air cavity where the second heat exchanger is located and the cavity where the commodity shelf is located, the air conditioning module can be operated in a refrigerating mode or in a heating mode, and the heat exchange operation state of the air conditioning module can be selected by a user, can be randomly selected, and can also be determined based on the temperature condition of the indoor environment. For example, when the indoor environment temperature is lower than a first set temperature, the air conditioning module can be controlled to perform heating operation, at the moment, the air vent between the air cavity of the first heat exchanger and the cavity of the commodity shelf is closed, and the air vent between the air cavity of the second heat exchanger and the cavity of the commodity shelf is opened; when the indoor environment temperature is higher than the second set temperature (higher than the first set temperature), the air conditioning module can be controlled to operate in a refrigerating mode, at the moment, the air vent between the air cavity where the second heat exchanger is located and the cavity where the storage rack is located is closed, and the air vent between the air cavity where the first heat exchanger is located and the cavity where the storage rack is located is opened.

The air conditioning module can operate according to fixed parameters after being started, and can also operate according to parameters (such as the operating frequency of a compressor and the like) determined by actual drying requirements of objects (such as the weight of the objects placed on the commodity shelf and/or the humidity of the area where the commodity shelf is located) and/or actual heat exchange requirements of an indoor environment (such as the current temperature of the indoor environment or the temperature deviation between the current temperature of the indoor environment and a set temperature and the like).

And S20, in the opening process of the air conditioning module, controlling the air conditioning module to blow cold air after heat exchange of the evaporator to the storage rack so as to dry objects on the storage rack.

In the process of opening the air conditioning module, no matter the air conditioning module performs refrigerating operation or heating operation, cold air after heat exchange of the heat exchanger in the current evaporation state is blown to the storage rack, wherein the airflow direction of the cold air is specifically driven by a fan in the air conditioning module. Specifically, when the air conditioning module operates in a refrigerating mode, cold air after heat exchange of the first heat exchanger is blown to the storage rack; when the air conditioning module heats and operates, the cold air after the heat exchange of the second heat exchanger is blown to the storage rack.

The air speed of the air supply from the air conditioning module to the area where the commodity shelf is located can be a preset fixed air speed, and can also be determined according to the actual drying requirement of the object (such as the weight of the object placed on the commodity shelf and/or the humidity of the area where the commodity shelf is located) and/or the actual heat exchange requirement of the indoor environment (such as the current temperature of the indoor environment or the temperature deviation between the current temperature of the indoor environment and the set temperature).

According to the control method of the integrated cooker, in the drying mode of the integrated cooker, cold air formed by heat exchange in the opening process of the air conditioning module is blown to the storage rack to dry objects on the storage rack, so that when the objects such as tableware are placed on the storage rack, moisture on the surface of the storage rack can be rapidly eliminated, bacteria are prevented from breeding, and the objects such as the tableware in the integrated cooker are dried, so that the health of a user is protected.

Further, based on the above embodiment, another embodiment of the control method of the integrated cooker of the present application is provided. In this embodiment, referring to fig. 4, the process of controlling the air conditioning module to blow the cold air after heat exchange of the evaporator to the rack in step S20 is specifically as follows:

step S21, acquiring the humidity of the area where the commodity shelf is located;

in this embodiment, the humidity of the area where the rack is located can be detected by a humidity sensor disposed in the area where the rack is located. In other embodiments, the humidity of the area where the commodity shelf is located can also be calculated based on the detected weight and a preset humidity value per unit weight by detecting the weight of the object placed on the commodity shelf.

S22, determining a target air supply wind shield of the air conditioning module according to the humidity;

the air conditioning module's that is used for under different target air supply shelves to have different rotational speeds to the fan of supporter air supply, then air conditioning module blows to the regional wind speed difference of supporter place, and target air supply shelves are big more, and air conditioning module blows to the regional wind speed of supporter place big more, otherwise, target air supply shelves are little less, and air conditioning module blows to the regional wind speed of supporter place less.

Specifically, the correspondence between the humidity and the target air supply damper may be established in advance, and may be in the form of a calculation relationship, a mapping relationship, or the like. Based on the corresponding relation between the preset humidity and the target air supply windshield, the target air supply windshield corresponding to the current humidity can be determined by calculating or inquiring a mapping table and the like. In the embodiment, as the humidity of the area where the object placing rack is located increases, the target air supply damper tends to increase, so that the drying efficiency of objects in the object placing rack is ensured, and the breeding of bacteria is further effectively prevented; on the contrary, as the humidity of the area where the object placing rack is located is reduced, the target air supply wind shield can be in a reduction trend so as to ensure that the objects on the object placing rack are dry and simultaneously reduce the energy consumption of the integrated cooker. In other embodiments, the target supply air damper may decrease as the humidity increases, or the target supply air damper may increase as the humidity decreases.

In this embodiment, the humidity data of the area where the rack is located is divided into at least two humidity sections in advance, and the different humidity sections correspond to the air supply air gears of different air conditioning modules. Specifically, as the humidity of the humidity interval increases, the corresponding air supply damper can be increased; conversely, as the humidity in the humidity region decreases, the corresponding air supply damper tends to decrease. Here, the humidity intervals divided here may be continuous intervals or discontinuous intervals. The number of divided humidity intervals is not particularly limited, and may be two intervals, three intervals, four intervals, or a greater number of intervals.

Based on the above division of the interval, step S22 may specifically include: when the humidity is in a first humidity interval, determining a first wind shield as the target air supply wind shield; when the humidity is in a second humidity interval, determining a second wind shield as the target air supply wind shield; when the humidity is in a third humidity range, determining a third wind shield as the target air supply wind shield; the humidity in the first humidity interval is smaller than the humidity in the second humidity interval, the humidity in the second humidity interval is smaller than the humidity in the third humidity interval, the first windshield is smaller than the second windshield, and the second windshield is smaller than the third windshield. In a specific example, the first wind shield, the second wind shield and the third wind shield are a low wind shield, a medium wind shield and a wind shield in sequence, the first humidity interval, the second humidity interval and the third humidity interval are [10%,30% ], [40%,50% ], [60%,100% ], and when the humidity of the area where the commodity shelf is located is within [10%,30% ], the target air supply wind shield is determined to be the low wind shield; when the humidity of the area where the commodity shelf is located is within 40 percent and 50 percent, determining that the target air supply wind gear is a medium wind gear; and when the humidity of the area where the storage rack is located is within 60 percent and 100 percent, determining that the target air supply wind level is a high wind level.

And S23, controlling the air conditioning module to blow cold air subjected to heat exchange of the evaporator to the storage rack according to the target air supply gear.

Specifically, the operation of a fan in an air cavity where an evaporator of the air conditioning module is located is controlled according to the target air supply gear, so that the fan can drive cold air formed after heat exchange of the evaporator to blow air to an object on the storage rack at a target air speed corresponding to the target air supply gear.

In this embodiment, be adapted to the humidity in the supporter place region and confirm the target air supply air gear when air conditioning module sends the cold air to the supporter, can ensure that air conditioning module can input the cold air of sufficient cold volume and air current circulation rate to the supporter place region to guarantee that air conditioning module's air supply can match with dry demand is accurate, avoid unnecessary energy resource consumption simultaneously with object drying efficiency on guaranteeing the supporter.

Further, after step S23, the method further includes:

step S24, acquiring humidity change parameters and temperature of an area where the commodity shelf is located in the process that the air conditioning module runs by the target air supply wind gear;

the humidity variation parameter is specifically characterized by a humidity variation characteristic of an area where the commodity shelf is located within a set time. In the process of operating the target air supply air gear by the air conditioning module, the humidity of the area where the commodity shelf is located is detected at different moments, and the variation or the variation rate of the detected humidity is used as the humidity variation parameter.

The temperature can be detected by a temperature sensor in the area of the commodity shelf.

S25, determining the target operation rotating speed of an exhaust fan corresponding to the commodity shelf according to the humidity change parameter and the temperature in a target rotating speed interval; and the exhaust air speed corresponding to the target rotating speed interval is smaller than the air supply air speed corresponding to the target air supply gear.

Specifically, the maximum critical rotation speed of the target rotation speed interval can be determined according to the target air supply gear, and the larger the target air supply gear is, the larger the maximum critical rotation speed is. The set of rotation speed values less than or equal to the maximum threshold rotation speed is taken as the target rotation speed interval here.

Different humidity change parameters and different temperatures correspond to different target operation rotating speeds. The corresponding relation between the humidity change parameter, the temperature and the target operation rotating speed can be a calculation relation, a mapping relation and the like, and the current humidity change parameter and the target operation rotating speed corresponding to the current temperature can be determined in the target rotating speed interval through the corresponding relation. In the correspondence relationship, the smaller the humidity change parameter is, the larger the target operation rotation speed may be, and the lower the temperature is, the smaller the target operation rotation speed may be.

Specifically, in this embodiment, a rotation speed correction value may be determined according to the humidity variation parameter and the temperature, and a result obtained by correcting the maximum critical rotation speed according to the determined rotation speed correction value is used as the target operation rotation speed, for example, a difference between the maximum critical value and the rotation speed correction value is used as the target operation rotation speed.

And S26, controlling the exhaust fan to operate according to the target operation rotating speed so as to drain moisture in the area where the commodity shelf is located.

In the embodiment, the air conditioning module is matched with the exhaust fan to dry the object on the object shelf, so that the drying efficiency of the object is improved. Wherein, the rotational speed of exhaust fan is restricted through air conditioning module's windscreen, can ensure that exhaust fan's operation can not influence air conditioning module to the dehumidification effect of object to adjust and control exhaust fan rotational speed with the humidity change parameter and the temperature of object rest in the target air supply windscreen operation process based on air conditioning module, accessible exhaust fan and air conditioning module's operation cooperation realizes that the drying efficiency of object reaches the best.

In other embodiments, the exhaust fan may be controlled to operate at a preset rotational speed during the operation of the air conditioning module at the target supply air level without detecting the humidity change parameter and the temperature.

Further, when the humidity is greater than or equal to the set humidity threshold (e.g., the humidity is within the third humidity range), steps S24 to S26 may be performed; otherwise, the air conditioning module is adopted for independent drying, so that the drying effect is improved, and the energy consumption of the integrated stove is saved.

Further, based on any of the above embodiments, another embodiment of the control method of the integrated cooker of the present application is provided. In this embodiment, referring to fig. 5, the step of controlling the air conditioning module to be turned on in step S10 is defined as step S10a, and the control method of the integrated cooker further includes:

step S101, when the integrated cooker is in the drying mode, acquiring a target drying rate corresponding to the drying mode;

the target drying rate can be determined by obtaining instructions input by the user, and can also be determined by identifying the humidity of the area where the commodity shelf is located.

Specifically, the drying mode may be divided into a power drying mode and a normal drying mode. When the current drying mode is a powerful drying mode, determining that the target drying rate is greater than a set rate threshold; when the current drying mode is the general drying mode, it may be determined that the target drying rate is less than or equal to the set rate threshold.

In this embodiment, the drying mode may be determined by a user inputting a corresponding command based on his/her own needs, and the drying mode may be determined as the power drying mode when the user inputs a first command, and may be determined as the general drying mode when the user inputs a second command.

In another embodiment, the drying mode is determined by detecting the current humidity of the rack, and the drying mode is determined as the power drying mode when the humidity is greater than the set humidity threshold (e.g. the humidity is within the third humidity range); the drying mode may be determined as the general drying mode if the humidity is less than or equal to the set humidity threshold.

In another embodiment, the process of obtaining the target drying rate corresponding to the drying mode specifically includes: acquiring the current weight of the object in the commodity shelf; when the object weight is greater than a second set weight threshold, determining that the target drying rate is greater than or equal to the set rate threshold; when the object weight is less than or equal to the second set weight threshold, determining that the target drying rate is less than the set rate threshold. In this embodiment, the object weight can be obtained through the data detected by the weight detection module disposed in the cavity of the article rack. In other embodiments, the object weight may also be calculated by acquiring the number of objects input by the user, and calculating the object weight according to the unit weight and the number of objects corresponding to the preset unit number of objects. The second set weight threshold is specifically a weight threshold used for identifying whether the exhaust fan corresponding to the article shelf operates alone to dry the articles in the article shelf within a set time period. Specifically, when the weight of the object is greater than a second set weight threshold, the exhaust fan operates alone and cannot meet the drying efficiency for drying the object in the commodity shelf, and then it can be determined that the target drying rate is greater than the set rate threshold; when the weight of the object is smaller than or equal to the second set weight threshold value, the exhaust fan operates independently to meet the drying efficiency of drying the object in the storage rack, and then the target drying rate can be determined to be smaller than or equal to the set rate threshold value. Here, because the weight of object is different in the supporter, then the humidity and the exhaust resistance of the supporter place region that corresponds are different, humidity is big more then requires dehumidification efficiency to be higher, exhaust resistance is big more then just only rely on the air current to flow and be difficult to make the moisture on object surface eliminate fast, consequently can accurately reflect the demand of the drying efficiency of the object of supporter placed at present through the object weight on the supporter, can guarantee that the target drying rate of confirming is more accurate, so that follow-up drying efficiency based on the object drying rate of confirming more can guarantee the object.

Step S102, judging whether the target drying rate is greater than a set rate threshold value;

if the target drying rate is greater than the set rate threshold, executing a step S10a; if the target drying rate is less than or equal to the set rate threshold, step S103 is executed.

And S103, controlling an exhaust fan corresponding to the commodity shelf to be started, and exhausting moisture in the area where the commodity shelf is located when the exhaust fan is started.

The exhaust fan can be operated according to a preset fixed rotating speed when being started, and can also be operated according to the rotating speed determined by the current actual condition (such as humidity, weight, temperature and/or tableware type and the like) of the commodity shelf.

When exhaust fan opened, the humidity in supporter place region can discharge the outside in supporter place region under exhaust fan's drive. The exterior can be indoor environment, outdoor environment, smoke exhaust duct in the integrated cooker and air cavity where the evaporator in the air conditioning module is located. When the current air conditioning module is in refrigeration operation (such as dehumidification operation), the exhaust fan exhausts the moisture to the air cavity where the evaporator is located, so that the moisture can be condensed into condensed water on the evaporator after heat exchange of the evaporator and cannot be sent into the room, the influence of the moisture generated in the drying process on the indoor environment can be effectively avoided while the object on the object shelf is dried, and the drying of the indoor environment is ensured.

In this embodiment, adopt the exhaust mode to carry out the drying to the object on the thing frame when the drying rate that drying mode required is lower, just adopt the mode that air conditioning module blows cold wind to carry out the drying to the object on the thing frame when drying rate that drying mode required is higher to guarantee that the drying efficiency of object can match with the dry demand of reality, and it is lower to compare in the energy consumption of the dry object of air conditioning module when adopting the object of the dry supporter of exhaust mode, consequently can effectively reduce the energy consumption of integrated kitchen.

Specifically, in this embodiment, the step of controlling the exhaust fan that the supporter corresponds opens includes: determining a target operation wind gear of the exhaust fan according to the weight of the object in the commodity shelf; and controlling the exhaust fan to be started according to the target operation wind gear.

In this embodiment, the object weight can be obtained through the data detected by the weight detection module arranged in the cavity where the article holder is located. In other embodiments, the object weight may also be calculated by acquiring the number of objects input by the user, and calculating the object weight according to the unit weight and the number of objects corresponding to the preset unit number of objects.

The larger the target operation windshield is, the larger the rotating speed of the exhaust fan is, and the higher the humidity is exhausted from the area where the commodity shelf is located. The target operation wind grades of the exhaust fan corresponding to different object weights are different. The corresponding relation between the object weight and the target operation wind shield can be established in advance, and can be in the forms of calculation relation, mapping relation and the like. Based on the preset corresponding relation between the object weight and the operation wind shield of the exhaust fan, the target operation wind shield corresponding to the current object weight can be determined by calculating or inquiring a mapping table and the like.

Specifically, in the present embodiment, the target operating windshield increases with the weight of the object. In other embodiments, the target operating windshield may also be decreased as the weight of the object increases according to actual demand.

In this embodiment, the object weight is divided into at least two different weight sections in advance, and different weight sections are correspondingly provided with different operation wind shelves of the exhaust fan. The target operation windshield is in an increasing trend along with the increase of the weight interval; and the target operation windshield is in a small increase and decrease trend along with the increase of the weight interval. The weight sections divided here may be continuous sections or discontinuous sections. The number of divided weight sections is not particularly limited, and may be two sections, three sections, four sections, or a greater number of sections.

In this embodiment, the weight set greater than or equal to the first set weight threshold may be divided into a first interval, and the weight set smaller than the first set weight threshold may be divided into a second interval, and when the weight of the object is greater than or equal to the first set weight threshold, it is determined that the first operating windshield is the target operating windshield; when the weight of the object is smaller than the first set weight threshold value, determining a second operation wind gear as the target operation wind gear; the first operating gear is larger than the second operating gear. The first set weight threshold here is smaller than the second set weight threshold mentioned above. For example, the first operating wind gear is a high wind gear, the second operating wind gear is a low wind gear, and when the weight of the object is greater than or equal to 1kg, the target operating wind gear corresponding to the exhaust fan is determined to be the high wind gear; and when the weight of the object is less than 1kg, determining that the target operation wind level corresponding to the exhaust fan is a low wind level.

In this embodiment, because the humidity and the exhaust resistance in the supporter place region that different object weights correspond are different, the big humidity of weight is big more then requires dehumidification efficiency high more, the big exhaust resistance of weight is big more then dehumidification efficiency low more, vice versa, consequently determine the operation windscreen of exhaust fan among the exhaust drying process based on the object weight on the supporter, can guarantee that exhaust drying operation can be with the accurate matching of the dry demand of object on the supporter, can guarantee the drying efficiency of object on the supporter.

Furthermore, an embodiment of the present invention also provides a computer-readable storage medium, on which a control program of an integrated cooker is stored, which, when executed by a processor, implements the relevant steps of any of the above control methods of the integrated cooker.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrases "comprising a," "8230," "8230," or "comprising" does not exclude the presence of other like elements in a process, method, article, or system comprising the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solution of the present invention or the portions contributing to the prior art may be embodied in the form of a software product, which is stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk) as described above and includes several instructions for enabling a terminal device (which may be a mobile phone, a computer, a server, an integrated stove, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The control method of the integrated cooker is characterized by comprising an air conditioning module and a storage rack, and comprises the following steps:

when the integrated stove is in a drying mode, controlling the air conditioning module to be started;

the air conditioning module is controlled to blow cold air after heat exchange of the evaporator to the storage rack in the opening process of the air conditioning module so as to dry objects on the storage rack.

2. The control method of the integrated cooker according to claim 1, wherein the step of controlling the air conditioning module to blow the cold air after heat exchange of the evaporator to the rack comprises:

acquiring the humidity of the area where the commodity shelf is located;

determining a target air supply wind shield of the air conditioning module according to the humidity;

and controlling the air conditioning module to blow cold air subjected to heat exchange of the evaporator to the storage rack according to the target air supply gear.

3. The control method of the integrated cooker according to claim 2, wherein the step of determining a target blowing wind level of the air conditioning module according to the humidity includes:

when the humidity is in a first humidity interval, determining a first wind shield as the target air supply wind shield;

when the humidity is in a second humidity interval, determining a second wind shield as the target air supply wind shield;

when the humidity is in a third humidity interval, determining a third wind shield as the target air supply wind shield;

the humidity in the first humidity interval is smaller than the humidity in the second humidity interval, the humidity in the second humidity interval is smaller than the humidity in the third humidity interval, the first windshield is smaller than the second windshield, and the second windshield is smaller than the third windshield.

4. The control method of the integrated cooker according to claim 2, wherein after the step of controlling the air conditioning module to blow the cold air after heat exchange of the evaporator to the rack according to the target air supply gear, the method further comprises:

acquiring humidity change parameters and temperature of an area where the commodity shelf is located in the process that the air conditioning module runs by the target air supply wind shield;

in a target rotating speed interval, determining a target operating rotating speed of an exhaust fan corresponding to the commodity shelf according to the humidity change parameter and the temperature;

controlling the exhaust fan to operate according to the target operation rotating speed so as to drain moisture in the area where the commodity shelf is located;

and the exhaust air speed corresponding to the target rotating speed interval is smaller than the air supply air speed corresponding to the target air supply gear.

5. The control method of the integrated cooker according to any one of claims 1 to 4, further comprising:

when the integrated cooker is in the drying mode, acquiring a target drying rate corresponding to the drying mode;

if the target drying rate is larger than a set rate threshold value, executing the step of controlling the air conditioning module to be started;

if the target drying rate is smaller than or equal to the set rate threshold value, controlling the exhaust fan corresponding to the commodity shelf to be opened, and discharging moisture in the area where the commodity shelf is located when the exhaust fan is opened.

6. The control method of the integrated cooker according to claim 5, wherein the step of controlling the exhaust fan corresponding to the rack to be turned on comprises:

determining a target operation wind gear of the exhaust fan according to the weight of the object in the commodity shelf;

and controlling the exhaust fan to be started according to the target operation wind gear.

7. The control method of the integrated cooker according to claim 6, wherein the step of determining the target operation gear of the exhaust fan according to the object weight includes:

when the weight of the object is greater than or equal to a first set weight threshold value, determining a first operation gear as the target operation gear;

when the weight of the object is smaller than the first set weight threshold value, determining a second operation gear as the target operation gear;

the first operating gear is greater than the second operating gear.

8. The control method of the integrated cooker according to claim 5, wherein the step of obtaining the target drying rate corresponding to the drying mode comprises:

acquiring the current weight of the object in the commodity shelf;

when the object weight is greater than a second set weight threshold, determining that the target drying rate is greater than the set rate threshold;

when the object weight is less than or equal to the second set weight threshold, determining that the target drying rate is less than or equal to the set rate threshold.

9. An integrated cooker, characterized in that it comprises:

an air conditioning module;

the storage rack is used for placing objects to be dried;

a control device, the air conditioning module with the control device is connected, the control device includes: memory, a processor and a control program of an integrated hob stored on said memory and executable on said processor, said control program of an integrated hob, when executed by said processor, implementing the steps of the control method of an integrated hob according to any one of the claims 1 to 8.

10. A computer-readable storage medium, characterized in that the computer-readable storage medium has stored thereon a control program of an integrated cooker, which when executed by a processor implements the steps of the control method of an integrated cooker according to any one of claims 1 to 8.

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