CN110953695A - Oscillating-vane oscillating fan heater with rapid heating function - Google Patents

Abstract

A swing blade swing type fan heater with a quick heating function can start a quick heating mode through a remote terminal, and carry out quick heating with maximum heating power, maximum air outlet volume operation, full-area coverage and wind shielding treatment through a swing blade assembly of the swing type fan heater. The working steps of the fan heater comprise 5 steps. The fan heater is operated at the maximum heating power and the maximum air outlet volume before the preset temperature T, when the preset temperature T is reached, the fan heater is subjected to constant temperature control, and meanwhile, the air outlet range is adjusted and the objects are subjected to wind shielding treatment according to the size of the current area and the arrangement of the objects, so that the energy loss is reduced, and the temperature of each position of the current area is ensured to be uniform. Meanwhile, the fan heater has the functions of purification and humidification, and reduces the occupied space and the operation difficulty. The warm air blower can realize automatic control according to the current environmental condition, and the intelligent degree of the warm air blower is greatly improved.

Description

Oscillating-vane oscillating fan heater with rapid heating function

Technical Field

The invention relates to the field of warm air blowers, in particular to a swinging-vane type warm air blower with a quick heating function.

Background

The existing fan heater can not be used for heating through remote control, so that the indoor space can be quickly heated, and a user needs to operate the fan heater before starting the fan heater; meanwhile, the air outlet mode of the warm air blower in the prior art is simple and is only periodically swept, air outlet cannot be used for heating and supplying air according to the environment of the current region, the same air sweeping mode is carried out on the environments with different region areas, air can be supplied to the regions when large objects such as large furniture or pillars exist, energy is wasted, and the warm air blower has the defect of low intelligent degree, so that the experience of a user is greatly reduced.

Therefore, aiming at the defects in the prior art, the oscillating blade oscillating type fan heater with the rapid heating function is provided to solve the defects in the prior art.

Disclosure of Invention

The invention aims to avoid the defects of the prior art and provides a swinging blade type fan heater with a quick heating function. The swing-blade swing type warm air blower with the rapid warm-up function can automatically adjust the heating power and the air outlet quantity and can also carry out constant temperature control.

The above object of the present invention is achieved by the following technical measures:

the oscillating blade oscillating type warm air blower with the rapid warming function can start a rapid warming mode through a remote terminal, and performs rapid warming of maximum warming power, maximum air outlet volume operation, full-area coverage and wind shielding treatment through an oscillating blade assembly of the oscillating warm air blower.

The invention relates to a swing blade swing type warm air blower with a quick heating function, which comprises the following working steps:

step one, a user starts a rapid heating mode through a remote terminal and enters step two;

step two, detecting the size of the current area and the arrangement of the objects by the warm air blower to obtain area data, and entering step three;

step three, obtaining heating parameters and wind sweeping parameters according to the regional data in the step two, and entering the step four;

step four, the fan heater operates at the maximum heating power and the maximum air outlet volume according to the heating parameters and the air sweeping parameters obtained in the step three, swings a swing blade assembly of the fan heater to heat, and enters the step five;

and step five, after the temperature of the current area reaches the preset temperature T, adjusting according to the heating parameter and the air sweeping parameter obtained in the step four and the area parameter obtained in the step two to obtain an operation parameter, swinging a swing blade assembly of the fan heater according to the operation parameter, and performing constant temperature control to maintain the temperature of the current area at the preset temperature T.

Preferably, the heating parameter is to reduce the output heating power when the object is located in the direction according to the arrangement of the current object.

Preferably, the wind sweeping parameter is at least one of a swing angle of the swing blade assembly or an object wind shielding treatment.

Preferably, the wind sweeping parameter is an object wind sheltering treatment.

Preferably, the object wind-shielding treatment includes at least one of a closing mode of the swing blade assembly, a fast sweeping mode of the swing blade assembly, or a mode of reducing air volume.

Preferably, the operation parameters are reduction of heating power and reduction of air outlet volume.

The oscillating-vane oscillating fan heater with the rapid heating function is provided with a data acquisition assembly, and the data acquisition assembly is used for acquiring the size of an area and area data of the arrangement of objects and detecting the temperature of the area.

The oscillating-vane oscillating fan heater with the rapid heating function is provided with a processing device, and the processing device is connected with a data acquisition assembly.

Preferably, the processing device is configured to receive a fast heating mode command sent by a user; controlling the fan heater to rapidly heat according to the rapid heating mode instruction, the region data and the temperature; and controlling the fan heater to perform constant temperature control when the temperature reaches a preset temperature T.

The oscillating-vane oscillating fan heater with the rapid heating function is provided with a signal receiving device, the signal receiving device is connected with the processing device, and the signal receiving device is wirelessly connected with a remote terminal.

Preferably, the signal receiving device is configured to receive a command of a fast heating mode from a user through a remote terminal.

The oscillating-vane oscillating type fan heater with the rapid heating function is provided with an oscillating vane component, and the oscillating vane component is connected with the processing device.

Preferably, the swing blade assembly is used for adjusting the air supply direction and the air outlet volume.

Preferably, the data acquisition assembly is provided with an infrared sensor, and the infrared sensor is used for detecting at least one of the temperature of the current area, the space range or the size range of the object in real time and correspondingly obtaining an infrared signal.

Preferably, the data acquisition assembly is provided with a depth camera, and the depth camera is used for detecting the size of the current area and the position where the object is placed in real time and obtaining a camera signal.

The oscillating vane oscillating type fan heater with the rapid heating function is also provided with a heating component, and the heating component is connected with the processing device.

Preferably, the heating assembly is used for heating the air flow, so that the output air flow is output in the form of warm air.

The oscillating-vane oscillating type fan heater with the rapid heating function is provided with a driving assembly, and the driving assembly is connected with the processing device.

Preferably, the drive assembly is adapted to generate an air flow.

The oscillating vane oscillating type fan heater with the rapid heating function is provided with an air duct component for guiding air, and the oscillating vane component is assembled at an air outlet of the air duct component.

Preferably, the processing device receives the rapid heating mode instruction of the signal receiving device, and performs analysis processing according to the rapid heating mode instruction, the infrared signal and the camera signal to obtain a processing signal, the processing device correspondingly sends the processing signal to the driving assembly, the heating assembly and the swinging blade assembly, the driving assembly receives the processing signal and performs maximum blowing work, the heating assembly receives the processing signal and performs maximum heating power heating work, and the swinging blade assembly receives the processing signal and performs swinging adjustment on the air supply direction.

When the temperature reaches the preset temperature T, the processing device obtains an adjusting signal, the processing device correspondingly sends the adjusting signal to the driving assembly, the heating assembly and the swinging blade assembly, the driving assembly receives the adjusting signal and adjusts the air outlet speed, the heating assembly receives the adjusting signal and performs constant temperature control, and the swinging blade assembly receives the adjusting signal and performs swinging rhythm adjustment on the air quantity and swinging amplitude adjustment on the air direction.

Preferably, the data acquisition assembly is provided with a humidity sensor, and the humidity sensor is used for detecting the humidity of the current area in real time and obtaining a humidity signal.

Preferably, the data acquisition assembly is provided with a temperature sensor, and the temperature sensor is used for detecting the temperature of the current area in real time and obtaining a temperature signal.

Preferably, the data acquisition assembly is provided with an air speed sensor, and the air speed sensor is used for detecting the ambient air flow rate in real time to obtain an air speed signal.

Preferably, the data acquisition assembly is provided with a PM2.5 sensor, and the PM2.5 sensor is used for detecting the concentration of particulate matters with equivalent diameters of less than or equal to 2.5 micrometers in the current area in real time and obtaining a PM2.5 signal.

The invention relates to a swing blade oscillating type warm air blower with a rapid heating function, which is a warm air blower capable of realizing automatic control according to the current environmental condition.

The oscillating-vane oscillating fan heater with the rapid heating function is also provided with a purification assembly, and the purification assembly is used for purifying air flow so that the output air flow is output in a purification mode.

The oscillating-vane oscillating fan heater with the rapid heating function is also provided with an AI control component capable of realizing automatic control according to the current environmental condition, wherein the AI control component is connected with the processing device and is also connected with at least one of a purification component, a heating component, an air channel component, a driving component or a humidifying component.

Preferably, the AI control module is provided with a sleep control device for determining whether the user is in a sleep state and starting a sleep mode.

Preferably, the sleep control device is provided with a camera monitoring device for monitoring eye closure of a human body and a sleep controller, and the sleep controller is connected with at least one of the driving assembly, the humidifying assembly or the heating assembly, and is connected with the processing device and the camera monitoring device.

Preferably, the AI control module is provided with a purification control device, and the purification control device is used for judging whether a person exists in the current area, and starting the purification mode according to the air quality of the current area.

Preferably, the purification control device is connected to the processing device, the driving assembly and the purification assembly respectively.

Preferably, the AI control module is provided with a customized intelligent air control device, and the customized intelligent air control device is used for receiving the instruction of the user and controlling the customized required air quantity blowing to the wind-receiving target.

Preferably, the customized intelligent wind control device is connected with the driving assembly and the processing device.

Preferably, the customized intelligent wind control device is provided with an input device, and the input device is used for receiving user instructions.

Preferably, the customized intelligent wind control device is provided with an input device, and the input device is used for receiving user instructions.

Preferably, the wireless connection is a WIFI wireless connection or a mobile network wireless connection.

Preferably, the remote terminal may be a mobile phone, a tablet computer or an APP.

The swinging blade swinging type warm air blower with the rapid warming function can start the rapid warming mode through the remote terminal, and perform rapid warming of maximum warming power, maximum air outlet volume operation, full-area coverage and wind shielding treatment through the swinging blade assembly of the swinging warm air blower. The oscillating-vane oscillating fan heater with the rapid heating function comprises 5 working steps. The fan heater of the invention operates with the maximum heating power and the maximum air outlet volume before the preset temperature T, when the preset temperature T is reached, the fan heater performs constant temperature control, and simultaneously adjusts the air outlet range and performs air shielding treatment on the objects according to the size of the current area and the arrangement of the objects, thereby reducing energy loss and ensuring that the temperature of each position of the current area is uniform. Meanwhile, the fan heater has the functions of purification and humidification, and reduces the occupied space and the operation difficulty. The warm air blower can realize automatic control according to the current environmental condition, and the intelligent degree of the warm air blower is greatly improved.

Drawings

The invention is further illustrated by means of the attached drawings, the content of which is not in any way limiting.

Fig. 1 is a schematic flow chart of a swing blade oscillating type fan heater with a rapid heating function according to the present invention.

Fig. 2 is a schematic signal transmission relationship diagram of the oscillating vane oscillating type fan heater with a rapid heating function in embodiment 1.

Fig. 3 is a schematic diagram of signal transmission relationship of the customized intelligent wind control device.

Fig. 4 is a schematic diagram of signal transmission relationship of the purge control apparatus.

Fig. 5 is a schematic diagram of signal transmission relationship of the sleep control device.

Detailed Description

The technical solution of the present invention is further illustrated by the following examples.

Example 1.

A swing blade swing type fan heater with a quick heating function is disclosed, as shown in figures 1 and 2, a quick heating mode can be started through a remote terminal, and quick heating of maximum heating power, maximum air outlet quantity operation, whole-area coverage and wind shielding treatment is carried out through a swing blade assembly of the swing type fan heater.

The oscillating-vane oscillating type warm air blower with the rapid warming function comprises the following working steps:

step one, a user starts a rapid heating mode through a remote terminal and enters step two;

step two, detecting the size of the current area and the arrangement of the objects by the warm air blower to obtain area data, and entering step three;

step three, obtaining a heating parameter and a wind sweeping parameter according to the regional data in the step two, and entering the step four;

step four, the fan heater operates at the maximum heating power and the maximum air outlet volume according to the heating parameters and the air sweeping parameters obtained in the step three, swings a swing blade assembly of the fan heater to heat, and enters the step five;

and step five, after the temperature of the current area reaches the preset temperature T, adjusting according to the heating parameter and the air sweeping parameter obtained in the step four and the area parameter obtained in the step two to obtain an operation parameter, swinging a swing blade assembly of the fan heater according to the operation parameter, and performing constant temperature control to maintain the temperature of the current area at the preset temperature T.

The heating parameter of the invention is to reduce the output heating power when the object is positioned according to the arrangement of the current object. The wind sweeping parameter of the invention is at least one of the swing angle of the swing blade component or the object wind shielding treatment. The wind sweeping parameters of the embodiment are the swing angle of the swing blade assembly and the object wind shielding treatment. The operation parameters are to reduce the heating power and reduce the air outlet volume.

It should be noted that the wind sweeping parameters of the present invention can be based on the size of the current area, for example, when the room space where the fan heater is located is large, the flap assemblies swing greatly, so as to deliver the warm air flow to each corner of the room, so that the temperature of each position of the room is uniform, and if the room space where the fan heater is located is small, the flap assemblies swing at a small angle, so as to deliver the warm air flow to each corner of the room, so that the temperature of each position of the room is uniform.

The object wind shielding treatment comprises at least one of a swinging blade component closing mode, a swinging blade component fast sweeping mode or an air volume reducing mode. For example, when a large object is placed at a certain position in a room, the swinging blade assembly can swing to the angle within the range of the object in a closing mode of the swinging blade assembly, or in a fast sweeping mode of the swinging blade assembly, or in a mode of reducing air volume, and in all, the energy output in the direction is reduced. The object wind-shielding treatment of the embodiment is specifically a closing mode of the swing blade assembly.

The fan heater is provided with the data acquisition assembly, and the data acquisition assembly is used for acquiring the size of an area and the area data of the arrangement of objects and detecting the temperature of the area.

The fan heater is provided with a processing device, and the processing device is connected with the data acquisition assembly. The processing device is used for receiving a rapid heating mode instruction sent by a user; controlling the fan heater to rapidly heat according to the rapid heating mode instruction, the region data and the temperature; and controlling the fan heater to perform constant temperature control when the temperature reaches a preset temperature T.

The fan heater is provided with a signal receiving device, the signal receiving device is connected with the processing device, and the signal receiving device is wirelessly connected with a remote terminal. The signal receiving device is used for receiving a rapid heating mode instruction sent by a user through a remote terminal.

The fan heater is provided with the swinging blade assembly, and the swinging blade assembly is connected with the processing device. The swing blade assembly is used for adjusting the air supply direction and the air outlet quantity.

The data acquisition assembly is provided with an infrared sensor, and the infrared sensor is used for detecting at least one of the temperature of the current area, the space range or the size range of the object in real time and correspondingly obtaining an infrared signal.

The data acquisition assembly is provided with a depth camera, and the depth camera is used for detecting the size of the current area and the position where an object is placed in real time and obtaining a camera signal.

A user sends a rapid heating mode instruction to the processing device through the signal receiving device, an infrared signal of the infrared sensor is sent to the processing device, a camera signal of the depth camera is sent to the processing device, the processing device respectively receives the rapid heating mode instruction, the infrared signal and the camera signal and carries out analysis processing to obtain a processing signal, the processing device carries out heating according to a control fan heater, meanwhile, the processing device sends the processing signal to the swinging blade assembly, and the swinging blade assembly receives the processing signal and carries out swinging to adjust the air supply direction; when the temperature reaches the preset temperature T, the processing device obtains an adjusting signal and sends the adjusting signal to the main body and the swinging blade assembly, the main body receives the adjusting signal to perform constant temperature control work, and the swinging blade assembly receives the adjusting signal to perform swinging adjustment on the air supply direction.

The fan heater is also provided with a heating component, and the heating component is connected with the processing device. The heating assembly is used for heating the air flow, so that the output air flow is output in a warm air form. The fan heater is provided with a driving assembly, and the driving assembly is connected with the processing device. The drive assembly is used for generating air flow. The fan heater is provided with an air duct assembly for guiding air. The swing blade component is assembled at the air outlet of the air duct component.

The processing device receives a rapid heating mode instruction of the signal receiving device and performs analysis processing according to the rapid heating mode instruction, the infrared signal and the camera signal to obtain a processing signal, the processing device correspondingly sends the processing signal to the driving assembly, the heating assembly and the swinging blade assembly, the driving assembly receives the processing signal and performs maximum blowing work, the heating assembly receives the processing signal and performs maximum heating power heating work, and the swinging blade assembly receives the processing signal and performs swinging to adjust the air supply direction.

When the temperature reaches the preset temperature T, the processing device obtains an adjusting signal, the processing device correspondingly sends the adjusting signal to the driving assembly, the heating assembly and the swinging blade assembly, the driving assembly receives the adjusting signal and adjusts the air outlet speed, the heating assembly receives the adjusting signal and performs constant temperature control, and the swinging blade assembly receives the adjusting signal and performs swinging rhythm adjustment on the air quantity and swinging amplitude adjustment on the air direction.

After the fan heater is in the rapid heating mode, the space and objects in the current area are detected, the maximum heating power and the maximum wind speed are operated according to the obtained obstacle data and the space data, heating is carried out, and the obstacle is subjected to wind shielding treatment in the process, so that energy loss is reduced. When the temperature of the current area reaches the preset temperature T, the space and the objects in the current area are detected, the maximum heating power and the maximum wind speed are operated according to the obtained obstacle data and the space data, heating is carried out, and the obstacle is subjected to wind shielding treatment in the process, so that the energy loss is reduced. When the current region temperature reaches the preset temperature T, the wind speed of the outlet air is automatically reduced according to the heating parameters, the air sweeping parameters and the region parameters, the heating power is reduced, the swing rhythm of the swing blade component and the swing amplitude of the swing blade component are adjusted according to the space size and the distribution of objects, and therefore constant temperature control is conducted.

The processing device of the present invention can be any processing device that can only realize the data analysis processing function, and the processing device having such a function is also widely used in industrial production, and the type and structure of the processing device are not the main points of the present invention, and therefore, they will not be described in detail herein.

The swing blade swing type fan heater with the rapid heating function can start a rapid heating mode through a remote terminal, and performs rapid heating of maximum heating power, maximum air outlet volume operation, full-area coverage and wind shielding treatment through a swing blade assembly of the swing type fan heater. The oscillating-vane oscillating fan heater with the rapid heating function comprises 5 working steps. The fan heater of the invention operates with the maximum heating power and the maximum air outlet volume before the preset temperature T, when the preset temperature T is reached, the fan heater performs constant temperature control, and simultaneously adjusts the air outlet range and performs air shielding treatment on the objects according to the size of the current area and the arrangement of the objects, thereby reducing energy loss and ensuring that the temperature of each position of the current area is uniform.

Example 2.

A swing blade oscillating fan heater with a rapid heating function, as shown in fig. 3 to 5, other features are the same as those of embodiment 1, except that: the data acquisition assembly is provided with a humidity sensor, and the humidity sensor is used for detecting the humidity of the current area in real time and obtaining a humidity signal.

The data acquisition assembly is provided with a temperature sensor, and the temperature sensor is used for detecting the temperature of the current area in real time and obtaining a temperature signal.

The data acquisition assembly is provided with an air speed sensor, and the air speed sensor is used for detecting the ambient air flow rate in real time to obtain an air speed signal.

The data acquisition assembly is provided with a PM2.5 sensor, and the PM2.5 sensor is used for detecting the concentration of the particulate matters with equivalent diameters of less than or equal to 2.5 microns in the current area in real time and obtaining a PM2.5 signal.

The warm air blower provided by the invention can realize automatic control according to the current environmental condition.

The fan heater is also provided with a purification assembly, and the purification assembly is used for purifying the air flow so that the output air flow is output in a purification mode.

The fan heater is also provided with an AI control component which can realize automatic control according to the current environmental condition, and the AI control component is connected with the processing device and is also connected with at least one of a purification component, a heating component, an air channel component, a driving component or a humidifying component.

The AI control component is provided with a sleep control device for determining whether the user is in a sleep state and initiating a sleep mode. The sleep control device is provided with a camera monitoring device and a sleep controller, wherein the camera monitoring device is used for monitoring human eye closure, and the sleep controller is connected with at least one of the driving assembly, the humidifying assembly or the heating assembly and is connected with the processing device and the camera monitoring device.

When the camera monitoring equipment monitors that all people in the current area are continuously closed and the infrared signals indicate that no action exists in the human body in the current area within the time period of T minutes, the sleep controller judges that the people are in the sleep state and starts the sleep mode; or

When the camera monitoring equipment monitors that the eyes of the people in the current area are not continuously closed or the infrared signals indicate that the people in the current area move within the time period of T minutes, the sleep controller judges that the people are in the non-sleep state and does not start the sleep mode.

In the sleep mode, the sleep controller controls the humidifying assembly to keep the current humidity at a humidity threshold value, the sleep controller controls the driving assembly to keep the speed of the air flow generated by the driving assembly to be less than or equal to a wind speed threshold value, and the sleep controller controls the heating assembly to keep the temperature of the current area at a temperature threshold value.

The temperature threshold is 15-26 ℃, the humidity threshold is 35-65%, and the wind speed threshold is 0.35 m/s. T is 15 minutes.

The present invention is explained in this embodiment, for example, when the camera monitoring device monitors that all people in the current area are continuously closed and the infrared signal indicates that no human body is moving in the current area within 15 minutes, it is determined as a sleep state and a sleep mode is started. The sleep mode is that the humidifying component is controlled by the sleep controller to keep the current humidity within the range of 35-65%, the driving component is controlled to keep the speed of the air flow generated by the driving component within 0.35m/s, and finally the heating component is controlled to keep the temperature of the current area within the range of 15-26 ℃. And when the infrared signal indicates that the human body in the current area moves within 15 minutes, the sleep controller judges that the human body is in the non-sleep state and does not start the sleep mode.

It should be noted that the temperature threshold of the present invention is not limited to 15-26 ℃, and may be other temperatures; the humidity threshold is not limited to 35-65%, and other humidities can be adopted; the wind speed threshold is not limited to 0.35m/s, and other wind speeds can be adopted, and the specific implementation mode is determined according to the actual situation. T can be 15 minutes or other time, and the specific implementation mode is determined according to actual conditions.

The AI control assembly is provided with a customized intelligent air control device which is used for receiving the indication of a user and controlling the customized required air quantity blown to the wind-receiving target. The customized intelligent wind control device is connected with the driving assembly and the processing device. The customized intelligent wind control device is provided with an input device for receiving a user indication. The customized intelligent wind control device is provided with an input device for receiving a user indication.

The input device receives the indication of the current user to obtain an indication signal and sends the indication signal to the intelligent air controller, the intelligent air controller monitors the spatial position of the current user in real time according to the infrared sensor, and the intelligent air controller controls the driving assembly to increase or decrease the air volume when the driving assembly rotates to the direction of the current user. Meanwhile, the intelligent air controller reduces air quantity, increases air quantity or carries out wind shielding treatment according to the position of the corresponding user.

The present invention is described by taking this embodiment as an example, where the input device receives an indication of a current user to obtain an indication signal and sends the indication signal to the intelligent wind controller, if the user requires to keep out of the wind, the intelligent wind controller obtains a user spatial position of the current user through human body data of the infrared sensor, and the intelligent wind controller drives the assembly to rotate to the direction of the current user, so as to reduce airflow blowing to the current user direction by quickly blowing, reducing the wind speed, or closing the hinge of the main air duct assembly.

The AI control assembly is provided with a purification control device which is used for judging whether a person exists in the current area and starting a purification mode according to the air quality of the current area. The purification control device is respectively connected with the processing device, the driving assembly and the purification assembly. The purification control device is set as a purification controller, and the purification controller is respectively connected with the purification assembly, the driving assembly and the treatment device.

When the infrared signal monitors that no person exists in the current area and the PM2.5 value is greater than or equal to the purification threshold value, the purification controller starts a purification mode; or

When the infrared signals monitor that people exist in the current area or the PM2.5 value is smaller than the purification threshold value, the purification controller does not start the purification mode.

The purification threshold values comprise a first purification threshold value, a second purification threshold value, a third purification threshold value and a fourth purification threshold value.

When the purification threshold value is the first purification threshold value, the purification controller controls the driving assembly to generate micro-speed wind, and the purification controller controls the purification assembly to work. When the purification threshold value is the second purification threshold value, the purification controller controls the driving assembly to generate low-speed wind, and the purification controller controls the purification assembly to work. When the purification threshold value is the III purification threshold value, the purification controller controls the driving assembly to generate medium-speed wind, and the purification controller controls the purification assembly to work. When the purification threshold is the IV purification threshold, the purification controller controls the driving assembly to generate high wind and controls the purification assembly to work.

The first purification threshold was 35. mu.g/m³≤PM2.5≤75μg/m³II the purification threshold is 75 mu g/m³＜PM2.5≤115μg/m³III the third decontamination threshold is 115. mu.g/m³＜PM2.5≤150μg/m³The IV purge threshold is 150. mu.g/m³＜PM2.5。

The present invention is illustrated by taking the embodiment as an example, when the infrared signal detects that no person is in the current area and the PM2.5 value is 135 μ g/m³In time, since the PM2.5 value is in the III purification threshold range, the purification controller controls the driving assembly to generate medium-speed wind, and the purification controller controls the purification assembly to work. When the purification is carried out for a period of time, the current PM2.5 value is reduced to 30 mu g/m³Namely, the purification controller controls the purification component to exit the purification mode. If the infrared signal monitors that people exist in the current area, the purification controller does not start the purification mode.

The intelligent wind controller, the sleep controller and the purification controller are all controllers capable of realizing data analysis, processing and judgment functions, the controllers with the functions can be used as the controllers of the invention, the controllers with the functions can be widely applied to industrial production, and meanwhile, the model and the structure of the controllers are not the key points of the invention, so that the description is not repeated.

It should be noted that the temperature sensor, the humidity sensor, the infrared sensor, the wind speed sensor, the depth camera and the PM2.5 sensor of the present invention are common knowledge, and those skilled in the art should know the usage method, model and operation principle thereof, and the present invention will not be described herein repeatedly.

The information transceiver of the present invention, which can only realize data receiving and transmitting functions, can be used as the information transceiver of the present invention, and the information transceiver having such a function is also widely used in industrial production, and the type and structure of the information transceiver are not the main points of the present invention, and therefore, they will not be described in detail herein.

It should be noted that the air duct assembly, the humidifying assembly, the purifying assembly, the heating assembly, the driving assembly and the swinging vane assembly are all common knowledge, and the structure and principle of the air duct assembly, the humidifying assembly, the purifying assembly, the heating assembly, the driving assembly and the swinging vane assembly are known to those skilled in the art. The structures of the air duct assembly, the humidifying assembly, the purifying assembly, the heating assembly, the driving assembly and the swinging vane assembly are not the key points of the invention, so that the structures are not described in detail.

The swing blade swing type fan heater with the rapid heating function can start a rapid heating mode through a remote terminal, and performs rapid heating of maximum heating power, maximum air outlet volume operation, full-area coverage and wind shielding treatment through a swing blade assembly of the swing type fan heater. The oscillating-vane oscillating fan heater with the rapid heating function comprises 5 working steps. The fan heater of the invention operates with the maximum heating power and the maximum air outlet volume before the preset temperature T, when the preset temperature T is reached, the fan heater performs constant temperature control, and simultaneously adjusts the air outlet range and performs air shielding treatment on the objects according to the size of the current area and the arrangement of the objects, thereby reducing energy loss and ensuring that the temperature of each position of the current area is uniform. Meanwhile, the fan heater has the functions of purification and humidification, and reduces the occupied space and the operation difficulty. The warm air blower can realize automatic control according to the current environmental condition, and the intelligent degree of the warm air blower is greatly improved.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (33)

1. The utility model provides a pendulum leaf oscillating electric fan heater with quick warm function of heating which characterized in that: the rapid heating mode can be started through the remote terminal, and the rapid heating with the maximum heating power, the maximum air outlet quantity operation, the whole-area coverage and the wind shielding treatment is carried out through swinging the swing blade assembly of the fan heater.

2. The oscillating fan heater with quick heating function according to claim 1, characterized in that the working steps comprise:

step one, a user starts a rapid heating mode through a remote terminal and enters step two;

step two, detecting the size of the current area and the arrangement of the objects by the warm air blower to obtain area data, and entering step three;

step three, obtaining a heating parameter and a wind sweeping parameter according to the regional data in the step two, and entering the step four;

step four, the fan heater operates at the maximum heating power and the maximum air outlet volume according to the heating parameters and the air sweeping parameters obtained in the step three, swings a swing blade assembly of the fan heater to heat, and enters the step five;

and step five, after the temperature of the current area reaches the preset temperature T, adjusting according to the heating parameter and the air sweeping parameter obtained in the step four and the area parameter obtained in the step two to obtain an operation parameter, swinging a swing blade assembly of the fan heater according to the operation parameter, and performing constant temperature control to maintain the temperature of the current area at the preset temperature T.

3. The oscillating vane oscillating fan heater with quick heating function according to claim 2, characterized in that: the heating parameter is to reduce the output heating power when the object is located in the direction according to the arrangement of the current object.

4. The oscillating vane oscillating fan heater with quick heating function according to claim 2, characterized in that: the wind sweeping parameter is at least one of a swing angle of the swing blade assembly or object wind shielding treatment.

5. The oscillating vane oscillating fan heater with quick heating function according to claim 2, characterized in that: the wind sweeping parameter is object wind sheltering treatment;

the object wind-shielding treatment comprises at least one of a swinging blade component closing mode, a swinging blade component fast sweeping mode or an air volume reducing mode.

6. The oscillating vane oscillating fan heater with quick heating function according to claim 2, characterized in that: the operation parameters are to reduce heating power and reduce air outlet volume.

7. The oscillating vane oscillating fan heater with quick heating function according to claim 2, characterized in that: the temperature detection device is provided with a data acquisition assembly, and the data acquisition assembly is used for acquiring the size of an area and the area data of the arrangement of objects and detecting the temperature of the area.

8. The oscillating vane oscillating fan heater with a rapid heating function according to claim 7, characterized in that: the processing device is connected with the data acquisition assembly;

the processing device is used for receiving a rapid heating mode instruction sent by a user; controlling the fan heater to rapidly heat according to the rapid heating mode instruction, the region data and the temperature; and controlling the fan heater to perform constant temperature control when the temperature reaches a preset temperature T.

9. The oscillating vane oscillating fan heater with a rapid heating function according to claim 8, wherein: the system is provided with a signal receiving device, the signal receiving device is connected with the processing device, and the signal receiving device is wirelessly connected with a remote terminal;

the signal receiving device is used for receiving a rapid heating mode instruction sent by a user through a remote terminal.

10. The oscillating vane oscillating fan heater with a rapid heating function according to claim 8, wherein: the swing blade component is arranged and connected with the processing device;

the swing blade assembly is used for adjusting the air supply direction and the air outlet quantity.

11. The oscillating vane oscillating fan heater with a rapid heating function according to claim 7, characterized in that: the data acquisition assembly is provided with an infrared sensor, and the infrared sensor is used for detecting at least one of the temperature of the current area, the space range or the size range of an object in real time and correspondingly obtaining an infrared signal.

12. The oscillating vane oscillating fan heater with a rapid heating function according to claim 7, characterized in that: the data acquisition assembly is provided with a depth camera, and the depth camera is used for detecting the size of a current area and the position where an object is placed in real time and obtaining a camera signal.

13. The oscillating vane oscillating fan heater with a rapid heating function according to claim 8, wherein: the heating assembly is connected with the processing device;

the heating assembly is used for heating the air flow, so that the output air flow is output in a warm air form.

14. The oscillating vane oscillating fan heater with a rapid heating function according to claim 8, wherein: the device is provided with a driving component, and the driving component is connected with the processing device;

the drive assembly is used for generating air flow.

15. The oscillating vane oscillating fan heater with a rapid heating function according to claim 10, wherein: the air duct assembly is used for guiding air, and the swing blade assembly is assembled at an air outlet of the air duct assembly.

16. The oscillating vane oscillating fan heater with a rapid heating function according to claim 8, wherein: the processing device receives a rapid heating mode instruction of the signal receiving device and carries out analysis processing according to the rapid heating mode instruction, the infrared signal and the camera signal to obtain a processing signal, the processing device correspondingly sends the processing signal to the driving assembly, the heating assembly and the swinging blade assembly, the driving assembly receives the processing signal and carries out maximum blowing work, the heating assembly receives the processing signal and carries out maximum heating power heating work, and the swinging blade assembly receives the processing signal and carries out swinging regulation on the air supply direction;

when the temperature reaches the preset temperature T, the processing device obtains an adjusting signal, the processing device correspondingly sends the adjusting signal to the driving assembly, the heating assembly and the swinging blade assembly, the driving assembly receives the adjusting signal and adjusts the air outlet speed, the heating assembly receives the adjusting signal and performs constant temperature control, and the swinging blade assembly receives the adjusting signal and performs swinging rhythm adjustment on the air quantity and swinging amplitude adjustment on the air direction.

17. The oscillating vane oscillating fan heater with a rapid heating function according to claim 7, characterized in that: the data acquisition assembly is provided with a humidity sensor, and the humidity sensor is used for detecting the humidity of the current area in real time and obtaining a humidity signal.

18. The oscillating vane oscillating fan heater with a rapid heating function according to claim 7, characterized in that: the data acquisition assembly is provided with a temperature sensor, and the temperature sensor is used for detecting the temperature of the current area in real time and obtaining a temperature signal.

19. The oscillating vane oscillating fan heater with a rapid heating function according to claim 7, characterized in that: the data acquisition assembly is provided with an air speed sensor, and the air speed sensor is used for detecting the ambient air flow rate in real time to obtain an air speed signal.

20. The oscillating vane oscillating fan heater with a rapid heating function according to claim 7, characterized in that: the data acquisition assembly is provided with a PM2.5 sensor, and the PM2.5 sensor is used for detecting the concentration of the particulate matters with equivalent diameters of less than or equal to 2.5 micrometers in the current area in real time and obtaining a PM2.5 signal.

21. The oscillating vane oscillating fan heater with quick heating function according to claim 1, characterized in that: the warm air blower can realize automatic control according to the current environmental condition.

22. The oscillating vane oscillating fan heater with quick heating function according to claim 1, characterized in that: a purification assembly is also provided for purifying the gas stream so that the output gas stream is output in a purified form.

23. The oscillating vane oscillating fan heater with a rapid heating function according to claim 8, wherein: the automatic air conditioner is characterized by further comprising an AI control assembly capable of achieving automatic control according to the current environmental condition, wherein the AI control assembly is connected with the processing device and is further connected with at least one of the purification assembly, the heating assembly, the air channel assembly, the driving assembly or the humidifying assembly.

24. The oscillating vane oscillating fan heater with rapid heating function according to claim 23, characterized in that: the AI control component is provided with a sleep control device which is used for judging whether a user is in a sleep state and starting a sleep mode.

25. The oscillating vane oscillating fan heater with rapid heating function according to claim 24, characterized in that: the sleep control device is provided with a camera monitoring device and a sleep controller for monitoring human eye closure, and the sleep controller is connected with at least one of the driving assembly, the humidifying assembly or the heating assembly and is connected with the processing device and the camera monitoring device.

26. The oscillating vane oscillating fan heater with rapid heating function according to claim 23, characterized in that: the AI control assembly is provided with a purification control device which is used for judging whether a person exists in the current area and starting a purification mode according to the air quality of the current area.

27. The oscillating vane oscillating fan heater with rapid heating function according to claim 26, characterized in that: the purification control device is respectively connected with the processing device, the driving assembly and the purification assembly.

28. The oscillating vane oscillating fan heater with rapid heating function according to claim 23, characterized in that: the AI control assembly is provided with a customized intelligent air control device which is used for receiving the indication of a user and controlling the customized required air quantity blown to the wind-receiving target.

29. The oscillating vane oscillating fan heater with rapid heating function according to claim 28, characterized in that: the customized intelligent wind control device is connected with the driving assembly and the processing device.

30. The oscillating vane oscillating fan heater with rapid heating function according to claim 28, characterized in that: the customized intelligent wind control device is provided with an input device, and the input device is used for receiving user instructions.

31. The oscillating vane oscillating fan heater with rapid heating function according to claim 30, characterized in that: the customized intelligent wind control device is provided with an input device, and the input device is used for receiving user instructions.

32. The oscillating vane oscillating fan heater with a rapid heating function according to claim 9, characterized in that: the wireless connection is WIFI wireless connection or mobile network wireless connection.

33. The oscillating vane oscillating fan heater with a rapid heating function according to claim 9, characterized in that: the remote terminal can be a mobile phone, a tablet computer or an APP.

Images