CN105627510A - Wearable equipment-based air conditioner energy saving control method and air conditioner - Google Patents
Wearable equipment-based air conditioner energy saving control method and air conditioner Download PDFInfo
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- CN105627510A CN105627510A CN201511034211.8A CN201511034211A CN105627510A CN 105627510 A CN105627510 A CN 105627510A CN 201511034211 A CN201511034211 A CN 201511034211A CN 105627510 A CN105627510 A CN 105627510A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/30—Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/70—Control systems characterised by their outputs; Constructional details thereof
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2120/00—Control inputs relating to users or occupants
- F24F2120/10—Occupancy
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
- F24F11/63—Electronic processing
- F24F11/64—Electronic processing using pre-stored data
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/62—Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
- F24F11/63—Electronic processing
- F24F11/65—Electronic processing for selecting an operating mode
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2120/00—Control inputs relating to users or occupants
- F24F2120/10—Occupancy
- F24F2120/12—Position of occupants
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2120/00—Control inputs relating to users or occupants
- F24F2120/10—Occupancy
- F24F2120/14—Activity of occupants
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- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Fuzzy Systems (AREA)
- Mathematical Physics (AREA)
- Signal Processing (AREA)
- Air Conditioning Control Device (AREA)
Abstract
The invention discloses a wearable equipment-based air conditioner energy saving control method. The method comprises the following steps: determining the distance between wearable equipment and an air conditioner; obtaining the currently monitored physiological parameter of the wearable equipment when the distance between the wearable equipment and the air conditioner is less than a preset distance; judging whether the physiological parameter is in a preset parameter range; and when the physiological parameter is in the preset parameter range, controlling to reduce the running frequency of a compressor of the air conditioner so as to enable the air conditioner to enter an energy saving mode. The invention furthermore discloses the air conditioner. According to the method, the users can decide whether to control the air conditioner to enter the energy saving mode through judging whether the physiological parameter satisfies the preset parameter range, so that the power consumption of the air conditioner is effectively reduced and the aim of automatically saving energy is achieved.
Description
Technical field
The present invention relates to air-conditioning technical field, particularly relate to a kind of air conditioner energy-saving control method based on wearable device and air-conditioner.
Background technology
Electric energy is a kind of power source that air-conditioning equipment is the most frequently used, modern society, and in the face of energy growing tension, energy-saving and emission-reduction increasingly become the hot issue of industry-by-industry, and therefore, air conditioner industry also increasingly payes attention to energy-saving and emission-reduction problem. In prior art, air-conditioner manually selects energy saver mode to reduce the electric energy of its consumption typically via user, intelligent not.
Summary of the invention
Present invention is primarily targeted at a kind of air conditioner energy-saving control method based on wearable device of offer and air-conditioner, it is intended to be effectively reduced the power consumption of air-conditioner, reach the purpose of automatic energy saving.
Air conditioner energy-saving control method based on wearable device provided by the invention comprises the following steps:
Determine the distance between wearable device and air-conditioner;
When distance between described wearable device and described air-conditioner is less than predeterminable range, obtain the physiological parameter that described wearable device is the currently monitored;
Judge whether described physiological parameter is positioned within preset parameter range;
When described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode.
Preferably, after the step of the described distance determined between wearable device and air-conditioner, described air conditioner energy-saving control method also includes:
When distance between described wearable device and described air-conditioner is more than or equal to predeterminable range, the compressor operating frequency controlling described air-conditioner reduces, so that described air-conditioner enters energy saver mode, or controls the shutdown of described air-conditioner.
Preferably, before the step that the compressor operating frequency of described control air-conditioner reduces, the described air conditioner energy-saving control method based on wearable device also includes:
The first temperature parameter that record air-conditioner is currently running;
After the step that the compressor operating frequency of described control air-conditioner reduces, the described air conditioner energy-saving control method based on wearable device also includes:
Record the second temperature parameter that described air-conditioner is currently running;
When described second temperature parameter differs by more than preset temperature threshold value with described first temperature parameter, the running frequency controlling described compressor raises.
Preferably, after the step that the compressor operating frequency of described control air-conditioner reduces, the described air conditioner energy-saving control method based on wearable device also includes:
Continue to obtain the physiological parameter that wearable device is the currently monitored, and determine whether described physiological parameter is positioned within preset parameter range;
When described physiological parameter is positioned at outside described preset parameter range, the running frequency controlling described compressor raises.
Preferably, described physiological parameter includes body temperature parameter, Pulse-Parameters, speed parameter and/or acceleration parameter.
Additionally, the air-conditioner that the present invention further provides includes:
Determine module, for determining the distance between wearable device and air-conditioner;
Acquisition module, during for the distance between described wearable device and described air-conditioner less than predeterminable range, obtains the physiological parameter that described wearable device is the currently monitored;
Judge module, is used for judging whether described physiological parameter is positioned within preset parameter range;
Controlling module, for when described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode.
Preferably, when described control module is additionally operable to the distance between described wearable device and described air-conditioner more than or equal to predeterminable range, the compressor operating frequency controlling described air-conditioner reduces, so that described air-conditioner enters energy saver mode, or controls the shutdown of described air-conditioner.
Preferably, described air-conditioner also includes logging modle;
Described logging modle is for, before reducing in compressor operating frequency, recording the first temperature parameter that air-conditioner is currently running;
Described logging modle is additionally operable to, after compressor operating frequency reduces, record the second temperature parameter that described air-conditioner is currently running;
Described control module is additionally operable to when described second temperature parameter differs by more than preset temperature threshold value with described first temperature parameter, and the running frequency controlling described compressor raises.
Preferably, described acquisition module is additionally operable to after compressor operating frequency reduces, and continues to obtain the physiological parameter that wearable device is the currently monitored, and determines whether described physiological parameter is positioned within preset parameter range;
Described control module is additionally operable to when described physiological parameter is positioned at outside described preset parameter range, and the running frequency controlling described compressor raises.
Preferably, described physiological parameter includes body temperature parameter, Pulse-Parameters, speed parameter and/or acceleration parameter.
The physiological parameter that the present invention is the currently monitored by obtaining wearable device, and judge whether described physiological parameter is positioned within preset parameter range, when described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode, thus significantly reducing the power consumption of air-conditioner, reach the purpose of automatic energy saving.
Accompanying drawing explanation
Fig. 1 is the present invention schematic flow sheet based on the air conditioner energy-saving control method first embodiment of wearable device;
Fig. 2 is the present invention schematic flow sheet based on air conditioner energy-saving control method the 3rd embodiment of wearable device;
Fig. 3 is the present invention schematic flow sheet based on air conditioner energy-saving control method the 4th embodiment of wearable device;
Fig. 4 is the high-level schematic functional block diagram of air-conditioner first embodiment of the present invention;
Fig. 5 is the high-level schematic functional block diagram of air-conditioner the 3rd embodiment of the present invention.
The realization of the object of the invention, functional characteristics and advantage will in conjunction with the embodiments, are described further with reference to accompanying drawing.
Detailed description of the invention
Should be appreciated that specific embodiment described herein is only in order to explain the present invention, is not intended to limit the present invention.
The present invention provides a kind of air conditioner energy-saving control method based on wearable device, and this air conditioner energy-saving control method can realize based on the controller of air-conditioner. Being the present invention schematic flow sheet based on the air conditioner energy-saving control method first embodiment of wearable device with reference to Fig. 1, Fig. 1, the air conditioner energy-saving control method based on wearable device that the present invention proposes comprises the following steps:
Step S10, it is determined that the distance between wearable device and air-conditioner;
In the present embodiment, wearable device can be Intelligent bracelet, intelligent watch etc. Wearable device can communicate to connect wirelessly and between air-conditioner, for instance, it is possible to communicated to connect by the mode such as bluetooth, WIFI. Additionally, wearable device can also pass through high in the clouds sets up communication connection with air-conditioner.
In the present embodiment, wearable device can obtain GPS information, then sends GPS information to air-conditioner, and air-conditioner determines the distance between wearable device according to the GPS information received. Or, wearable device can also send ultrasonic signal to air-conditioner, and air-conditioner is provided with the receiver module for received ultrasonic signal, and namely propagation duration and spread speed based on ultrasonic signal can calculate the distance between wearable device and air-conditioner. Or, air-conditioner is also provided with range sensor, detects the distance between wearable device and air-conditioner by range sensor. Or, wearable device can also launch wireless signal to air-conditioner, and wireless signal can be Bluetooth signal, infrared signal or WIFI signal etc., and air-conditioner determines the distance between wearable device and air-conditioner according to the signal intensity of the wireless signal received.
Step S20, when the distance between described wearable device and described air-conditioner is less than predeterminable range, obtains the physiological parameter that described wearable device is the currently monitored;
Optionally, air-conditioner only obtains the physiological parameter that wearable device is the currently monitored under open state.
Physiological parameter can include body temperature parameter, Pulse-Parameters, speed parameter and/or acceleration parameter etc. Specifically can select according to actual needs.
Predeterminable range can be configured according to actual needs, for instance, it is possible to it is 15 meters, 20 meters, 25 meters etc.
Step S30, it is judged that whether described physiological parameter is positioned within preset parameter range;
In the present embodiment, preset parameter range can be configured according to actual needs. For body temperature parameter, preset body temperature parameter area and such as can be less than 37 DEG C. Or for acceleration parameter or speed parameter, when acceleration parameter or speed parameter are less than preset value, then it is assumed that this acceleration parameter or speed parameter are positioned within preset parameter range.
Optionally, it is also possible to judge whether described physiological parameter is positioned within preset parameter range according to air conditioning operating mode. Such as, the preset parameter range that refrigeration mode and heating mode can be corresponding different. When refrigeration mode, preset body temperature parameter area and such as can be less than 36.8 DEG C; When heating mode, preset body temperature parameter area and such as can be more than 37 DEG C.
When described physiological parameter is positioned within described preset parameter range, perform step S41;
Step S41, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode.
It should be noted that, when described physiological parameter is positioned at outside described preset parameter range, perform step S42;
Step S42, the compressor operating frequency controlling air-conditioner is constant.
In the present embodiment, the mode controlling the reduction of compressor operating frequency can be configured according to actual needs, predeterminated frequency value can be reduced every time, such as, predeterminated frequency value can be 5Hz, and before controlling the reduction of compressor operating frequency, the running frequency of compressor is 100Hz, when judging that physiological parameter is positioned within described preset parameter range, then the running frequency of compressor can be reduced to 95Hz.
Optionally, can also after the compressor operating frequency controlling air-conditioner reduces, judge whether to arrive preset duration, when arriving preset duration, again obtain the physiological parameter of wearable device current detection, and judge whether described physiological parameter is positioned within preset parameter range, when described physiological parameter is positioned within preset parameter range, then again reduce the running frequency of described compressor; When described physiological parameter is positioned at outside preset parameter range, then raise the running frequency of compressor, for instance, it is possible to raise predeterminated frequency value, or be increased to the running frequency before compressor operating frequency reduces. Then when arriving preset duration, then obtain the physiological parameter that wearable device is the currently monitored, and reduce or raise the running frequency of compressor according to physiological parameter.
The present invention is determined by the distance between wearable device and air-conditioner, and the distance between wearable device and described air-conditioner less than predeterminable range time, obtain the physiological parameter that wearable device is the currently monitored, and judge whether described physiological parameter is positioned within preset parameter range, when described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode, thus significantly reducing the power consumption of air-conditioner, reach the purpose of automatic energy saving.
Further, based on the present invention first embodiment based on the air conditioner energy-saving control method of wearable device, the invention allows for the second embodiment of the air conditioner energy-saving control method based on wearable device, after step slo, the described air conditioner energy-saving control method based on wearable device also includes: when the distance between described wearable device and described air-conditioner is more than or equal to predeterminable range, the compressor operating frequency controlling described air-conditioner reduces, so that described air-conditioner enters energy saver mode, or control the shutdown of described air-conditioner.
It should be noted that, when the distance between described wearable device and described air-conditioner is more than or equal to predeterminable range, represents that user is current no longer indoor, therefore can directly control air-conditioner and enter energy saver mode or shutdown.
The present embodiment is by when the distance judged between wearable device and air-conditioning is more than or equal to predeterminable range, directly controlling air-conditioner and enter energy saver mode or shutdown, effectively further saved electric energy.
Further, based on the present invention first or second embodiments based on the air conditioner energy-saving control method of wearable device, the invention allows for the 3rd embodiment of the air conditioner energy-saving control method based on wearable device, with reference to Fig. 2, Fig. 2 is the present invention schematic flow sheet based on air conditioner energy-saving control method the 3rd embodiment of wearable device, before step S41, the described air conditioner energy-saving control method based on wearable device also includes:
Step S50, the first temperature parameter that record air-conditioner is currently running;
Such as, air-conditioner is currently at refrigeration mode, and before step S30, the currently running design temperature of air-conditioner is 23 DEG C, then described first temperature parameter recorded is 23 DEG C.
After described step S41, the described air conditioner energy-saving control method based on wearable device also includes:
Step S60, records the second temperature parameter that described air-conditioner is currently running;
In the present embodiment, it is possible to perform to start timing after step S30, and when reaching preset duration, then perform step S60, so that reduce after certain time length in compressor operating frequency, record the second temperature parameter starting so that the second temperature parameter of record is more stable. Such as, preset duration can be 20 minutes, and the second temperature parameter of record can be 26 DEG C.
After performing step S41, can also obtain in real time and record the second temperature parameter.
Step S70, when described second temperature parameter differs by more than preset temperature threshold value with described first temperature parameter, the running frequency controlling described compressor raises.
It should be noted that, when described second temperature parameter differs less than or equal to preset temperature threshold value with described first temperature parameter, the running frequency keeping compressor is constant.
Preset temperature threshold value can be configured according to actual needs, for instance, it is possible to it is 2 DEG C or 3 DEG C. The present embodiment illustrates for 2 DEG C.
Owing to the second temperature parameter is 26 DEG C, first temperature parameter is 23 DEG C, therefore, second temperature parameter and the first temperature parameter difference are 3 DEG C, more than preset temperature threshold value 2 DEG C, represent that compressor makes the temperature of air-conditioner bigger with the temperature difference of user's actual set after reducing running frequency, it is thus desirable to readjust the running frequency of compressor, namely, again the running frequency of compressor is raised, so that the temperature control parameter of air-conditioner is unlikely to differ too big with the actual set temperature of user, make user imperceptible or fundamental sensation is less than the change of the desired temperature of air-conditioner, thus under the premise of automatic energy saving, the state modulator making air-conditioner meets the comfort need of user more, further increase the comfort level that air-conditioner regulates.
Further, based on the present invention the first to the 3rd any embodiment based on the air conditioner energy-saving control method of wearable device, the invention allows for the 4th embodiment of the air conditioner energy-saving control method based on wearable device, with reference to Fig. 3, Fig. 3 is the present invention schematic flow sheet based on air conditioner energy-saving control method the 4th embodiment of wearable device, after step S41, the described air conditioner energy-saving control method based on wearable device also includes:
Step S80, continues to obtain the physiological parameter that wearable device is the currently monitored, and determines whether described physiological parameter is positioned within preset parameter range;
In the present embodiment, obtain physiological parameter and determine whether physiological parameter is positioned at the mode of preset parameter range and is referred to above-mentioned first embodiment, does not repeat them here.
Step S90, when described physiological parameter is positioned at outside described preset parameter range, the running frequency controlling described compressor raises.
It should be noted that, when described physiological parameter is positioned within described preset parameter range, the running frequency keeping compressor is constant.
In the present embodiment, when physiological parameter is positioned at outside preset parameter range, represent that the currently running frequency of cooler compressor can not meet the demand of user, therefore cooler compressor needs again to raise its running frequency, user's body is made to be in comparatively comfortable state all the time, thus under the premise of automatic energy saving so that the state modulator of air-conditioner meets the comfort need of user more, further increases the comfort level that air-conditioner regulates.
The present invention further provides a kind of air-conditioner.
With reference to the high-level schematic functional block diagram that Fig. 4, Fig. 4 are air-conditioner first embodiment of the present invention, air-conditioner provided by the invention includes:
Determine module 10, for determining the distance between wearable device and air-conditioner;
In the present embodiment, wearable device can be Intelligent bracelet, intelligent watch etc. Wearable device can communicate to connect wirelessly and between air-conditioner, for instance, it is possible to communicated to connect by the mode such as bluetooth, WIFI. Additionally, wearable device can also pass through high in the clouds sets up communication connection with air-conditioner.
In the present embodiment, wearable device can obtain GPS information, then sends GPS information to air-conditioner, and air-conditioner determines the distance between wearable device according to the GPS information received. Or, wearable device can also send ultrasonic signal to air-conditioner, and air-conditioner is provided with the receiver module for received ultrasonic signal, and namely propagation duration and spread speed based on ultrasonic signal can calculate the distance between wearable device and air-conditioner. Or, air-conditioner is also provided with range sensor, detects the distance between wearable device and air-conditioner by range sensor. Or, wearable device can also launch wireless signal to air-conditioner, and wireless signal can be Bluetooth signal, infrared signal or WIFI signal etc., and air-conditioner determines the distance between wearable device and air-conditioner according to the signal intensity of the wireless signal received.
Acquisition module 20, for obtaining the physiological parameter that wearable device is the currently monitored;
Optionally, air-conditioner only obtains the physiological parameter that wearable device is the currently monitored under open state.
Physiological parameter can include body temperature parameter, Pulse-Parameters, speed parameter and/or acceleration parameter etc. Specifically can select according to actual needs.
Predeterminable range can be configured according to actual needs, for instance, it is possible to it is 15 meters, 20 meters, 25 meters etc.
Judge module 30, is used for judging whether described physiological parameter is positioned within preset parameter range;
In the present embodiment, preset parameter range can be configured according to actual needs. For body temperature parameter, preset body temperature parameter area and such as can be less than 37 DEG C. Or for acceleration parameter or speed parameter, when acceleration parameter or speed parameter are less than preset value, then it is assumed that this acceleration parameter or speed parameter are positioned within preset parameter range.
Optionally, it is also possible to judge whether described physiological parameter is positioned within preset parameter range according to air conditioning operating mode. Such as, the preset parameter range that refrigeration mode and heating mode can be corresponding different. When refrigeration mode, preset body temperature parameter area and such as can be less than 36.8 DEG C; When heating mode, preset body temperature parameter area and such as can be more than 37 DEG C.
Controlling module 40, for when described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode.
It should be noted that, when described physiological parameter is positioned at outside described preset parameter range, the compressor operating frequency that control module 30 controls air-conditioner is constant.
In the present embodiment, the mode controlling the reduction of compressor operating frequency can be configured according to actual needs, predeterminated frequency value can be reduced every time, such as, predeterminated frequency value can be 5Hz, and before controlling the reduction of compressor operating frequency, the running frequency of compressor is 100Hz, when judging that physiological parameter is positioned within described preset parameter range, then the running frequency of compressor can be reduced to 95Hz.
Optionally, can also after the compressor operating frequency controlling air-conditioner reduces, judge whether to arrive preset duration, when arriving preset duration, again obtain the physiological parameter of wearable device current detection, and judge whether described physiological parameter is positioned within preset parameter range, when described physiological parameter is positioned within preset parameter range, then again reduce the running frequency of described compressor; When described physiological parameter is positioned at outside preset parameter range, then raise the running frequency of compressor, for instance, it is possible to raise predeterminated frequency value, or be increased to the running frequency before compressor operating frequency reduces. Then when arriving preset duration, then obtain the physiological parameter that wearable device is the currently monitored, and reduce or raise the running frequency of compressor according to physiological parameter.
The present invention is determined by the distance between wearable device and air-conditioner, and the distance between wearable device and described air-conditioner less than predeterminable range time, obtain the physiological parameter that wearable device is the currently monitored, and judge whether described physiological parameter is positioned within preset parameter range, when described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode, thus significantly reducing the power consumption of air-conditioner, reach the purpose of automatic energy saving.
Further, first embodiment based on air-conditioner of the present invention, the invention allows for the second embodiment of air-conditioner, when described control module 40 is additionally operable to the distance between described wearable device and described air-conditioner more than or equal to predeterminable range, the compressor operating frequency controlling described air-conditioner reduces, so that described air-conditioner enters energy saver mode, or control the shutdown of described air-conditioner.
It should be noted that, when the distance between described wearable device and described air-conditioner is more than or equal to predeterminable range, represents that user is current no longer indoor, therefore can directly control air-conditioner and enter energy saver mode or shutdown.
The present embodiment is by when the distance judged between wearable device and air-conditioning is more than or equal to predeterminable range, directly controlling air-conditioner and enter energy saver mode or shutdown, effectively further saved electric energy.
Further, based on the first or second embodiments of air-conditioner of the present invention, the invention allows for the 3rd embodiment of air-conditioner, with reference to the high-level schematic functional block diagram that Fig. 5, Fig. 5 are air-conditioner the 3rd embodiment of the present invention, described air-conditioner also includes logging modle 50;
Described logging modle 50 is for, before reducing in compressor operating frequency, recording the first temperature parameter that air-conditioner is currently running;
Such as, air-conditioner is currently at refrigeration mode, and before the compressor operating frequency controlling air-conditioner reduces, the currently running design temperature of air-conditioner is 23 DEG C, then described first temperature parameter recorded is 23 DEG C.
Described logging modle 50 is additionally operable to, after compressor operating frequency reduces, record the second temperature parameter that described air-conditioner is currently running;
In the present embodiment, timing can be started after compressor operating frequency reduces, and when reaching preset duration, then record the second temperature parameter that described air-conditioner is currently running, so that after compressor operating frequency reduces certain time length, record the second temperature parameter starting so that the second temperature parameter of record is more stable. Such as, preset duration can be 20 minutes, and the second temperature parameter of record can be 26 DEG C.
After reducing in compressor operating frequency, can also obtain in real time and record the second temperature parameter.
Described control module 30 is additionally operable to when described second temperature parameter differs by more than preset temperature threshold value with described first temperature parameter, and the running frequency controlling described compressor raises.
It should be noted that, when described second temperature parameter differs less than or equal to preset temperature threshold value with described first temperature parameter, the running frequency keeping compressor is constant.
Preset temperature threshold value can be configured according to actual needs, for instance, it is possible to it is 2 DEG C or 3 DEG C. The present embodiment illustrates for 2 DEG C.
Owing to the second temperature parameter is 26 DEG C, first temperature parameter is 23 DEG C, therefore, second temperature parameter and the first temperature parameter difference are 3 DEG C, more than preset temperature threshold value 2 DEG C, represent that compressor makes the temperature of air-conditioner bigger with the temperature difference of user's actual set after reducing running frequency, it is thus desirable to readjust the running frequency of compressor, namely, again the running frequency of compressor is raised, so that the temperature control parameter of air-conditioner is unlikely to differ too big with the actual set temperature of user, make user imperceptible or fundamental sensation is less than the change of the desired temperature of air-conditioner, thus under the premise of automatic energy saving, the state modulator making air-conditioner meets the comfort need of user more, further increase the comfort level that air-conditioner regulates.
Further, the first to the 3rd any embodiment based on air-conditioner of the present invention, the invention allows for the 4th embodiment of air-conditioner, described acquisition module 10 is additionally operable to after compressor operating frequency reduces, continue to obtain the physiological parameter that wearable device is the currently monitored, and determine whether described physiological parameter is positioned within preset parameter range;
In the present embodiment, obtain physiological parameter and determine whether physiological parameter is positioned at the mode of preset parameter range and is referred to the first embodiment of above-mentioned air-conditioner, does not repeat them here.
Described control module 30 is additionally operable to when described physiological parameter is positioned at outside described preset parameter range, and the running frequency controlling described compressor raises.
It should be noted that, when described physiological parameter is positioned within described preset parameter range, the running frequency keeping compressor is constant.
In the present embodiment, when physiological parameter is positioned at outside preset parameter range, represent that the currently running frequency of cooler compressor can not meet the demand of user, therefore cooler compressor needs again to raise its running frequency, user's body is made to be in comparatively comfortable state all the time, thus under the premise of automatic energy saving so that the state modulator of air-conditioner meets the comfort need of user more, further increases the comfort level that air-conditioner regulates.
It should be noted that, in this article, term " includes ", " comprising " or its any other variant are intended to comprising of nonexcludability, so that include the process of a series of key element, method, article or device not only include those key elements, but also include other key elements being not expressly set out, or also include the key element intrinsic for this process, method, article or device. When there is no more restriction, statement " including ... " key element limited, it is not excluded that there is also other identical element in including the process of this key element, method, article or device.
The invention described above embodiment sequence number, just to describing, does not represent the quality of embodiment.
Through the above description of the embodiments, those skilled in the art is it can be understood that can add the mode of required general hardware platform by software to above-described embodiment method and realize, hardware can certainly be passed through, but in a lot of situation, the former is embodiment more preferably. Based on such understanding, the part that prior art is contributed by technical scheme substantially in other words can embody with the form of software product, this computer software product is stored in a storage medium (such as ROM/RAM, magnetic disc, CD), including some instructions with so that a station terminal equipment (can be mobile phone, computer, server, air-conditioner, or the network equipment etc.) perform the method described in each embodiment of the present invention.
It addition, relate to the description of " first ", " second " etc. in invention only for descriptive purposes, and it is not intended that instruction or imply its relative importance or the implicit quantity indicating indicated technical characteristic. Thus, define " first ", the feature of " second " can express or implicitly include at least one this feature. Additionally; technical scheme between each embodiment can be combined with each other; but must be based on those of ordinary skill in the art are capable of; when technical scheme combination occur conflicting maybe cannot realize time people should think that the combination of this technical scheme is absent from, also not within the protection domain of application claims.
These are only the preferred embodiments of the present invention; not thereby the scope of the claims of the present invention is limited; every equivalent structure utilizing description of the present invention and accompanying drawing content to make or equivalence flow process conversion; or directly or indirectly it is used in other relevant technical fields, all in like manner include in the scope of patent protection of the present invention.
Claims (10)
1. the air conditioner energy-saving control method based on wearable device, it is characterised in that the described air conditioner energy-saving control method based on wearable device comprises the following steps:
Determine the distance between wearable device and air-conditioner;
When distance between described wearable device and described air-conditioner is less than predeterminable range, obtain the physiological parameter that described wearable device is the currently monitored;
Judge whether described physiological parameter is positioned within preset parameter range;
When described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode.
2. the air conditioner energy-saving control method based on wearable device as claimed in claim 1, it is characterised in that after the step of the described distance determined between wearable device and air-conditioner, described air conditioner energy-saving control method also includes:
When distance between described wearable device and described air-conditioner is more than or equal to predeterminable range, the compressor operating frequency controlling described air-conditioner reduces, so that described air-conditioner enters energy saver mode, or controls the shutdown of described air-conditioner.
3. the air conditioner energy-saving control method based on wearable device as claimed in claim 1 or 2, it is characterised in that before the step that the compressor operating frequency of described control air-conditioner reduces, the described air conditioner energy-saving control method based on wearable device also includes:
The first temperature parameter that record air-conditioner is currently running;
After the step that the compressor operating frequency of described control air-conditioner reduces, the described air conditioner energy-saving control method based on wearable device also includes:
Record the second temperature parameter that described air-conditioner is currently running;
When described second temperature parameter differs by more than preset temperature threshold value with described first temperature parameter, the running frequency controlling described compressor raises.
4. the air conditioner energy-saving control method based on wearable device as claimed in claim 1 or 2, it is characterised in that after the step that the compressor operating frequency of described control air-conditioner reduces, the described air conditioner energy-saving control method based on wearable device also includes:
Continue to obtain the physiological parameter that wearable device is the currently monitored, and determine whether described physiological parameter is positioned within preset parameter range;
When described physiological parameter is positioned at outside described preset parameter range, the running frequency controlling described compressor raises.
5. the air conditioner energy-saving control method based on wearable device as claimed in claim 1 or 2, it is characterised in that described physiological parameter includes body temperature parameter, Pulse-Parameters, speed parameter and/or acceleration parameter.
6. an air-conditioner, it is characterised in that described air-conditioner includes:
Determine module, for determining the distance between wearable device and air-conditioner;
Acquisition module, during for the distance between described wearable device and described air-conditioner less than predeterminable range, obtains the physiological parameter that described wearable device is the currently monitored;
Judge module, is used for judging whether described physiological parameter is positioned within preset parameter range;
Controlling module, for when described physiological parameter is positioned within described preset parameter range, the compressor operating frequency controlling air-conditioner reduces, so that described air-conditioner enters energy saver mode.
7. air-conditioner as claimed in claim 6, it is characterized in that, when described control module is additionally operable to the distance between described wearable device and described air-conditioner more than or equal to predeterminable range, the compressor operating frequency controlling described air-conditioner reduces, so that described air-conditioner enters energy saver mode, or control the shutdown of described air-conditioner.
8. air-conditioner as claimed in claims 6 or 7, it is characterised in that described air-conditioner also includes logging modle;
Described logging modle is for, before reducing in compressor operating frequency, recording the first temperature parameter that air-conditioner is currently running;
Described logging modle is additionally operable to, after compressor operating frequency reduces, record the second temperature parameter that described air-conditioner is currently running;
Described control module is additionally operable to when described second temperature parameter differs by more than preset temperature threshold value with described first temperature parameter, and the running frequency controlling described compressor raises.
9. air-conditioner as claimed in claims 6 or 7, it is characterized in that, described acquisition module is additionally operable to after compressor operating frequency reduces, and continues to obtain the physiological parameter that wearable device is the currently monitored, and determines whether described physiological parameter is positioned within preset parameter range;
Described control module is additionally operable to when described physiological parameter is positioned at outside described preset parameter range, and the running frequency controlling described compressor raises.
10. air-conditioner as claimed in claims 6 or 7, it is characterised in that described physiological parameter includes body temperature parameter, Pulse-Parameters, speed parameter and/or acceleration parameter.
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