Disclosure of Invention
The invention mainly aims to provide a control method of an integrated kitchen, the integrated kitchen and a computer readable storage medium, and aims to realize effective dehumidification of a kitchen, avoid bacteria breeding and protect the health of a user.
In order to achieve the above object, the present invention provides a control method of an integrated cooker including an air conditioning module and an exhaust module, the control method of the integrated cooker including the steps of:
Acquiring an operation mode of the integrated cooker;
And when the operation mode is a dehumidification mode, controlling the air conditioning module to perform refrigeration operation, or controlling the air conditioning module to perform refrigeration operation and controlling the exhaust module to be opened.
Optionally, when the operation mode is a dehumidification mode, the step of controlling the air conditioning module to perform cooling operation, or controlling the air conditioning module to perform cooling operation and controlling the exhaust module to be turned on includes:
When the operation mode is a dehumidification mode, acquiring human body state information in a space where the integrated kitchen is located;
when the human body state information indicates that a human body exists in the space, executing the step of controlling the refrigerating operation of the air conditioning module;
And when the human body state information indicates that no human body exists in the space, executing the steps of controlling the air conditioning module to perform refrigeration operation and controlling the exhaust module to be started.
Optionally, the step of controlling the cooling operation of the air conditioning module includes:
Acquiring position change parameters of a human body in the space;
Determining a first air outlet parameter of the air conditioning module according to the position change parameter;
And controlling the refrigerating operation of the air conditioning module according to the first air outlet parameter.
Optionally, the first air outlet parameter includes a first target air outlet gear of the air conditioning module, and the step of determining the first air outlet parameter of the air conditioning module according to the position change parameter includes:
If the position change parameter is smaller than or equal to a set change threshold value, determining a first set wind gear as the first target wind outlet wind gear;
If the position change parameter is larger than the set change threshold value, determining a second set wind gear as the first target wind outlet wind gear;
wherein the first set wind gear is larger than the second set wind gear.
Optionally, the step of acquiring the position change parameter of the human body in the space includes:
detecting a first distance between the integrated kitchen range and a human body;
detecting a second distance between the integrated kitchen and a human body at intervals of a preset time length;
A distance difference between the first distance and the second distance is determined, the location change parameter comprising the distance difference.
Optionally, the step of controlling the air conditioning module to perform cooling operation and controlling the exhaust module to be turned on includes:
Acquiring the ambient humidity in the space;
Determining a second target air outlet wind level of the air conditioning module and a target operation wind level of the exhaust module according to the ambient humidity;
And controlling the air conditioning module to perform refrigeration operation according to the second target air outlet wind shield, and controlling the exhaust module to be opened according to the target operation wind shield.
Optionally, the step of determining the second target outlet air rail of the air conditioning module and the target operation rail of the exhaust module according to the ambient humidity includes:
Determining a target humidity interval in which the ambient humidity is located;
When the target humidity interval is within a first humidity interval, determining a third set wind gear as the second target wind outlet wind gear, and determining a first running wind gear as the target running wind gear;
When the target humidity interval is within a second humidity interval, determining a fourth set wind gear as the second target wind outlet wind gear, and determining a second running wind gear as the target running wind gear;
The third set wind level is greater than the fourth set wind level, the first running wind level is less than the second running wind level, and the humidity in the first humidity interval is less than the humidity in the second humidity interval.
Optionally, after the step of acquiring the ambient humidity in the space, the method further includes:
When the environmental humidity is smaller than a set humidity threshold, controlling the air conditioning module to stop, and controlling the exhaust module to be closed after the exhaust module runs for a set period of time with the lowest running wind gear;
executing the step of determining a target humidity interval in which the ambient humidity is located when the ambient temperature is greater than or equal to the set humidity threshold;
and the humidity in the first humidity interval and the humidity in the second humidity interval are both greater than the set humidity threshold.
In addition, in order to achieve the above object, the present application also proposes an integrated cooker including:
An air conditioning module;
exhaust module, and
The control device comprises a memory, a processor and a control program of the integrated kitchen range, wherein the control program of the integrated kitchen range is stored in the memory and can run on the processor, and the control program of the integrated kitchen range realizes the steps of the control method of the integrated kitchen range when being executed by the processor.
In addition, 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 an integrated cooker as set forth in any one of the above.
The integrated kitchen comprises an air conditioning module and an exhaust module, and is operated by refrigerating the air conditioning module or is started by the air conditioning module during the refrigerating operation, the air conditioning module exchanges heat with indoor air in the refrigerating operation process, so that moisture in the air is condensed in the air module and then is sent into the room, the effective reduction of indoor air humidity is realized, and the exhaust module is started in the process to exhaust the air with indoor moisture outdoors while the air conditioning module dehumidifies, so that the dehumidification efficiency is improved, the influence of outdoor moisture air brought by a window opening mode on the kitchen environment is avoided, the effective dehumidification of the kitchen is realized, bacteria are avoided, and the health of a user is protected.
Detailed Description
It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.
The main solution of the embodiment of the invention is to acquire the operation mode of the integrated kitchen based on the integrated kitchen comprising the air conditioning module and the exhaust module, and when the operation mode is a dehumidification mode, the air conditioning module is controlled to perform refrigeration operation, or the air conditioning module is controlled to perform refrigeration operation and the exhaust module is controlled to be opened.
Because in the prior art, the user can generally reduce the kitchen humidity only through the windowing mode, if the outdoor environment humidity is larger in the process, the outdoor environment high-humidity air enters the kitchen, so that the kitchen humidity cannot be reduced, even the kitchen humidity can be deteriorated, bacteria are bred, and the health of the user is affected.
The invention provides the solution scheme, and aims to realize effective dehumidification of a kitchen, avoid bacteria breeding and protect the health of a user.
The embodiment of the invention provides an integrated kitchen. The integrated kitchen range is in particular an integrated device integrated with cooking modules (such as a kitchen range 2, a microwave oven and/or an oven, etc.) and other kitchen appliance functional modules (such as an exhaust module3, a dish sterilization module, a dish drying module and /).
In the present embodiment, referring to fig. 1, the integrated cooker includes a housing 1, a cooktop 2, an exhaust module 3, an air conditioning module 4, and the like. The hob 2, the exhaust module 3 and the air conditioning module 4 are integrally mounted on the housing 1. At least two separated installation cavities are arranged in the shell 1, the exhaust module 3 and the air conditioning module 4 are respectively installed in different installation cavities, the air flow channel of the exhaust module 3 and the air flow channel in the air conditioning module 4 can be mutually isolated, a ventilation opening can also be arranged, and a bypass valve is arranged at the ventilation opening so as to communicate or cut off the two air flow channels according to actual control requirements.
The cooking bench 2 is specifically used for installing a kitchen range, and the kitchen range can be an integrated module installed on an integrated kitchen range or can be installed by a user based on own requirements.
The exhaust module 3 is specifically used for exhausting indoor oil smoke outdoors. The shell 1 is provided with an indoor exhaust port and a smoke outlet, and the exhaust module 3 comprises an exhaust air duct and an exhaust fan arranged in the exhaust air duct, wherein the exhaust air duct is communicated with the indoor exhaust port and the smoke outlet. The smoke outlet can be directly communicated with the outdoor environment, can also be communicated with the oil smoke purifying device, can also be communicated with an exhaust channel of the air conditioning module 4, and the like. The number of the indoor exhaust ports may be one or more than one.
In this embodiment, the exhaust fan is a fan with different rotational speed gears. When the exhaust fan operates at different rotational speed gears, the operation wind gear of the exhaust fan is different, and the amount of the oil smoke sucked from the indoor air by the exhaust module 3 in unit time is different. The larger the rotational speed gear of the exhaust fan is, the larger the running wind gear is, the larger the amount of the oil smoke sucked in per unit time is, and vice versa. In other embodiments, the exhaust fan may also be a constant speed fan.
The indoor exhaust port of the exhaust module 3 may be provided with an exhaust valve or a flow guide for controlling the opening or closing of the indoor exhaust port. Further, the opening degree of the exhaust valve or the position of the flow guiding member can be adjusted, and the air amount sucked by the exhaust module 3 from the indoor environment is different under different opening degrees or different flow guiding positions.
The air conditioning module 4 comprises a refrigerant circulation loop, wherein the refrigerant circulation loop comprises a compressor, a first heat exchanger, a throttling device and a second heat exchanger which are sequentially connected. The installation space of the air conditioning module 4 in the shell 1 is internally provided with a first air cavity and a second air cavity which are isolated, and the shell 1 is provided with an air outlet and an air return opening 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 outlets, inlets, outlets and/or inlets may be one or more than one. In the present embodiment, the indoor air outlet of the air-conditioning module 4 is disposed above the air outlet of the air-conditioning module 3.
In this embodiment, the housing 1 is further provided with a fresh air inlet communicating with the first air chamber, and outdoor air can enter the first air chamber from the fresh air inlet. An air return port the fresh air inlet can be respectively provided with a valve which can control the fresh air inlet to be opened or closed.
The first heat exchanger is arranged in the first air cavity, an air supply fan is arranged in the first air cavity, and when the air supply fan operates, the air supply fan drives indoor air to enter the first air cavity from the return air inlet and/or the fresh air inlet, and the indoor air is sent into the indoor environment from the air outlet after heat exchange of the first heat exchanger. In this embodiment, the air supply fan is a fan with different rotational speed gears. When the air supply fan runs at different rotational speed gears, the air conditioning module 4 has different air outlet gears, so that the air quantity fed into the indoor environment in unit time of the air conditioning module 4 is different. The larger the rotation speed gear is, the larger the air outlet gear of the air conditioning module 4 is, the larger the amount of oil smoke inhaled by the air conditioning module 4 in unit time is, and vice versa. In other embodiments, the blower fan may also be a constant speed fan.
The second heat exchanger is arranged in the second air cavity, an exhaust fan is arranged in the second air cavity, and 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 discharged from the air outlet to the outdoor environment 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 exhaust module 3 may be a common air port.
The air outlet of the air conditioning module 4 may be provided with an air guide, and when the air guide operates at different air guide positions, the air outlet direction and/or the air outlet amount of the air outlet of the air conditioning module 4 are different.
When the air conditioning module 4 is in refrigeration operation, the first heat exchanger is an evaporator, the second heat exchanger is a condenser, and the temperature of indoor air can be reduced through the first heat exchanger. When the air conditioning module 4 heats, the first heat exchanger is a condenser, the second heat exchanger is an evaporator, and the indoor air can be raised in temperature through the first heat exchanger.
The air conditioning module 4 may be a heat pump module for cooling alone, a heat pump module for heating alone, or a heat pump module having a cooling and heating switching function. When the air conditioning module 4 is a heat pump module with a refrigerating and heating switching function, the refrigerant circulation loop comprises a four-way valve connected with a compressor exhaust port, a compressor return port, a first heat exchanger and a second heat exchanger in addition to the components. When the four-way valve is operated at the first valve position, the air conditioning module 4 is operated in a refrigerating mode, and when the four-way valve is operated at the second valve position, the air conditioning module 4 is operated in a heating mode.
Further, the integrated kitchen further comprises a human body detection module 5, such as an infrared sensor, and the human body detection module 5 is specifically configured to detect human body information (such as whether a human body exists, a human body position, etc.) in the space. The human body detection module 5 is specifically disposed on the housing 1.
Further, the integrated cooker further comprises a humidity sensor 6 for detecting the humidity of the space where the integrated cooker is located. The humidity sensor 6 can be arranged at the return air inlet of the air conditioning module 4, can be arranged on the outer wall of the shell, and can even be arranged outside the integrated kitchen independently of the shell.
Further, the integrated cooker further comprises a control device. Referring to fig. 2, the air conditioning module 4, the air exhaust module 3, the human body detection module 5 and the temperature sensor 6 are all connected with the control device, and the control device can be used for controlling the operation of the air conditioning module 4 and the air exhaust module 3, and can also be used for data detected by the human body detection module 5 and the temperature sensor 6.
The control means includes a processor 1001 (e.g., CPU), a memory 1002, and the like. The memory 1002 may be a high-speed RAM memory or a stable memory (non-volatile memory), such as a disk memory. The memory 1002 may alternatively be a storage device separate from the processor 1001 described above.
It will be appreciated by those skilled in the art that the device structure shown in fig. 2 is not limiting of the device and may include more or fewer components than shown, or certain components may be combined, or a different arrangement of components.
As shown in fig. 2, an integrated oven control program may be included in a memory 1002 as a computer-readable storage medium. In the apparatus shown in fig. 2, a processor 1001 may be used to call an integrated oven control program stored in a memory 1002 and perform the relevant step operations of the integrated oven control method in the following embodiments.
The embodiment of the invention also provides a control method of the integrated cooker, which is applied to control the integrated cooker.
Referring to fig. 3, an embodiment of a control method of the integrated cooker of the application is provided. In this embodiment, the control method of the integrated cooker includes:
step S10, acquiring an operation mode of the integrated kitchen range;
The integrated kitchen range can be divided into a plurality of operation modes such as an exhaust mode, a disinfection mode, a dehumidification mode and the like according to the functions required to be realized. In the dehumidification mode, the integrated kitchen is operated for the purpose of reducing the humidity of the space where the integrated kitchen is located.
The operation mode can be determined by acquiring a mode control instruction input by a user, and can also be determined by a mode starting instruction generated based on the monitored environment parameters.
Specifically, when the user feels that the humidity is too high, the dehumidification mode can be started by inputting a dehumidification mode starting instruction. Or when the integrated kitchen range monitors that the indoor humidity is lower than the minimum humidity value allowed by the comfort state of the user, the integrated kitchen range can be controlled to enter a dehumidification mode.
And step S20, when the operation mode is a dehumidification mode, controlling the air conditioning module to perform refrigeration operation, or controlling the air conditioning module to perform refrigeration operation and controlling the exhaust module to be opened.
When the air conditioning module is in refrigeration operation, indoor air exchanges heat through the evaporator, moisture in the air is condensed to form condensed water on the surface of the evaporator, and low-humidity air is sent to the indoor environment after the heat exchange. In the process of dehumidifying the air conditioner module by refrigerating operation, the operation parameters of the air conditioner module can be operated according to preset fixed parameters, and the actual operation parameters of the air conditioner module can be determined according to the actual conditions of indoor environments so as to improve the dehumidifying effect. For example, the rotation speed of the air supply fan, the frequency of the compressor and/or the opening degree of the electronic expansion valve in the air conditioning module can be operated according to set parameters, and the rotation speed of the air supply fan, the operation frequency of the compressor and/or the opening degree of the electronic expansion valve can be determined according to indoor scene parameters (such as human body detection information, indoor temperature, indoor humidity and/or space tightness information and the like).
The air conditioning module can perform independent refrigeration and dehumidification (at the moment, the exhaust module is in a closed state), and can be started while the air conditioning module performs refrigeration and dehumidification so as to assist the air conditioning module in dehumidification. When the exhaust module is opened, indoor air is exhausted outdoors through the exhaust module, and moisture in the air is sent outdoors along with the dehumidifying module. When the exhaust module is started, the operation parameters of the exhaust module can be operated according to preset fixed parameters, and the actual operation parameters of the exhaust module can be determined according to the actual conditions of the indoor environment. For example, the rotation speed of the exhaust fan in the exhaust module and/or the opening time duration of the exhaust module may also be determined according to indoor scene parameters (such as human body detection information, indoor temperature, indoor humidity, oil smoke concentration and/or space tightness information, etc.).
The integrated kitchen comprises an air conditioning module and an exhaust module, and is operated in a dehumidification mode by refrigerating the air conditioning module or is started by the air conditioning module while the exhaust module is started, so that moisture in the air is condensed in the air module and then sent into the room in the refrigerating operation process of the air conditioning module, the humidity of the indoor air is effectively reduced, the exhaust module is started in the process to exhaust the air with the humidity in the room out of the room while the air conditioning module dehumidifies, the dehumidification efficiency is improved, the influence of the outdoor humidity air brought by a window opening mode on the kitchen environment is avoided, the effective dehumidification of a kitchen is realized, bacteria are avoided, and 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 application is provided. In this embodiment, referring to fig. 4, the step S20 includes:
Step S2a, when the operation mode is a dehumidification mode, acquiring human body state information in a space where the integrated kitchen is located;
The human body state information includes state information of whether or not a human body exists in the space. Specifically, in the dehumidification mode, the human body state information can be obtained at the time of mode starting, in real time or at set intervals.
The human body state information can be obtained through data analysis of human body detection modules arranged on the integrated kitchen. For example, the detection signal of the infrared sensor arranged on the integrated kitchen is read, if the detection signal contains the characteristic signal of the human body, the human body state information can be determined to be the human body in the space, and if the detection signal does not contain the characteristic signal of the human body, the human body state information of the air roof is determined to be the human body in the space.
In addition, in other embodiments, the human body state information may be obtained by acquiring information input by the user. For example, when the user is in the space of the integrated kitchen range, the first state instruction can be input through the control panel or the mobile terminal connected with the integrated kitchen range, if the first state instruction is received, the human body is determined to exist in the space, when the user leaves the space of the integrated kitchen range, the second state instruction can be input through the control panel or the mobile terminal connected with the integrated kitchen range, and if the second state instruction is received, the human body is determined to not exist in the space.
Step S2b, judging whether the human body state information is that a human body exists in the space;
And when the human body state information is that no human body exists in the space, executing the step S2d.
Step S2c, controlling the refrigerating operation of the air conditioning module;
and S2d, controlling the air conditioning module to perform refrigeration operation and controlling the exhaust module to be opened.
In this embodiment, based on whether someone is in the space of the integrated kitchen, different dehumidification modes are respectively adopted to dehumidify the space of the integrated kitchen, so that the user thermal comfort and the dehumidification effect are effectively considered. The air conditioning module is independently used for refrigerating when people exist (the exhaust module is closed at the moment), so that heat loss in the space is avoided, the heat exchange efficiency of the air conditioning module to the indoor environment is guaranteed while dehumidification is achieved, the comfort of indoor users is guaranteed, the air conditioning module is combined for refrigerating and exhausting when people do not exist for dehumidification, the rapid improvement of the dehumidification efficiency is achieved through double-channel dehumidification, and indoor moisture is rapidly discharged.
Further, in order to further improve the comfort of the indoor user, before step S2a, the outdoor ambient temperature may be obtained, if the outdoor ambient temperature is greater than or equal to the first set ambient temperature, which indicates that the current outdoor ambient temperature is too high, and at this time, the indoor user has a refrigeration requirement, S2a may be executed, and the dehumidification mode may be selected in the above manner, and if the outdoor ambient temperature is less than the second set ambient temperature (less than the first set ambient temperature), the heating operation of the air conditioner is controlled, so as to dry the moisture in the indoor air and simultaneously ensure the thermal comfort of the indoor user.
Further, based on any one of the above embodiments, a further embodiment of the control method of the integrated kitchen range of the present application is provided. In this embodiment, referring to fig. 5, the step of controlling the cooling operation of the air conditioning module includes:
step S201, obtaining the position change parameters of the human body in the space;
The position change parameter is specifically a state parameter representing the difference of human body positions in space along with time. The position change parameter may be a position change amplitude, a position change rate, a position change curve, or the like.
The position change parameter can be detected by a human body detection module arranged on the integrated kitchen range, for example, the position change parameter can be determined based on human body positioning data detected by the infrared sensor at different times.
Step S202, determining a first air outlet parameter of the air conditioning module according to the position change parameter;
the first air outlet parameter may include an air outlet angle, an air outlet damper, and/or an air outlet temperature, etc.
The different position change parameters correspond to different first air outlet parameters. The corresponding relation between the position change parameter and the first air outlet parameter can be preset, for example, a calculation relation, a mapping relation and the like. And determining a first air outlet parameter corresponding to the current position change parameter based on the corresponding relation. For example, if the first air outlet parameter is M and the position change parameter is D, a calculation formula of M is pre-established, where a and b are preset coefficients. Based on the above, the current first air outlet parameter can be calculated by substituting the current acquired position change parameter into the above formula.
And step 203, controlling the air conditioning module to perform refrigeration operation according to the first air outlet parameter.
When the first air outlet parameter comprises an air outlet gear, the operation of an air supply fan in the air conditioner module can be controlled according to the rotating speed corresponding to the air outlet gear, when the first air outlet parameter comprises an air outlet angle, the operation of an air guide piece at an air outlet of the air conditioner module can be controlled according to the air guide angle corresponding to the air outlet angle, when the first air outlet parameter comprises an air outlet temperature, the operation of the air supply fan, the electronic expansion valve and/or the compressor can be correspondingly controlled according to the rotating speed of the air speed corresponding to the air outlet temperature, the opening degree of the expansion valve, the frequency of the compressor and the like, and the like.
In this embodiment, different position change parameters can represent the motion state of a human body in a space, and the different motion states are affected by the air outlet of the integrated kitchen differently, based on this, the air outlet parameters of the air conditioning module are determined based on the position change parameters of the human body, which is favorable for ensuring that the air carrying cold energy in the room fed by the air conditioning module can be matched with the actual motion state of a user, and ensuring further improvement of the thermal comfort of the human body while dehumidification.
Further, in the embodiment, a first distance between the integrated kitchen and a human body is detected, a second distance between the integrated kitchen and the human body is detected at intervals of a preset time period, a distance difference between the first distance and the second distance is determined, and the position change parameter comprises the distance difference. The preset duration may be a preset fixed parameter, or may be a parameter determined based on an actual scene parameter in a space where the integrated cooker is located. Specifically, the preset time period may be determined according to the cooking type of the cooking operation currently performed by the user, and different cooking types correspond to different preset time periods. For example, the cooking type corresponds to a first preset time period when steaming, corresponds to a second preset time period when frying, and is longer than the second preset time period. The distance difference here refers in particular to the absolute value of the difference between the first distance and the second distance. Here, the position change parameters of the human body in the space are represented by detecting the deviation of the distance between the human body and the integrated kitchen at different moments, so that the air conditioner air outlet of the integrated kitchen corresponding to the determined air conditioner module air outlet parameters is facilitated, and the comfort of the position of the human body can be further improved.
Further, in this embodiment, the first air outlet parameter includes a first target air outlet gear of the air conditioning module, and step S202 includes determining that a first set air outlet gear is the first target air outlet gear if the position change parameter is less than or equal to a set change threshold value, and determining that a second set air outlet gear is the first target air outlet gear if the position change parameter is greater than the set change threshold value, wherein the first set air outlet gear is greater than the second set air outlet gear. The set change threshold is specifically a preset parameter. The air outlet gear of the air conditioning module can be divided into at least two wind gears in advance, wherein the at least two wind gears comprise the first set wind gear and the second set wind gear, and the at least two wind gears can be divided into more wind gears according to actual requirements besides the first set wind gear and the second set wind gear. The position change parameter is larger than the set change threshold value, and if the distance difference is larger than the set deviation threshold value, the position change of the user in the space is larger, the user is not easily influenced by cold air directly blown by the air conditioning module for a long time, and the air conditioning module supplies air with a lower wind shield at the moment, so that strong dehumidification is facilitated, and drying of a kitchen is ensured. The position change parameter is smaller than or equal to a set change threshold value, and if the distance difference is smaller than or equal to a set deviation threshold value, the position change of a user in the space is smaller, the user is easily influenced by the direct blowing cold air of the air conditioner module for a long time, and the air conditioner module supplies air with a higher air rail at the moment so as to improve the air outlet temperature of the air conditioner module, thereby realizing dehumidification, ensuring the comfort of the user and avoiding the user catching a cold.
The corresponding relation between the position change parameter and the first target air outlet gear can be a preset fixed relation, or one of the corresponding relations can be selected from a plurality of preset corresponding relations based on scene parameters in the current space. For example, different cooking types correspond to different correspondence between position change parameters and wind levels, in the different correspondence, the wind levels corresponding to the same position change parameters are different, based on which the cooking type (such as steaming, stir-frying, braising, frying, etc.) of the cooking operation performed by the user in the space can be obtained, the correspondence corresponding to the cooking type is determined, and based on the determined correspondence, the wind level corresponding to the current position change parameter is determined to be the first target wind outlet wind level.
Further, based on any one of the above embodiments, another embodiment of the control method of the integrated kitchen range of the present application is provided. In this embodiment, referring to fig. 6, the step of controlling the air conditioning module to perform cooling operation and controlling the exhaust module to be turned on includes:
step S21, acquiring the ambient humidity in the space;
The ambient humidity can be detected by a humidity sensor arranged at the air return port of the air conditioning module.
Step S22, determining a second target air outlet wind gear of the air conditioning module and a target operation wind gear of the exhaust module according to the ambient humidity;
Different ambient humidity corresponds to different second target air outlet vents of the air conditioning module and target operating vents of the air exhaust module. In this embodiment, along with the increase of ambient humidity, the second target air outlet wind level and the target operation wind level are both in an increasing trend, so as to be favorable to improving dehumidification efficiency and ensuring dehumidification effect. In addition, along with the reduction of the environmental humidity, the second target air outlet wind gear and the target operation wind gear can be in a reducing trend, so that energy conservation is facilitated. In other embodiments, as the ambient humidity increases, one of the second target outlet air rail and the target operating air rail may be in an increasing trend, and the other of the second target outlet air rail and the target operating air rail may be in a decreasing trend. The corresponding relation among the environment humidity, the second target air outlet wind level and the target operation wind level can be preset, and the corresponding relation can be in the forms of calculation relation, mapping relation and the like. And determining a second target air outlet wind gear and a target running wind gear corresponding to the current environmental humidity based on the corresponding relation.
Furthermore, in order to achieve the best dehumidification efficiency by mutually coordinating and matching the air conditioning module and the exhaust module, based on the dehumidification efficiency, a target running wind gear of the exhaust module can be determined according to the ambient humidity, and then a target air outlet wind gear of the air conditioning module can be determined according to the target running wind gear.
And S23, controlling the air conditioning module to perform refrigeration operation according to the second target air outlet wind shield, and controlling the exhaust module to be opened according to the target operation wind shield.
In this embodiment, the respective wind shelves of the air conditioning module and the exhaust module are regulated and controlled based on the indoor environment humidity, so as to ensure that the dehumidification effect achieved by the cooperation of the air conditioning module and the exhaust module can be matched with the actual humidity condition of the current environment, ensure that the indoor humidity can be quickly reduced, and improve the dehumidification effect.
Specifically, in this embodiment, the step S22 includes:
Step S221, determining a target humidity interval in which the ambient humidity is located;
Specifically, the humidity interval corresponding to at least two environmental humidities may be divided in advance. In this embodiment, the divided humidity intervals include a first humidity interval and a second humidity interval, and in other embodiments, the divided humidity intervals may further be provided with a number of more than two humidity intervals according to actual requirements.
The first humidity interval and the second humidity interval are specifically determined according to the highest humidity acceptable to indoor users in a comfortable state, and the humidity in the first humidity interval and the second humidity interval is larger than or equal to the highest humidity. The first humidity interval and the second humidity interval can be the humidity interval divided by default of the system, and can also be the interval divided according to the highest humidity set by the user. In this embodiment, the first humidity range is 40% -50% and the second humidity range is 60% -100%. In other embodiments, other intervals may be set according to the actual setting.
Step S222, when the target humidity interval is within the first humidity interval, determining that a third set wind gear is the second target wind outlet wind gear, and determining that a first running wind gear is the target running wind gear;
step S223, when the target humidity interval is within a second humidity interval, determining a fourth set wind gear as the second target wind outlet wind gear and determining a second running wind gear as the target running wind gear;
The third set wind level is greater than the fourth set wind level, the first running wind level is less than the second running wind level, and the humidity in the first humidity interval is less than the humidity in the second humidity interval.
The fourth set wind level is greater than or equal to the second set wind level, the third set wind level and the first set wind level may be the same wind level, and the third set wind level may be greater than or less than the first set wind level. Specifically, in this embodiment, the second set wind gear and the fourth set wind gear are both low windshields, the first set wind gear is high wind gear, and the third set wind gear is medium wind gear.
The rotating speed of the air supply fan corresponding to the third set wind level is greater than that of the air supply fan corresponding to the fourth set wind level, the heat exchange efficiency of the air supply fan of the air conditioning module when the air supply fan operates with the third set wind level is greater than that of the air supply fan when the air supply fan of the air conditioning module operates with the fourth set wind level, the air outlet temperature of the evaporator when the air supply fan operates with the third set wind level is greater than that of the air supply fan when the air supply fan operates with the fourth set wind level, and the dehumidification efficiency of the air conditioning module when the air supply fan of the air conditioning module operates with the third set wind level is less than that of the air supply fan when the air supply fan operates with the fourth set wind level.
The rotating speed of the exhaust fan corresponding to the first running wind gear is smaller than that of the exhaust fan corresponding to the second running wind gear, and the exhaust efficiency of the exhaust module when running in the first running wind gear is lower than that of the exhaust module when running in the second running wind gear.
In this embodiment, when the ambient humidity is located in the first humidity range with a lower level, the air conditioning module operates with a higher level and the exhaust module operates with a lower level, so as to implement the weak dehumidification function of the integrated stove. Based on this to can ensure that integrated kitchen is through air conditioning module and exhaust module cooperation dehumidification time, dehumidification efficiency can with dehumidify the accurate matching of demand, improve dehumidification effect.
Further, in the present embodiment, after step S21, the method further includes:
step S211, when the ambient humidity is smaller than a set humidity threshold, controlling the air conditioning module to stop, and controlling the exhaust module to be closed after the exhaust module is operated for a set period of time with the lowest operation wind gear;
step S212, when the ambient temperature is greater than or equal to the set humidity threshold, executing the step S22;
and the humidity in the first humidity interval and the humidity in the second humidity interval are both greater than the set humidity threshold.
The humidity threshold is specifically a maximum humidity value allowed by an indoor dry environment for avoiding bacteria growing in the indoor space. The humidity threshold can be a parameter preset by the system, or can be a parameter set by a user based on own needs. The set duration can be a preset parameter or a parameter determined according to the concentration of the oil smoke in the current indoor environment.
In the embodiment, when the environmental humidity is lower than the set humidity threshold, the current environmental humidity is low enough, dehumidification is not needed, the air conditioning module is closed at the moment, but the air exhausting module is controlled to be closed in a delayed mode, so that the kitchen is guaranteed to have no peculiar smell and stay and take away part of humidity emitted by food in the kitchen at the same time, clean and dry of the kitchen are guaranteed, and when the environmental humidity is higher than the set humidity threshold, the air baffles of the air conditioning module and the air exhausting module are controlled to dehumidify according to the interval where the environmental humidity is located, so that dehumidification efficiency of the integrated kitchen can be matched with actual humidity, and dehumidification effect of an indoor environment is guaranteed.
Further, based on any of the above embodiments, the dehumidification mode may be exited when any one of (1) a user forcibly turns off (without pulling out electricity, control of the smoke exhaust motor in a delayed state) via the panel control button and (2) exits the dehumidification mode via the panel button.
If one of the above 2 conditions is not satisfied, the dehumidification mode is maintained, and the above steps S10 and S20 are cyclically performed.
In order to better understand the control method of the integrated cooker of the invention, the following description will be given by way of a specific example:
The user can start the dehumidification mode function through the function key equipment of the panel, at the moment, the integrated kitchen starts data acquisition, relevant parameters of the kitchen are detected through the infrared distance sensor and the humidity sensor, and then judgment is carried out:
1. After the integrated kitchen is started, if a user starts a dehumidification function, the infrared sampler can detect whether a human body exists or not;
2. If the room is judged to be unmanned, the humidity sensor compares humidity values according to a preset temperature range;
(1) If the humidity is RH1 (the humidity range of RH1 is 10% -30%), the refrigerating system of the integrated kitchen is stopped at the moment, and the integrated kitchen is stopped after the low-wind-level operation of smoke exhaust is carried out for 10 minutes, so that the over-humidity is low, dehumidification is not needed, but smoke exhaust operation delayed for 10 minutes is carried out, and part of humidity emitted by food is taken away while the kitchen is ensured to stay without peculiar smell;
(2) If the current humidity is detected to be HR2 (the humidity value of RH2 is 60% -100%), the refrigeration of the integrated kitchen is a low wind level, meanwhile, the smoke discharging system is a strong level, mainly in a strong dehumidification mode, and meanwhile, smoke is discharged strongly, so that the humidity of a kitchen is discharged as much as possible, and the volatilization of the water in the kitchen is accelerated;
(3) If the current humidity is detected to be HR3 (the humidity value of RH3 is 40% -50%), the refrigeration of the integrated cooker is a middle wind gear, a smoke discharging system adopts a middle wind gear, mainly operates in a weak dehumidification mode, and simultaneously discharges smoke in a middle gear;
3. Under the condition that a person is judged by infrared, the distance of the person is further detected by infrared;
detecting the distance R1 between a person and a cooking bench within t time, detecting the distance R2 between the person and the cooking bench again within t1 of interval time, if |R1-R2| < threshold value 1 is adopted, the temperature of an air outlet is lower and the comfort is affected, so that the air conditioner is refrigerated by high wind, the temperature of the air outlet is higher, the dehumidification effect is slightly poor at the moment, and if the distance between the person and the cooking bench is detected to not meet the |R1-R2| < threshold value 1, the air conditioner is refrigerated by low wind and is refrigerated by strong dehumidification, and the dryness of a kitchen is kept;
4. The dehumidification mode is exited if one of the following 2 conditions is met:
(1) The user controls the button to forcibly turn off (under the condition of not pulling electricity, the smoke discharging motor is controlled in a delayed mode);
(2) And the dehumidification mode is withdrawn through the panel button.
If one of the above 2 conditions is not met, keeping a dehumidification mode, continuously detecting indoor humidity values, simultaneously detecting the distance between personnel and a cooking bench, continuously detecting whether the dehumidification mode exits, and judging whether the exit condition of the dehumidification mode is met.
In addition, the embodiment of the invention also provides a computer readable storage medium, wherein the computer readable storage medium stores a control program of the integrated kitchen range, and the control program of the integrated kitchen range realizes the relevant steps of any embodiment of the control method of the integrated kitchen range when being executed by a processor.
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 phrase "comprising one does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.
The foregoing embodiment numbers of the present invention are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments.
From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present invention may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. ROM/RAM, magnetic disk, optical disk) as described above, comprising instructions for causing a terminal device (which may be a mobile phone, a computer, a server, an integrated stove, or a network device, etc.) to perform the method according to the embodiments of the present invention.
The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.