Detailed Description
Preferred embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention.
It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.
An air conditioner and a control method thereof, which operate a vaccine mode when receiving user vaccination information by adding the vaccine mode to the existing air conditioner. The vaccine mode is to control the operation of the air conditioner according to the air conditioner control parameter corresponding to the vaccine information, wherein the air conditioner control parameter corresponding to the vaccine information is the air conditioner control parameter which is determined in advance through experiments and is most suitable for the human body state after the vaccine is inoculated, and the indoor environment temperature and humidity obtained after the operation of the air conditioner is particularly suitable for the human body state after the vaccine is inoculated under the control of the air conditioner control parameter, so that a user who is inoculated with the vaccine is in a suitable environment, and the recovery of the body of the user is facilitated. Therefore, the air conditioner only needs to receive the vaccination information of the user, the air conditioner can operate in a state which is most beneficial to a vaccine injection user without manually adjusting the temperature and the humidity, the requirement of the vaccine injection user can be met, and the condition that the comfort level is reduced or even the air conditioner is sick due to inaccurate manual adjustment is avoided.
The structure of the air conditioner is not limited, the air conditioner can be any type of air conditioner, and the key point is to improve the controller of the air conditioner, so that the vaccine mode is added to the operation mode of the air conditioner, and the requirement of comfort level of a user after vaccine injection is met.
The following embodiments specifically describe an air conditioner and a control method thereof:
example one
The following description is given by way of specific examples in conjunction with the accompanying drawings:
as shown in fig. 1, an air conditioner at least includes a signal receiving module, a storage module, and a controller, and in some preferred embodiments, may further include a user sign obtaining module and a reminding module.
And the signal receiving module is used for receiving the vaccination information of the user.
And the storage module is used for storing the air conditioner control parameters corresponding to the vaccine information.
And the controller is used for operating a vaccine mode after receiving the vaccination information of the user, and the vaccine mode is used for controlling the operation of the air conditioner according to the air conditioner control parameters corresponding to the vaccine information stored in the storage module.
The air conditioner control parameters may include a set temperature control parameter and/or a humidity control parameter and/or a fresh air control parameter.
Specifically, the signal receiving module may be a remote controller signal receiving module or a wireless communication module.
When the signal receiving module is a remote controller signal receiving module, the user vaccination information can be sent out through keys on the remote controller.
When the signal receiving module is the wireless communication module, the accessible user intelligent terminal APP carries out the communication with the air conditioner, with user vaccination information send to signal receiving module.
In this embodiment, the information for the user to vaccinate the vaccine is only a vaccination signal, and a set of fixed air conditioner control parameters is stored in the storage module, the fixed air conditioner control parameters are determined in advance through experiments and are most suitable for the human body state after the vaccine is vaccinated, and under the control of the air conditioner control parameters, the indoor environment temperature and humidity obtained after the air conditioner is operated are particularly suitable for the human body state after the vaccine is vaccinated, so that the user to be vaccinated is in a suitable environment, and the recovery of the user body is facilitated.
Because different users have different user's sign after the vaccination, some user's sign is normal, some user can appear the condition such as having a fever, in order to adapt to different user's health state, for the user provides the most suitable comfortable environment, user's sign acquisition module is preferred to set up in this embodiment.
The user sign acquisition module is used for acquiring user sign information.
Wherein, the user physical sign information is generally body temperature information.
The user sign acquisition module can be an infrared detection module, and the body temperature of the user is detected by the infrared detection module.
Of course, the user sign acquisition module may also be an information input module or a wireless communication module, and after acquiring the user sign information through other devices, the user sign information is input or sent to the user sign information acquisition module.
The storage module of the embodiment is further used for storing the correction relationship between the user physical sign information and the air conditioner control parameter. The correction relation is determined in advance through experiments, and the corrected control parameters can ensure the optimal comfort level of the user sign information. Generally, the user sign information is negatively correlated with the temperature control parameter of the air conditioner, the user sign information is positively correlated with the humidity control parameter of the air conditioner, and the user sign information is positively correlated with the fresh air control parameter. The correction relationship can be generally realized by a correction formula or a correction curve.
The control module is used for correcting the air conditioner control parameters according to the user sign information to obtain corrected air conditioner control parameters, and controlling the operation of the air conditioner according to the corrected air conditioner control parameters.
Therefore, the control parameters of the air conditioner can be determined according to different body states of the user after vaccine injection, and the user in different body states is ensured to be in the optimal comfortable state.
The signal receiving module of the present embodiment is further configured to receive a vaccination time requirement, and to receive information about a user's expected date of delivery or birth date or age.
Wherein the vaccination time requirement is a nationally specified vaccination time requirement, such as the following vaccination schedule:
within 24 hours of birth: hepatitis b vaccine-first needle; BCG vaccine-first seed;
1 month old: hepatitis b vaccine-second needle;
2 months old: poliomyelitis dragee-first needle;
3 months old: poliomyelitis dragee-second needle; diphtheria-pertussis-tetanus vaccine-first needle;
4 months old: poliomyelitis pill-third needle; diphtheria-pertussis-tetanus vaccine-second needle;
6 months old: diphtheria-tetanus vaccine-third needle; hepatitis b vaccine-third needle; group A epidemic encephalitis vaccine first needle;
the 8-month-old: measles vaccine-first needle;
9 months old: group a epidemic encephalitis vaccine — second needle;
1 year of age: encephalitis B vaccine-first race;
1.5 to 2 years old: diphtheria-pertussis-vaccinum; polio dragees-partial reinforcement; encephalitis vaccine-boost; a hepatitis A vaccine;
3 years old: group A epidemic encephalitis vaccine-third needle (A + C epidemic encephalitis vaccine can also be used)
4 years old: polio vaccine-booster needle;
6 years old: measles vaccine-booster needle; diphtheria-pertussis-tetanus bivalent vaccine-booster needle; encephalitis b vaccine-third needle; group a epidemic encephalitis vaccine-fourth needle;
and (4) 12 years old: BCG vaccine-strengthening needle.
Of course, in order to always keep consistent with the requirement of the vaccination time specified by the country, the signal receiving module is a wireless communication module, and can obtain the latest vaccination schedule specified by the country.
The control module is used for determining the user vaccination time according to the vaccination time requirement and the user expected delivery date or birth date or age information.
And the reminding module is used for sending out a reminder before the vaccination time is reached. The reminding information can include the vaccination type, vaccination time, attention and the like.
The reminding module can be a module for pushing reminding information to the user intelligent terminal or can be a display module of the air conditioner, such as a display screen or an indicator light.
Since the existing vaccines generally comprise free vaccine types and free vaccine types, wherein the free vaccine types mainly comprise domestic vaccines, the free vaccine types mainly comprise imported vaccines, and the different vaccine types have different requirements on the inoculation time. Therefore, the signal receiving module of this embodiment is further configured to receive information of a type of vaccine selected by a user, and the control module is configured to determine the vaccination time of the user according to the vaccination time requirement corresponding to the information of the type of vaccine and the information of the expected date of birth or the age of the user.
In order to ensure that the air conditioner operates in the vaccine mode and preferably meet the comfort level of a vaccine inoculation user, the controller is also used for forcing the air conditioner to operate in the vaccine mode within the set time after receiving the vaccine inoculation information of the user and when the air conditioner operates. For example, the controller forces the air conditioner to run the vaccine mode within three days after receiving the vaccination information of the user and the air conditioner runs, and within the three days, the controller directly adjusts the temperature through a remote controller or an APP or switches the mode to be invalid, and sends out the vaccine mode and adjusts the invalid prompt. Other operations can be performed to meet other user requirements unless special circumstances, such as, after the vaccinee leaves home and manually exits the vaccination mode through a remote controller or APP.
The embodiment also provides a control method of the air conditioner, which comprises the following steps:
receiving vaccination information of a user; the vaccination information of the user in the embodiment is mainly a vaccination signal.
And (5) operating the vaccine mode, and controlling the operation of the air conditioner according to the air conditioner control parameter corresponding to the vaccine information.
The air conditioner control parameters may include a set temperature control parameter and/or a humidity control parameter and/or a fresh air control parameter.
Because different users have different user's physical signs after the vaccination, some user's physical signs are normal, some users can have the condition such as fever, in order to adapt to different users ' physical state, for providing the most suitable comfortable environment for the user, the method of this embodiment still includes:
acquiring user sign information;
correcting the air conditioner control parameters according to the user sign information to obtain corrected air conditioner control parameters;
and controlling the operation of the air conditioner according to the corrected air conditioner control parameter.
Wherein, the user physical sign information is generally body temperature information.
The correction relation is determined in advance through experiments, and the corrected control parameters can ensure the optimal comfort level of the user sign information. Generally, the user sign information is negatively correlated with the temperature control parameter of the air conditioner, the user sign information is positively correlated with the humidity control parameter of the air conditioner, and the user sign information is positively correlated with the fresh air control parameter. The correction relationship can be generally realized by a correction formula or a correction curve.
Therefore, the control parameters of the air conditioner can be determined according to different body states of the user after vaccine injection, and the user in different body states is ensured to be in the optimal comfortable state.
The control method of the air conditioner of the embodiment further comprises the following steps:
receiving a vaccination time requirement;
receiving information of a user's expected date of delivery or date of birth or age;
determining the user vaccination time according to the vaccination time requirement and the user expected delivery date or birth date or age information;
a reminder is issued before the time of vaccination is reached. The reminder information can comprise the vaccination type, vaccination time, attention matters and the like.
Wherein the vaccination time requirement is a nationally specified vaccination time requirement, such as the following vaccination schedule:
within 24 hours of birth: hepatitis b vaccine-first needle; BCG vaccine-first seed;
1 month old: hepatitis b vaccine-second needle;
2 months old: poliomyelitis dragee-first needle;
3 months old: poliomyelitis dragee-second needle; diphtheria-pertussis-tetanus vaccine-first needle;
4 months old: poliomyelitis pill-third needle; diphtheria-pertussis-tetanus vaccine-second needle;
6 months old: diphtheria-tetanus vaccine-third needle; hepatitis b vaccine-third needle; group A epidemic encephalitis vaccine first needle;
the 8-month-old: measles vaccine-first needle;
9 months old: group a epidemic encephalitis vaccine — second needle;
1 year of age: encephalitis B vaccine-first race;
1.5 to 2 years old: diphtheria-pertussis-vaccinum; polio dragees-partial reinforcement; encephalitis vaccine-boost; a hepatitis A vaccine;
3 years old: group A epidemic encephalitis vaccine-third needle (A + C epidemic encephalitis vaccine can also be used)
4 years old: polio vaccine-booster needle;
6 years old: measles vaccine-booster needle; diphtheria-pertussis-tetanus bivalent vaccine-booster needle; encephalitis b vaccine-third needle; group a epidemic encephalitis vaccine-fourth needle;
and (4) 12 years old: BCG vaccine-strengthening needle.
Of course, in order to always keep up with the nationally stipulated vaccination schedule, the present example receives a vaccination schedule that is required to be up-to-date nationally stipulated.
Since the existing vaccines generally comprise free vaccine types and free vaccine types, wherein the free vaccine types mainly comprise domestic vaccines, the free vaccine types mainly comprise imported vaccines, and the different vaccine types have different requirements on the inoculation time. Therefore, the control method of the air conditioner in this embodiment further includes receiving information of the type of the vaccine selected by the user, and determining the vaccination time of the user according to the vaccination time requirement corresponding to the information of the type of the vaccine and the information of the expected date of birth or the age of the user.
In order to ensure that the air conditioner operates in the vaccine mode and preferentially meet the comfort level of a vaccine inoculation user, the air conditioner is forced to operate in the vaccine mode within the set time after the vaccine inoculation information of the user is received and the air conditioner operates. For example, the controller forces the air conditioner to run the vaccine mode within three days after receiving the vaccination information of the user and the air conditioner runs, and within the three days, the controller directly adjusts the temperature through a remote controller or an APP or switches the mode to be invalid, and sends out the vaccine mode and adjusts the invalid prompt. Other operations can be performed to meet other user requirements unless special circumstances, such as, after the vaccinee leaves home and manually exits the vaccination mode through a remote controller or APP.
As shown in fig. 2, the control method of the air conditioner of the present embodiment includes the following steps:
s1, receiving a vaccination schedule request, receiving user expected date of birth or age information.
And S2, determining the user vaccination time according to the vaccination time requirement and the user expected delivery date or birth date or age information.
S3, judging whether a period of time is before the vaccination time, if yes, entering step S4, otherwise entering step S3.
And S4, sending out a vaccination reminding.
S5, whether a user vaccination signal is received, if yes, the step S6 is executed, otherwise, the step S4 is executed.
S6, and operating a vaccine mode.
In the step, the air conditioner control parameter is corrected according to the air conditioner control parameter corresponding to the vaccine information or according to the user sign information to obtain the corrected air conditioner control parameter, and the operation of the air conditioner is controlled.
And S7, judging whether the time of the vaccine running mode is expired or the vaccine mode is manually and forcibly exited, if so, entering a step S8, and otherwise, entering a step S6.
And step S8, exiting the vaccine mode and entering the normal control mode of the air conditioner. The process advances to step S3.
Certainly, in the operation process of the air conditioner, the vaccination time requirement can be determined according to the vaccine type information selected by the user, and the vaccination time of the user can be determined according to the vaccination time requirement corresponding to the vaccine type information and the expected date of birth or age information of the user.
Some users may change the vaccine type, for example, from a free vaccine type to a free vaccine type or from a free vaccine type to a free vaccine type, in this case, the air conditioner only needs to determine the user vaccination time from the new user vaccination time according to the vaccination time requirement corresponding to the vaccine type information and the user's expected date or birth date or age information.
Example two
The following description is given by way of specific examples in conjunction with the accompanying drawings:
as shown in fig. 1, an air conditioner at least includes a signal receiving module, a storage module, and a controller, and in some preferred embodiments, may further include a user sign obtaining module and a reminding module.
And the signal receiving module is used for receiving the vaccination information of the user.
And the storage module is used for storing the air conditioner control parameters corresponding to the vaccine information.
And the controller is used for operating a vaccine mode after receiving the vaccination information of the user, and the vaccine mode is used for controlling the operation of the air conditioner according to the air conditioner control parameters corresponding to the vaccine information stored in the storage module.
The air conditioner control parameters may include a set temperature control parameter and/or a humidity control parameter and/or a fresh air control parameter.
Specifically, the signal receiving module of this embodiment is wireless communication module, and accessible user intelligent terminal APP communicates with the air conditioner, with user vaccination information send to signal receiving module.
In this embodiment, the information of the vaccination of the user is not only a signal of vaccination, but also includes relatively rich contents, such as signal of vaccination + type of vaccine (hepatitis a, hepatitis b, karate, epidemic encephalitis, etc.).
And the storage module stores the air conditioner control parameters corresponding to a plurality of vaccine types. For example, hepatitis A corresponds to a first set of air conditioner control parameters, hepatitis B corresponds to a second set of air conditioner control parameters, cards correspond to a third set of air conditioner control parameters, and a epidemic cerebrospinal fluid corresponds to a fourth set of air conditioner control parameters. The air conditioner control parameters corresponding to the vaccine types are the air conditioner control parameters which are determined in advance through experiments and are most suitable for the human body state after the vaccine of the types is inoculated.
Of course, the vaccine types may be divided according to the inoculation reaction degree, for example, a first type which is non-reactive after inoculation, a second type which is relatively light in response and a third type which is relatively heavy in response, wherein the first type corresponds to the I-group air conditioner control parameters, the second type corresponds to the II-group air conditioner control parameters, and the third type corresponds to the III-group air conditioner control parameters.
The controller is used for obtaining the vaccine type after receiving the vaccination information of the user and controlling the operation of the air conditioner according to the air conditioner control parameter corresponding to the vaccine type.
Under the control of the air conditioner control parameters determined according to the type of the inoculated vaccine, the indoor environment temperature and humidity obtained after the air conditioner operates is particularly suitable for the human body state after the vaccine of the type is inoculated, so that a user inoculated with the vaccine of the type is in a suitable environment, and the recovery of the body of the user is facilitated.
Because the human body states are different after different vaccine types are inoculated, different air conditioner control parameters are set for the inoculated vaccine types, the human body states after different vaccine types are inoculated can be adapted, and the human body state is more humanized and intelligent.
Because different users have different user's sign after the vaccination, some user's sign is normal, some user can appear the condition such as having a fever, in order to adapt to different user's health state, for the user provides the most suitable comfortable environment, user's sign acquisition module is preferred to set up in this embodiment.
The user sign acquisition module is used for acquiring user sign information.
Wherein, the user physical sign information is generally body temperature information.
The user sign acquisition module can be an infrared detection module, and the body temperature of the user is detected by the infrared detection module.
Of course, the user sign acquisition module may also be an information input module or a wireless communication module, and after acquiring the user sign information through other devices, the user sign information is input or sent to the user sign information acquisition module.
The storage module of the embodiment is further used for storing the correction relationship between the user physical sign information and the air conditioner control parameter. The correction relation is determined in advance through experiments, and the corrected control parameters can ensure the optimal comfort level of the user sign information. Generally, the user sign information is negatively correlated with the temperature control parameter of the air conditioner, the user sign information is positively correlated with the humidity control parameter of the air conditioner, and the user sign information is positively correlated with the fresh air control parameter. The correction relationship can be generally realized by a correction formula or a correction curve.
The control module is used for correcting the air conditioner control parameters according to the user sign information to obtain corrected air conditioner control parameters, and controlling the operation of the air conditioner according to the corrected air conditioner control parameters.
Therefore, the control parameters of the air conditioner can be determined according to different body states of the user after vaccine injection, and the user in different body states is ensured to be in the optimal comfortable state.
The signal receiving module of the present embodiment is further configured to receive a vaccination time requirement, and to receive information about a user's expected date of delivery or birth date or age.
Wherein the vaccination time requirement is a nationally specified vaccination time requirement, such as the following vaccination schedule:
within 24 hours of birth: hepatitis b vaccine-first needle; BCG vaccine-first seed;
1 month old: hepatitis b vaccine-second needle;
2 months old: poliomyelitis dragee-first needle;
3 months old: poliomyelitis dragee-second needle; diphtheria-pertussis-tetanus vaccine-first needle;
4 months old: poliomyelitis pill-third needle; diphtheria-pertussis-tetanus vaccine-second needle;
6 months old: diphtheria-tetanus vaccine-third needle; hepatitis b vaccine-third needle; group A epidemic encephalitis vaccine first needle;
the 8-month-old: measles vaccine-first needle;
9 months old: group a epidemic encephalitis vaccine — second needle;
1 year of age: encephalitis B vaccine-first race;
1.5 to 2 years old: diphtheria-pertussis-vaccinum; polio dragees-partial reinforcement; encephalitis vaccine-boost; a hepatitis A vaccine;
3 years old: group A epidemic encephalitis vaccine-third needle (A + C epidemic encephalitis vaccine can also be used)
4 years old: polio vaccine-booster needle;
6 years old: measles vaccine-booster needle; diphtheria-pertussis-tetanus bivalent vaccine-booster needle; encephalitis b vaccine-third needle; group a epidemic encephalitis vaccine-fourth needle;
and (4) 12 years old: BCG vaccine-strengthening needle.
Of course, in order to always keep consistent with the requirement of the vaccination time specified by the country, the signal receiving module is a wireless communication module, and can obtain the latest vaccination schedule specified by the country.
The control module is used for determining the user vaccination time according to the vaccination time requirement and the user expected delivery date or birth date or age information.
And the reminding module is used for sending out a reminder before the vaccination time is reached. The reminding information can include the vaccination type, vaccination time, attention and the like.
The reminding module can be a module for pushing reminding information to the user intelligent terminal or can be a display module of the air conditioner, such as a display screen or an indicator light.
Since the existing vaccines generally comprise free vaccine types and free vaccine types, wherein the free vaccine types mainly comprise domestic vaccines, the free vaccine types mainly comprise imported vaccines, and the different vaccine types have different requirements on the inoculation time. Therefore, the signal receiving module of this embodiment is further configured to receive information of a type of vaccine selected by a user, and the control module is configured to determine the vaccination time of the user according to the vaccination time requirement corresponding to the information of the type of vaccine and the information of the expected date of birth or the age of the user.
Preferably, the signal receiving module is further configured to receive user constitution information, the control module is configured to generate notice information after vaccination according to the user constitution information and the vaccination information, and the reminding module is configured to send notice information reminding. The user constitution information comprises contents such as allergen, medicament contraindication, diseases and the like.
In order to ensure that the air conditioner operates in the vaccine mode and preferably meet the comfort level of a vaccine inoculation user, the controller is also used for forcing the air conditioner to operate in the vaccine mode within the set time after receiving the vaccine inoculation information of the user and when the air conditioner operates. For example, the controller forces the air conditioner to run the vaccine mode within three days after receiving the vaccination information of the user and the air conditioner runs, and within the three days, the controller directly adjusts the temperature through a remote controller or an APP or switches the mode to be invalid, and sends out the vaccine mode and adjusts the invalid prompt. Other operations can be performed to meet other user requirements unless special circumstances, such as, after the vaccinee leaves home and manually exits the vaccination mode through a remote controller or APP.
The embodiment also provides a control method of the air conditioner, which comprises the following steps:
receiving vaccination information of a user; the vaccination information of the user in this embodiment includes vaccination signal + vaccine species (hepatitis A, hepatitis B, Care, epidemic encephalitis, etc.). .
And (4) a vaccine operation mode, namely acquiring the vaccine type according to the vaccine information, and controlling the operation of the air conditioner according to the air conditioner control parameter corresponding to the vaccine type.
Different vaccine types correspond to different air conditioner control parameters, the vaccine types are obtained after the vaccination information of the user is received, and the operation of the air conditioner is controlled according to the air conditioner control parameters corresponding to the vaccine types.
For example, hepatitis A corresponds to a first set of air conditioner control parameters, hepatitis B corresponds to a second set of air conditioner control parameters, cards correspond to a third set of air conditioner control parameters, and a epidemic cerebrospinal fluid corresponds to a fourth set of air conditioner control parameters. The air conditioner control parameters corresponding to the vaccine types are the air conditioner control parameters which are determined in advance through experiments and are most suitable for the human body state after the vaccine of the types is inoculated.
Of course, the vaccine types may be divided according to the inoculation reaction degree, for example, a first type which is non-reactive after inoculation, a second type which is relatively light in response and a third type which is relatively heavy in response, wherein the first type corresponds to the I-group air conditioner control parameters, the second type corresponds to the II-group air conditioner control parameters, and the third type corresponds to the III-group air conditioner control parameters.
Under the control of the air conditioner control parameters determined according to the type of the inoculated vaccine, the indoor environment temperature and humidity obtained after the air conditioner operates is particularly suitable for the human body state after the vaccine of the type is inoculated, so that a user inoculated with the vaccine of the type is in a suitable environment, and the recovery of the body of the user is facilitated.
The air conditioner control parameters may include a set temperature control parameter and/or a humidity control parameter and/or a fresh air control parameter.
Because different users have different user's physical signs after the vaccination, some user's physical signs are normal, some users can have the condition such as fever, in order to adapt to different users ' physical state, for providing the most suitable comfortable environment for the user, the method of this embodiment still includes:
acquiring user sign information;
correcting the air conditioner control parameters according to the user sign information to obtain corrected air conditioner control parameters;
and controlling the operation of the air conditioner according to the corrected air conditioner control parameter.
Wherein, the user physical sign information is generally body temperature information.
The correction relation is determined in advance through experiments, and the corrected control parameters can ensure the optimal comfort level of the user sign information. Generally, the user sign information is negatively correlated with the temperature control parameter of the air conditioner, the user sign information is positively correlated with the humidity control parameter of the air conditioner, and the user sign information is positively correlated with the fresh air control parameter. The correction relationship can be generally realized by a correction formula or a correction curve.
Therefore, the control parameters of the air conditioner can be determined according to different body states of the user after vaccine injection, and the user in different body states is ensured to be in the optimal comfortable state.
The control method of the air conditioner of the embodiment further comprises the following steps:
receiving a vaccination time requirement;
receiving information of a user's expected date of delivery or date of birth or age;
determining the user vaccination time according to the vaccination time requirement and the user expected delivery date or birth date or age information;
a reminder is issued before the time of vaccination is reached. The reminder information can comprise the vaccination type, vaccination time, attention matters and the like.
Wherein the vaccination time requirement is a nationally specified vaccination time requirement, such as the following vaccination schedule:
within 24 hours of birth: hepatitis b vaccine-first needle; BCG vaccine-first seed;
1 month old: hepatitis b vaccine-second needle;
2 months old: poliomyelitis dragee-first needle;
3 months old: poliomyelitis dragee-second needle; diphtheria-pertussis-tetanus vaccine-first needle;
4 months old: poliomyelitis pill-third needle; diphtheria-pertussis-tetanus vaccine-second needle;
6 months old: diphtheria-tetanus vaccine-third needle; hepatitis b vaccine-third needle; group A epidemic encephalitis vaccine first needle;
the 8-month-old: measles vaccine-first needle;
9 months old: group a epidemic encephalitis vaccine — second needle;
1 year of age: encephalitis B vaccine-first race;
1.5 to 2 years old: diphtheria-pertussis-vaccinum; polio dragees-partial reinforcement; encephalitis vaccine-boost; a hepatitis A vaccine;
3 years old: group A epidemic encephalitis vaccine-third needle (A + C epidemic encephalitis vaccine can also be used)
4 years old: polio vaccine-booster needle;
6 years old: measles vaccine-booster needle; diphtheria-pertussis-tetanus bivalent vaccine-booster needle; encephalitis b vaccine-third needle; group a epidemic encephalitis vaccine-fourth needle;
and (4) 12 years old: BCG vaccine-strengthening needle.
Of course, in order to always keep up with the nationally stipulated vaccination schedule, the present example receives a vaccination schedule that is required to be up-to-date nationally stipulated.
Since the existing vaccines generally comprise free vaccine types and free vaccine types, wherein the free vaccine types mainly comprise domestic vaccines, the free vaccine types mainly comprise imported vaccines, and the different vaccine types have different requirements on the inoculation time. Therefore, the control method of the air conditioner in this embodiment further includes receiving information of the type of the vaccine selected by the user, and determining the vaccination time of the user according to the vaccination time requirement corresponding to the information of the type of the vaccine and the information of the expected date of birth or the age of the user.
The control method of the air conditioner further comprises the steps of receiving the user constitution information, generating the notice information after vaccination according to the user constitution information and the vaccination information, and sending notice information reminding. The user constitution information comprises contents such as allergen, medicament contraindication, diseases and the like.
In order to ensure that the air conditioner operates in the vaccine mode and preferentially meet the comfort level of a vaccine inoculation user, the air conditioner is forced to operate in the vaccine mode within the set time after the vaccine inoculation information of the user is received and the air conditioner operates. For example, the controller forces the air conditioner to run the vaccine mode within three days after receiving the vaccination information of the user and the air conditioner runs, and within the three days, the controller directly adjusts the temperature through a remote controller or an APP or switches the mode to be invalid, and sends out the vaccine mode and adjusts the invalid prompt. Other operations can be performed to meet other user requirements unless special circumstances, such as, after the vaccinee leaves home and manually exits the vaccination mode through a remote controller or APP.
As shown in fig. 3, the control method of the air conditioner of the present embodiment includes the following steps:
s1, receiving a vaccination schedule request, receiving user expected date of birth or age information.
And S2, determining the user vaccination time according to the vaccination time requirement and the user expected delivery date or birth date or age information.
S3, judging whether a period of time is before the vaccination time, if yes, entering step S4, otherwise entering step S3.
And S4, sending out a vaccination reminding.
S5, whether the user vaccination information is received, if yes, the step S6 is entered, otherwise, the step S4 is entered.
And S6, obtaining the vaccine type according to the vaccine information, and controlling the vaccine running mode of the air conditioner according to the air conditioner control parameter corresponding to the vaccine type.
In the step, the air conditioner control parameters corresponding to the vaccine types or the user sign information are corrected to obtain corrected air conditioner control parameters, and the operation of the air conditioner is controlled.
And S7, judging whether the time of the vaccine running mode is expired or the vaccine mode is manually and forcibly exited, if so, entering a step S8, and otherwise, entering a step S6.
And step S8, exiting the vaccine mode and entering the normal control mode of the air conditioner. The process advances to step S3.
Certainly, in the operation process of the air conditioner, the vaccination time requirement can be determined according to the vaccine type information selected by the user, and the vaccination time of the user can be determined according to the vaccination time requirement corresponding to the vaccine type information and the expected date of birth or age information of the user.
Some users may change the vaccine type, for example, from a free vaccine type to a free vaccine type or from a free vaccine type to a free vaccine type, in this case, the air conditioner only needs to determine the user vaccination time from the new user vaccination time according to the vaccination time requirement corresponding to the vaccine type information and the user's expected date or birth date or age information.
The air conditioner can also receive the user constitution information, generate the attention information after vaccination according to the user constitution information and the vaccination information, and send out the attention information prompt.
In the invention, if the user can always perform inoculation according to the requirement of the vaccination time, the reminding time of the air conditioner can be reminded according to the vaccination time, if the user has the condition of early or late vaccination, the controller calculates the next vaccination time as the current vaccination time plus two times of vaccination interval time, and reminds before the next vaccination time so as to meet the requirement of the vaccination interval.
The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions.