WO2018028327A1 - 空调器及其一键开机控制方法 - Google Patents

空调器及其一键开机控制方法 Download PDF

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Publication number
WO2018028327A1
WO2018028327A1 PCT/CN2017/090612 CN2017090612W WO2018028327A1 WO 2018028327 A1 WO2018028327 A1 WO 2018028327A1 CN 2017090612 W CN2017090612 W CN 2017090612W WO 2018028327 A1 WO2018028327 A1 WO 2018028327A1
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Prior art keywords
air conditioner
temperature
wearable device
smart wearable
air
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PCT/CN2017/090612
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English (en)
French (fr)
Inventor
屈金祥
杜鹏杰
向兴华
Original Assignee
广东美的制冷设备有限公司
美的集团股份有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Priority claimed from CN201610649839.7A external-priority patent/CN106247539B/zh
Priority claimed from CN201610649870.0A external-priority patent/CN106288163B/zh
Application filed by 广东美的制冷设备有限公司, 美的集团股份有限公司 filed Critical 广东美的制冷设备有限公司
Publication of WO2018028327A1 publication Critical patent/WO2018028327A1/zh

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements

Definitions

  • the invention relates to the field of refrigeration, and in particular to an air conditioner and a one-button power-on control method thereof.
  • Air conditioners usually require the user to press the power button before selecting the cooling, heating, air supply or dehumidification modes, and the specific temperature is set by the user himself.
  • the air conditioner runs for a period of time according to the mode selected by the user. The user may feel that the temperature is too high or too low. At this time, the user needs to manually adjust the temperature again, which causes troublesome operation.
  • the existing air conditioner adopts an automatic power-on mode, and the scheme is based on the return air temperature of the indoor unit, and automatically enters each mode.
  • the disadvantage of this technology is that the return air temperature does not truly reflect the user's body surface temperature. Therefore, in some environments, the mode of automatic power-on selection is not necessarily the mode that the user wants, thereby reducing the user experience.
  • the main object of the present invention is to provide an air conditioner and a one-button power-on control method thereof.
  • the air conditioner When the air conditioner is turned on, it can perform a control program that makes the user comfortable according to the real temperature feeling of the user, thereby improving the user experience.
  • the present invention provides a one-button power-on control method for an air conditioner, comprising the following steps:
  • the present invention also provides an air conditioner, the air conditioner comprising:
  • An acquiring module configured to acquire an outdoor ambient temperature and a temperature detected by the smart wearable device when receiving a one-button power-on command, and determine a current operating mode of the air conditioner according to the outdoor ambient temperature and the temperature detected by the smart wearable device ;
  • control module configured to control the air conditioner to perform the current operation mode.
  • the one-button power-on control method and the air conditioner of the air conditioner provided by the present invention acquire the outdoor ambient temperature and the temperature detected by the smart wearable device when receiving a one-button power-on command, and detect according to the outdoor ambient temperature and the smart wearable device.
  • the temperature determines the current operating mode to control the air conditioner to perform the current operating mode. In this way, when the air conditioner is turned on, it can perform a control program that makes the user comfortable according to the real temperature feeling of the user, thereby improving the user experience.
  • FIG. 1 is a schematic flow chart of a first embodiment of a one-button power-on control method for an air conditioner according to the present invention
  • FIG. 2 is a schematic flow chart of a second embodiment of a one-button power-on control method for an air conditioner according to the present invention
  • FIG. 3 is a schematic flow chart of a third embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • FIG. 4 is a schematic flow chart of a fourth embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • FIG. 5 is a schematic flow chart of a fifth embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • FIG. 6 is a schematic flow chart of a sixth embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • FIG. 7 is a schematic flow chart of a seventh embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • FIG. 8 is a schematic flow chart of an eighth embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • FIG. 9 is a schematic flow chart of a ninth embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • Figure 10 is a schematic view showing a first embodiment of an air conditioner operating mode control routine in the summer
  • Figure 11 is a schematic view showing a first embodiment of an air conditioner operating mode control program in the winter
  • Figure 12 is a schematic view showing a second embodiment of an air conditioner operating mode control program in the summer
  • Figure 13 is a schematic view showing a second embodiment of an air conditioner operating mode control program in the winter
  • FIG. 14 is a schematic flow chart of a tenth embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • 15 is a schematic flow chart of an eleventh embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • 16 is a schematic flow chart of a twelfth embodiment of a one-button power-on control method for an air conditioner according to the present invention.
  • Figure 17 is a flow chart showing the thirteenth embodiment of the one-button power-on control method of the air conditioner of the present invention.
  • the invention provides an air conditioner and a one-button power-on control method thereof, which determine a current operation mode by acquiring an outdoor ambient temperature and a temperature detected by the smart wearable device when receiving a one-button power-on command. Therefore, the present invention can truly know the actual temperature perception of the user through the smart wearable device or the like, and thus can be more accurately adjusted to the air conditioner operation mode suitable for the user. In this way, not only the manual operation of the user but also the user comfort can be improved.
  • a one-button power-on control method of the air conditioner includes the following steps:
  • Step S1 Acquire an outdoor ambient temperature and a temperature detected by the smart wearable device when receiving a one-button power-on command, and determine a current operating mode according to the outdoor ambient temperature and the temperature detected by the smart wearable device;
  • the temperature detected by the smart wearable device may of course be a mobile terminal having a temperature detecting function for detecting.
  • the smart wearable device is a wearable smart terminal, such as a smart wristband, and the mobile terminal can be a mobile phone, a tablet computer, or the like. It is also possible to set the temperature detection module in the remote control.
  • the detected temperature is the body surface temperature of the user; when the user does not wear the smart wearable device, the detected temperature is the air temperature in the vicinity of the user. Therefore, the user's true temperature experience can be obtained more accurately.
  • the detected temperature is the body surface temperature of the user, it can also be detected by an infrared sensor provided by the air conditioner, and the body surface temperature detects the average temperature of the human skin temperature and the clothing temperature.
  • the one-button power-on command can be triggered by the smart wearable device worn by the user, or can be triggered by a one-button power-on button set on the remote controller, or can be triggered by a mobile terminal that is wirelessly connected to the smart wearable device, such as a mobile phone.
  • the smart wearable device can set a one-button power-on button, or can set a display screen with a temperature display function, and the virtual one-button power-on button can be set on the display screen; and the smart wearable device can be preset to shake a predetermined number of times in a predetermined direction.
  • a one-button power-on command can be triggered; one-touch power-on can also be controlled by voice control.
  • Step S2 Control the air conditioner to execute the current operation mode.
  • the air conditioner determines the current operation mode according to the preset rules of Table 1 or Table 2 below, and executes The current operating mode.
  • the set temperature is a preset default fixed value, and therefore, no acquisition is required. The details will be described below in conjunction with specific embodiments.
  • the one-button power-on control method for an air conditioner acquires an outdoor ambient temperature and a temperature detected by the smart wearable device when receiving a one-button power-on command, and according to the outdoor ambient temperature and the temperature detected by the smart wearable device.
  • a current operating mode is determined to control the air conditioner to perform the current operating mode. In this way, when the air conditioner is turned on, the air conditioner can be controlled to execute the corresponding operation mode according to the preset rule, thereby avoiding manual operation of the user, and can truly reflect the user's temperature feeling, thereby improving the user experience.
  • step S2 further includes:
  • Step S3 When the indoor air humidity is acquired, the user's body temperature is calculated according to the temperature detected by the smart wearable device and the indoor air humidity, and the current operation of the air conditioner is determined according to the outdoor environment temperature and the body temperature. mode.
  • the temperature detected by the smart wearable device and the indoor air humidity may of course be detected by a mobile terminal having a temperature detecting function and a humidity detecting function.
  • the user's body temperature calculation method is as follows:
  • Ta is the body surface temperature of the user detected by the smart wearable device worn by the user or the air temperature in the vicinity of the user
  • RH1 is the indoor air humidity around the user detected by the smart wearable device
  • Tp is the somatosensory temperature of the user.
  • the air conditioner determines the current operation mode according to the preset rules of Table 1 or Table 2 below, and executes the current operation mode.
  • the method further includes:
  • the set temperature may be acquired by the smart wearable device by the temperature of the user input, or by a temperature button on the remote controller, or by a mobile terminal wirelessly connected to the smart wearable device.
  • the set temperature is selected by the user and adjustable.
  • the set temperature may be a preset default fixed value.
  • the method further includes:
  • S8 Receive a one-button power-on command sent by the smart wearable device, and a body surface temperature detected by the smart wearable device or an air temperature and indoor air humidity in the vicinity of the user.
  • the one-button power-on command and the body surface temperature or the air temperature in the vicinity of the user are respectively triggered and detected by the smart wearable device.
  • the one-button power-on command, the body surface temperature or the air temperature in the vicinity of the user, and the indoor air humidity are respectively triggered and detected by the smart wearable device.
  • the smart wearable device can set a one-button power-on button, or can set a display screen with a temperature display function, and the virtual one-button power-on button can be set on the display screen; and the smart wearable device can be preset to shake a predetermined number of times in a predetermined direction.
  • a one-button power-on command can be triggered; one-touch power-on can also be controlled by voice control.
  • the smart wearable device is also provided with a temperature sensor, and since the smart wearable device is in contact with the skin, the temperature feeling of the user can be accurately reflected. In this way, in the embodiment, the air conditioner can perform a control program that makes the user comfortable according to the real temperature feeling of the user.
  • the method further includes:
  • the body surface temperature or the air temperature in the vicinity of the user is detected by the smart wearable device and sent to the mobile terminal.
  • the one-button power-on command is triggered by the mobile terminal, and the body surface temperature or the air temperature in the vicinity of the user is detected by the smart wearable device and sent to the mobile terminal.
  • the indoor air humidity is detected by the mobile terminal, and the body surface temperature or the air temperature in the vicinity of the user is detected by the smart wearable device and transmitted to the mobile terminal.
  • the mobile terminal may set a one-button power-on shortcut button, or set a one-button power-on button in the air-conditioning control application; and may also preset that when the mobile terminal shakes a predetermined number of times in a predetermined direction, a one-button power-on command may be triggered; Start with a voice control.
  • the smart wearable device is also provided with a temperature sensor, and since the smart wearable device is in close contact or direct contact with the skin, the temperature feeling of the user can be accurately reflected.
  • the air conditioner can perform a control program that makes the user comfortable according to the real temperature feeling of the user.
  • the difference between the embodiment and the first embodiment is that the one-button power-on command is triggered by the mobile terminal, and the indoor air humidity is detected by the mobile terminal, so that the frequency of the user using the mobile phone is far higher, so the trigger is triggered by the mobile phone.
  • One-button power-on command combined with the body surface temperature detected by the smart wearable device in real time or the air temperature near the user, or the air humidity detected in real time by the smart wearable device and the body surface temperature detected by the smart wearable device or the air temperature in the vicinity of the user, thereby It can also provide users with comfortable ambient temperature conveniently and quickly.
  • the method further includes:
  • the determination rule of the current operating mode may correspondingly execute different mode control programs according to the season (summer and winter), as shown in Tables 1 and 2 below:
  • T4 is the outdoor ambient temperature detected by the outdoor sensor
  • Ta is the surface temperature of the user detected by the smart wearable device worn by the user or the air temperature near the user
  • Ts is the set temperature set by the air conditioner or set by the user.
  • Temperature the range of the set temperature is 17 ⁇ 30 °C, which can be set reasonably in combination with actual needs such as area and use.
  • the set temperature is the factory default, it can be set to 26 °C.
  • T4 defaults to 17 °C when a sensor failure occurs in the outdoor sensor
  • Ta defaults to 26 °C when the temperature sensor of the smart wearable device fails.
  • the air conditioner can obtain the current date every time the power is turned on, and determine whether the current date enters a preset season transition period.
  • two season transition periods can be set, and the conversion node is May.
  • the mode control program of the air conditioner in Table 1 is executed; when the current date is November 1st, the air conditioner in Table 2 is correspondingly executed. Mode control program. In this way, users can be provided with better comfort according to seasonal temperature changes.
  • the determination rule of the current operation mode may perform different mode control according to the season (summer and winter). The procedure, as shown in Figures 12 and 13, at this time, the body surface temperature is not adjustable.
  • the method further includes:
  • the current position information is added with respect to the first embodiment, and in combination with the current position information and the current date, the air conditioner can be controlled to execute the corresponding position and season air conditioner mode control program.
  • the air conditioner can be controlled to execute the corresponding position and season air conditioner mode control program.
  • the current location is Shanghai, and the current date enters the summer from May 1st to October 31st:
  • the method further includes:
  • step S13 When the set temperature changes, the process proceeds to step S5 or S6 to determine the actual operation mode of the air conditioner.
  • the air conditioner when the set temperature changes, the corresponding operation mode will change at the same time. Therefore, when the air conditioner detects that the set temperature changes, it will be monitored according to real-time or timing.
  • the outdoor ambient temperature, the body surface temperature, or the air temperature near the user and the set temperature determine the current operating mode of the air conditioner.
  • step S2 further includes:
  • step S40 If the actual operation mode is inconsistent with the current operation mode, return to step S20 until the number of cycles reaches a preset number of times.
  • the air supply mode is first defaulted, and when the relay of the outdoor unit is closed, immediately Perform mode judgment. If it is judged that the actual operation mode is the cooling mode, then it will be judged again after a predetermined time, such as 1 minute. If it is still determined to be the cooling mode after 1 minute, the actual operation mode is no longer judged; If it is judged to be the air supply mode or the heating mode after 1 minute, the actual operation mode is re-determined after another one minute. It should be understood that the setting of the predetermined number of times may be reasonably set according to actual needs. In the preferred embodiment, it may be set twice, and of course, may be set once, three times or multiple times.
  • the method further includes:
  • Step S50 When receiving a one-button power-on command, determine whether the outdoor unit is started;
  • Step S60 if the outdoor unit is not started, determining that the current operating mode of the air conditioner is the air supply mode
  • the relay of the outdoor unit when the air conditioner receives the one-button power-on command, the relay of the outdoor unit is not in the closed state. Therefore, it is necessary to judge the relay state of the outdoor unit, and the relay of the outdoor unit is broken. When the state is on, at this time, the outdoor unit is not activated, and the outdoor ambient temperature cannot be obtained. Therefore, the default operating mode of the air conditioner is the air supply mode.
  • Step S70 If the outdoor unit is started, step S1 is performed.
  • the outdoor ambient temperature and the body surface temperature of the user or the air temperature near the user are immediately acquired, and according to the outdoor ambient temperature and the body surface temperature.
  • the air temperature near the user makes a mode determination to determine the current operating mode of the air conditioner and controls the air conditioner to perform the current operating mode.
  • the present invention also provides an air conditioner.
  • the specific embodiment refers to the foregoing method item embodiment, and details are not described herein again.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
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Abstract

本发明公开了一种空调器的一键开机控制方法,包括以下步骤:在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和智能穿戴设备检测的温度,确定当前运行模式;控制空调器执行所述当前运行模式。本发明还公开了一种空调器。本发明可以根据用户的真实温度感受,对应执行令用户舒适的控制程序,从而提高用户体验。

Description

空调器及其一键开机控制方法
技术领域
本发明涉及制冷领域,尤其涉及一种空调器及其一键开机控制方法。
背景技术
空调器通常需要用户先按下电源键,然后才能选择制冷、制热、送风或除湿等模式,而且具体的温度由用户自己进行设定,当空调器根据用户选择的模式运行了一段时间后,用户很可能感觉温度调的过高或过低了,此时,则需要用户再次手动进行温度调整,导致操作麻烦。为解决这种问题,现有空调器采取自动开机模式,其方案是以室内机的回风温度为基础,自动判断而进入各个模式。此技术的缺点是:回风温度并不能真实反映用户的体表温度,因此,在某些环境下,自动开机选择的模式并不一定是用户想要的模式,从而降低了用户体验。
上述内容仅用于辅助理解本发明的技术方案,并不代表承认上述内容是现有技术。
发明内容
本发明的主要目的在于提供一种空调器及其一键开机控制方法,旨在空调器开机启动时,可以根据用户的真实温度感受,对应执行令用户舒适的控制程序,从而提高用户体验。
为实现上述目的,本发明提供一种空调器的一键开机控制方法,包括以下步骤:
S1、在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和所述智能穿戴设备检测的温度,确定空调器的当前运行模式;
S2、控制空调器执行所述当前运行模式。
为实现上述目的,本发明还提供一种空调器,所述空调器包括:
获取模块,用于在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和所述智能穿戴设备检测的温度,确定空调器的当前运行模式;
控制模块,用于控制空调器执行所述当前运行模式。
本发明提供的空调器的一键开机控制方法及空调器,通过在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和智能穿戴设备检测的温度来确定当前运行模式,以控制空调器执行所述当前运行模式。这样,空调器开机启动时,可以根据用户的真实温度感受,对应执行令用户舒适的控制程序,从而提高用户体验。
附图说明
图1为本发明空调器的一键开机控制方法第一实施例的流程示意图;
图2为本发明空调器的一键开机控制方法第二实施例的流程示意图;
图3为本发明空调器的一键开机控制方法第三实施例的流程示意图;
图4为本发明空调器的一键开机控制方法第四实施例的流程示意图;
图5为本发明空调器的一键开机控制方法第五实施例的流程示意图;
图6为本发明空调器的一键开机控制方法第六实施例的流程示意图;
图7为本发明空调器的一键开机控制方法第七实施例的流程示意图;
图8为本发明空调器的一键开机控制方法第八实施例的流程示意图;
图9为本发明空调器的一键开机控制方法第九实施例的流程示意图;
图10为本发明空调器在夏季执行模式控制程序第一实施例的示意图;
图11为本发明空调器在冬季执行模式控制程序第一实施例的示意图;
图12为本发明空调器在夏季执行模式控制程序第二实施例的示意图;
图13为本发明空调器在冬季执行模式控制程序第二实施例的示意图;
图14为本发明空调器的一键开机控制方法第十实施例的流程示意图;
图15为本发明空调器的一键开机控制方法第十一实施例的流程示意图;
图16为本发明空调器的一键开机控制方法第十二实施例的流程示意图;
图17为本发明空调器的一键开机控制方法第十三实施例的流程示意图。
本发明目的的实现、功能特点及优点将结合实施例,参照附图做进一步说明。
具体实施方式
应当理解,此处所描述的具体实施例仅仅用以解释本发明,并不用于限定本发明。
本发明提供一种空调器及其一键开机控制方法,通过在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,来确定当前运行模式。因此,本发明可以通过智能穿戴设备等来真实地获知用户的实际温度感受,进而可以更精确地调整到适合用户的空调运行模式。如此,不仅可以避免用户手动操作,还可以提高用户舒适度。
参照图1,在一实施例中,所述空调器的一键开机控制方法包括以下步骤:
步骤S1、在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和智能穿戴设备检测的温度,确定当前运行模式;
本实施例中,智能穿戴设备检测的温度,当然还可以是具有温度检测功能的移动终端来进行检测。而智能穿戴设备为可佩戴的智能终端,如智能手环,移动终端可以是手机、平板电脑等。还可以在遥控器内设置温度检测模块。当用户佩戴该智能穿戴设备时,检测的温度是用户的体表温度;当用户未佩戴智能穿戴设备时,检测的温度则是用户附近的空气温度。因此,可以较准确的获取用户的真实温度感受。应当理解的是,若检测的温度是用户的体表温度时,还可以通过空调器设置的红外传感器进行检测,而所述体表温度检测的是人体皮肤温度和衣服温度的平均温度。
一键开机指令可以由用户佩戴的智能穿戴设备触发,也可以由遥控器上设置的一键开机按钮触发,还可以由与智能穿戴设备无线连接的移动终端如手机触发。具体地,智能穿戴设备可以设置一键开机按钮,也可以设置具有温度显示功能的显示屏,该显示屏上可以设置虚拟一键开机按钮;还可以预设当智能穿戴设备朝预定方向晃动预定次数时,可触发一键开机指令;还可通过语音控制一键开机。
步骤S2、控制空调器执行所述当前运行模式。
本实施例中,在获取到室外环境温度以及用户的体表温度或用户附近的空气温度时,空调器则会对应根据如下表一或表二的预设规则,来确定当前运行模式,并执行该当前运行模式。本实施例中,设定温度为预设的默认固定值,因此,无需获取。以下将结合具体实施例作详细介绍。
本发明提供的空调器的一键开机控制方法,通过在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和智能穿戴设备检测的温度来确定当前运行模式,以控制空调器执行所述当前运行模式。这样,空调器开机启动时,即可控制空调器根据预设规则执行对应的运行模式,避免用户手动操作,同时可以真实地反映用户的温度感受,从而可以提高用户体验。
在一实施例中,如图2所示,在上述图1所示的基础上,所述步骤S2之前还包括:
步骤S3、在获取到室内空气湿度时,根据所述智能穿戴设备检测的温度和室内空气湿度计算得到用户的体感温度,并根据所述室外环境温度和所述体感温度,确定空调器的当前运行模式。
本实施例中,智能穿戴设备检测的温度和室内空气湿度,当然还可以是具有温度检测功能和湿度检测功能的移动终端来进行检测。
本实施例中,用户的体感温度计算方法如下:
Tp=f(Ta,RH1)=Ta-0.4*(Ta-10)(1-RH1),
其中,Ta为用户佩戴的智能穿戴设备检测的用户的体表温度或用户附近的空气温度,RH1为所述智能穿戴设备检测的用户周边的室内空气湿度,Tp为用户的体感温度。
在获取到室外环境温度以及用户的体表温度或用户附近的空气温度时,空调器则会对应根据如下表一或表二的预设规则,来确定当前运行模式,并执行该当前运行模式。
在一实施例中,如图3、4所示,在上述图1或图2所示的基础上,所述步骤S2之前还包括:
S4、在接收到一键开机指令时,还获取空调器的设定温度;
本实施例中,设定温度可以通过智能穿戴设备获取用户输入的温度,或通过遥控器上的温度按键获取,或通过与智能穿戴设备无线连接的移动终端获取。本优选实施例中,所述设定温度是由用户选择的,并可调节。当然,在其他实施例中,所述设定温度可以为预设的默认固定值。
S5、根据所述室外环境温度、智能穿戴设备检测的温度及所述空调器的设定温度,确定空调器的当前运行模式;或
S6、根据所述室外环境温度、体感温度及所述空调器的设定温度,确定空调器的当前运行模式。
本实施例中,具体的当前运行模式的确定规则,同下表一和表二以及图6和图7,在此,不再赘述。
在第一实施例中,如图5、6所示,在上述图1或图2所示的基础上,所述步骤S1之前还包括:
S7、接收智能穿戴设备发送的一键开机指令以及智能穿戴设备检测的体表温度或用户附近的空气温度;或
S8、接收所述智能穿戴设备发送的一键开机指令以及智能穿戴设备检测的体表温度或用户附近的空气温度和室内空气湿度。
本优选实施例中,所述一键开机指令和体表温度或用户附近的空气温度,分别由智能穿戴设备触发和检测的。或者所述一键开机指令、体表温度或用户附近的空气温度以及室内空气湿度分别由智能穿戴设备触发和检测的。具体地,智能穿戴设备可以设置一键开机按钮,也可以设置具有温度显示功能的显示屏,该显示屏上可以设置虚拟一键开机按钮;还可以预设当智能穿戴设备朝预定方向晃动预定次数时,可触发一键开机指令;还可通过语音控制一键开机。智能穿戴设备上还设置有温度传感器,由于智能穿戴设备与皮肤接触,因此,可以精确地反映用户的温度感受。这样,本实施例中,空调器可以根据用户的真实温度感受,对应执行令用户舒适的控制程序。
在第二实施例中,如图7、8所示,在上述图1或图2所示的基础上,所述步骤S1之前还包括:
S9、接收所述移动终端发送的一键开机指令和体表温度或用户附近的空气温度;或
S10、接收所述移动终端发送的一键开机指令、室内空气湿度和体表温度或用户附近的空气温度;
其中,所述体表温度或用户附近的空气温度由智能穿戴设备检测并发送至所述移动终端。
本实施例中,一键开机指令由移动终端触发,而体表温度或用户附近的空气温度由所述智能穿戴设备检测并发送至所述移动终端。或所述室内空气湿度由所述移动终端检测,而体表温度或用户附近的空气温度由所述智能穿戴设备检测并发送至所述移动终端。具体地,移动终端可以设置一键开机快捷按钮,或者在空调控制应用程序中设置一键开机按钮;还可以预设当移动终端朝预定方向晃动预定次数时,可触发一键开机指令;还可通过语音控制一键开机。智能穿戴设备上还设置有温度传感器,由于智能穿戴设备与皮肤靠近或直接接触,因此,可以精确地反映用户的温度感受。这样,本实施例中,空调器可以根据用户的真实温度感受,对应执行令用户舒适的控制程序。本实施例相对于第一实施例,差别仅在于一键开机指令由移动终端触发,室内空气湿度由所述移动终端检测,这样,由于用户使用手机的频率远远较高,因此,通过手机触发一键开机指令,结合智能穿戴设备实时检测的体表温度或用户附近的空气温度,或结合智能穿戴设备实时检测的空气湿度以及智能穿戴设备实时检测的体表温度或用户附近的空气温度,从而也可以很方便、快捷地为用户提供舒适的环境温度。
在第一实施例中,如图9、图10和图11所示,在上述图1至图8任一项所示的基础上,所述步骤S2之后还包括:
S11、获取当前日期,并在所述当前日期进入预设季节转换期时,执行对应季节的空调器模式控制程序。
在一优选实施例中,当前运行模式的确定规则可以根据季节(夏季和冬季)来对应执行不同的模式控制程序,如下表一和表二:
夏季:5月1日~10月31日:
满足条件 运行模式
T4≤15 制热随身感模式
15<T4<28且Ta<Ts-3 制热随身感模式
15<T4<28且Ts-3≤Ta≤Ts+7 送风模式
15<T4<28且Ts+7<Ta 制冷随身感模式
T4≥28 制冷随身感模式
表一
冬季:11月1日~4月30日:
满足条件 运行模式
T4≤14 制热随身感模式
14<T4<27且Ta<Ts-3 制热随身感模式
14<T4<27且Ts-3≤Ta≤Ts+7 送风模式
14<T4<27且Ts+7<Ta 制冷随身感模式
T4≥27 制冷随身感模式
表二
其中,T4为室外传感器检测的室外环境温度,Ta为用户佩戴的智能穿戴设备检测的用户的体表温度或用户附近的空气温度,而Ts为空调器出厂设置的设定温度或用户设定的温度,该设定温度的区间范围为17~30℃,具体可以结合地区、用途等实际需要合理设置。当所述设定温度为出厂默认值时,可以设置为26℃。
应当理解的是,当室外传感器发生传感器故障时,T4默认为17℃,而当智能穿戴设备的温度传感器发生故障时,Ta默认26℃。
本实施例中,空调器可以在每次开机启动时获取当前日期,并判断当前日期是否进入预设季节转换期,在一具体实施例中,可以设置两个季节转换期,转换节点为5月1日和11月1日,当当前日期为5月1日时,则对应执行表一中空调器的模式控制程序;当当前日期为11月1日时,则对应执行表二中空调器的模式控制程序。这样,可以根据季节温度变化,给用户提供更好的舒适感。
在另一实施例中,当通过智能穿戴设备或红外传感器检测的是用户的体表温度Tcl时,此时,当前运行模式的确定规则可以根据季节(夏季和冬季)来对应执行不同的模式控制程序,如图12和图13,此时,体表温度不可调节。
在第二实施例中,如图14所示,在上述图1或图2所示的基础上,所述步骤S2之后还包括:
S12、获取当前位置信息和当前日期,并在所述当前日期进入预设季节转换期时,执行对应位置和季节的空调器模式控制程序。
本实施例中,相对于第一实施例增加了当前位置信息,结合当前位置信息和当前日期,可以控制空调器执行对应位置和季节的空调器模式控制程序。以下将以上海和广州两个位置进行举例说明。
1、在当前位置为上海,且当前日期进入夏季5月1日~10月31日时:
满足条件 运行模式
T4≤15 制热随身感模式
15<T4<28且Ta<Ts-3 制热随身感模式
15<T4<28且Ts-3≤Ta≤Ts+7 送风模式
15<T4<28且Ts+7<Ta 制冷随身感模式
T4≥28 制冷随身感模式
表一
2、在当前位置为上海,且当前日期进入冬季11月1日~4月30日时:
满足条件 运行模式
T4≤14 制热随身感模式
14<T4<27且Ta<Ts-3 制热随身感模式
14<T4<27且Ts-3≤Ta≤Ts+7 送风模式
14<T4<27且Ts+7<Ta 制冷随身感模式
T4≥27 制冷随身感模式
表二
3、在当前位置为广州,且当前日期进入夏季4月1日~11月14日时:
满足条件 运行模式
T4≤14 制热随身感模式
14<T4<28且Ta<TS-3 制热随身感模式
14<T4<28且TS-3≤Ta≤TS+7 送风模式
14<T4<28且TS+7<Ta 制冷随身感模式
T4≥28 制冷随身感模式
表三
4、在当前位置为广州,且当前日期进入冬季11月15日~3月31日时:
满足条件 运行模式
T4≤13 制热随身感模式
13<T4<27且Ta<TS-3 制热随身感模式
13<T4<27且TS-3≤Ta≤+7 送风模式
13<T4<27且TS+7<Ta 制冷随身感模式
T4≥27 制冷随身感模式
表四
在一实施例中,如图15所示,在上述图2所示的基础上,所述步骤S4之后还包括:
S13、在所述设定温度发生变化时,转入步骤S5或S6,确定所述空调器的实际运行模式。
本实施例中,根据表一至表四,当设定温度发生变化时,则对应的运行模式将同时发生变化,因此,当空调器监测到设定温度发生变化时,则将根据实时或定时监测的室外环境温度、体表温度或用户附近的空气温度以及设定温度,来确定空调器的当前运行模式。
在一实施例中,如图16所示,在上述图1所示的基础上,所述步骤S2之后还包括:
S20、在预定时间后,确定所述空调器的实际运行模式;
S30、若所述实际运行模式与所述当前运行模式一致,则停止实际运行模式的判断;
S40、若所述实际运行模式与所述当前运行模式不一致,则返回至步骤S20,直至循环次数达到预设次数。
在一具体实施例中,若空调器处于关机状态,且室外机的继电器没有闭合,则在接收到一键开机指令时,先默认为送风模式,当监测到室外机的继电器闭合后,立即进行模式判断,此时若判断实际运行模式为制冷模式,则过在预定时间如1分钟后,再重新判断一次,如果1分钟后仍然判断为制冷模式,则不再进行实际运行模式的判断;如果1分钟后判断为送风模式或者制热模式,则再隔1分钟后重新判断实际运行模式。应当理解的是,预定次数的设置可以根据实际需要合理设置,本优选实施例中,可以设置2次,当然还可以设置1次、3次或多次。
在一实施例中,如图17所示,在上述图1或图2所示的基础上,所述步骤S1之前还包括:
步骤S50、在接收到一键开机指令时,判断室外机是否启动;
步骤S60、若室外机未启动,则确定空调器的当前运行模式为送风模式;
本实施例中,由于空调器在接收到一键开机指令时,存在室外机的继电器还未处于闭合状态的情况,因此,有必要对室外机的继电器状态进行判断,当室外机的继电器处于断开状态时,此时,室外机并未启动,从而无法获取室外环境温度,因此,默认空调器当前运行模式为送风模式。
步骤S70、若室外机启动,则执行步骤S1。
本实施例中,当室外机的继电器处于闭合状态时,此时,室外机启动,则立即获取室外环境温度和用户的体表温度或用户附近的空气温度,并根据室外环境温度和体表温度或用户附近的空气温度进行模式判断,以确定空调器的当前运行模式,并控制空调器执行当前运行模式。
本发明还提供一种空调器,具体实施方式参照上述方法项实施例,此处不再赘述。
以上仅为本发明的优选实施例,并非因此限制本发明的专利范围,凡是利用本发明说明书及附图内容所作的等效结构或等效流程变换,或直接或间接运用在其他相关的技术领域,均同理包括在本发明的专利保护范围内。

Claims (18)

  1. 一种空调器的一键开机控制方法,其特征在于,所述空调器的一键开机控制方法包括以下步骤:
    S1、在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和所述智能穿戴设备检测的温度,确定空调器的当前运行模式;
    S2、控制空调器执行所述当前运行模式。
  2. 如权利要求1所述的空调器的一键开机控制方法,其特征在于,所述步骤S2之前还包括:
    S3、在获取到室内空气湿度时,根据所述智能穿戴设备检测的温度和室内空气湿度计算得到用户的体感温度,并根据所述室外环境温度和所述体感温度,确定空调器的当前运行模式。
  3. 如权利要求2所述的空调器的一键开机控制方法,其特征在于,所述步骤S2之前还包括:
    S4、在接收到一键开机指令时,还获取空调器的设定温度;
    S5、根据所述室外环境温度、智能穿戴设备检测的温度及所述空调器的设定温度,确定空调器的当前运行模式;或
    S6、根据所述室外环境温度、体感温度及所述空调器的设定温度,确定空调器的当前运行模式。
  4. 如权利要求3所述的空调器的一键开机控制方法,其特征在于,所述在接收到一键开机指令时,还获取空调器的设定温度的步骤之后还包括:
    在所述设定温度发生变化时,转入步骤S5或S6,确定所述空调器的实际运行模式。
  5. 如权利要求2所述的空调器的一键开机控制方法,其特征在于,所述步骤S1之前还包括:
    接收智能穿戴设备发送的一键开机指令以及智能穿戴设备检测的体表温度或用户附近的空气温度;或。
    接收所述智能穿戴设备发送的一键开机指令以及智能穿戴设备检测的体表温度或用户附近的空气温度和室内空气湿度。
  6. 如权利要求2所述的空调器的一键开机控制方法,其特征在于,所述步骤S1之前还包括:
    接收所述移动终端发送的一键开机指令和体表温度或用户附近的空气温度;或
    接收所述移动终端发送的一键开机指令、室内空气湿度和体表温度或用户附近的空气温度;
    其中,所述体表温度或用户附近的空气温度由智能穿戴设备检测并发送至所述移动终端。
  7. 如权利要求1所述的空调器的一键开机控制方法,其特征在于,所述步骤S2之后还包括:
    获取当前日期,并在所述当前日期进入预设季节转换期时,执行对应季节的空调器模式控制程序。
  8. 如权利要求1所述的空调器的一键开机控制方法,其特征在于,所述步骤S2之后还包括:
    获取当前位置信息和当前日期,并在所述当前日期进入预设季节转换期时,执行对应位置和季节的空调器模式控制程序。
  9. 如权利要求1所述的空调器的一键开机控制方法,其特征在于,所述步骤S1之后还包括:
    在预定时间后,确定所述空调器的实际运行模式;
    若所述实际运行模式与所述当前运行模式一致,则停止实际运行模式的判断;
    若所述实际运行模式与所述当前运行模式不一致,则重新确定所述空调器的实际运行模式,直至循环次数达到预设次数。
  10. 一种空调器,其特征在于,所述空调器包括:
    获取模块,用于在接收到一键开机指令时,获取室外环境温度以及智能穿戴设备检测的温度,并根据所述室外环境温度和所述智能穿戴设备检测的温度,确定空调器的当前运行模式;
    控制模块,用于控制空调器执行所述当前运行模式。
  11. 如权利要求10所述的空调器,其特征在于,所述获取模块还用于:
    在获取到室内空气湿度时,根据所述智能穿戴设备检测的温度和室内空气湿度计算得到用户的体感温度,并根据所述室外环境温度和所述体感温度,确定空调器的当前运行模式。
  12. 如权利要求11所述的空调器,其特征在于,所述空调器还包括:
    获取模块,还用于在接收到一键开机指令时,还获取空调器的设定温度;
    确定模块,用于根据所述室外环境温度、智能穿戴设备检测的温度及所述空调器的设定温度,确定空调器的当前运行模式;或
    根据所述室外环境温度、体感温度及所述空调器的设定温度,确定空调器的当前运行模式。
  13. 如权利要求12所述的空调器,其特征在于,所述确定模块还用于:
    在所述设定温度发生变化时,重新确定所述空调器的实际运行模式。
  14. 如权利要求11所述的空调器,其特征在于,所述空调器还包括:
    第一接收模块,用于接收智能穿戴设备发送的一键开机指令以及智能穿戴设备检测的体表温度或用户附近的空气温度;或
    接收所述智能穿戴设备发送的一键开机指令以及智能穿戴设备检测的体表温度或用户附近的空气温度和室内空气湿度。
  15. 如权利要求9所述的空调器,其特征在于,所述空调器还包括:
    第二接收模块,用于接收所述移动终端发送的一键开机指令和体表温度或用户附近的空气温度;或
    接收所述移动终端发送的一键开机指令、室内空气湿度和体表温度或用户附近的空气温度;
    其中,所述体表温度或用户附近的空气温度由智能穿戴设备检测并发送至所述移动终端。
  16. 如权利要求10所述的空调器,其特征在于,所述控制模块还用于:
    获取当前日期,并在所述当前日期进入预设季节转换期时,执行对应季节的空调器模式控制程序。
  17. 如权利要求10所述的空调器,其特征在于,所述控制模块还用于:
    获取当前位置信息和当前日期,并在所述当前日期进入预设季节转换期时,执行对应位置和季节的空调器模式控制程序。
  18. 如权利要求10所述的空调器,其特征在于,所述确定模块还用于:
    在预定时间后,确定所述空调器的实际运行模式;
    所述控制模块还用于,若所述实际运行模式与所述当前运行模式一致,则停止实际运行模式的判断;
    所述控制模块还用于,若所述实际运行模式与所述当前运行模式不一致,则重新确定所述空调器的实际运行模式,直至循环次数达到预设次数。
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