WO2020125807A1 - 智能吹风机及其作业控制和信息显示方法、存储介质 - Google Patents

智能吹风机及其作业控制和信息显示方法、存储介质 Download PDF

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Publication number
WO2020125807A1
WO2020125807A1 PCT/CN2019/129392 CN2019129392W WO2020125807A1 WO 2020125807 A1 WO2020125807 A1 WO 2020125807A1 CN 2019129392 W CN2019129392 W CN 2019129392W WO 2020125807 A1 WO2020125807 A1 WO 2020125807A1
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WO
WIPO (PCT)
Prior art keywords
hair dryer
airflow
blown
smart
information
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Application number
PCT/CN2019/129392
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English (en)
French (fr)
Inventor
朱涛
徐锡胜
Original Assignee
添可智能科技有限公司
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Publication date
Priority claimed from CN201910887334.8A external-priority patent/CN111345568A/zh
Application filed by 添可智能科技有限公司 filed Critical 添可智能科技有限公司
Priority to US17/417,722 priority Critical patent/US12029299B2/en
Publication of WO2020125807A1 publication Critical patent/WO2020125807A1/zh

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    • AHUMAN NECESSITIES
    • A45HAND OR TRAVELLING ARTICLES
    • A45DHAIRDRESSING OR SHAVING EQUIPMENT; EQUIPMENT FOR COSMETICS OR COSMETIC TREATMENTS, e.g. FOR MANICURING OR PEDICURING
    • A45D20/00Hair drying devices; Accessories therefor
    • A45D20/04Hot-air producers
    • A45D20/08Hot-air producers heated electrically
    • A45D20/10Hand-held drying devices, e.g. air douches
    • A45D20/12Details thereof or accessories therefor, e.g. nozzles, stands
    • AHUMAN NECESSITIES
    • A45HAND OR TRAVELLING ARTICLES
    • A45DHAIRDRESSING OR SHAVING EQUIPMENT; EQUIPMENT FOR COSMETICS OR COSMETIC TREATMENTS, e.g. FOR MANICURING OR PEDICURING
    • A45D20/00Hair drying devices; Accessories therefor
    • A45D20/04Hot-air producers
    • A45D20/08Hot-air producers heated electrically
    • A45D20/10Hand-held drying devices, e.g. air douches
    • AHUMAN NECESSITIES
    • A45HAND OR TRAVELLING ARTICLES
    • A45DHAIRDRESSING OR SHAVING EQUIPMENT; EQUIPMENT FOR COSMETICS OR COSMETIC TREATMENTS, e.g. FOR MANICURING OR PEDICURING
    • A45D20/00Hair drying devices; Accessories therefor
    • A45D20/04Hot-air producers
    • A45D20/08Hot-air producers heated electrically
    • A45D20/10Hand-held drying devices, e.g. air douches
    • A45D20/12Details thereof or accessories therefor, e.g. nozzles, stands
    • A45D2020/126Stands therefor
    • A45D2020/128Stands therefor involving features of the hand-held hair dryer

Definitions

  • the present application relates to the field of hair dryers, in particular to an intelligent hair dryer, its operation control and information display method, and storage medium.
  • Hair dryers are widely used in daily life. They are mainly used for hair drying and styling. They can also be used for local drying, heating, and physiotherapy in laboratories, physiotherapy rooms, industrial production, and art. Its working principle is that the rotor is driven by the motor to drive the fan blades to rotate. When the fan blades rotate, air is sucked in from the air inlet, and the resulting centrifugal air flow is blown out by the front nozzle of the fan. When the air passes through, if the heating wire installed on the heating bracket in the tuyere has been energized to become hot, then blowing out hot air; if the selection switch does not make the heating wire energized to generate heat, then blowing out cold wind.
  • the hair dryer is used to achieve drying and shaping.
  • the user selects the heat position and the air volume position by himself.
  • a large amount of air is required to quickly blow away the moisture, that is, first blow with hot air to about 60% Dry, and then blow it to 80% dry with cold wind, and then wait for natural drying.
  • the user needs to adjust the air volume and heat several times, which obviously increases the user's troubles of repeatedly adjusting the gear, resulting in a poor user experience.
  • the user cannot accurately perceive the current state of the blown object of the hair dryer, and can only roughly perceive the current state of the blown object of the hair dryer, resulting in a poor user experience.
  • the present application provides an intelligent hair dryer and its operation control method to solve the problem that the user needs to repeatedly adjust the gear in the actual process of using the existing hair dryer, and also enhances the user's experience.
  • This application provides an intelligent hair dryer, including: airflow detection channel, sensor, control system and main air duct;
  • the airflow detection channel is provided on at least one side of the main air duct, and the air inlet opening of the airflow detection channel faces the direction of the main air duct of the smart blower, and can collect the airflow that has been in contact with the blown object;
  • the sensor is disposed in the airflow detection channel, and is used to detect status information of the airflow that has been in contact with the blown object;
  • the control system is used to receive the status information of the airflow and use the status information of the airflow to control the working status of the smart hair dryer.
  • control system uses the state information of the airflow to control the working state of the smart hair dryer, it is specifically used to:
  • the blowing parameters of the smart blower required by the blown object obtain the blowing parameters of the smart blower required by the blown object; and control the rotation speed of the fan unit and/or the heating temperature of the heating unit in the main channel to change the
  • the blowing parameters of the smart hair dryer are adjusted to the blowing parameters of the smart hair dryer required by the smart hair dryer according to the object to be blown.
  • the airflow state information includes at least one of the following information: airflow temperature information and airflow humidity information.
  • the airflow detection channel is connected to the upstream area of the fan unit, and the air outlet of the main air duct is located in the downstream area of the fan unit.
  • the area of the air outlet of the main air duct is larger than the area of the air inlet of the airflow detection channel.
  • the main air duct further includes a main air inlet connected to the upstream area, the main air inlet is located at the rear end of the smart hair dryer, and the air outlet is located at the front end of the smart hair dryer.
  • the airflow detection channel collects the airflow in contact with the blown object through the air inlet, and the sensor receives the airflow in contact with the blown object and analyzes the state of the airflow in contact with the blown object information.
  • the airflow detection channel has a variable cross-sectional structure with a wide front and a narrow front, and the sensor is disposed on the rear side.
  • At least two sensors which are arranged at a set distance in the airflow direction of the airflow detection channel.
  • the number of the airflow detection channels is set to one, two or more.
  • the senor further includes a distance sensor, and the airflow state information includes an airflow movement distance.
  • This application additionally provides a job control method, including:
  • blowing parameters of the smart hair dryer required by the blown object according to the state estimation information of the blown object, wherein the blowing parameters of the smart blower include the wind speed and the temperature of the blow;
  • the airflow state information includes at least one of airflow temperature information and airflow humidity information
  • the blown object state estimation information includes both blown object temperature estimation information and humidity estimation information At least one of them.
  • the method further includes obtaining the current blowing parameters of the smart hair dryer in real time, and judging whether to adjust the blowing of the smart hair dryer according to the current blowing parameters of the smart hair dryer and the blowing parameters of the smart hair dryer required by the blown object parameter;
  • the current blowing parameters of the smart hair dryer are less than the blowing parameters of the smart hair dryer required by the object to be blown, the current blowing parameters of the smart hair dryer are enhanced, otherwise, the current blowing parameters of the smart hair dryer are weakened.
  • the present application provides an intelligent hair dryer, including: an air flow detection channel, a sensor, a control system, and a main air duct; a fan unit for generating air flow and a heating unit for heating the air flow are provided in the main air duct; the air flow
  • the detection channel is provided on at least one side of the main air channel, and the air inlet opening of the air flow detection channel faces the blowing direction of the main air channel of the smart blower;
  • the sensor is provided in the air flow detection channel, and the sensor is used For detecting airflow status information;
  • the control system is used to receive the detection result output by the sensor, and use the detection result for adjusting the rotation speed of the fan unit and/or the heating temperature of the heating unit.
  • the application of the intelligent hair dryer of this application can ensure that users do not need to worry about repeatedly adjusting the gear of the hair dryer during use.
  • the intelligent hair dryer of this application uses an intelligent mode, that is, a sensor and a control system are installed inside the hair dryer. The automatic control of the work of the intelligent hair dryer enhances the user experience.
  • This application also provides a job control method, which is based on the above-mentioned intelligent hair dryer, and automatically controls the work of the hair dryer, thereby facilitating the user's use.
  • the present application also provides an intelligent hair dryer to solve the problem that the user cannot accurately know the current state of the blown object of the hair dryer during the use of the existing hair dryer, and also enhances the user experience.
  • the application also provides another intelligent hair dryer and its operation control method, which can save the trouble of repeatedly adjusting the gear.
  • the present application provides an intelligent hair dryer, including: a fuselage, a main air duct provided in the fuselage, an airflow detection channel, a sensor and a control system, and an indicating device disposed outside the fuselage; wherein,
  • the main air duct is provided with an air outlet in the fuselage, and an air flow generating device is provided inside;
  • the air inlet of the airflow detection channel and the air outlet of the main air channel are provided on the same side of the fuselage;
  • the sensor is disposed in the airflow detection channel and connected with the control system, and is used for detecting status information of the airflow entering the airflow detection channel;
  • the control system is connected to the indicating device, and is used for controlling the indicating device to indicate the current state of the blown object according to the state information of the airflow.
  • the shape of the indicator device is set to any one of the following: a continuous or discontinuous ring structure surrounding the fuselage, and a strip structure provided along the outer side of the fuselage.
  • the senor is a temperature sensor or a humidity sensor; correspondingly, the current state is the current humidity state or temperature state of the blown object.
  • it also includes a distance sensor provided on the side of the main air duct outlet of the fuselage;
  • the distance sensor is connected to the control system and used to detect the distance between the object to be blown and the air outlet;
  • the control system is further used for controlling the indicating device to indicate the distance between the blown object and the air outlet according to the detection result of the distance sensor.
  • it further includes a working state information collection module of the hair dryer provided in the body, and the working state information collection module of the hair dryer is connected to the control system;
  • the control system is also used to control the indicating device to indicate the working state of the hair dryer according to the working state information of the hair dryer collected by the working state collection module;
  • the working state information includes at least one of the following: blowing temperature, blowing wind speed, blowing time, or motor power.
  • control system is specifically used to: according to the information collected by the hair dryer working state information collection module, control the indicating device to indicate the current state of the blown object or the working state of the hair dryer in any of the following ways: gradual display , Monochrome display, gradient flashing or monochrome flashing.
  • control system is specifically configured to: according to the detection result of the sensor, control the indicating device to indicate the current device of the blown object in any of the following ways: gradient display, monochrome display, gradient flashing Or monochrome flashing.
  • the present application also provides an intelligent hair dryer, including: a body, a main air duct provided in the body, an airflow detection channel, a sensor and a control system, and a display driving device provided in the body; wherein,
  • the main air duct is provided with an air outlet in the fuselage, and an air flow generating device is provided inside;
  • the air inlet of the airflow detection channel and the air outlet of the main air channel are provided on the same side of the fuselage;
  • the sensor is disposed in the airflow detection channel and connected to the processor, and is used to detect the status information of the airflow entering the airflow detection channel;
  • the display driving device is connected to the processor and used to output the current status information of the blown object to the display terminal according to the status information of the airflow; or to the display terminal according to the working status information of the blower obtained by the control system Output the working status information of the hair dryer.
  • it further includes a display screen disposed on the outside of the fuselage, the display screen is connected to the display driving device, and the display screen is disposed on an end of the outside of the fuselage opposite to the air outlet.
  • a wireless communication module is further included, and the wireless communication module is connected to the display driving device, and is used to output the output information of the display driving device to an intelligent terminal or intelligent robot connected by an electrical signal.
  • it further includes an indicating device provided on the outside of the fuselage, the indicating device being connected to the processor and used to indicate the current state of the blown object or the working state of the blower according to the detection result of the sensor.
  • This application provides a method for automatically controlling the work of an intelligent hair dryer, including:
  • the smart hair dryer is operated according to the initial default power.
  • the method further includes:
  • the acquiring current state information of the blown object includes:
  • the state estimation information of the blown object is estimated based on the state information of the airflow, and the state estimation information is used as the current state information of the blown object.
  • the airflow state information includes at least one of airflow temperature information and airflow humidity information
  • the blown object state estimation information includes both blown object temperature estimation information and humidity estimation information At least one of them.
  • An embodiment of the present application also provides an information display method, including:
  • the current state of the blown object is displayed.
  • the present application provides an intelligent hair dryer, including: a fuselage, a main air duct provided in the fuselage, an airflow detection channel, a sensor and a control system, and an indicating device provided outside the fuselage; wherein the main air duct is located in the fuselage An air outlet is opened, and an air flow generating device is provided inside; the air inlet of the air flow detection channel and the air outlet of the main air duct are provided on the same side of the fuselage; the sensor is provided in the air flow detection channel and is connected to the control system for detecting air flow Status information; the control system is connected to the indicating device, and is used to control the indicating device to indicate the current state of the blown object according to the detection result of the sensor.
  • FIG. 1 is a schematic structural diagram of an intelligent hair dryer provided in the first embodiment of the present application.
  • FIG. 2 is a method flowchart of a job control method according to a second embodiment of the present application.
  • FIG. 3 is a schematic diagram of a peripheral structure of an intelligent hair dryer provided by the first embodiment of the present application.
  • FIG 4 is a cross-sectional view of a smart hair dryer provided by the first embodiment of the present application.
  • FIG. 5 is a connection diagram between components of a smart hair dryer provided by an embodiment of the present application.
  • FIG. 6 is a method flowchart of a job control method according to a third embodiment of the present application.
  • FIG. 7 is a schematic flowchart of an information display method provided by an embodiment of the present application.
  • the present application provides an intelligent hair dryer and related operation control methods.
  • the following uses specific embodiments to describe the intelligent hair dryer of the present application and a method for automatically controlling the operation of the intelligent hair dryer.
  • the first embodiment is a schematic structural diagram of a smart hair dryer provided by the present application.
  • the smart hair dryer includes: an air flow detection channel 1, a sensor 2, a control system, and a main air duct 3; the main air duct 3 is provided with a fan unit for generating airflow and a heating unit for heating the airflow, in this embodiment, respectively corresponding to the fan 5 and the heating wire 7 of FIG.
  • the airflow detection channel 1 is connected to the upstream area of the fan unit, and the air outlet 8 of the main air duct 3 is located in the downstream area of the fan unit, so that the airflow in the air flow detection channel 1 moves to the air outlet 8 of the main air duct 3 through the fan unit .
  • the principle of the airflow movement in the above process is described as follows: When the smart blower is working, the fan unit, that is, the upstream area of the fan 5 will form a negative pressure.
  • the airflow detection channel 1 Since the airflow detection channel 1 is connected to the upstream area of the fan unit, the airflow can pass through the airflow detection channel
  • the air inlet of 1 is automatically drawn into the airflow detection channel 1, and under the action of the fan 5, the airflow will move to the air outlet 8 of the main air duct 3 through the fan unit.
  • a sensor 2 is provided in the airflow detection channel 1.
  • the sensor 2 can detect the status information of the airflow entering the airflow detection channel 1.
  • the air inlet opening of the airflow detection channel 1 faces the blowing direction of the main air duct 3 of the smart blower. In this way, when the smart hair dryer blows the object to be blown, the airflow that has been in contact with the object to be blown can enter the airflow detection channel 1 through the air inlet of the airflow detection channel 1 and flow in the airflow detection channel 1 to contact the sensor 2 . In this way, the sensor 2 can collect the status information of the airflow that has been in contact with the blown object.
  • the airflow state information includes at least one of the following information: airflow temperature information and airflow humidity information.
  • the temperature information of the airflow may be relative temperature information or absolute temperature information of the airflow; the humidity information of the airflow may be relative humidity information or absolute humidity information of the airflow, etc.
  • the state information of the object to be blown may also be at least one of temperature and humidity information.
  • the senor 2 can provide the control system with the status information of the airflow that has been in contact with the blown object. Further, the control system can control the working state of the smart blower according to the state information of the airflow, that is, use the state information of the airflow to control the working state of the smart blower.
  • control system may determine the state information of the air blown according to the airflow state information with the object being blown, and control the working state of the smart hair dryer according to the state information of the object blown.
  • the hair dryer provided in this embodiment can obtain the status information of the airflow that has been in contact with the object being blown, the status information can reflect the status information of the object being blown to a certain extent, therefore, the operation of the smart hair dryer is controlled according to the status information of the airflow
  • the state can make the working state of the smart hair dryer match the state of the object being blown, and realize the automatic adjustment of the working state of the hair dryer without manual adjustment by the user, which helps to improve the user experience.
  • the airflow detection channel 1 is provided on at least one side of the main air duct 3, and the airflow detection channel 1 may be provided at any position around the main air duct 3, for example It may be the upper side, the lower side, the left side, or the right side of the main air duct 3, and the number of the airflow detection channels 1 is at least one.
  • Fig. 1a only illustrates that the airflow detection channel 1 is provided on the upper side of the main air duct 3, but does not limit the installation position and number thereof.
  • the airflow detection channel 1 collects the airflow that has been in contact with the blown object through the air inlet of the airflow detection channel 1.
  • the airflow detection channel 1 can be set to a variable cross-sectional structure with a front width and a narrow width, that is, the air inlet of the airflow detection channel 1 is set to the entire airflow detection
  • the sensor 2 may be arranged at the rear side of the airflow detection channel 1, and the interior of the airflow detection channel 1 gradually narrows to ensure that the airflow detection channel 1 sucks the airflow that has been in contact with the blown object ,
  • the airflow is more concentrated, which helps to maintain the temperature and humidity of the airflow, and at the same time, the sensor 2 can be arranged at the rear side of the airflow detection channel 1 so that the sensitive elements in the sensor 2 can fully communicate with the denser airflow Contact to get better measurement results.
  • two or more sensors 2 may be provided in the airflow detection channel 1.
  • multiple refers to 3 or more.
  • the sensor 2 can detect the temperature and humidity information of the airflow, or one of the two information of temperature information and humidity information; specifically, the airflow is drawn into the airflow detection channel 1 and the airflow is in the airflow detection channel Flows in 1, and then touches the sensor 2, accordingly, the temperature and humidity response device in the sensor 2 will detect the temperature and humidity of the air flow due to contact with the air flow.
  • the process of forming the airflow that has been touched by the blowing object is described as follows:
  • the main air duct 3 of the smart hair dryer of the present application is provided with a main air inlet connected to the upstream area of the fan unit.
  • the motor of the smart hair dryer is inside Under the action of 6 and fan 5, a large amount of air will be drawn into the main air duct 3 from the main air inlet through the rear protective cover 4.
  • a large amount of air is heated by the heating wire 7 inside the blower.
  • it is blown out from the air outlet 8 of the main air duct 3 of the hair dryer, and a large amount of air is blown toward the object to be blown through the hair dryer.
  • the area of the main air inlet of the main air duct 3 and the area of the air outlet 8 of the main air duct 3 provided in this application are larger than the area of the air inlet of the air flow detection channel 1, only a small part of the air flow enters the air flow detection channel 1. Basically, it does not affect the blowing effect of the hair dryer.
  • this part of the airflow is a part of the airflow where a large amount of air comes into contact with the object being blown back, so the airflow state information of the airflow can reflect the state information of the object being blown.
  • the state information of the object to be blown may be at least one of temperature and humidity information of the object to be blown.
  • hair dryers are widely used. The following uses the intelligent hair dryer in this embodiment as an example to describe the hair blowing process.
  • a rear protective cover 4 is installed at the rear end of the smart hair dryer in this embodiment, and a main air inlet of the main air duct 3 is provided at the rear end of the smart hair dryer.
  • the air outlet 8 of the main air duct 3 is located Front end of smart hair dryer.
  • a large amount of air is blown to the hair through the hair dryer.
  • the sensor 2 can obtain the status information of the airflow contacted with the hair and provide the status information of the airflow to the control system. Further, the control system can determine the status information of the hair through the airflow status information, and control the working status of the smart hair dryer according to the status information of the hair.
  • the sensor 2 can be located at any position of the airflow detection channel 1.
  • the sensor 2 can be installed at the air inlet of the airflow detection channel 1 or inside the airflow detection channel 1 or at other positions.
  • Multiple sensors can be installed at the same time, for example, the sensor 2 is placed closer to the air inlet of the airflow detection channel 1, and the sensor 2 installed near the air inlet of the airflow detection channel 1 can be in contact with the contacted hair in a short time
  • the airflow of the airflow can therefore more accurately detect the temperature and humidity information of the airflow that has touched the hair;
  • the sensor 2 is disposed inside the airflow detection channel 1, because the internal channel of the airflow detection channel 1 is a structure that is wide in front and narrow at the back, especially When the sensor 2 is disposed in the narrowest part of the inner channel of the airflow detection channel 1, since the airflow is most concentrated here, the sensor 2 installed here can respond to the temperature and humidity information of the airflow that has touched the hair as quickly as possible.
  • the sensors 2 are arranged at different positions in the airflow detection channel 1 according to the set distance interval to check the temperature and humidity information of the airflow at different positions.
  • the sensor 2 is set at different positions as above, which can detect the temperature and humidity change information of the airflow flowing through different positions inside the smart hair dryer, so as to fit the temperature and humidity parameters of the airflow flowing through the smart hair dryer, and then estimate the state of the hair Estimation information, wherein the hair condition estimation information includes at least one of hair temperature estimation information and humidity estimation information, so that the wind blown from the air outlet 8 of the main air duct of the intelligent hair dryer of the present application more closely matches the object to be blown The required hair dryer.
  • the temperature of the blower can be detected by setting the sensor at any position of the main air duct 3, for example, setting the temperature sensor at the position of the air outlet 8.
  • the temperature of the hair dryer's blowing hair can be estimated from the theoretical temperature corresponding to the working gear of the hair dryer.
  • the wind speed can also be obtained according to the above-mentioned method for obtaining the temperature of the blower, which will not be repeated here.
  • the fitting can be performed according to the above parameters to obtain hair condition estimation information, that is, the airflow is used to contact the hair Before and after the temperature change information and humidity change information to obtain hair condition estimation information. More specifically, when fitting the hair state estimation information, there are many ways, and the following two ways are used to illustrate the fitting method:
  • the first method of fitting fitting by a formula method, specifically, after obtaining the temperature and humidity information of the temperature and the wind speed of the hair dryer and the airflow flowing through the airflow detection channel 1, the above parameters and the hair
  • the relationship of the status information of the relationship is established. In the actual operation of the relationship, multiple experiments can be carried out.
  • the content of the experiment includes but is not limited to detecting the status information of the hair at different times and the corresponding temperature of the hair dryer, the wind speed of the hair, and the flow through The temperature and humidity information of the airflow inside the airflow detection channel 1, or replace different objects to be blown and detect the status information of the different objects to be blown, and the corresponding blower temperature, air speed, and flow through the airflow detection channel 1
  • the temperature and humidity information of the internal airflow can be established as a functional relationship between the detected parameter and the status information of the blown object, and this functional relationship is used as an empirical formula, where the The detected parameters include the temperature of the blower, the wind speed of the blower, and the temperature and humidity information of the airflow flowing through the airflow detection channel 1.
  • the second fitting method make a one-to-one correspondence table between the above-mentioned detected parameters and the status information of the object to be blown, only the temperature of the blower, the wind speed of the blower, and the airflow through the airflow detection channel 1
  • the temperature and humidity information can be queried from the table to calculate the hair status information.
  • a distance sensor can also be provided in the above-mentioned sensor, and the distance of airflow movement in the airflow status information can be detected by the distance sensor.
  • the distance sensor can be implemented in various ways, for example, the head of the hair dryer The department is equipped with LDS lidar ranging device.
  • the airflow movement distance may be defined as the distance between the airflow from the air outlet and the object to be blown (such as hair), or the distance from the air outlet to the object to be blown and back to the air inlet of the airflow detection channel 1.
  • the humidity and temperature obtained by the sensor in the airflow detection channel are only the temperature and humidity of the airflow in the airflow detection channel, which are different from the temperature and humidity parameters of the object to be blown, and the distance between the hair dryer and the object to be blown is The difference between the two has a great influence. Therefore, the measurement result of the distance sensor can be applied to the above fitting method as an important parameter.
  • the air outlet of the airflow detection channel 1 can be opened upstream of the main air duct 3, that is, the airflow detection channel 1 is connected to the upstream area of the fan 5, this connection can be It is understood that the low air pressure upstream of the main air duct 3 is introduced to the air inlet position of the air flow detection channel 1, and after the air flow contacting the blown object is blocked, it is more likely to flow back to the main through the air flow detection channel 1
  • the upstream area of the air inlet merges with the large amount of air sucked in the main air inlet, and after being merged, it is blown out from the air outlet 8 of the main air channel 3 through the main air channel 3 under the action of the fan 5, through the above process, the air flow of the hair is touched
  • An airflow channel circulating through the airflow detection channel 1 can be formed.
  • a sensor 2 can also be installed at the air outlet 8 of the main air duct 3 of the smart hair dryer. Further, the sensor 2 installed at the air outlet 8 of the smart hair dryer, the sensor 2 installed at the air inlet of the airflow detection channel 1 and the sensor 2 installed inside the airflow detection channel 1 can form a continuous gradient to the working airflow of the blower and to detect the airflow Type temperature and humidity measurement, and use this as a basis to more accurately calculate the temperature and humidity conditions of the object being blown, providing more accurate information for the control system to control the work of the intelligent blower.
  • two or more sensors in the airflow detection channel 1 may be provided, and are arranged at a set distance interval in the airflow direction of the airflow detection channel, so that the detection of the airflow Gradient measurement effect, which can more accurately estimate the temperature and humidity of the object being blown.
  • the sensor 2 After the sensor 2 obtains the temperature and humidity information of the airflow touching the hair, the sensor 2 transmits the temperature and humidity information of the airflow touching the hair to the control system of the smart hair dryer, the control system is used to receive the detection result output by the sensor, And use the detection result to adjust the rotation speed of the fan unit and/or the heating temperature of the heating unit.
  • the heating temperature corresponds to adjusting the rotation speed of the fan 5 of FIG. 1 and/or the heating temperature of the heating wire 7.
  • control system further includes a controller that receives the temperature and humidity information detected by each sensor 2 and the temperature and humidity change information of the airflow before and after contacting the hair, and controls the intelligent hair dryer through a preset program
  • the blowing parameters of the intelligent hair dryer include the air speed and temperature of the blowing hair, more specifically, the controller controls the blowing parameters of the intelligent hair dryer by controlling the speed of the fan 5 and the heating of the heating wire 7 through the controller, To control the air speed and temperature of the smart blower.
  • the wind speed and the temperature of the air blowing are specifically embodied as the air volume of the air blowing and the coolness of the blown wind.
  • the above control process may be that a control chip is provided inside the intelligent hair dryer, and the control chip receives temperature and humidity information of the airflow in contact with the hair transmitted by each sensor 2 and before and after contacting the hair.
  • the temperature and humidity change information of the user and according to the temperature and humidity information of the airflow of the hair and the temperature and humidity change information of the airflow before and after contacting the hair, the data is converted to obtain the temperature and humidity of the user's hair, and the control chip then converts the user's hair according to the conversion Temperature and humidity information, and through a preset program, control the blowing parameters of the smart hair dryer, and use this blowing parameter to adjust the actual blowing condition of the smart hair dryer, that is, adjust the blowing power of the smart hair dryer.
  • the preset program may be: first, based on the temperature and humidity information of the user's hair converted by the control chip, periodically or in real time to calculate the blowing parameters required by the object being blown; in addition, the current hair dryer's current Blowing parameters, wherein the blowing parameters at least include the wind speed and the temperature of the blowing, after obtaining the blowing parameters required by the object to be blown and the current blowing parameters of the smart blower, compare the blowing parameters required by the blown object with the current blowing parameters of the smart blower The relationship between the parameters of the hair dryer and the actual situation of the intelligent hair dryer is adjusted in this way.
  • the intelligent hair dryer automatically calculates the blowing parameters and automatically adjusts the blowing situation of the intelligent hair dryer, eliminating the tedious manual shifting of the user and improving the User experience.
  • the blowing parameters required by the object to be blown by the preset program described above are the blowing parameters required by the object to be blown determined according to the current of the air flow inhaled by the hair flow detection channel 1, if the current blowing parameters of the smart hair dryer are less than The blowing parameters required by the object being blown, that is, the current air speed and temperature of the air blowing are less than the air speed and temperature of the air being blown by the object, then the control system increases the power of the motor of the blower to automatically enhance the intelligence The air volume and temperature of the hair dryer.
  • the rotation speed of the motor of the fan 5 can be increased and the heating power of the heating wire 7 can be increased; if the current blowing parameters of the smart hair dryer are greater than the required blowing parameters of the hair to be blown, that is, the current wind speed and temperature of the blowing are greater than that of the blower
  • the control system can reduce the power of the hair dryer to automatically weaken the air volume and temperature of the smart hair dryer, for example, it can be a motor that reduces the fan 5 in the smart hair dryer And the heating power of the heating wire 7 is reduced.
  • the airflow detection channel 1 sucks the airflow that touches the hair in real time or periodically.
  • the temperature and humidity information of the airflow that touches the hair that is inhaled will change, that is, control
  • the temperature and humidity information of the user's hair obtained by the conversion of the chip will also change, and the temperature and humidity of the hair also change in real time during the blowing process of the actual smart hair dryer.
  • the humidity of the hair continuously decreases, and the temperature Constantly rising, therefore, the working parameters of the smart hair dryer required to blow hair in this process are also constantly changing.
  • the control system needs to continuously or periodically adjust the parameters of the intelligent hair dryer to meet the needs of the object being blown.
  • the above-mentioned control chip obtains the temperature and humidity of the user's hair through data conversion, which is mainly obtained according to the temperature and humidity information of the airflow contacting the hair and the temperature and humidity change information of the airflow before and after contacting the hair sent by each sensor 2, at each of the above installation locations
  • the temperature and humidity information detected by the sensor 2 installed at the air inlet of the airflow detection channel 1 of the smart hair dryer is closest to the temperature and humidity of the hair
  • the sensor 2 installed at the narrowest part of the airflow detection channel 1 can sense the fastest
  • the sensor 2 installed at the air outlet 8 of the main air duct 3 can sense the temperature and humidity information of the airflow blown through the main air duct 3.
  • the smart gear button is set in the hand-held part of the smart hair dryer of this application.
  • the smart hair dryer of this application can intelligently adjust the wind speed and temperature of the hair dryer according to the sensor and the control chip, thus eliminating The problem that the user adjusts the position of the hair dryer multiple times enhances the user's experience.
  • an intelligent hair dryer is provided, and correspondingly, the second embodiment of the present application provides a method of job control.
  • FIG. 2 it is a method flowchart of a job control method provided by a second embodiment of the present application. Since the method embodiment is basically similar to the device embodiment, the description is relatively simple. For related parts, please refer to the description of the device embodiment. The method embodiments described below are only schematic.
  • the method of the job control method provided in the second embodiment of the present application includes steps S201 to S204:
  • Step S201 Acquire status information of the airflow that has been in contact with the blown object.
  • Step S202 estimate the state estimation information of the blown object according to the state information of the airflow.
  • Step S203 Obtaining the blowing parameters of the smart hair dryer required by the blown object according to the state estimation information of the blown object, wherein the blowing parameters of the smart blower include the wind speed and temperature of the blower.
  • Step S204 controlling the intelligent hair dryer to blow the object to be blown according to the blowing parameters of the intelligent hair dryer required by the object to be blown.
  • the airflow state information includes at least one of airflow temperature information and airflow humidity information
  • the blown object state estimation information includes both blown object temperature estimation information and humidity estimation information At least one of them.
  • the method further includes obtaining the current blowing parameters of the smart hair dryer in real time, and judging whether to adjust the blowing of the smart hair dryer according to the current blowing parameters of the smart hair dryer and the blowing parameters of the smart hair dryer required by the blown object parameter;
  • the current blowing parameters of the smart hair dryer are less than the blowing parameters of the smart hair dryer required by the object to be blown, the current blowing parameters of the smart hair dryer are enhanced, otherwise, the current blowing parameters of the smart hair dryer are weakened.
  • the above method for automatically controlling the operation of the smart hair dryer utilizes the humidity and/or temperature information obtained by the sensor provided in the airflow detection channel in the smart hair dryer provided in the first embodiment of the present application to achieve intelligent control of the work of the hair dryer and effectively improve The experience of using a hairdryer.
  • Embodiments of the present application also provide a computer-readable storage medium that stores computer instructions.
  • the computer instructions are executed by one or more processors, the one or more processors are caused to perform the steps in the foregoing job control method.
  • the present application also provides an intelligent hair dryer and related operation control methods.
  • the following uses specific embodiments to describe the intelligent hair dryer and the operation control method of the application.
  • FIG. 3 is a schematic structural diagram of a smart hair dryer provided in the first embodiment of the present application
  • FIG. 4 is a cross-sectional view of the smart hair dryer in the first embodiment of the present application.
  • the smart hair dryer includes: a body 101, a main air duct 105 provided in the body, an air flow detection channel 103, a sensor 104, and a control system (not shown), and a body provided outside the body 101 ⁇ 102 ⁇ The pointing device 102.
  • the main air duct is provided with an air outlet 108 in the fuselage 101, and an air flow generating device is provided inside.
  • the air inlet of the airflow detection channel and the air outlet 108 of the main air channel 105 are disposed on the same side of the body 101.
  • the air inlet of the airflow detection channel 103 and the air outlet 108 of the main air channel 105 are disposed on the same side of the body 101 means that the air inlet of the air flow detection channel 103 and the air outlet 108 of the main air channel 105 are disposed at The side opposite to the air inlet of the main air duct 105.
  • the sensor is disposed in the air flow detection channel and connected to the control system, and is used to detect the status information of the air flow entering the air flow detection channel 103.
  • the air inlet opening of the airflow detection channel 103 faces the blowing direction of the main air channel 105 of the smart hair dryer.
  • the airflow that has been in contact with the object to be blown may enter the airflow detection channel 103 through the air inlet of the airflow detection channel 103 and flow in the airflow detection channel 103 to contact the sensor 104 .
  • the sensor 104 can collect the status information of the airflow that has been in contact with the blown object. Since the airflow touched by the blowing object carries the status information of the blown object, the status information of the airflow touched by the blowing object may reflect the status information of the blown object.
  • the sensor 104 can provide the control system with the status information of the airflow that has been in contact with the blown object.
  • control system is connected to the pointing device 102, and is used to control the pointing device 102 to indicate the current state of the blown object according to the detection result of the sensor. That is, the control system may control the indicating device 102 to indicate the current state of the blown object according to the state information of the airflow. In this way, the user can intuitively understand the current state of the blown object, which helps to improve the user experience.
  • the indicator device 102 may use an indicator light, an LED display screen, a liquid crystal display screen, or an OLED display screen, but is not limited thereto.
  • the display screen used by the pointing device 102 may be a flat screen or a curved screen. Further, the pointing device 102 may adopt any one of the following shapes, including: a continuous or discontinuous annular structure surrounding the fuselage, and a strip-shaped structure provided along the outer side of the fuselage.
  • the reason why the pointing device in this embodiment can display the current state of the object to be blown is mainly due to the detection of the airflow of the object to be blown by a sensor installed on the smart hair dryer.
  • the sensor mainly includes at least one of a temperature sensor and a humidity sensor.
  • the temperature sensor is mainly used to detect the current temperature of the blown object
  • the humidity sensor is mainly used to detect the current humidity of the blown object.
  • a distance sensor 111 is installed on the side of the main air duct outlet of the smart hair dryer, and the distance sensor 111 is connected to the control system.
  • the distance sensor can be used to determine the presence or absence of the object to be blown; on the other hand, in the presence of the object to be blown, it can be used to detect the distance between the object to be blown and the air outlet of the main channel.
  • the control system can issue a corresponding control instruction according to the detection result of the distance sensor 111.
  • the control instruction includes at least one of the following: adjusting power, controlling the display device to display the distance between the blown object and the air outlet, and controlling the indicating device 102 to indicate the distance between the blown object and the air outlet.
  • the smart hair dryer of this embodiment uses sensors to obtain the current state information of the blown object, and displays the current state information of the blown object on the pointing device 102.
  • the working state information collection module of the hair dryer installed in the body can be used to collect the working state of the hair dryer, and display the working state information of the hair dryer on the indicating device 102.
  • the information collection module of the working state of the hair dryer includes: a distance sensor, an acceleration sensor, a negative ion generator, a blowing temperature sensor, a blowing wind speed sensor and a motor detection module. These information collection modules are respectively connected to the control system and feed back the collected signals to the control system.
  • the control system sends corresponding signals to the pointing device 102 or the driving unit of the display device, and the driving unit drives the display unit of the pointing device 102 or the display device to display various corresponding state information.
  • the working state information of the hair dryer is collected by the working state information collection module of the hair dryer, and the working state information of the hair dryer is displayed on the indicating device 102 in the manner described as follows: the working state information collection module of the hair dryer is connected to the control system, and the control The system controls the indicating device 102 to indicate the working state of the hair dryer according to the working state information of the hair dryer collected by the working state collection module.
  • the working state of the smart hair dryer includes at least one of the following information: distance to the object to be blown, acceleration of the hair dryer, concentration of negative ions, blowing temperature, blowing wind speed, blowing time, or motor power.
  • control system may control the indicating device 102 to display the information in parallel.
  • control system can also prioritize according to preset instructions, or output a single display state according to the current state change of the hair dryer .
  • the working state information collection module of the hair dryer outputs the above-mentioned various types of information to the control system, and the control system outputs the information of no object to be blown to the driving unit of the pointing device 102 according to the highest priority
  • the driving unit drives the pointing device 102 to display the specific state of no blown object.
  • the temperature and humidity sensor detects that the temperature of the object being blown is low and the humidity is high, and the acceleration sensor detects that the acceleration is increasing, and the blowing temperature sensor detects that the temperature of the blown air is low, and the blowing air speed The sensor detects that the wind speed is not high, and after the control system obtains this information, it is determined that the user needs to increase the motor power when blowing the object to be blown. Therefore, the indicating device 102 displays the status of the motor power.
  • control system can control the indicating device 102 to display the instruction information that can increase the motor power, so that the user can understand that the blower gear can be increased according to the instruction information, thereby helping to meet the user's increase The purpose of power and express air-drying.
  • control system of this embodiment may also control the pointing device 102 to indicate the current state of the blown object in at least one of the following ways based on the detection result of the sensor or distance sensor 111 or the information collected by the hair dryer working status information collection module Or the working state of the hair dryer: gradient display, monochrome display, gradient flashing or monochrome flashing.
  • Monochrome display is a monochromatic display of red, green, blue, yellow and other colors.
  • Gradient display refers to a gradual change from one of the above-mentioned monochrome displays to another monochrome display, such as a gradual display from red to blue.
  • the gradual display may be that when the distance of the blown object gradually gets closer, the pointing device 102 gradually changes from red to blue.
  • the same is true for gradient flashes or monochrome flashes, and I will not illustrate them one by one again.
  • the pointing device 102 in FIG. 1 may be a smart light ring.
  • the indicating device 102 can display the working state of the smart hair dryer and/or the current state of the object being blown in an intuitive manner by using at least one of a gradation display, a monochrome display, a gradual blink, and a monochrome blink display mode , So that the user can accurately know the working state of the smart blower and/or the current state of the blown object directly according to the display state of the observed indication device 102.
  • the pointing device 102 can be arranged in a circle on the body of the smart hair dryer, or a half circle can be arranged on the body of the smart hair dryer, or it can be a discontinuous one circle or half circle structure.
  • the above strip structure can also be realized.
  • the pointing device 102 when the body of the smart hair dryer has a circular structure, the pointing device 102 is disposed on the outer surface of the body, extending along the surface of the body of the smart hair dryer, and when the pointing device 102 is along the axial direction of the smart hair dryer When the direction extends, optionally, the pointing device 102 is a bar-shaped structure; when the pointing device 102 extends along the radial direction of the smart blower, optionally, the pointing device 102 is a ring-shaped structure, one circle or half circle or other circle
  • the structure can be realized. In the embodiments of the present application, regardless of whether the pointing device 102 is a bar-shaped structure or a ring-shaped structure, this structure may be continuous or discontinuous. Optionally, the pointing device 102 is a continuous ring-shaped structure or a discontinuous bar ⁇ Shaped structure.
  • the indicating device 102 is presented by means of LED or curved screen display, and may be display devices such as LED lights, liquid crystal display screens, OLED display screens and the like. As shown in FIGS. 1 and 2, in order to facilitate the user to observe the display state of the pointing device 102 and to understand the working state of the hair dryer in time, the pointing device 102 is provided on the surface of the body of the smart hair dryer, optionally, near the end of the body surface The location is better presented to the user for observation.
  • the air outlet is provided at one end of the body of the hair dryer, and the pointing device 102 is provided at the other end of the body opposite the air outlet.
  • the indicating device 102 may be provided on the surface of the fuselage or at the end of the fuselage.
  • the indicating device 102 is provided at the other end of the fuselage relative to the air outlet
  • the air outlet is located at the front of the fuselage
  • the pointing device 102 is located at the rear of the fuselage
  • the pointing device 102 is facing away from the wind direction, which is more conducive to observing the working status of the smart blower and/or the current status of the blown object .
  • the air outlet faces the object to be blown
  • the pointing device 102 at the other end of the air outlet faces away from the wind direction and faces the user, so that the user can observe the pointing device 102 in time Display status.
  • the pointing device 102 has two working modes, namely an intelligent mode and a manual mode.
  • the pointing device 102 can display the working status information of the blown object and/or the current status information of the blown object during the operation of the smart hair dryer, and can be implemented with a display device (such as a display screen) installed on the fuselage Synchronous display.
  • the smart light ring when the humidity of the object being blown is detected to be high, it may be that when the hair is very wet, the smart light ring shows a gradual color, and when the hair is very dry, the smart light ring shows blue. According to the change of dry humidity, the smart light ring shows the color gradient. In this way, the user can automatically determine the wet and dry state of the hair, work progress, whether to blow dry, etc. according to the color change of the smart light ring. Or it can be that when the object is not detected in the smart working mode, the distance sensor installed inside the smart hair dryer can be used for detection, and the user has not stopped the hair dryer or the hair dryer has been started, and the smart light ring displays a monochrome flash to remind the user Shut down.
  • the smart hair dryer realizes automatic shutdown. Therefore, the safety problem during the use of the intelligent hair dryer is guaranteed.
  • the state information of the blown object can be intuitively displayed to the user through the above process, so as to enhance the user experience.
  • the indicating device 102 may display the working state of the smart hair dryer.
  • the smart light ring can flash in a gradual color to indicate high winds and heat, reminding the user to pay attention to the safety of the hair dryer.
  • blue flashing may indicate that the blower is too close or too far away from the blown object.
  • the blower moves toward the predetermined object to be blown at a short distance, the closer the distance to the target, the slower the blue flashing, and the longer the distance, the faster the blue flashing of the smart light ring.
  • the smart light ring is displayed in blue, and when wet hair is blown, the smart light ring is displayed in gradual color. It may also be that the smart light ring displays a gradual color when the blower is a predetermined distance away from the object to be blown, and displays red flashing when there is no object being blown.
  • the working state information of the smart hair dryer and/or the current state information of the object to be blown displayed by the above-mentioned indicating device 102 are only exemplary descriptions, and are not limited herein.
  • the above working state information and/or the current state information of the blown object can be preset in the controller through a program, and display the working state information of at least one smart blower and/or the current state information of the blown object in different application scenarios, Users only need to learn about various display states through the instruction manual of the hair dryer.
  • an airflow generating unit is installed inside the hair dryer of the present application, and the airflow generating unit includes a fan unit and a heating unit.
  • the main air duct 105 is provided with a fan unit 106 for generating airflow and a heating unit 107 for heating the airflow.
  • the heating unit 107 may be a heating wire 107;
  • the detection channel 103 is provided on at least one side of the main air channel 105, and the airflow detection channel 103 may be provided at any position around the main air channel 105, for example, may be above and below the main air channel 105 Side, left, or right, and the number of the airflow detection channels 103 is at least one.
  • the airflow detection channel 103 is provided on the upper side of the main air duct 105, and the air inlet opening of the airflow detection channel 103 is directed toward the blowing direction of the smart blower main air duct 105, and the sensor 104 is provided in the airflow In the detection channel 103, the sensor 104 can detect airflow status information of the airflow, wherein the airflow status information includes at least one of the following information: airflow temperature information, airflow humidity information, for example, airflow relative humidity information, relative temperature information , Absolute humidity information and absolute temperature information.
  • the airflow detection channel 103 collects the airflow that has been in contact with the blown object through the air inlet of the airflow detection channel 103, and obtains status information of the airflow through the sensor 104.
  • the airflow detection channel 103 can be set to a variable cross-sectional structure with a front width and a narrow width, that is, the air inlet of the airflow detection channel 103 is set to the entire airflow detection In the widest part of the channel 103, the sensor 104 is disposed inside the air flow channel 103.
  • a plurality of sensors 104 may be provided in the airflow detection channel 103, and the sensors 104 may detect the Air temperature and humidity information, or one of the two types of information: temperature information and humidity information; optionally, the airflow is drawn into the airflow detection channel 103, and the airflow flows in the airflow detection channel 103 when the flow touches
  • the temperature and humidity response device in the sensor 104 will detect the temperature and humidity of the airflow due to contact with the airflow.
  • the airflow in the airflow detection channel 103 is the airflow that has been in contact with the object to be blown and carries the status information of the object to be blown
  • the status information of the object to be blown can be obtained by detecting the airflow that has contacted with the object to be blown.
  • the process of forming the airflow that the above-mentioned object is exposed to is described as follows: During the blowing process of the smart blower, the smart blower, under the action of the internal motor 110 and the fan 106, draws a large amount of air into the main air duct 105 through the main air inlet, After entering the main air duct 105 of the hair dryer, a large amount of air is heated by the heating wire 107 inside the hair dryer, and finally blown out from the air outlet 108 of the main air duct 105 of the hair dryer. A large amount of air is blown to the object to be blown through the blower.
  • the object After blowing the object, it will enter the airflow detection channel 103 through the air inlet of the airflow detection channel 103, because the area of the main air inlet of the main air channel 105 and the area of the air outlet 108 of the main air channel 105 provided in this application are larger than the air flow detection The area of the air inlet of the channel 103, so only a small part of the airflow enters the airflow detection channel 103 without basically affecting the blowing effect of the blower. At the same time, this part of the airflow is a large amount of air that contacts the part of the airflow that is folded back by the blown object, so this The airflow can truly reflect the status information of the airflow touched by the blowing object.
  • hair dryers are widely used, and the hair blowing process of the intelligent hair dryer in this embodiment will be described as an example.
  • a rear protective cover 109 is installed at the rear end of the smart hair dryer in this embodiment, and a main air inlet of the main air duct 105 is provided at the rear end of the smart hair dryer.
  • the air outlet 108 of the main air duct 105 is located Front end of smart hair dryer.
  • the sensor 104 can obtain the status information of the airflow contacted with the hair and provide the status information of the airflow to the control system. Further, the control system may determine the status information of the hair through the airflow status information, and control the indicating device 102 to indicate the current status of the hair.
  • the sensor 104 may be disposed at any position of the airflow detection channel 103. In actual installation, the sensor 104 may be disposed at the air inlet of the airflow detection channel 103 or inside the airflow detection channel 103 or at other positions. Of course, Multiple sensors can be installed at the same time, for example, the sensor 104 is located closer to the air inlet of the airflow detection channel 103, and the sensor 104 installed near the air inlet of the airflow detection channel 103 can be in contact with the contacted hair in the shortest time The airflow of the airflow can therefore more accurately detect the temperature and humidity information of the airflow that has touched the hair; the sensor 104 is disposed inside the airflow detection channel 103, because the internal channel of the airflow detection channel 103 is a structure that is wide in front and narrow at the back, especially When the sensor 104 is disposed in the narrowest part of the inner channel of the airflow detection channel 103, since the airflow is most concentrated here, the sensor 104 installed here can respond to the temperature and humidity information of the
  • the sensors 104 are disposed at different positions of the airflow detection channel 103 according to the set distance interval to check the temperature and humidity information of the airflow at different positions.
  • the sensors 104 are set at different positions as described above, which can detect the temperature and humidity change information of the airflow flowing through different positions inside the smart hair dryer, so as to fit the temperature and humidity parameters of the airflow flowing through the smart hair dryer, and then estimate the state of the hair Estimation information, wherein the hair condition estimation information includes at least one of hair temperature estimation information and humidity estimation information, so that the wind blown from the air outlet 108 of the main air duct of the intelligent hair dryer of the present application more closely matches the object to be blown The required hair dryer.
  • the temperature of the blower can be detected by setting the sensor at any position of the main air duct 105.
  • the temperature sensor is provided at the position of the air outlet 108; the temperature sensor may also be provided at the downstream direction of the heating wire 107, or at a position between the heating wire 107 and the air outlet 108.
  • the temperature of the hair dryer's blowing hair can be estimated from the theoretical temperature corresponding to the working gear of the hair dryer.
  • the wind speed can also be obtained according to the above-mentioned method for obtaining the temperature of the blower, which will not be repeated here.
  • the hair dryer's blowing temperature and blowing speed As well as the temperature and humidity of the airflow flowing through the airflow detection channel 103, it can be fitted according to the above parameters to obtain hair condition estimation information, that is, the airflow is used to contact the hair Before and after the temperature change information and humidity change information to obtain hair condition estimation information.
  • hair condition estimation information that is, the airflow is used to contact the hair Before and after the temperature change information and humidity change information to obtain hair condition estimation information.
  • hair status estimation information there are various ways. The following two ways are used to illustrate the fitting method:
  • the first method of fitting fitting by the formula method, optionally, after obtaining the temperature and humidity information of the temperature and the wind speed of the blower and the airflow passing through the airflow detection channel 103, the above parameters and The relationship of the hair status information is established.
  • the experimental content includes but is not limited to detecting the status information of the hair at different times and the corresponding temperature, wind speed, and flow rate of the hair dryer.
  • the temperature and humidity information of the airflow through the airflow detection channel 103 or replace different objects to be blown and detect the status information of the different objects to be blown, and the corresponding blower temperature, wind speed, and flow through the airflow detection channel 103.
  • the detected parameters include the temperature of the blower, the wind speed of the blower, and the temperature and humidity information of the airflow flowing through the airflow detection channel 103.
  • the empirical formula it is only necessary to substitute the temperature and humidity information of the blower temperature, the wind speed of the blower, and the airflow flowing through the airflow detection channel 103 into the empirical formula to calculate the hair status information.
  • the second fitting method is to form a one-to-one data table corresponding to the above-mentioned detected parameters and the status information of the blown object. Only the temperature of the blower, the wind speed of the blower, and the airflow through the airflow detection channel 103 The temperature and humidity information can be retrieved from the data table to estimate the hair condition information.
  • a distance sensor can also be provided in the above-mentioned sensor to detect the airflow movement distance in the airflow status information through the distance sensor, and at the same time, the distance sensor can also be used to determine whether there is a blown object.
  • the distance sensor may be implemented in various ways, for example, an LDS lidar distance measuring device may be provided on the head of the hair dryer.
  • the movement distance of the airflow may be defined as the distance between the airflow from the air outlet to the object to be blown (such as hair), or the distance from the air outlet to the object to be blown and back to the air inlet of the airflow detection channel 103.
  • the humidity and temperature obtained by the sensor in the airflow detection channel are only the temperature and humidity of the airflow in the airflow detection channel, which are different from the temperature and humidity parameters of the object to be blown, and the distance between the hair dryer and the object to be blown is The difference between the two has a great influence. Therefore, the measurement result of the distance sensor can be applied to the above fitting method as an important parameter.
  • the air outlet of the airflow detection channel 103 can be opened upstream of the main air channel 105, that is, the airflow detection channel 103 is connected to the upstream area of the fan 106, this connection can be It is understood that the low air pressure upstream of the main air duct 105 is introduced to the air inlet position of the air flow detection channel 103, and after the air flow contacting the blown object is blocked, it is more likely to flow back to the main through the air flow detection channel 103 The upstream area of the air inlet merges with the large amount of air sucked in the main air inlet, and then merges and then blows out from the air outlet 108 of the main air passage 105 through the main air passage 105 under the action of the fan 106. Through the above process, the air flow of the hair is contacted An airflow channel circulating through the airflow detection channel 103 may be formed.
  • a sensor 104 can also be installed at the air outlet 108 of the main air duct 105 of the smart hair dryer. Further, the sensor 104 installed at the air outlet 108 of the smart hair dryer, the sensor 104 installed at the air inlet of the airflow detection channel 103 and the sensor 104 installed inside the airflow detection channel 103 can form a continuous gradient to the working airflow of the blower and to detect the airflow Type temperature and humidity measurement, and use this as a basis to more accurately calculate the temperature and humidity conditions of the object being blown, providing more accurate information for the control system to control the work of the intelligent blower.
  • two or more sensors may be provided in the airflow detection channel 103, and the sensors may be provided at positions separated by a set distance in the airflow direction of the airflow detection channel, so that the detected airflow can also be obtained
  • the gradient measurement effect can more accurately calculate the temperature and humidity status of the object being blown.
  • the sensor 104 After the sensor 104 obtains the temperature and humidity information of the airflow touching the hair, the sensor 104 transmits the temperature and humidity information of the airflow touching the hair to the control system of the smart hair dryer, the control system is used to receive the detection result output by the sensor, And use the detection result to adjust the rotation speed of the fan unit and/or the heating temperature of the heating unit.
  • the heating temperature corresponds to adjusting the rotation speed of the fan 106 of FIG. 2 and/or the heating temperature of the heating wire 107.
  • control system further includes a controller that receives the temperature and humidity information detected by each sensor 104 and the temperature and humidity change information of the airflow before and after contacting the hair, and passes a preset program to control intelligence
  • the blower parameters of the hair dryer wherein the blower parameters of the smart blower include the wind speed and the temperature of the blower
  • the controller controls the blower parameters of the smart blower by controlling the speed of the fan 106 and the heating of the heating wire 107 respectively through the controller , To control the air speed and temperature of the smart blower.
  • the wind speed and the temperature of the air blowing are specifically embodied as the air volume of the air blowing and the coolness of the blown wind.
  • the above control process may be that a control chip is provided inside the intelligent hair dryer, and the control chip receives temperature and humidity information of the airflow in contact with the hair transmitted by each sensor 104 and before and after contacting the hair.
  • the temperature and humidity change information of the user and according to the temperature and humidity information of the airflow of the hair and the temperature and humidity change information of the airflow before and after contacting the hair, the data is converted to obtain the temperature and humidity of the user's hair.
  • Temperature and humidity information and through a preset program, control the blowing parameters of the smart hair dryer, and use this blowing parameter to adjust the actual blowing condition of the smart hair dryer, that is, adjust the blowing power of the smart hair dryer.
  • the preset program may be: first, based on the temperature and humidity information of the user's hair converted by the control chip, periodically or in real time to calculate the blowing parameters required by the object being blown; in addition, the current hair dryer's current Blowing parameters, wherein the blowing parameters at least include the wind speed and the temperature of the blowing, after obtaining the blowing parameters required by the object to be blown and the current blowing parameters of the smart blower, compare the blowing parameters required by the blown object with the current blowing parameters of the smart blower The relationship between the parameters of the hair dryer and the actual situation of the intelligent hair dryer is adjusted in this way.
  • the intelligent hair dryer automatically calculates the blowing parameters and automatically adjusts the blowing situation of the intelligent hair dryer, eliminating the tedious manual shifting of the user and improving the User experience.
  • the blowing parameters required by the object to be blown in the preset program described above are the blowing parameters required by the object to be blown determined according to the current of the air flowing through the hair-contacting channel 103, if the current blowing parameters of the smart hair dryer are less than The blowing parameters required by the object being blown, that is, the current air speed and temperature of the air blowing are less than the air speed and temperature of the air being blown by the object, then the control system can automatically increase the power of the motor of the blower to enhance the The air volume and temperature of the smart hair dryer can be increased by, for example, increasing the rotation speed of the fan's motor and increasing the heating power of the heating wire 107 in the smart hair dryer; if the current smart hair dryer's blowing parameters are greater than those required for the hair to be blown , That is, the current wind speed and temperature of the blower are greater than the wind speed and temperature of the hair to be blown, then the control system can reduce the power of the motor of the hair dryer to automatically reduce the air volume and the blow
  • the airflow detection channel 103 sucks the airflow that touches the hair in real time or periodically.
  • the temperature and humidity information of the airflow that touches the hair that is inhaled will change, that is, control
  • the temperature and humidity information of the user's hair obtained by the conversion of the chip will also change, and the temperature and humidity of the hair also change in real time during the blowing process of the actual smart hair dryer.
  • the humidity of the hair continuously decreases, and the temperature Constantly rising, therefore, the working parameters of the smart hair dryer required to blow hair in this process are also constantly changing.
  • the control system needs to continuously or periodically adjust the parameters of the intelligent hair dryer to meet the needs of the object being blown.
  • the control chip obtains the temperature and humidity of the blown object through data conversion, which is mainly obtained based on the temperature and humidity information of the airflow contacting the blown object and the temperature and humidity change information of the airflow before and after contacting the blown object transmitted by each sensor 104, Among the sensors in the above installation positions, the temperature and humidity information detected by the sensor 104 installed at the air inlet of the airflow detection channel 103 of the smart blower is closest to the temperature and humidity of the object to be blown, and the airflow detection channel 103 is installed at the narrowest Some sensors 104 can quickly sense the temperature and humidity of the airflow passing through the airflow detection channel 103 that has touched the object to be blown.
  • the sensor 104 installed at the air outlet 108 of the main air duct 105 can sense the air blowing through the main air duct 105 Temperature and humidity information of the airflow.
  • the above description process mainly uses the sensor to obtain the current state information of the blown object, and displays it on the pointing device 102 through the control system.
  • This application uses an instruction device installed on the body of the smart hair dryer, and indicates the working state of the smart hair dryer and/or the current state of the object being blown according to the control system. This method allows the user to accurately know the working state of the hair dryer and /Or the current state of the blown object.
  • the working principle of the intelligent hair dryer provided by the present application is mainly controlled by the control system to control the working state collection module of the hair dryer including temperature sensor, humidity sensor, distance sensor, temperature control module and wind control module.
  • control system to control the working state collection module of the hair dryer including temperature sensor, humidity sensor, distance sensor, temperature control module and wind control module.
  • temperature sensor humidity sensor
  • distance sensor distance sensor
  • temperature control module wind control module.
  • the humidity sensor as a detection component for detecting the humidity information of the object to be blown, can be installed in the air inlet of the smart blower, preferably in a position near the air inlet in the airflow channel, for collecting the air humidity near the object to be blown in real time.
  • the power of the intelligent hair dryer and the wind speed and air volume of the wind control module are dynamically adjusted according to the detected humidity information, so as to achieve constant temperature hair care and energy saving.
  • the distance sensor is used as a detection component to detect the distance of the object to be blown by the smart hair dryer and whether there is an object to be blown within the blowing range.
  • the distance sensor can be installed on the body of the smart hair dryer, preferably near the air outlet, of course, it can also be selected in the smart The outer periphery of the hair dryer.
  • the acceleration sensor as a detection component for detecting the moving speed of the smart blower, can be installed at any position in the smart blower. By detecting the moving speed to determine whether the blower is moving fast, the greater the acceleration, the greater the amount of air required by the blower and the higher the temperature. It means that users want to dry quickly and need to execute high wind, high heat and high negative ion concentration mode; the acceleration sensor controls the blower to execute at least one of the following instructions: increase heating wire power, increase motor power, increase negative ion concentration, etc.
  • the acceleration sensor is set in the handle of the smart hair dryer, recognizes the rapid swing of the gesture, and gives a signal to the controller. After the controller recognizes the signal of the acceleration sensor, the high wind high heat high ion concentration mode is activated to adjust the heating wire power. Increase the power of the motor fan and increase the concentration of negative ions.
  • Blowing temperature sensor placed between the heating wire (temperature control module) and the air outlet, optional, can also be placed near the air outlet in the air channel, used to detect the temperature of the smart blower in real time, and according to the temperature Changes to dynamically adjust the power of the heating wire (temperature control module) and the wind speed and volume of the blower motor (wind control module), so that the temperature difference of the blowing temperature is within the deviation range to achieve constant temperature hair care.
  • the hair dryer of the present application also includes: ion generator, mica sheet, heating wire and other components.
  • the ion generator is arranged at the air outlet of the intelligent blower and used to generate positive ions and/or negative ions.
  • the ion generator is arranged between the heating wire and the air outlet.
  • the ion generator is a negative ion generator.
  • the mica sheet is the shell of the heating wire, which has the role of protection, insulation, heat insulation and support of the heating wire.
  • the round mica sheet forms the air outlet of the heating wire.
  • the mica sheet can be selected from carbon fiber products, far infrared ceramics, jade and other materials
  • the inner wall of the mica film is also coated with a far-infrared coating for generating far-infrared rays.
  • the far-infrared coating emits far-infrared rays and is used to promote blood circulation to the scalp during hair blowing, improve immunity, and relieve headaches. , Dizziness, insomnia, fatigue and other symptoms; at the same time, it can also be skin care and beauty, enhance metabolism, improve immune function; accelerate dry hair.
  • the mica sheet of the smart hair dryer of the present application is arranged in a drum shape with a built-in bracket, and a spiral or corrugated heating wire is arranged between the brackets in the mica sheet to increase the contact area with the airflow.
  • the mica sheet also has the functions of insulation, heat insulation and supporting heating wire.
  • the pointing device and the display device are important components in the smart hair dryer of the present application, and the embodiments adopted above are respectively the working principles and structures of the pointing device and the display device in the smart hair dryer described.
  • FIG. 5 shows a connection diagram between various components, mainly including: a micro controller (Microcontroller Unit; MCU), a distance sensor, a temperature/humidity sensor, a WIFI module, a Bluetooth module, a display module, a wind control module, Connection relationship of temperature control module, AC-DC module, AC power collection and zero-crossing detection.
  • MCU Microcontroller Unit
  • the second embodiment of the present application provides another intelligent hair dryer, including: a body, a main air duct provided in the body, an airflow detection channel, a sensor and a control system, and a display driver provided in the body Device.
  • the main air duct is provided with an air outlet in the fuselage, an air flow generating device (motor fan unit) is provided inside, and the air inlet of the air flow detection channel and the main air duct outlet are provided at the Describe the same side of the fuselage.
  • the sensor is arranged in the airflow detection channel and connected with the processor, and is used for detecting the status information of the airflow.
  • the display driving device is connected to the control system, and is used for outputting the current state information of the blown object to the display terminal according to the detection result of the sensor; or outputting the blower's air conditioner to the display terminal according to the working state information of the hair dryer obtained by the control system Work status information.
  • the display device of the smart hair dryer can be installed on the body of the smart hair dryer. As an embodiment of installing the display device, it can be arranged on the other side relative to the air outlet. Since the air outlet is located at the front end of the smart hair dryer, the display device can be located at the rear end of the intelligent hair dryer. Optionally, the display device faces away from the direction of the air outlet. In the embodiment of the present application, the display device is perpendicular to the axis direction of the body of the hair dryer The axis of the blower body passes through the display device.
  • the display device may be a ring structure or a square structure, which is not particularly limited.
  • Such a position layout facilitates the user to observe the display device when the user uses the hair dryer, and obtains the operation state information of the hair dryer in time.
  • the display device is a display screen, preferably a touch screen, and the display screen is connected to the display driving device.
  • the display device is used to display the change in humidity of the surface of the object to be blown, the working mode of the smart blower, and environmental parameters during the blowing process.
  • it is used to display the working mode (including smart mode and manual mode), or to display the fault identification when the smart blower fails; and to display the environmental parameters of the smart blower work (including temperature, humidity, distance, power, wind speed, motor speed) Information), working status information (including smart light ring, air duct blocked, motor overheating, sensor status information, battery power information, etc.), user status information (for example, different objects require different working parameters, set for different objects
  • user information is stored in the cloud or processor, the smart hair dryer obtains user status information from the cloud or processor, and displays) and displays user operation guide and related after-sales and other related information.
  • the above user status information can be obtained from the cloud of the hair dryer or the processor.
  • the information of different blown objects is stored in the cloud in advance. It can be obtained through face recognition, text input, and wireless
  • a wireless communication module is further provided inside the smart hair dryer, and the wireless communication module is connected to the display driving device, and is used to output the output information of the display driving device to an intelligent terminal connected to an electrical signal Or intelligent robot.
  • the intelligent terminal or intelligent robot performs information interaction with the intelligent hair dryer.
  • the intelligent terminal or intelligent robot displays the output information of the intelligent hair dryer, or the intelligent hair dryer executes the instructions of the intelligent terminal or intelligent robot.
  • the smart terminal may be at least one of data processing devices such as smartphones, PADs, and computers.
  • the smart robot may be any robot such as a cleaning robot, a vacuum cleaner, a washing machine, a window cleaning robot, a service robot, a butler robot, a nanny robot, a companion robot, etc. At least one of them.
  • other materials that can be used as the display device of this embodiment also belong to the protection scope of the present application.
  • an indication device may be provided on the outside of the fuselage inside the smart hair dryer.
  • the indication device is connected to the processor and used to indicate the current state of the object to be blown or to indicate the status of the blower according to the detection result of the sensor.
  • Working status For the working principle of the specific indicating device, please refer to the relevant description of the first embodiment, which will not be repeated here.
  • the display device of the smart hair dryer of the present application has a touch function for controlling the switching of the working mode of the smart hair dryer, and inputting and/or outputting the blowing parameters of the smart hair dryer.
  • control mode the user can input and/or output the blowing parameters of the smart hair dryer by manual input, click, check, long press, slide, gesture control, voice control, etc.
  • the display device may display the working state information of the smart hair dryer in the form of text, pattern or language.
  • the indication device and the display device of the smart hair dryer are any one of LED lights, LCD screens, and OLED display screens.
  • the indication device and the display device are LED light strips and curved screens Or any kind of flexible display.
  • the third embodiment of the present application provides a method for automatically controlling the operation of the intelligent hair dryer.
  • FIG. 6 it is a flowchart of a job control method provided in a third embodiment of the present application. Since the method embodiment is basically similar to the device embodiment, the description is relatively simple. For related parts, please refer to the description of the device embodiment. The method embodiments described below are only schematic.
  • FIG. 6 is a schematic flowchart of a job control method provided by a third embodiment of the present application. As shown in FIG. 6, the method includes steps S601 to S604.
  • Step S601 Obtain the current working power of the smart hair dryer and the current state information of the blown object.
  • the smart hair dryer is operated according to the initial default power.
  • the power P 0 at the initial operation hairdryer, P 0 is the smart blower can run and standby power than a minimum power P min slightly larger.
  • Step S602 Acquire the blowing power of the smart hair dryer required by the blown object according to the current state information of the blown object and the relationship between the preset working power and the object state information.
  • the power required by the blown object is obtained according to the current state information of the blown object and the relationship between the preset working power and the object state information.
  • the state information of the blown object will change, therefore, it is necessary to obtain the state information of the blown object in real time, and thereby obtain the blowing power of the smart blower required by the blown object .
  • the airflow that has been in contact with the object being blown is obtained; then, the status information of the airflow that has been in contact with the object being blown is obtained; finally, the blown air is estimated according to the status information of the airflow
  • the state estimation information of the object uses the state estimation information as the current state information of the blown object.
  • the airflow state information includes at least one of airflow temperature information and airflow humidity information
  • the blown object state estimation information includes both of the blown object temperature estimation information and the humidity estimation information At least one.
  • Step S603 judging whether the current working power needs to be adjusted according to the current working power of the smart hair dryer and the blowing power of the smart hair dryer required by the blown object.
  • the blowing power of the intelligent hair dryer required by the object to be blown After obtaining the blowing power of the intelligent hair dryer required by the object to be blown, determine whether the current power of the intelligent hair dryer is required according to the current power of the intelligent hair dryer and the blowing power of the intelligent hair dryer required by the object to be blown The working power is adjusted.
  • Step S604 Adjust or maintain the current working power of the smart hair dryer according to the judgment result.
  • the current working power of the smart hair dryer is adjusted or maintained based on the judgment result.
  • the object to be blown is changed from the original wet hair to semi-wet hair.
  • the current working power of the smart hair dryer is P max
  • the blowing power P 1 P 1 is less than P max
  • the power P max of the hair dryer needs to be adjusted to P 1 ; if the object to be blown is still wet hair, the current working power P max of the smart hair dryer is kept unchanged.
  • the above method for automatically controlling the operation of the intelligent hair dryer utilizes the humidity and/or temperature information obtained by the sensors provided in the airflow detection channel in the intelligent hair dryer to achieve intelligent control of the operation of the hair dryer and effectively improve the use experience of the hair dryer.
  • the smart hair dryer When the user uses a smart hair dryer to blow his hair, when the smart hair dryer is turned on, the smart mode is entered, the distance sensor detects the presence of hair to be blown, and the smart hair dryer operates at the initial power P 0 .
  • the humidity sensor detects that the hair is wet, and determines that there is a need for blowing hair, the power of the smart hair dryer is adjusted to P max .
  • the wet hair becomes semi-dry hair, and the color of the smart light ring gradually changes , From gradient to blue, the power of the smart blower is automatically reduced to P 1 . In this process, the smart hair dryer can automatically adjust the power, avoiding the trouble of manually adjusting the power of the smart hair dryer.
  • the distance sensor of the smart hair dryer automatically recognizes that there is no object to be blown within the specified distance, and the power of the smart hair dryer drops to P min to run. After running for a period of time, it still automatically recognizes that there is no blown object within the specified distance, and then automatically enters the standby state.
  • the intelligent hair dryer guarantees safety during use.
  • the embodiments of the present application also provide a computer-readable storage medium storing computer instructions, when the computer instructions are executed by one or more processors, causing the one or more processors to perform the above job control Steps in the method.
  • FIG. 7 is a schematic flowchart of an information display method provided by an embodiment of the present application. As shown in Figure 4, the method includes:
  • Step S701 Acquire status information of the airflow that has been in contact with the blown object.
  • Step S702 Determine the current state of the blown object according to the state information of the airflow.
  • Step S703 Display the current state of the blown object.
  • the hair dryer includes: a body, a main air duct provided in the body, a control system, an airflow detection channel, and a sensor provided in the airflow detection channel.
  • the hair dryer also includes: an indicating device provided on the body.
  • the air inlet of the airflow detection channel and the air outlet of the main air channel are provided on the same side of the fuselage. When the blower blows the object to be blown, the air inlet of the airflow detection channel and the air outlet of the main air channel are opposite to the object to be blown.
  • the sensor is disposed in the airflow detection channel, and can detect the status information of the airflow entering the airflow detection channel.
  • the airflow that has been in contact with the object to be blown may enter the airflow detection channel through the air inlet of the airflow detection channel, and flow in the airflow detection channel to contact the sensor.
  • the sensor can collect the status information of the airflow that has been in contact with the blown object. Since the airflow touched by the blowing object carries the status information of the blown object, the status information of the airflow touched by the blowing object may reflect the status information of the blown object.
  • the sensor can provide the control system with the status information of the airflow that has been in contact with the blown object.
  • control system is connected to the pointing device, and is used to control the pointing device to display the current state of the blown object according to the detection result of the sensor. That is, the control system can control the indicating device to indicate the current state of the blown object according to the status information of the airflow. In this way, the user can intuitively understand the current state of the blown object, which helps to improve the user experience.
  • steps S701-step S703 reference may be made to the relevant content of the foregoing embodiments, and details are not described herein again.
  • the embodiments of the present application also provide a computer-readable storage medium storing computer instructions, when the computer instructions are executed by one or more processors, causing the one or more processors to perform the above information display Steps in the method.
  • the execution body of each step of the method provided in the above embodiments may be the same device, or the method may also be performed by different devices.
  • the execution subject of steps S201 and S202 may be device A; for another example, the execution subject of step S201 may be device A, and the execution subject of step S202 may be device B; and so on.
  • the control system may include a controller and its peripheral circuits.
  • the controller can be any hardware processing device.
  • the processor may be a central processing unit (Central Processing Unit, CPU), a graphics processor (Graphics Processing Unit, GPU) or a micro control unit (Microcontroller Unit, MCU); or a field programmable gate array (Field -Programmable Gate Array (FPGA) Programmable Array Logic (PAL), General Array Logic (GAL), Complex Programmable Logic Device (Complex Programmable Logic Device, CPLD) and other programmable devices; Or it may be an advanced reduced instruction set (RISC) processor (Advanced RISC Machines, ARM) or a system chip (System on Chip SOC), etc., but it is not limited to this.
  • RISC advanced reduced instruction set
  • the embodiments of the present invention may be provided as methods, systems, or computer program products. Therefore, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment, or an embodiment combining software and hardware. Moreover, the present invention may take the form of a computer program product implemented on one or more computer usable storage media (including but not limited to disk storage, CD-ROM, optical storage, etc.) containing computer usable program code.
  • computer usable storage media including but not limited to disk storage, CD-ROM, optical storage, etc.
  • each flow and/or block in the flowchart and/or block diagram and a combination of the flow and/or block in the flowchart and/or block diagram may be implemented by computer program instructions.
  • These computer program instructions can be provided to the processor of a general-purpose computer, special-purpose computer, embedded processing machine, or other programmable data processing device to produce a machine that enables the generation of instructions executed by the processor of the computer or other programmable data processing device
  • These computer program instructions may also be stored in a computer readable memory that can guide a computer or other programmable data processing device to work in a specific manner, so that the instructions stored in the computer readable memory produce an article of manufacture including an instruction device, the instructions
  • the device implements the functions specified in one block or multiple blocks of the flowchart one flow or multiple flows and/or block diagrams.
  • These computer program instructions can also be loaded onto a computer or other programmable data processing device, so that a series of operating steps are performed on the computer or other programmable device to produce computer-implemented processing, which is executed on the computer or other programmable device
  • the instructions provide steps for implementing the functions specified in one block or multiple blocks of the flowchart one flow or multiple flows and/or block diagrams.
  • the computing device includes one or more processors (CPUs), input/output interfaces, network interfaces, and memory.
  • processors CPUs
  • input/output interfaces network interfaces
  • memory volatile and non-volatile memory
  • the memory may include non-permanent memory, random access memory (RAM) and/or non-volatile memory in a computer-readable medium, such as read only memory (ROM) or flash memory (flash RAM). Memory is an example of computer-readable media.
  • RAM random access memory
  • ROM read only memory
  • flash RAM flash memory
  • Computer readable media including permanent and non-permanent, removable and non-removable media, can store information by any method or technology.
  • the information may be computer readable instructions, data structures, modules of programs, or other data.
  • Examples of computer storage media include, but are not limited to, phase change memory (PRAM), static random access memory (SRAM), dynamic random access memory (DRAM), other types of random access memory (RAM), read-only memory (ROM), electrically erasable programmable read-only memory (EEPROM), flash memory or other memory technologies, read-only compact disc read-only memory (CD-ROM), digital versatile disc (DVD) or other optical storage, Magnetic tape cassettes, magnetic tape magnetic disk storage or other magnetic storage devices or any other non-transmission media can be used to store information that can be accessed by computing devices.
  • computer-readable media does not include temporary computer-readable media (transitory media), such as modulated data signals and carrier waves.

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Abstract

一种智能吹风机,包括:气流检测通道(1),传感器(2),控制系统以及主风道(3);气流检测通道(1)设置于主风道(3)的至少一侧,气流检测通道(1)的进风口开口朝向智能吹风机主风道(3)吹风方向;传感器(2)设置于气流检测通道(1)中,传感器(2)用于检测与被吹风对象接触过的气流的状态信息;控制系统可将气流的状态信息用于对智能吹风机的工作状态的控制。在吹风机内部安装传感器(2)与控制系统,通过检测气流状态信息,用以自动控制智能吹风机的工作,增强了用户的使用体验。

Description

智能吹风机及其作业控制和信息显示方法、存储介质
交叉引用
本申请引用于2018年12月30日递交的名称为“智能吹风机与自动控制智能吹风机工作的方法”的第201811563745.3号中国专利申请和2019年09月19日递交的名称为“智能吹风机与自动控制智能吹风机工作的方法”的第201910887334.8号中国专利申请,其通过引用被全部并入本申请。
技术领域
本申请涉及吹风机领域,具体涉及一种智能吹风机及其作业控制和信息显示方法、存储介质。
背景技术
吹风机在日常生活中较为广泛,主要用于头发的干燥和整形,也可供实验室、理疗室及工业生产、美工等方面作局部干燥、加热和理疗之用。其工作原理是直接靠电动机驱动转子带动风叶旋转,当风叶旋转时,空气从进风口吸入,由此形成的离心气流再由风筒前嘴吹出。空气通过时,若装在风嘴中的发热支架上的发热丝已通电变热,则吹出的是热风;若选择开关不使发热丝通电发热,则吹出的是冷风。吹风机就是以此来实现烘干和整形。
目前的吹风机在使用的时候都是用户自己选择热度档位和风量档位,在吹干头发时,在头发很湿的情况下需要大风量急速吹走水分,即先用热风吹到大约六成干,然后用冷风吹到八成干,然后等待自然风干。在整个使用过程中,用户需要多次调整风量和热度,显然增加了用户反复调节档位的烦恼,造成用户使用体验较差。
另一方面,在使用过程中,用户无法准确感知吹风机的被吹风对象的当前状态,只能粗略感知吹风机的被吹风对象的当前状态,造成用户使用体验 较差。
发明内容
本申请提供一种智能吹风机及其作业控制方法,以解决用户在使用现有的吹风机的实际过程中需要反复调节档位的问题,同时也增强了用户的使用体验。
本申请提供一种智能吹风机,包括:气流检测通道,传感器,控制系统以及主风道;
所述气流检测通道设置于所述主风道的至少一侧,所述气流检测通道的进风口开口朝向所述智能吹风机主风道吹风方向,可收集与被吹风对象接触过的气流;
所述传感器设置于所述气流检测通道中,用于检测所述与被吹风对象接触过的气流的状态信息;
所述控制系统用于接收所述气流的状态信息,并将所述气流的状态信息用于对所述智能吹风机的工作状态的控制。
可选的,所述控制系统在将所述气流的状态信息用于对所述智能吹风机的工作状态的控制时,具体用于:
根据所述气流的状态信息,获取所述被吹风对象所需的所述智能吹风机的吹风参数;并控制所述主通道内的风扇单元的转速和/或加热单元的加热温度,以将所述智能吹风机的吹风参数调整至所述智能吹风机按照所述被吹风对象所需的所述智能吹风机的吹风参数。
可选的,所述气流状态信息包括以下信息中的至少一种:气流的温度信息、气流的湿度信息。
可选的,所述气流检测通道连接至所述风扇单元的上游区域,所述主风道的出风口位于所述风扇单元的下游区域。
可选的,所述主风道的出风口的面积大于所述气流检测通道的进风口的 面积。
可选的,所述主风道还包括连接所述上游区域的主进风口,所述主进风口位于所述智能吹风机的后端,所述出风口位于所述智能吹风机的前端。
可选的,所述气流检测通道通过所述进风口收集与被吹风对象接触过的气流,所述传感器接收所述被吹风对象接触过的气流并解析所述被吹风对象接触过的气流的状态信息。
可选的,所述气流检测通道为前宽后窄的变截面结构,所述传感器设置在靠后侧的位置。
可选的,所述传感器至少有两个,并且在所述气流检测通道的气流流动方向上间隔设定距离设置。
可选的,所述气流检测通道的数量设置为一个、两个或者多个。
可选的,所述传感器还包括距离传感器,所述气流状态信息包括气流运动距离。
本申请另外提供一种作业控制方法,包括:
获取被吹风机接触过的气流的状态信息;
根据所述气流的状态信息推算被吹风对象的状态推算信息;
根据所述被吹风对象的状态推算信息,获得所述被吹风对象所需的所述智能吹风机的吹风参数,其中所述智能吹风机的吹风参数包括吹风的风速与吹风的温度;
控制所述智能吹风机按照所述被吹风对象所需的所述智能吹风机的吹风参数,向所述被吹风对象吹风。
可选的,所述气流状态信息包括气流的温度信息、气流的湿度信息两者中的至少一种,所述被吹风对象的状态推算信息包括被吹风对象的温度推算信息、湿度推算信息两者中的至少一种。
可选的,还包括实时获得所述智能吹风机当前的吹风参数,根据所述智 能吹风机当前的吹风参数,以及所述被吹风对象所需的智能吹风机的吹风参数判断是否调整所述智能吹风机的吹风参数;
其中,当所述智能吹风机当前的吹风参数小于所述被吹风对象所需的智能吹风机的吹风参数时,增强所述智能吹风机当前的吹风参数,反之,则减弱所述智能吹风机当前的吹风参数。
与现有技术相比,本申请具有以下优点:
本申请提供一种智能吹风机,包括:气流检测通道,传感器,控制系统以及主风道;所述主风道内设有用于产生气流的风扇单元和用于对气流加热的加热单元;所述气流检测通道设置于所述主风道的至少一侧,所述气流检测通道的进风口开口朝向所述智能吹风机主风道吹风方向;所述传感器设置于所述气流检测通道中,所述传感器用于检测气流状态信息;所述控制系统用于接收所述传感器输出的检测结果,并将所述检测结果用于对所述风扇单元的转速和/或所述加热单元的加热温度的调节。采用本申请的智能吹风机,能够保证用户在使用过程中省去反复调节吹风机档位的烦恼,本申请的智能吹风机采用智能模式,即在吹风机内部安装传感器与控制系统,通过检测气流状态信息,用以自动控制智能吹风机的工作,增强了用户的使用体验。
本申请同时提供的作业控制方法,该方法在上述智能吹风机的基础上,自动控制吹风机的工作,从而方便用户使用。
本申请提供还一种智能吹风机,以解决用户在使用现有吹风机过程中不能准确获知吹风机的被吹风对象的当前状态的问题,同时也增强了用户的使用体验。本申请同时提供另外一种智能吹风机与其作业控制方法,该方法能够省去反复调节档位的烦恼。
本申请提供一种智能吹风机,包括:机身、设置于所述机身内的主风道、气流检测通道、传感器及控制系统,以及设置于所述机身外侧的指示装置;其中,
所述主风道在机身开设有出风口,内部设置有气流产生装置;
所述气流检测通道的进风口与所述主风道出风口设置于所述机身同侧;
传感器设置于所述气流检测通道内并与所述控制系统相连接,用于检测进入所述气流检测通道中的气流的状态信息;
所述控制系统与所述指示装置相连接,用于根据所述气流的状态信息控制所述指示装置指示被吹风对象的当前状态。
可选的,所述指示装置形状设置为以下任一种:环绕机身的连续或非连续环状结构,沿机身外侧面设置的条状结构。
可选的,所述传感器为温度传感器或湿度传感器;相应的,所述当前状态为被吹风对象当前的湿度状态或温度状态。
可选的,还包括设置于机身上主风道出风口一侧的距离传感器;
所述距离传感器与所述控制系统相连接,用于检测所述被吹风对象与所述出风口的距离;
所述控制系统还用于根据所述距离传感器的检测结果控制所述指示装置指示所述被吹风对象与所述出风口的距离。
可选的,还包括设置于所述机身内的吹风机工作状态信息采集模块,所述吹风机工作状态信息采集模块与所述控制系统相连接;
所述控制系统还用于根据所述工作状态采集模块采集的吹风机的工作状态信息控制所述指示装置指示吹风机的工作状态;
所述工作状态信息包括以下至少一种:吹风温度、吹风的风速、吹风时间或电机功率。
可选的,所述控制系统具体用于:根据吹风机工作状态信息采集模块的采集的信息,控制指示装置以如下任一种方式指示所述被吹风对象的当前状态或吹风机的工作状态:渐变显示、单色显示、渐变闪烁或单色闪烁。
可选的,所述控制系统具体用于:根据所述传感器的检测结果,控制所述指示装置以如下任一种方式指示所述被吹风对象的当前装置:渐变显示、 单色显示、渐变闪烁或单色闪烁。
本申请还提供一种智能吹风机,包括:机身、设置于所述机身内的主风道、气流检测通道、传感器及控制系统,以及设置于所述机身内的显示驱动装置;其中,
所述主风道在机身开设有出风口,内部设置有气流产生装置;
所述气流检测通道的进风口与所述主风道出风口设置于所述机身同侧;
传感器设置于所述气流检测通道内并与所述处理器相连接,用于检测进入所述气流检测通道中的气流的状态信息;
所述显示驱动装置与所述处理器相连接,用于根据所述气流的状态信息,向显示终端输出被吹风对象的当前状态信息;或者,根据控制系统获取的吹风机的工作状态信息向显示终端输出吹风机的工作状态信息。
可选的,还包括设置于所述机身外侧显示屏,所述显示屏与所述显示驱动装置相连接,所述显示屏设置于所述机身外侧与出风口相对的一端。
可选的,还包括无线通信模块,所述无线通信模块与所述显示驱动装置相连接,用于将所述显示驱动装置的输出信息输出至电信号连接的智能终端或智能机器人。
可选的,还包括设置于机身外侧的指示装置,所述指示装置与所述处理器相连接,用于根据传感器的检测结果指示被吹风对象的当前状态或指示吹风机的工作状态。
本申请提供一种自动控制智能吹风机工作的方法,包括:
获取所述智能吹风机当前工作功率与被吹风对象当前状态信息;
根据所述被吹风对象当前状态信息,以及,预设的工作功率与被吹风对象状态信息的关系,获取所述被吹风对象所需的所述智能吹风机的吹风功率;
根据所述智能吹风机当前工作功率,以及,所述被吹风对象所需的所述智能吹风机的吹风功率判断是否需要对所述当前工作功率进行调整;
根据判断结果调整或保持所述智能吹风机工作功率。
可选的,在获取所述智能吹风机当前工作功率与被吹风对象当前状态信息之前,按照初始默认功率运行所述智能吹风机。
可选的,在按照初始默认功率运行所述智能吹风机之后,在获取所述智能吹风机当前工作功率与被吹风对象当前状态信息之前,还包括:
判断所述智能吹风机的出风口指定的距离内是否存在被吹风对象;若不存在,则将所述智能吹风机的功率调整至最低功率;若存在,则获取所述智能吹风机当前工作功率与被吹风对象当前状态信息。
可选的,所述获取被吹风对象当前状态信息,包括:
获取与被吹风对象接触过的气流的状态信息;
根据所述气流的状态信息推算被吹风对象的状态推算信息,将所述状态推算信息作为所述被吹风对象当前状态信息。
可选的,所述气流状态信息包括气流的温度信息、气流的湿度信息两者中的至少一种,所述被吹风对象的状态推算信息包括被吹风对象的温度推算信息、湿度推算信息两者中的至少一种。
本申请实施例还提供一种信息显示方法,包括:
获取与被吹风对象接触过的气流的状态信息;
根据所述气流的状态信息,确定所述被吹风对象的当前状态;
显示所述被吹风对象的当前状态。
与现有技术相比,本申请具有以下优点:
本申请提供一种智能吹风机,包括:机身、设置于机身内的主风道、气流检测通道、传感器及控制系统,以及设置于机身外侧的指示装置;其中,主风道在机身开设有出风口,内部设置有气流产生装置;气流检测通道的进风口与主风道出风口设置于机身同侧;传感器设置于气流检测通道内并与控制系统相连接,用于检测气流的状态信息;控制系统与指示装置相连接,用 于根据传感器的检测结果控制指示装置指示被吹风对象的当前状态。通过在智能吹风机机身上安装指示装置,并指示被吹风对象的当前状态,采用该方式能够让使用者准确且直观地获知吹风机的被吹风对象的当前状态。
附图说明
此处所说明的附图用来提供对本申请的进一步理解,构成本申请的一部分,本申请的示意性实施例及其说明用于解释本申请,并不构成对本申请的不当限定。在附图中:
图1为本申请第一实施例提供的一种智能吹风机的结构示意图。
图2为本申请第二实施例的一种作业控制方法的方法流程图。
图3为本申请第一实施例提供的一种智能吹风机的外围结构示意图。
图4为本申请第一实施例提供的一种智能吹风机的剖视图。
图5为本申请实施例提供的智能吹风机各部件之间的连接关系图。
图6为本申请第三实施例的一种作业控制方法的方法流程图。
图7为本申请实施例提供的一种信息显示方法的流程示意图。
具体实施方式
为使本申请的目的、技术方案和优点更加清楚,下面将结合本申请具体实施例及相应的附图对本申请技术方案进行清楚、完整地描述。显然,所描述的实施例仅是本申请一部分实施例,而不是全部的实施例。基于本申请中的实施例,本领域普通技术人员在没有做出创造性劳动前提下所获得的所有其他实施例,都属于本申请保护的范围。
以下结合附图,详细说明本申请各实施例提供的技术方案。
应注意到:相同的标号在下面的附图以及实施例中表示同一物体,因此,一旦某一物体在一个附图或实施例中被定义,则在随后的附图和实施例中不需要对其进行进一步讨论。
本申请提供一种智能吹风机与相关的作业控制方法,以下采用具体的实施例对本申请的智能吹风机与自动控制智能吹风机工作的方法进行描述。
如图1所示,第一实施例为本申请提供的一种智能吹风机的结构示意图,所述智能吹风机包括:气流检测通道1,传感器2,控制系统以及主风道3;所述主风道3内设有用于产生气流的风扇单元和用于对气流加热的加热单元,在本实施例中,分别对应于图1的风扇5与加热丝7;在本申请的智能吹风机的内部结构中,气流检测通道1连接至风扇单元的上游区域,主风道3的出风口8位于所述风扇单元的下游区域,使得气流检测通道1内的气流经过风扇单元向主风道3的出风口8移动。上述过程中气流移动的原理描述具体如下:在智能吹风机工作时,风扇单元即风扇5的上游区域会形成负压,由于气流检测通道1连接至风扇单元的上游区域,因此气流能够通过气流检测通道1的进风口被自动吸入气流检测通道1中,在风扇5的作用下,气流会经过风扇单元向主风道3的出风口8移动。
在本实施例中,气流检测通道1中设置有传感器2。其中,传感器2可检测进入气流检测通道1中的气流的状态信息。在本实施例中,气流检测通道1的进风口开口朝向智能吹风机主风道3的吹风方向。这样,当智能吹风机对被吹风对象吹风时,与被吹风对象接触过的气流便可通过气流检测通道1的进风口进入气流检测通道1内,并在气流检测通道1内流动而与传感器2接触。这样,传感器2便可采集与被吹风对象接触过的气流的状态信息。由于被吹风对象接触过的气流携带有被吹风对象的状态信息,因此,被吹风对象接触过的气流的状态信息可反映被吹风对象的状态信息。其中,气流状态信息包括以下信息中的至少一种:气流的温度信息、气流的湿度信息。气流的温度信息可以是气流的相对温度信息或绝对温度信息;气流的湿度信息可以为气流的相对湿度信息或绝对湿度信息等。相应地,被吹风对象的状态信息也可为温度和湿度信息中的至少一种。
进一步,传感器2便可将与被吹风对象接触过的气流的状态信息提供给 控制系统。进一步,控制系统可根据气流的状态信息,控制智能吹风机的工作状态,即将气流的状态信息用于对智能吹风机的工作状态的控制上来。
可选地,控制系统可根据与被吹风对象的气流状态信息确定被吹风的状态信息,并根据被吹风对象的状态信息,控制智能吹风机的工作状态。
本实施例提供的吹风机,可获取与被吹风对象接触过的气流的状态信息,该状态信息在一定程度上可反映被吹风对象的状态信息,因此,根据该气流的状态信息控制智能吹风机的工作状态,可使智能吹风机的工作状态与被吹风对象的状态相适配,实现吹风机工作状态的自动调节,无需用户手动调整,进而有助于提高用户体验。
在本申请的智能吹风机中,所述气流检测通道1设置于所述主风道3的至少一侧,所述气流检测通道1可以是设置在所述主风道3的周围的任意位置,例如可以是主风道3的上侧、下侧、左侧或者右侧,且所述气流检测通道1的数量至少为一个。图1a仅以气流检测通道1设置于主风道3的上侧进行图示,但并不对其设置位置和数量构成限定。
具体地,所述气流检测通道1通过所述气流检测通道1的进风口收集与被吹风对象接触过的气流。为更好地吸入智能吹风机被吹风对象接触过的气流,在实际中,所述气流检测通道1可以设置成前宽后窄的变截面结构,即气流检测通道1的进风口设置成整个气流检测通道1中最宽的部分,所述传感器2可设置在气流检测通道1靠后侧的位置,气流检测通道1内部逐渐变窄,可保证气流检测通道1吸入与被吹风对象接触过的气流后,气流比较聚集,从而有助于维持该气流的温度与湿度,同时将传感器2可设置在气流检测通道1靠后侧的位置,以便使传感器2中的敏感元件能够与密度更大的气流充分接触,获得更佳的测量结果。
为在所述气流检测通道1中多个位置检测并解析到与上述被吹风对象接触过的气流状态信息,在所述气流检测通道1中可以设置2个或多个传感器2。在本申请实施例中,多个是指3个或3个以上。所述传感器2能够检测所述 气流的温度与湿度信息,或者检测温度信息、湿度信息两个信息中的一种;具体地,在上述气流被吸入气流检测通道1中,气流会在气流检测通道1中流动,进而接触到传感器2,相应地,传感器2中的温度与湿度响应装置会因接触所述气流而探测气流的温度与湿度。
上述被吹风对象接触过的气流形成过程描述如下:在本申请的智能吹风机的主风道3设置有连接风扇单元的上游区域的主进风口,在智能吹风机吹风过程中,智能吹风机在内部的电机6与风扇5的作用下,会经后保护罩4从主进风口吸入大量的空气至主风道3中,大量的空气在进入吹风机主风道3后,经吹风机内部的加热丝7加热,最终从吹风机主风道3的出风口8吹出,大量空气经过吹风机吹向被吹风对象,少量空气气流在接触被吹风对象后会通过气流检测通道1的进风口进入气流检测通道1。由于在本申请中设置的主风道3的主进风口的面积与主风道3的出风口8的面积均大于气流检测通道1的进风口的面积,因此只有少部分的气流进入气流检测通道1而基本不会影响吹风机的吹风效果,同时这部分气流是大量空气接触到被吹风对象被折回的部分空气气流,因此该气流的气流状态信息能够反映被吹风对象的状态信息。其中,被吹风对象的状态信息可以为被吹风对象的温度和湿度信息中的至少一种。在实际生活中,吹风机应用较为广泛,以下以本实施例的智能吹风机吹头发过程为例进行说明。
如图1所示,本实施例的智能吹风机后端安装有后保护罩4,并且在智能吹风机后端设有主风道3的主进风口,对应的,主风道3的出风口8位于智能吹风机的前端。启动智能吹风机智能工作后,智能吹风机的风扇5启动,在电机6的带动下,智能吹风机会经后保护罩4从主风道3的主进风口吸入大量的空气至主风道3中,大量的空气在进入吹风机主风道3后,经吹风机内部的加热丝7加热后,从吹风机的主风道3的出风口8吹出,大量空气经过吹风机吹向头发,少量空气气流在接触头发后会通过气流检测通道1的进风口进入气流检测通道1,由于这部分气流是大量空气接触到头发后被折回的 部分空气气流,因此该气流能够反映头发的真实温度与湿度;之后该气流流经传感器2。传感器2便可通过获取与头发接触过的气流的状态信息,并将气流的状态信息提供给控制系统。进一步,控制系统可通过气流状态信息确定头发的状态信息,并根据头发的状态信息,控制智能吹风机的工作状态。
在本实施例中,传感器2可以设置在气流检测通道1的任意位置,在实际安装中,可以将传感器2设置在气流检测通道1的进风口或气流检测通道1的内部或者其他位置,当然也可以同时安装多个传感器,例如,将传感器2设置在较靠近气流检测通道1进风口的位置,在靠近气流检测通道1进风口的位置安装的传感器2能够在较短时间内接触到接触过头发的气流,因此能够更准确地探测接触过头发的气流的温度与湿度信息;将传感器2设置在气流检测通道1的内部,由于气流检测通道1的内部通道为前宽后窄的结构,尤其是将传感器2设置在气流检测通道1的内部通道最窄的部分时,由于此处气流最为聚集,因此安装在此处的传感器2能够最快地响应接触过头发的气流的温度与湿度信息。或者,传感器2按照设定的距离间隔设置在气流检测通道1中的不同位置上,以检查气流在不同位置的温度与湿度信息。上述将传感器2设置在不同的位置,可检测气流流经智能吹风机内部不同位置的温度与湿度变化信息,以便于对流经智能吹风机内部的气流的温度与湿度参数进行拟合,进而推算头发的状态推算信息,其中头发的状态推算信息包括头发的温度推算信息、湿度推算信息两者中的至少一种,从而使本申请的智能吹风机从主风道的出风口8吹出的风更匹配被吹风对象所需要的吹风。
在本申请的智能吹风机中,为推算头发的状态推算信息,除需要获得流经气流检测通道1的内部的气流的温度与湿度信息,还需要获得吹风机吹出的风接触头发之前吹风机的吹风的温度与吹风的风速,即吹风机吹风的温度与吹风的风速。获得吹风机吹风的温度与吹风的风速的途径有多种,例如吹风的温度可通过将传感器设置在主风道3的任意位置来检测,例如将温度传感器设置在出风口8的位置。或者,由于在智能吹风机吹风时,在吹风机工 作的档位下存在与该工作档位对应的理论温度,因此可通过吹风机的工作档位对应的理论温度推测吹风机的吹风的温度,同样地,吹风的风速也可依据上述获得吹风的温度的获得方式获得,此处不再赘述。
在获得吹风机吹风的温度与吹风的风速以及流经气流检测通道1的内部的气流的温度与湿度信息后,可根据上述参数进行拟合,从而获得头发的状态推算信息,即利用了气流接触头发前、后的温度变化信息与湿度变化信息来获得头发的状态推算信息。更具体地,在拟合获得头发的状态推算信息时,可通过多种方式,以下采用两种方式说明拟合方式:
第一种拟合方式:通过公式方法进行拟合,具体地,在获得吹风机吹风的温度与吹风的风速以及流经气流检测通道1的内部的气流的温度与湿度信息后,将上述参数与头发的状态信息建立关系,在建立关系的实际操作中,可进行多次实验,实验内容包括但不限于检测不同时间内头发的状态信息以及与此对应的吹风机吹风的温度、吹风的风速、流经气流检测通道1的内部的气流的温度与湿度信息,或者更换不同的被吹风对象并检测不同被吹风对象的状态信息以及与此对应的吹风机吹风的温度、吹风的风速、流经气流检测通道1的内部的气流的温度与湿度信息,在获得大量的上述对应数据之后,可建立检测的上述参数与被吹风对象的状态信息的函数关系式,并将此函数关系式作为经验公式,其中所述检测的参数包括吹风机吹风的温度、吹风的风速、流经气流检测通道1的内部的气流的温度与湿度信息等。在获得经验公式后,只需将吹风机吹风的温度、吹风的风速、流经气流检测通道1的内部的气流的温度与湿度信息代入经验公式,即可推算头发的状态信息。
第二种拟合方式:将上述检测的参数与被吹风对象的状态信息做成一一对应的表,只需将吹风机吹风的温度、吹风的风速、流经气流检测通道1的内部的气流的温度与湿度信息从表格中查询,即可推算头发的状态信息。
为更全面检测气流状态信息,在上述的传感器中还可以设置距离传感器,通过距离传感器探测气流状态信息中的气流运动距离,所述距离传感器可以 采用多种方式实现,例如,可以在吹风机的头部设置LDS激光雷达测距装置。所述气流运动距离,可以定义为气流从出风口到被吹风对象(如头发)之间的距离,或者从出风口到被吹风对象又折返到所述气流检测通道1的进风口的距离。由于传感器在气流检测通道中检测获得的湿度、温度等只是气流检测通道中气流的温度、湿度,与真正希望获得的被吹风对象的温度、湿度参数有差别,而吹风机与被吹风对象的距离对两者的差别有很大影响,因此,所述距离传感器的测量结果,可以应用到上述拟合方式中作为一个重要的参数使用。
为使得流经气流检测通道1的气流形成流通的气流,可将气流检测通道1的出风口开设在主风道3的上游,即将气流检测通道1连接至风扇5的上游区域,此连接方式可以理解为将所述主风道3上游的低气压引入到所述气流检测通道1的进风口位置,接触被吹风对象的气流被挡回后,就更可能通过所述气流检测通道1流回主进风口的上游区域,与主进风口吸入的大量空气汇合,汇合之后再在风扇5的作用下,经主风道3从主风道3的出风口8吹出,通过上述过程,接触头发的气流可形成经过气流检测通道1循环流通的气流通道。
为更好地探测气流的温度与湿度的变化,在智能吹风机的主风道3的出风口8处也可安装传感器2。进一步,安装在智能吹风机的出风口8处的传感器2、安装在气流检测通道1的进风口的传感器2以及安装在气流检测通道1内部的传感器2能够对吹风机工作气流以及检测气流形成连续的梯度式的温度与湿度测量,并以此为依据更精确的推算被吹风对象的温度、湿度状况,为控制系统控制智能吹风机的工作提供更为精确的信息。
同样的,在所述气流检测通道1中的传感器可以设置两个或者多个,并且在所述气流检测通道的气流流动方向上按照设定距离间隔设置,这样同样可以获得对所述检测气流的梯度测量效果,从而能够更为精准的推算被吹风对象的温度、湿度状态。
在传感器2获得接触头发的气流的温度与湿度信息后,传感器2将接触头发的气流的温度与湿度信息传送至智能吹风机的控制系统,所述控制系统用于接收所述传感器输出的检测结果,并将所述检测结果用于对所述风扇单元的转速和/或所述加热单元的加热温度的调节,在本实施例中,上述调节所述风扇单元的转速和/或所述加热单元的加热温度对应于调节图1的风扇5的转速和/或加热丝7的加热温度。具体地,所述控制系统还包括控制器,所述控制器接收各个传感器2的检测的温度与湿度信息以及气流在接触头发前后的温度与湿度变化信息,并经过预设的程序,控制智能吹风机的吹风参数,其中所述智能吹风机的吹风参数包括吹风的风速与吹风的温度,更具体地,控制器控制智能吹风机的吹风参数是通过控制器分别控制风扇5的转速与加热丝7的加热,来控制智能吹风机的吹风的风速与吹风的温度。上述吹风的风速与吹风的温度在实际中具体体现为吹风的风量大小与吹出的风的凉热。
在智能吹风机控制系统的具体实现方式中,上述控制过程可以是在所述智能吹风机内部设置有控制芯片,控制芯片接收各个传感器2传送的接触头发的气流的温度与湿度信息以及气流在接触头发前后的温度与湿度变化信息,并根据头发的气流的温度与湿度信息以及气流在接触头发前后的温度与湿度变化信息经过数据转换得到用户的头发温度与湿度,控制芯片再根据转换得到的用户头发的温度与湿度信息,并经过预设的程序,控制智能吹风机的吹风参数,并以此吹风参数去调整智能吹风机的实际吹风情况,即调整智能吹风机的吹风功率。
例如在上述控制过程中,预设的程序可以是:首先根据控制芯片转换得到的用户头发的温度与湿度信息,周期或者实时计算被吹风对象所需的吹风参数;另外还需获得智能吹风机当前的吹风参数,其中所述吹风参数至少包括吹风的风速与吹风的温度,在获得被吹风对象所需的吹风参数与智能吹风机当前的吹风参数之后,比较被吹风对象所需的吹风参数与智能吹风机当前的吹风参数的关系,并以此调整智能吹风机的吹风的实际情况,在这个过程 中,智能吹风机是自动计算吹风参数并且自动调整智能吹风机的吹风情况,省去用户手工换挡的繁琐,提高了用户的体验。
具体而言,上述的预设程序的被吹风对象所需的吹风参数为根据当前气流检测通道1吸入的接触头发的气流确定的被吹风对象所需的吹风参数,若当前智能吹风机的吹风参数小于被吹风对象所需的吹风参数,即当前吹风的风速与吹风的温度小于被吹风对象所需的吹风的风速与吹风的温度,则控制系统增大吹风机的电机的功率,以自动增强所述智能吹风机吹风的风量与吹风的温度。例如可以增大风扇5的电机的转速与提高加热丝7的加热功率;若当前智能吹风机的吹风参数大于待吹的头发所需的吹风参数,即当前吹风的风速与吹风的温度大于待吹的头发所需的吹风的风速与吹风的温度,则控制系统可减小吹风机的功率,以自动减弱所述智能吹风机吹风的风量与吹风的温度,例如可以是在智能吹风机中减小风扇5的电机的转速与降低加热丝7的加热功率。由于智能吹风机在工作期间,气流检测通道1是以实时或者周期性吸入接触过头发的气流,经过智能吹风机吹风一段时间,吸入的接触过头发的气流的温度与湿度信息会有所变化,即控制芯片转换得到的用户头发的温度与湿度信息也会变化,而在实际智能吹风机的吹风过程中,头发的温度与湿度也是实时变化的,随着吹风的时间增加,头发的湿度不断减小,温度不断升高,因此,在此过程中吹头发所需的智能吹风机的工作参数也是不断变化的,例如在头发在不断吹干的过程中,所需智能吹风机所提供的风量大小与风的温度均逐渐减小,即待吹的头发所需的吹风参数不断减小,相应地,控制系统需要不断或者周期性调整所述智能吹风机的参数以适应被吹风对象的需求。
上述控制芯片经过数据转换得到用户的头发温度与湿度,主要是依据各个传感器2传送的接触头发的气流的温度与湿度信息以及气流在接触头发前后的温度与湿度变化信息获得,在上述各个安装位置的各个传感器中,安装在智能吹风机的气流检测通道1进风口的传感器2检测到的温度与湿度信息 最为接近头发的温度与湿度,安装在气流检测通道1最窄的部分的传感器2能够最快感应到通过气流检测通道1的接触过头发的气流的温度与湿度,安装在主风道3的出风口8处的传感器2能够感应到通过主风道3吹风的气流的温度与湿度信息。
在本申请的智能吹风机手持部分设置智能档位按钮,用户在使用的时候,只需调整到智能档,本申请的智能吹风机就可以根据传感器与控制芯片智能调节吹风机的风速和温度,从而免去用户多次调节吹风机档位的问题,增强了用户的使用体验。
在上述的实施例中,提供了一种智能吹风机,与之相对应的,本申请第二实施例提供一种作业控制的方法。
如图2所示,其为本申请第二实施例提供的一种作业控制方法的方法流程图。由于方法实施例基本相似于装置实施例,所以描述得比较简单,相关之处参见装置实施例的部分说明即可。下述描述的方法实施例仅仅是示意性的。
本申请第二实施例提供的作业控制方法的方法,如图2所示,所述方法包括步骤S201~S204:
步骤S201:获取与被吹风对象接触过的气流的状态信息。
步骤S202:根据所述气流的状态信息推算被吹风对象的状态推算信息。
步骤S203:根据所述被吹风对象的状态推算信息,获得所述被吹风对象所需的所述智能吹风机的吹风参数,其中所述智能吹风机的吹风参数包括吹风的风速与吹风的温度。
步骤S204:控制智能吹风机按照被吹风对象所需的智能吹风机的吹风参数,向被吹风对象吹风。
可选的,所述气流状态信息包括气流的温度信息、气流的湿度信息两者中的至少一种,所述被吹风对象的状态推算信息包括被吹风对象的温度推算信息、湿度推算信息两者中的至少一种。
可选的,还包括实时获得所述智能吹风机当前的吹风参数,根据所述智能吹风机当前的吹风参数,以及所述被吹风对象所需的智能吹风机的吹风参数判断是否调整所述智能吹风机的吹风参数;
其中,当所述智能吹风机当前的吹风参数小于所述被吹风对象所需的智能吹风机的吹风参数时,增强所述智能吹风机当前的吹风参数,反之,则减弱所述智能吹风机当前的吹风参数。
上述自动控制智能吹风机工作的方法,利用了本申请第一实施例提供的智能吹风机中通过设置在气流检测通道中的传感器获得的湿度和/或温度信息,实现对吹风机工作的智能控制,有效提升了吹风机的使用体验。
本申请虽然以较佳实施例公开如上,但其并不是用来限定本申请,任何本领域技术人员在不脱离本申请的精神和范围内,都可以做出可能的变动和修改,因此本申请的保护范围应当以本申请权利要求所界定的范围为准。
本申请实施例还提供一种存储有计算机指令的计算机可读存储介质,当计算机指令被一个或多个处理器执行时,致使一个或多个处理器执行上述作业控制方法中的步骤。
本申请分别还提供一种智能吹风机与相关的作业控制的方法,以下采用具体的实施例对本申请的智能吹风机与作业控制方法进行描述。
如图3和图4所示,图3为本申请第一实施例提供的智能吹风机的结构示意图,图4为本申请第一实施例的智能吹风机的剖视图。所述智能吹风机包括:机身101、设置于所述机身内的主风道105、气流检测通道103、传感器104及控制系统(图未示出),以及设置于所述机身101外侧的指示装置102。其中,所述主风道在机身101开设有出风口108,内部设置有气流产生装置。所述气流检测通道的进风口与所述主风道105的出风口108设置于所述机身101同侧。其中,气流检测通道103的进风口与所述主风道105的出风口108设置于所述机身101同侧是指:气流检测通道103的进风口和主风道105的出风口108设置于与主风道105的进风口相对的一侧。传感器设置于所述气 流检测通道内并与所述控制系统相连接,用于检测进入气流检测通道103中的气流的状态信息。
在本实施例中,气流检测通道103的进风口开口朝向智能吹风机主风道105的吹风方向。这样,当智能吹风机对被吹风对象吹风时,与被吹风对象接触过的气流便可通过气流检测通道103的进风口进入气流检测通道103内,并在气流检测通道103内流动而与传感器104接触。这样,传感器104便可采集与被吹风对象接触过的气流的状态信息。由于被吹风对象接触过的气流携带有被吹风对象的状态信息,因此,被吹风对象接触过的气流的状态信息可反映被吹风对象的状态信息。其中,气流状态信息的描述可参见上述实施例的相关内容,在此不再赘述。进一步,传感器104便可将与被吹风对象接触过的气流的状态信息提供给控制系统。
进一步,所述控制系统与所述指示装置102相连接,用于根据传感器的检测结果控制所述指示装置102指示被吹风对象的当前状态。即控制系统可根据气流的状态信息,控制指示装置102指示被吹风对象的当前状态。这样,用户便可直观地了解被吹风对象的当前状态,有助于提高用户体验。
在本实施例中,所述指示装置102可以采用指示灯、LED显示屏、液晶显示屏、或OLED显示屏等,但不限于此。指示装置102所采用的显示屏可以为平面屏或曲面屏。进一步,指示装置102可以采用以下形状中的任一种,包括:环绕机身的连续或非连续环状结构,沿机身外侧面设置的条状结构。
本实施例中指示装置之所以能够显示被吹风对象的当前状态,主要是通过安装在智能吹风机上的传感器对被吹风对象的气流的检测。传感器主要包括温度传感器和湿度传感器中的至少一种。温度传感器主要用来检测被吹风对象当前的温度,湿度传感器主要用来检测被吹风对象当前的湿度。
进一步在智能吹风机的主风道出风口一侧还安装有距离传感器111,所述距离传感器111与所述控制系统相连接。一方面距离传感器可用来判断有无被吹风对象,另一方面,在存在被吹风对象的情况下,可用于检测所述被吹 风对象与主通道的出风口的距离。在距离传感器111检测到所述被吹风对象与所述出风口的距离信息后,控制系统能够根据所述距离传感器111的检测结果发出相应的控制指令。控制指令包括如下的至少一种:调整功率、控制显示装置显示被吹风对象与出风口的距离以及控制指示装置102指示所述被吹风对象与所述出风口的距离。
本实施例的智能吹风机采用传感器获得被吹风对象的当前状态信息,并将被吹风对象的当前状态信息显示在指示装置102上。此外还可以利用安装在机身内的吹风机工作状态信息采集模块,来采集吹风机的工作状态,并将吹风机工作状态信息显示在指示装置102上。吹风机工作状态信息采集模块包括:距离传感器、加速度传感器、负离子发生器、吹风温度传感器、吹风风速传感器以及电机检测模块,这些信息采集模块分别与控制系统连接,将采集到的信号反馈给控制系统,控制系统发出相应的信号给指示装置102或显示装置的驱动单元,驱动单元驱动指示装置102或显示装置的显示单元显示各种对应的状态信息。
通过吹风机工作状态信息采集模块来采集吹风机的工作状态,并将吹风机工作状态信息显示在指示装置102上,是按照如下描述的方式:将吹风机工作状态信息采集模块与控制系统相连接,所述控制系统根据所述工作状态采集模块采集的吹风机的工作状态信息,控制所述指示装置102以指示吹风机的工作状态。本实施例中,所述智能吹风机的工作状态包括以下至少一种信息:与被吹风对象的距离、吹风机的加速度、负离子的浓度、吹风温度、吹风的风速、吹风时间或电机功率。
对于吹风机工作状态信息采集模块采集到的多种信息,控制系统可并行控制指示装置102显示这些信息。或者,对于吹风机工作状态信息采集模块采集到的多种信息需要单一输出给指示装置102,控制系统也可根据预置的指令进行优先级排序,或者根据吹风机当前的状态改变来输出单一的显示状态。例如,当距离传感器检测到无被吹风对象时,吹风机工作状态信息采集模块 将上述多种信息输出给控制系统后,控制系统根据最高优先级输出无被吹风对象的信息给指示装置102的驱动单元,驱动单元驱动指示装置102显示无被吹风对象的特定状态。当距离传感器检测到有被吹风对象,温度湿度传感器检测到被吹风对象的温度低且湿度大时,而加速度传感器检测到加速度在增大,而吹风温度传感器检测到出风温度较低,吹风风速传感器检测到出风速度不高,控制系统获取到这些信息后,确定用户在给被吹风对象吹风,需要增加电机功率。所以指示装置102显示电机功率的状态,进一步,控制系统可控制指示装置102显示可增加电机功率的指示信息,这样,用户可根据指示信息了解可增大吹风档位,进而有助于满足用户增加功率和快递风干的目的。
总之,本实施例的控制系统还可根据传感器或距离传感器111的检测结果或吹风机工作状态信息采集模块的采集的信息,控制指示装置102以至少如下一种方式指示所述被吹风对象的当前状态或吹风机的工作状态:渐变显示、单色显示、渐变闪烁或单色闪烁。单色显示为红色、绿色、蓝色、黄色等颜色的单色显示,渐变显示是指从一种上述单色显示向另一种单色显示逐渐变化,例如从红色向蓝色渐变显示,在具体的工作状态中,渐变显示可以是被吹风对象的距离逐渐变近时,指示装置102从红色向蓝色渐变。渐变闪烁或单色闪烁的也是如此,再次不再一一举例说明。
例如,图1中指示装置102可以为智能灯环。并且所述指示装置102可以采用包括渐变显示、单色显示、渐变闪烁以及单色闪烁显示方式中的至少一种将智能吹风机的工作状态和/或被吹风对象的当前状态以直观的方式显示出来,以便于用户直接根据观测的指示装置102的显示状态准确得知智能吹风机的工作状态和/或被吹风对象的当前状态。
可选的,可将指示装置102环形一圈设置在智能吹风机机身上,或者环形半圈设置在智能吹风机机身上,还可以是环形的不连续的一圈或半圈结构,同样机身上的条状结构也是可以实现的。本本申请的实施例中,当智能吹风 机的机身为圆形结构,指示装置102设置在机身外侧面上,沿着智能吹风机的机身表面延伸,当指示装置102沿着智能吹风机的轴向方向延伸时,可选的,指示装置102为条状结构;当指示装置102沿着智能吹风机的径向方向延伸时,可选的,指示装置102为环形结构,一圈或半圈或其他环形结构均可以实现。本申请的实施例中,不论指示装置102为条状结构还是环形结构,这种结构可以是连续的或者不连续的,可选的,指示装置102为连续的环状结构,或者不连续的条状结构。
指示装置102采用LED或曲面屏显示的方法呈现,可以为LED灯、液晶显示屏、OLED显示屏等显示器件。如图1和图2所示,为方便用户观察指示装置102的显示状态,及时了解吹风机的工作状态,指示装置102设置在智能吹风机机身表面,可选的,机身表面的靠近端部的位置,更好地呈现给用户观察,出风口设置在吹风机机身的一端,指示装置102设置在机身上相对出风口的另一端。在本申请的实施例中,指示装置102既可以设置在机身表面上,还可以设置在机身端部,可选的,指示装置102设置在机身相对于出风口的另一端的端部上,或者说,出风口位于机身的前端,指示装置102位于机身的后端,指示装置102背向出风方向,更有利于观察智能吹风机的工作状态和/或被吹风对象的当前状态。在实际应用过程中,用户手持吹风机向被吹风对象吹风时,出风口朝向被吹风对象,相对于出风口另一端的指示装置102背向出风方向,朝向用户,以便用户能及时观察指示装置102的显示状态。
该指示装置102具有2个工作模式,分别为智能模式与手动模式。当处于智能模式时,指示装置102可以显示智能吹风机工作中被吹风对象的工作状态信息和/或被吹风对象的当前状态信息,并且能够与安装在机身上的显示装置(例如显示屏)实现同步显示。
例如:当检测到被吹风对象湿度较大时,可以是头发非常湿的时候,智能灯环显示渐变色,头发非常干的时候智能灯环显示蓝色。根据干湿度的变 化,智能灯环显示颜色渐变。这样用户可以根据智能灯环的颜色变化自动判断头发的干湿状态、工作进度、是否吹干等等。或者还可以是,在智能工作模式下未检测到对象时,可采用安装在智能吹风机内部的距离传感器进行检测,而用户没有停止吹风机或者吹风机已经启动,智能灯环显示单色快闪以来提醒用户关机。当在预定的时间或预定的次数后未得到用户的反馈(即关机),智能吹风机实现自动关机。因此保证了该智能吹风机使用过程中的安全问题。同时通过上述过程可以直观地将被吹风对象的状态信息展示给用户,以增强用户的使用体验。
当智能吹风机处于手动模式,指示装置102可以显示所述智能吹风机的工作状态。可选的,在手动模式下,智能灯环可以采用渐变色闪烁表示高风高热,提醒用户注意吹风机的工作安全。例如,可用蓝色闪烁表示吹风机距离被吹风对象太近或太远。当吹风机向预定的被吹风对象近距离移动时,离目标距离越近,蓝色闪烁越慢,距离越远,智能灯环蓝色闪烁越快。或者,在干发吹风时,智能灯环显示为蓝色,在湿发吹风时,智能灯环显示为渐变色。还可以是,在吹风机距离被吹风对象预定距离时智能灯环显示渐变色,在无被吹风对象时智能灯环显示红色闪烁。
智能吹风机在手动模式和智能模式下,上述指示装置102显示的智能吹风机的工作状态信息和/或被吹风对象的当前状态信息只是示例性说明,在此不做限制。上述工作状态信息和/或被吹风对象的当前状态信息可以通过程序预置于控制器内,在不同的应用场景显示至少一种智能吹风机的工作状态信息和/或被吹风对象的当前状态信息,用户只需要通过吹风机的使用说明书学习了解多种显示状态即可。
为产生工作气流,本申请的吹风机内部安装有气流产生单元,气流产生单元包括风扇单元和加热单元。请参考图4,所述主风道105内设有用于产生气流的风扇单元106和用于对气流加热的加热单元107,在本实施例中,加热单元107可以为加热丝107;所述气流检测通道103设置于所述主风道105的 至少一侧,所述气流检测通道103可以是设置在所述主风道105的周围的任意位置,例如可以是主风道105的上侧、下侧、左侧或者右侧,且所述气流检测通道103的数量至少为一个。在本实施例中,气流检测通道103设置于主风道105的上侧,且所述气流检测通道103的进风口开口朝向所述智能吹风机主风道105吹风方向,传感器104设置于所述气流检测通道103中,传感器104能够检测气流的气流状态信息,其中气流状态信息包括以下信息中的至少一种:气流的温度信息、气流的湿度信息,例如可以是气流的相对湿度信息、相对温度信息、绝对湿度信息以及绝对温度度信息等。
可选的,所述气流检测通道103通过所述气流检测通道103的进风口收集与被吹风对象接触过的气流,并通过传感器104获得该气流的状态信息。为更好地吸入智能吹风机被吹风对象接触过的气流,在实际中,所述气流检测通道103可以设置成前宽后窄的变截面结构,即气流检测通道103的进风口设置成整个气流检测通道103中最宽的部分,所述传感器104设置于所述气流通道103内部。
为在所述气流检测通道103中多个位置检测并解析到上述被吹风对象接触过的气流状态信息,在所述气流检测通道103中可以设置多个传感器104,所述传感器104能够检测所述气流的温度与湿度信息,或者检测温度信息、湿度信息两个信息中的一种;可选的,在上述气流被吸入气流检测通道103中,气流在气流检测通道103中流动,当流动接触到传感器104时,传感器104中的温度与湿度响应装置会因接触所述气流而探测气流的温度与湿度。由于气流检测通道103中的气流为与被吹风对象接触过的气流,携带有被吹风对象的状态信息,因此,可通过探测与被吹风对象接触过的气流,获取被吹风对象的状态信息。
上述被吹风对象接触过的气流形成过程描述如下:在智能吹风机吹风过程中,智能吹风机在内部的电机110与风扇106的作用下,会经主进风口吸入大量的空气至主风道105中,大量的空气在进入吹风机主风道105后,经 吹风机内部的加热丝107加热,最终从吹风机主风道105的出风口108吹出,大量空气经过吹风机吹向被吹风对象,少量空气气流在接触被吹风对象后会通过气流检测通道103的进风口进入气流检测通道103,由于在本申请中设置的主风道105的主进风口的面积与主风道105的出风口108的面积均大于气流检测通道103的进风口的面积,因此只有少部分的气流进入气流检测通道103而基本不会影响吹风机的吹风效果,同时这部分气流是大量空气接触到被吹风对象被折回的部分空气气流,因此该气流能够真实反映被吹风对象接触过的气流的状态信息。
在实际生活中,吹风机应用较为广泛,本实施例的智能吹风机吹头发过程为例进行说明。
如图2所示,本实施例的智能吹风机后端安装有后保护罩109,并且在智能吹风机后端设有主风道105的主进风口,对应的,主风道105的出风口108位于智能吹风机的前端。启动智能吹风机智能工作后,智能吹风机的风扇106启动,在电机110的带动下,智能吹风机会经后保护罩109从主风道105的主进风口吸入大量的空气至主风道105中,大量的空气在进入吹风机主风道105后,经吹风机内部的加热丝107加热后,从吹风机的主风道105的出风口108吹出,大量空气经过吹风机吹向头发,少量空气气流在接触头发后会通过气流检测通道103的进风口进入气流检测通道103,由于这部分气流是大量空气接触到头发后被折回的部分空气气流,因此该气流能够真实反映头发的真实温度与湿度;之后该气流流经传感器104。传感器104便可通过获取与头发接触过的气流的状态信息,并将气流的状态信息提供给控制系统。进一步,控制系统可通过气流状态信息确定头发的状态信息,并控制指示装置102指示头发的当前状态。
在本实施例中,传感器104可以设置在气流检测通道103的任意位置,在实际安装中,可以将传感器104设置在气流检测通道103的进风口或气流检测通道103的内部或者其他位置,当然也可以同时安装多个传感器,例如, 将传感器104设置在较靠近气流检测通道103进风口的位置,在靠近气流检测通道103进风口的位置安装的传感器104能够在最短的时间内接触到接触过头发的气流,因此能够更准确地探测接触过头发的气流的温度与湿度信息;将传感器104设置在气流检测通道103的内部,由于气流检测通道103的内部通道为前宽后窄的结构,尤其是将传感器104设置在气流检测通道103的内部通道最窄的部分时,由于此处气流最为聚集,因此安装在此处的传感器104能够最快地响应接触过头发的气流的温度与湿度信息。或者,传感器104按照设定的距离间隔设置在气流检测通道103的不同的位置上,以检查气流在不同位置的温度与湿度信息。上述将传感器104设置在不同的位置,可检测气流流经智能吹风机内部不同位置的温度与湿度变化信息,以便于对流经智能吹风机内部的气流的温度与湿度参数进行拟合,进而推算头发的状态推算信息,其中头发的状态推算信息包括头发的温度推算信息、湿度推算信息两者中的至少一种,从而使本申请的智能吹风机从主风道的出风口108吹出的风更匹配被吹风对象所需要的吹风。
在本申请的智能吹风机中,为推算头发的状态推算信息,除需要获得流经气流检测通道103的内部的气流的温度与湿度信息,还需要获得吹风机吹出的风接触头发之前吹风机的吹风的温度与吹风的风速,即吹风机吹风的温度与吹风的风速,获得吹风机吹风的温度与吹风的风速的途径有多种,例如吹风的温度可通过将传感器设置在主风道105的任意位置来检测,例如将温度传感器设置在出风口108的位置;温度传感器还可以设置在加热丝107的下游方向,或者加热丝107与出风口108之间的位置。或者,由于在智能吹风机吹风时,在吹风机工作的档位下存在与该工作档位对应的理论温度,因此可通过吹风机的工作档位对应的理论温度推测吹风机的吹风的温度,同样地,吹风的风速也可依据上述获得吹风的温度的获得方式获得,此处不再赘述。
在获得吹风机吹风的温度与吹风的风速以及流经气流检测通道103的内 部的气流的温度与湿度信息后,可根据上述参数进行拟合,从而获得头发的状态推算信息,即利用了气流接触头发前、后的温度变化信息与湿度变化信息来获得头发的状态推算信息。可选的,在拟合获得头发的状态推算信息时,可通过多种方式,以下采用两种方式说明拟合方式:
第一种拟合方式:通过公式方法进行拟合,可选的,在获得吹风机吹风的温度与吹风的风速以及流经气流检测通道103的内部的气流的温度与湿度信息后,将上述参数与头发的状态信息建立关系,在建立关系的实际操作中,可进行多次实验,实验内容包括但不限于检测不同时间内头发的状态信息以及与此对应的吹风机吹风的温度、吹风的风速、流经气流检测通道103的内部的气流的温度与湿度信息,或者更换不同的被吹风对象并检测不同被吹风对象的状态信息以及与此对应的吹风机吹风的温度、吹风的风速、流经气流检测通道103的内部的气流的温度与湿度信息,在获得大量的上述对应数据之后,可建立检测的上述参数与被吹风对象的状态信息的函数关系式,并将此函数关系式作为经验公式,其中所述检测的参数包括吹风机吹风的温度、吹风的风速、流经气流检测通道103的内部的气流的温度与湿度信息等。在获得经验公式后,只需将吹风机吹风的温度、吹风的风速、流经气流检测通道103的内部的气流的温度与湿度信息代入经验公式,即可推算头发的状态信息。
第二种拟合方式:将上述检测的参数与被吹风对象的状态信息形成一一对应的数据表,只需将吹风机吹风的温度、吹风的风速、流经气流检测通道103的内部的气流的温度与湿度信息从数据表格中检索,即可推算头发的状态信息。
为更全面检测气流状态信息,在上述的传感器中还可以设置距离传感器,通过距离传感器探测气流状态信息中的气流运动距离,同时距离传感器还可用作判断有无被吹风对象的判断。所述距离传感器可以采用多种方式实现,例如,可以在吹风机的头部设置LDS激光雷达测距装置。所述气流运动距离, 可以定义为气流从出风口到被吹风对象(如头发)之间的距离,或者从出风口到被吹风对象又折返到所述气流检测通道103的进风口的距离。由于传感器在气流检测通道中检测获得的湿度、温度等只是气流检测通道中气流的温度、湿度,与真正希望获得的被吹风对象的温度、湿度参数有差别,而吹风机与被吹风对象的距离对两者的差别有很大影响,因此,所述距离传感器的测量结果,可以应用到上述拟合方式中作为一个重要的参数使用。
为使得流经气流检测通道103的气流形成流通的气流,可将气流检测通道103的出风口开设在主风道105的上游,即将气流检测通道103连接至风扇106的上游区域,此连接方式可以理解为将所述主风道105上游的低气压引入到所述气流检测通道103的进风口位置,接触被吹风对象的气流被挡回后,就更可能通过所述气流检测通道103流回主进风口的上游区域,与主进风口吸入的大量空气汇合,汇合之后再在风扇106的作用下,经主风道105从主风道105的出风口108吹出,通过上述过程,接触头发的气流可形成经过气流检测通道103循环流通的气流通道。
为更好地探测气流的温度与湿度的变化,在智能吹风机的主风道105的出风口108处也可安装传感器104。进一步,安装在智能吹风机的出风口108处的传感器104、安装在气流检测通道103的进风口的传感器104以及安装在气流检测通道103内部的传感器104能够对吹风机工作气流以及检测气流形成连续的梯度式的温度与湿度测量,并以此为依据更精确的推算被吹风对象的温度、湿度状况,为控制系统控制智能吹风机的工作提供更为精确的信息。
同样的,在所述气流检测通道103中的传感器可以设置两个或者多个,并且设置在所述气流检测通道的气流流动方向上间隔设定距离的位置,这样同样可以获得对所述检测气流的梯度测量效果,从而能够更为精准的推算被吹风对象的温度、湿度状态。
在传感器104获得接触头发的气流的温度与湿度信息后,传感器104将接触头发的气流的温度与湿度信息传送至智能吹风机的控制系统,所述控制 系统用于接收所述传感器输出的检测结果,并将所述检测结果用于对所述风扇单元的转速和/或所述加热单元的加热温度的调节,在本实施例中,上述调节所述风扇单元的转速和/或所述加热单元的加热温度对应于调节图2的风扇106的转速和/或加热丝107的加热温度。可选的,所述控制系统还包括控制器,所述控制器接收各个传感器104的检测的温度与湿度信息以及气流在接触头发前后的温度与湿度变化信息,并经过预设的程序,控制智能吹风机的吹风参数,其中所述智能吹风机的吹风参数包括吹风的风速与吹风的温度,可选的,控制器控制智能吹风机的吹风参数是通过控制器分别控制风扇106的转速与加热丝107的加热,来控制智能吹风机的吹风的风速与吹风的温度。上述吹风的风速与吹风的温度在实际中具体体现为吹风的风量大小与吹出的风的凉热。
在智能吹风机控制系统的具体实现方式中,上述控制过程可以是在所述智能吹风机内部设置有控制芯片,控制芯片接收各个传感器104传送的接触头发的气流的温度与湿度信息以及气流在接触头发前后的温度与湿度变化信息,并根据头发的气流的温度与湿度信息以及气流在接触头发前后的温度与湿度变化信息经过数据转换得到用户的头发温度与湿度,控制芯片再根据转换得到的用户头发的温度与湿度信息,并经过预设的程序,控制智能吹风机的吹风参数,并以此吹风参数去调整智能吹风机的实际吹风情况,即调整智能吹风机的吹风功率。
例如在上述控制过程中,预设的程序可以是:首先根据控制芯片转换得到的用户头发的温度与湿度信息,周期或者实时计算被吹风对象所需的吹风参数;另外还需获得智能吹风机当前的吹风参数,其中所述吹风参数至少包括吹风的风速与吹风的温度,在获得被吹风对象所需的吹风参数与智能吹风机当前的吹风参数之后,比较被吹风对象所需的吹风参数与智能吹风机当前的吹风参数的关系,并以此调整智能吹风机的吹风的实际情况,在这个过程中,智能吹风机是自动计算吹风参数并且自动调整智能吹风机的吹风情况, 省去用户手工换挡的繁琐,提高了用户的体验。
具体而言,上述的预设程序的被吹风对象所需的吹风参数为根据当前气流检测通道103吸入的接触头发的气流确定的被吹风对象所需的吹风参数,若当前智能吹风机的吹风参数小于被吹风对象所需的吹风参数,即当前吹风的风速与吹风的温度小于被吹风对象所需的吹风的风速与吹风的温度,则控制系统可自动增大吹风机的电机的功率,以增强所述智能吹风机吹风的风量与吹风的温度,例如可以是在智能吹风机中增大风扇的电机的转速与提高加热丝107的加热功率;若当前智能吹风机的吹风参数大于待吹的头发所需的吹风参数,即当前吹风的风速与吹风的温度大于待吹的头发所需的吹风的风速与吹风的温度,则控制系统可减小吹风机的电机的功率,以自动减弱所述智能吹风机吹风的风量与吹风的温度,例如可以是在智能吹风机中减小风扇的电机的转速与降低加热丝107的加热功率。由于智能吹风机在工作期间,气流检测通道103是以实时或者周期性吸入接触过头发的气流,经过智能吹风机吹风一段时间,吸入的接触过头发的气流的温度与湿度信息会有所变化,即控制芯片转换得到的用户头发的温度与湿度信息也会变化,而在实际智能吹风机的吹风过程中,头发的温度与湿度也是实时变化的,随着吹风的时间增加,头发的湿度不断减小,温度不断升高,因此,在此过程中吹头发所需的智能吹风机的工作参数也是不断变化的,例如在头发在不断吹干的过程中,所需智能吹风机所提供的风量大小与风的温度均逐渐减小,即待吹的头发所需的吹风参数不断减小,相应地,控制系统需要不断或者周期性调整所述智能吹风机的参数以适应被吹风对象的需求。
上述控制芯片经过数据转换得到被吹风对象的温度与湿度,主要是依据各个传感器104传送的接触被吹风对象的气流的温度与湿度信息以及气流在接触被吹风对象前后的温度与湿度变化信息获得,在上述各个安装位置的各个传感器中,安装在智能吹风机的气流检测通道103进风口的传感器104检测到的温度与湿度信息最为接近被吹风对象的温度与湿度,安装在气流检测 通道103最窄的部分的传感器104能够最快感应到通过气流检测通道103的接触过被吹风对象的气流的温度与湿度,安装在主风道105的出风口108处的传感器104能够感应到通过主风道105吹风的气流的温度与湿度信息。
上述描述过程主要是采用传感器获得被吹风对象的当前状态信息,并通过控制系统将其显示在指示装置102上。本申请通过采用在智能吹风机机身上安装指示装置,并根据控制系统指示所述智能吹风机的工作状态和/或被吹风对象的当前状态,采用该方式能够让使用者精确获知吹风机的工作状态和/或被吹风对象的当前状态。
本申请提供的智能吹风机的工作原理主要是通过控制系统控制包括温度传感器、湿度传感器、距离传感器、温控模块、风控模块等吹风机工作状态采集模块进行工作的。以下对各部分模块进行简要说明。
湿度传感器,作为检测被吹风对象的湿度信息的检测部件,可以安装在智能吹风机进风口内,优选为气流通道内的靠近进风口的位置,用于实时采集被吹风对象附近的空气湿度。在采用本申请的智能吹风机进行吹发时,根据检测的湿度信息,来动态调整智能吹风机的功率和控风模块的出风风速及风量,以达到恒温护发和节能降耗。
距离传感器,作为检测智能吹风机被吹风对象的距离和吹风范围内是否存在被吹风对象的检测部件,可以将距离传感器设置在智能吹风机的机身上,优选为出风口附近,当然也可选在智能吹风机的外侧周沿。
加速度传感器,作为检测智能吹风机移动速度的检测部件,可以安装在智能吹风机内任意位置,通过检测移动速度来判断吹风机是否在快速移动,加速度越大,吹风机所需要的风量越大,温度越高,说明用户希望快速风干,需要执行高风高热高负离子浓度模式;加速度传感器控制吹风机执行如下至少一种指令:增加发热丝功率、增加电机功率、增加负离子浓度等。可选的,加速度传感器设置于智能吹风机的手柄内,识别手势的快速摆动,给控制器一个信号,控制器识别到加速度传感器的信号后,启动高风高热高离子浓度 模式,调整发热丝功率,增加电机风扇的功率,增加负离子浓度。
吹风温度传感器,置于发热丝(控温模块)与出风口之间,可选的,还可置于出风通道内的吹风口附近,用于实时检测智能吹风机吹风的温度,并根据温度的变化来动态调整发热丝(控温模块)的功率和吹风机电机(控风模块)的出风风速及风量,使得吹风温度的温度差在偏差范围内的以达到恒温护发。
同时在本申请的吹风机内部还包括:离子发生器、云母片、发热丝等部件。
离子发生器,安置于智能吹风机出风口位置,用于产生正离子和/或负离子,可选的,离子发生器设置于发热丝与出风口之间的位置。在本申请的实施例中,离子发生器为负离子发生器。在吹发时,可以中和头发表面的静电,使头发更加柔顺;同时离子发生器可以改善周边空气,并达到提神醒脑以及杀菌除尘的效果。
云母片为发热丝的外壳,对发热丝保护、绝缘、隔热、支撑的作用,圆管状的云母片构成了发热丝的出风通道,云母片可选碳纤维制品、远红外陶瓷、玉石等材料,同时在云母片内侧壁还涂覆有用于产生远红外线的远红外涂层,该远红外涂层发射出远红外射线,用于在吹发时促进头皮血液循环,提高免疫力降低,缓解头痛,目眩,失眠乏力等症状;同时还可以护肤美容,增强新陈代谢,提高免疫功能;加速干发。
此外,将本申请的智能吹风机的云母片设置为内置支架的圆桶状,将螺旋状或波纹状的发热丝设置在云母片内的支架之间,以增大与气流的接触面积。同时,云母片还具备绝缘、隔热、支撑发热丝的作用。
指示装置与显示装置作为本申请智能吹风机中的重要部件,以上采用的实施例分别正是说明的智能吹风机中的指示装置与显示装置的工作原理与结构。
另外,图5示出了各部件之间的连接关系图,主要包括:微控制单元 (Microcontroller Unit;MCU)、距离传感器、温/湿度传感器、WIFI模块、蓝牙模块、显示模块、控风模块、控温模块、AC-DC模块、AC电源采集及过零检测的连接关系。
本申请第二实施例提供另外一种智能吹风机,包括:机身、设置于所述机身内的主风道、气流检测通道、传感器及控制系统,以及设置于所述机身内的显示驱动装置。在本实施例中,所述主风道在机身开设有出风口,内部设置有气流产生装置(电机风扇单元),所述气流检测通道的进风口与所述主风道出风口设置于所述机身同侧。传感器设置于所述气流检测通道内并与所述处理器相连接,用于检测气流的状态信息。所述显示驱动装置与所述控制系统相连接,用于根据传感器的检测结果向显示终端输出被吹风对象的当前状态信息;或者,根据控制系统获取的吹风机的工作状态信息向显示终端输出吹风机的工作状态信息。
对于智能吹风机的显示装置,可以将其安装在智能吹风机的机身上。作为安装显示装置的一种实施方式,可以将其设置在相对于出风口的另一侧。由于吹风口设置在智能吹风机的前端,显示装置可以设置在智能吹风机的后端,可选的,显示装置背向出风口方向,在本申请的实施例中,显示装置垂直于吹风机机身轴线方向,吹风机机身的轴线穿过显示装置,显示装置可以为圆环结构或者方形结构,不作特别限制。这样的位置布局,在使用者使用吹风机时,方便使用者观察显示装置,及时获取吹风机的运行状态信息。例如,在使用者对宠物吹干毛发时,吹风口对准宠物,智能吹风机后端的显示屏面向使用者,使用者能及时获取智能吹风机的运行状态信息。在本实施例中,显示装置为显示屏,优选触摸屏,并将显示屏与所述显示驱动装置相连接。在向被吹风对象吹风时,使用者可通过显示装置实时观察智能吹风机的工作状态或被吹风对象的当前状态信息。可选的,显示装置用于显示吹风过程中,被吹风对象表面的湿度变化、智能吹风机的工作模式、环境参数等。例如用于显示工作模式(包括智能模式与手动模式),或者在智能吹风机出现 故障时显示故障标识;以及用于显示智能吹风机工作的环境参数(包括温度、湿度、距离、功率、风速、电机转速信息)、工作状态信息(包括智能灯环、风道堵转、电机过热、传感器状态信息、电池电量信息等信息)、用户状态信息(例如不同的对象需要不同的工作参数,针对不同的对象设定不同的用户信息,用户信息储存在云端或处理器中,智能吹风机从云端或处理器中获取用户状态信息,并显示出来)以及显示用户操作指南及相关售后等相关信息。此外,上述用户状态信息可从吹风机云端或者处理器获得。例如,预先将不同的被吹风对象信息储存在云端。并可通过人脸识别、文本输入、无线通信的方式获得。
在本实施例中,在智能吹风机内部还设置有无线通信模块,所述无线通信模块与所述显示驱动装置相连接,用于将所述显示驱动装置的输出信息输出至电信号连接的智能终端或智能机器人。智能终端或智能机器人与智能吹风机进行信息交互,作为可选的实施方案,智能终端或智能机器人显示智能吹风机的输出信息,或者智能吹风机执行智能终端或智能机器人的指令。智能终端可以是智能手机、PAD、计算机等数据处理装置的任意至少一种,智能机器人可以是扫地机器人、吸尘器、清洗机、擦窗机器人、服务机器人、管家机器人、保姆机器人、伴侣机器人等任意机器人中的至少一种。当然,其他可以作为本实施例的显示装置的材料,同样属于本申请的保护范围。
另外,在智能吹风机内机身外侧还可以设置前述实施例所述指示装置,所述指示装置与所述处理器相连接,用于根据传感器的检测结果指示被吹风对象的当前状态或指示吹风机的工作状态。具体指示装置的工作原理详见第一实施例的相关描述,此处不再赘述。
此外,本申请的智能吹风机的所述显示装置具备触摸功能,用于控制所述智能吹风机工作模式的切换,以及,输入和/或输出所述智能吹风机的吹风参数。在控制方式上,用户可采用手动输入、点选、勾选、长按、滑动、手势控制、语音控制等方式输入和/或输出所述智能吹风机的吹风参数。其中, 所述显示装置可以采用文本、图案或者语的方式显示所述智能吹风机工作状态信息。
在本申请的实施例中,智能吹风机的指示装置和显示装置为LED灯、LCD屏、OLED显示屏的任意一种,作为可选的实施例,指示装置和显示装置为LED灯带、曲面屏或柔性显示屏的任意一种。
在上述的两个实施例中,分别提供了两种智能吹风机,相对应的,本申请第三实施例提供一种自动控制智能吹风机工作的方法。
如图6所示,其为本申请第三实施例提供的一种作业控制方法的流程图。由于方法实施例基本相似于装置实施例,所以描述得比较简单,相关之处参见装置实施例的部分说明即可。下述描述的方法实施例仅仅是示意性的。
图6为本申请第三实施例提供的作业控制方法的流程示意图。如图6所示,所述方法包括步骤S601~S604。
步骤S601:获取智能吹风机当前工作功率与被吹风对象当前状态信息。
首先,在利用本申请方法自动控制智能吹风机进行吹风工作时,首先,按照初始默认功率运行所述智能吹风机。例如,可按照初始功率P 0运行吹风机,P 0是较该智能吹风机能够运行并待机的最低功率P min稍大的功率。
在运行该智能吹风机后,判断所述智能吹风机的出风口指定的距离内是否存在被吹风对象;若不存在,则将所述智能吹风机的功率调整至最低功率P min;若存在,则获取所述被吹风对象的当前状态信息。
步骤S602:根据所述被吹风对象的当前状态信息,以及,预设的工作功率与对象状态信息的关系,获取所述被吹风对象所需的所述智能吹风机的吹风功率。
在获得所述被吹风对象的当前状态信息之后,根据所述被吹风对象的当前状态信息,以及,预设的工作功率与对象状态信息的关系,获取所述被吹风对象所需的功率。由于使用该申请的方法吹风一段时间后,被吹风对象的状态信息会发生变化,因此,需要实时获取被吹风对象的状态信息,并以此 获得被吹风对象所需的所述智能吹风机的吹风功率。
作为获取被吹风对象的状态信息的一种方式,首先,获得与被吹风对象接触过的气流;之后,获取与被吹风对象接触过的气流的状态信息;最后,根据气流的状态信息推算被吹风对象的状态推算信息,将所述状态推算信息作为所述被吹风对象的当前状态信息。其中,所述气流状态信息包括气流的温度信息、气流的湿度信息两者中的至少一种,所述被吹风对象的状态推算信息包括被吹风对象的温度推算信息、湿度推算信息两者中的至少一种。
在获得被吹风对象的状态信息后,根据所述被吹风对象当前状态信息,以及,预设的工作功率与对象状态信息的关系,获取所述被吹风对象所需的所述智能吹风机的吹风功率。
步骤S603:根据所述智能吹风机当前工作功率,以及,所述被吹风对象所需的所述智能吹风机的吹风功率判断是否需要对所述当前工作功率进行调整。
在获得被吹风对象所需的所述智能吹风机的吹风功率后,根据所述智能吹风机当前工作功率,以及,所述被吹风对象所需的所述智能吹风机的吹风功率判断是否需要对所述当前工作功率进行调整。
步骤S604:根据判断结果调整或保持所述智能吹风机当前工作功率。
在判断是否需要对所述当前工作功率进行调整之后,根根据判断结果调整或保持所述智能吹风机当前工作功率。
例如,在吹风一段时间后,被吹风对象由原来的湿头发变为半湿头发,此时智能吹风机当前工作功率为P max,而被吹风对象所需的所述智能吹风机的吹风功率P 1(P 1小于P max),因此,需要调整吹风机的功率P max至P 1;若被吹风对象还为湿头发,则保持所述智能吹风机当前工作功率P max不变。
上述自动控制智能吹风机工作的方法,利用了智能吹风机中设置在气流检测通道中的传感器获得的湿度和/或温度信息,实现对吹风机工作的智能控制,有效提升了吹风机的使用体验。
应用场景1
用户使用智能吹风机吹湿头发时,开启该智能吹风机时,进入智能模式,距离传感器检测到有被吹风对象头发存在,该智能吹风机以初始功率P 0运行。当湿度传感器检测到头发较湿时,判断有湿头发时需要吹风时,则将智能吹风机的功率调整至P max,运行一段时间后,湿头发变为半干头发,智能灯环的颜色逐渐变化,由渐变色变为蓝色,智能吹风机功率自动降为P 1。在此过程中,智能吹风机能够自动调整功率,避免了人工调整智能吹风机功率的麻烦。
应用场景2
用户使用智能吹风机完毕时,智能吹风机的距离传感器自动识别指定距离内无被吹风对象,该智能吹风机功率下降至P min运行。运行一段时间后,仍然自动识别指定距离内无被吹风对象,则自动进入待机状态。该智能吹风机保证了使用过程中的安全。
相应地,本申请实施例还提供一种存储有计算机指令的计算机可读存储介质,当所述计算机指令被一个或多个处理器执行时,致使所述一个或多个处理器执行上述作业控制方法中的步骤。
图7为本申请实施例提供的一种信息显示方法的流程示意图。如图4所示,该方法包括:
步骤S701、获取与被吹风对象接触过的气流的状态信息。
步骤S702、根据该气流的状态信息,确定被吹风对象的当前状态。
步骤S703、显示被吹风对象的当前状态。
在本实施例中,吹风机包括:机身、设置于机身内的主风道、控制系统、气流检测通道以及设置于气流检测通道内的传感器。吹风机还包括:设置于机身的指示装置。其中,关于指示装置的实现形态可参见上述实施例的相关内容,在此不再赘述。在本实施例中,气流检测通道的进风口与主风道的出风口设置于机身的同侧。当吹风机向被吹风对象吹风时,气流检测通道的进 风口与主风道的出风口均与被吹风对象相对。
在本实施例中,传感器设置于气流检测通道内,可检测进入气流检测通道中的气流的状态信息。当吹风机向被吹风对象吹风时,与被吹风对象接触过的气流可通过气流检测通道的进风口进入气流检测通道内,并在气流检测通道内流动而与传感器接触。这样,传感器便可采集与被吹风对象接触过的气流的状态信息。由于被吹风对象接触过的气流携带有被吹风对象的状态信息,因此,被吹风对象接触过的气流的状态信息可反映被吹风对象的状态信息。其中,气流状态信息的描述可参见上述实施例的相关内容,在此不再赘述。进一步,传感器便可将与被吹风对象接触过的气流的状态信息提供给控制系统。
进一步,控制系统与指示装置相连接,用于根据传感器的检测结果控制指示装置显示被吹风对象的当前状态。即控制系统可根据气流的状态信息,控制指示装置指示被吹风对象的当前状态。这样,用户便可直观地了解被吹风对象的当前状态,有助于提高用户体验。
值得说明的是,关于步骤S701-步骤S703的具体实施方式均可参见上述实施例的相关内容,在此不再赘述。
相应地,本申请实施例还提供一种存储有计算机指令的计算机可读存储介质,当所述计算机指令被一个或多个处理器执行时,致使所述一个或多个处理器执行上述信息显示方法中的步骤。
需要说明的是,上述实施例所提供方法的各步骤的执行主体均可以是同一设备,或者,该方法也由不同设备作为执行主体。比如,步骤S201和S202的执行主体可以为设备A;又比如,步骤S201的执行主体可以为设备A,步骤S202的执行主体可以为设备B;等等。
另外,在上述实施例及附图中的描述的一些流程中,包含了按照特定顺序出现的多个操作,但是应该清楚了解,这些操作可以不按照其在本文中出现的顺序来执行或并行执行,操作的序号如S201、S202等,仅仅是用于区分 开各个不同的操作,序号本身不代表任何的执行顺序。另外,这些流程可以包括更多或更少的操作,并且这些操作可以按顺序执行或并行执行。
还值得说明的是,在本申请各实施例中,控制系统可包括控制器及其外围电路。其中,控制器可以为任意硬件处理设备。可选地,处理器可以为中央处理器(Central Processing Unit,CPU)、图形处理器(Graphics Processing Unit,GPU)或微控制单元(Microcontroller Unit,MCU);也可以为现场可编程门阵列(Field-Programmable Gate Array,FPGA)可编程阵列逻辑器件(Programmable Array Logic,PAL)、通用阵列逻辑器件(General Array Logic,GAL)、复杂可编程逻辑器件(Complex Programmable Logic Device,CPLD)等可编程器件;或者为先进精简指令集(RISC)处理器(Advanced RISC Machines,ARM)或系统芯片(System on Chip SOC)等等,但不限于此。
本申请虽然以较佳实施例公开如上,但其并不是用来限定本申请,任何本领域技术人员在不脱离本申请的精神和范围内,都可以做出可能的变动和修改,因此本申请的保护范围应当以本申请权利要求所界定的范围为准。
本领域内的技术人员应明白,本发明的实施例可提供为方法、系统、或计算机程序产品。因此,本发明可采用完全硬件实施例、完全软件实施例、或结合软件和硬件方面的实施例的形式。而且,本发明可采用在一个或多个其中包含有计算机可用程序代码的计算机可用存储介质(包括但不限于磁盘存储器、CD-ROM、光学存储器等)上实施的计算机程序产品的形式。
本发明是参照根据本发明实施例的方法、设备(系统)、和计算机程序产品的流程图和/或方框图来描述的。应理解可由计算机程序指令实现流程图和/或方框图中的每一流程和/或方框、以及流程图和/或方框图中的流程和/或方框的结合。可提供这些计算机程序指令到通用计算机、专用计算机、嵌入式处理机或其他可编程数据处理设备的处理器以产生一个机器,使得通过计算机或其他可编程数据处理设备的处理器执行的指令产生用于实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能的 装置。
这些计算机程序指令也可存储在能引导计算机或其他可编程数据处理设备以特定方式工作的计算机可读存储器中,使得存储在该计算机可读存储器中的指令产生包括指令装置的制造品,该指令装置实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能。
这些计算机程序指令也可装载到计算机或其他可编程数据处理设备上,使得在计算机或其他可编程设备上执行一系列操作步骤以产生计算机实现的处理,从而在计算机或其他可编程设备上执行的指令提供用于实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能的步骤。
在一个典型的配置中,计算设备包括一个或多个处理器(CPU)、输入/输出接口、网络接口和内存。
内存可能包括计算机可读介质中的非永久性存储器,随机存取存储器(RAM)和/或非易失性内存等形式,如只读存储器(ROM)或闪存(flash RAM)。内存是计算机可读介质的示例。
计算机可读介质包括永久性和非永久性、可移动和非可移动媒体可以由任何方法或技术来实现信息存储。信息可以是计算机可读指令、数据结构、程序的模块或其他数据。计算机的存储介质的例子包括,但不限于相变内存(PRAM)、静态随机存取存储器(SRAM)、动态随机存取存储器(DRAM)、其他类型的随机存取存储器(RAM)、只读存储器(ROM)、电可擦除可编程只读存储器(EEPROM)、快闪记忆体或其他内存技术、只读光盘只读存储器(CD-ROM)、数字多功能光盘(DVD)或其他光学存储、磁盒式磁带,磁带磁磁盘存储或其他磁性存储设备或任何其他非传输介质,可用于存储可以被计算设备访问的信息。按照本文中的界定,计算机可读介质不包括暂存电脑可读媒体(transitory media),如调制的数据信号和载波。
还需要说明的是,术语“包括”、“包含”或者其任何其他变体意在涵盖非排他性的包含,从而使得包括一系列要素的过程、方法、商品或者设备不仅包 括那些要素,而且还包括没有明确列出的其他要素,或者是还包括为这种过程、方法、商品或者设备所固有的要素。在没有更多限制的情况下,由语句“包括一个……”限定的要素,并不排除在包括所述要素的过程、方法、商品或者设备中还存在另外的相同要素。
以上所述仅为本申请的实施例而已,并不用于限制本申请。对于本领域技术人员来说,本申请可以有各种更改和变化。凡在本申请的精神和原理之内所作的任何修改、等同替换、改进等,均应包含在本申请的权利要求范围之内。

Claims (20)

  1. 一种智能吹风机,其特征在于,包括:气流检测通道,传感器,控制系统以及主风道;
    所述气流检测通道设置于所述主风道的至少一侧,所述气流检测通道的进风口开口朝向所述智能吹风机主风道吹风方向,可收集与被吹风对象接触过的气流;
    所述传感器设置于所述气流检测通道中,用于检测所述与被吹风对象接触过的气流的状态信息;
    所述控制系统用于接收所述气流的状态信息,并将所述气流的状态信息用于对所述智能吹风机的工作状态的控制。
  2. 根据权利要求1所述的智能吹风机,其特征在于,所述气流状态信息包括以下信息中的至少一种:气流的温度信息、气流的湿度信息。
  3. 根据权利要求1所述的智能吹风机,其特征在于,所述气流检测通道连接至所述风扇单元的上游区域,所述主风道的出风口位于所述风扇单元的下游区域。
  4. 根据权利要求3所述的智能吹风机,其特征在于,所述主风道的出风口的面积大于所述气流检测通道的进风口的面积。
  5. 根据权利要求1所述的智能吹风机,其特征在于,所述气流检测通道为前宽后窄的变截面结构,所述传感器设置在靠后侧的位置。
  6. 根据权利要求2所述的智能吹风机,其特征在于,所述传感器还包括距离传感器,所述气流状态信息包括气流运动距离。
  7. 根据权利要求1所述的智能吹风机,其特征在于,所述控制系统在将所述气流的状态信息用于对所述智能吹风机的工作状态的控制时,具体用于:
    根据所述气流的状态信息,获取所述被吹风对象所需的所述智能吹风机的吹风参数;并控制所述主通道内的风扇单元的转速和/或加热单元的加热温 度,以将所述智能吹风机的吹风参数调整至所述智能吹风机按照所述被吹风对象所需的所述智能吹风机的吹风参数。
  8. 一种作业控制方法,其特征在于,包括:
    获取被吹风对象接触过的气流的状态信息;
    根据所述气流的状态信息推算所述被吹风对象的状态推算信息;
    根据所述被吹风对象的状态推算信息,获得所述被吹风对象所需的所述智能吹风机的吹风参数;
    控制所述智能吹风机按照所述被吹风对象所需的所述智能吹风机的吹风参数,向所述被吹风对象吹风。
  9. 根据权利要求8所述的方法,其特征在于,所述气流状态信息包括气流的温度信息、气流的湿度信息两者中的至少一种,所述被吹风对象的状态推算信息包括被吹风对象的温度推算信息、湿度推算信息两者中的至少一种。
  10. 根据权利要求8所述的的方法,其特征在于,还包括实时获得所述智能吹风机当前的吹风参数,其中所述智能吹风机的吹风参数包括吹风的风速与吹风的温度,根据所述智能吹风机当前的吹风参数,以及所述被吹风对象所需的智能吹风机的吹风参数判断是否调整所述智能吹风机的吹风参数;
    其中,当所述智能吹风机当前的吹风参数小于所述被吹风对象所需的智能吹风机的吹风参数时,增强所述智能吹风机当前的吹风参数,反之,则减弱所述智能吹风机当前的吹风参数。
  11. 一种智能吹风机,其特征在于,包括:机身、设置于所述机身内的主风道、气流检测通道、传感器及控制系统,以及设置于所述机身外侧的指示装置;其中,
    所述主风道在机身开设有出风口,内部设置有气流产生装置;
    所述气流检测通道的进风口与所述主风道出风口设置于所述机身同侧;
    传感器设置于所述气流检测通道内并与所述控制系统相连接,用于检测 进入所述气流检测通道中的气流的状态信息;
    所述控制系统与所述指示装置相连接,用于根据所述气流的状态信息控制所述指示装置指示被吹风对象的当前状态。
  12. 根据权利要求11所述的智能吹风机,其特征在于,所述指示装置形状设置为以下任一种:环绕机身的连续或非连续环状结构,沿机身外侧面设置的条状结构。
  13. 根据权利要求11或12所述的智能吹风机,其特征在于,所述传感器为温度传感器或湿度传感器;相应的,所述当前状态为被吹风对象当前的湿度状态或温度状态。
  14. 根据权利要求11所述的智能吹风机,其特征在于,还包括设置于机身上主风道出风口一侧的距离传感器;
    所述距离传感器与所述控制系统相连接,用于检测所述被吹风对象与所述出风口的距离;
    所述控制系统还用于根据所述距离传感器的检测结果控制所述指示装置指示所述被吹风对象与所述出风口的距离。
  15. 根据权利要求11所述的智能吹风机,其特征在于,还包括设置于所述机身内的吹风机工作状态信息采集模块,所述吹风机工作状态信息采集模块与所述控制系统相连接;
    所述控制系统还用于根据所述工作状态采集模块采集的吹风机的工作状态信息控制所述指示装置指示吹风机的工作状态;
    所述工作状态信息包括以下至少一种:吹风温度、吹风的风速、吹风时间或电机功率。
  16. 根据权利要求11、12、14和15任一项所述的智能吹风机,其特征在于,所述控制系统具体用于:根据所述传感器的检测结果,控制所述指示装置以如下任一种方式指示所述被吹风对象的当前装置:渐变显示、单色显示、 渐变闪烁或单色闪烁。
  17. 一种信息显示方法,其特征在于,包括:
    获取与被吹风对象接触过的气流的状态信息;
    根据所述气流的状态信息,确定所述被吹风对象的当前状态;
    显示所述被吹风对象的当前状态。
  18. 一种作业控制的方法,其特征在于,包括:
    获取智能吹风机当前工作功率与被吹风对象的当前状态信息;
    根据所述被吹风对象的当前状态信息,以及,预设的工作功率与被吹风对象的状态信息的关系,获取所述被吹风对象所需的所述智能吹风机的吹风功率;
    根据所述智能吹风机当前工作功率,以及,所述被吹风对象所需的所述智能吹风机的吹风功率判断是否需要对所述当前工作功率进行调整;
    根据判断结果调整或保持所述智能吹风机工作功率。
  19. 根据权利要求18所述的方法,其特征在于,在获取所述智能吹风机当前工作功率与被吹风对象当前状态信息之前,还包括,按照初始默认功率运行所述智能吹风机;
    在按照初始默认功率运行所述智能吹风机之后,在获取所述智能吹风机当前工作功率与吹风对象当前状态信息之前,还包括:判断所述智能吹风机的出风口指定的距离内是否存在被吹风对象;若不存在,则将所述智能吹风机的功率调整至最低功率;若存在,则获取所述智能吹风机当前工作功率与被吹风对象当前状态信息。
  20. 根据权利要求18所述的方法,其特征在于,所述获取被吹风对象的当前状态信息,包括:
    获取与所述被吹风对象接触过的气流的状态信息;
    根据所述气流的状态信息推算所述被吹风对象的状态推算信息,并将所 述状态推算信息作为所述被吹风对象当前状态信息。
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