The utility model relates to the technical field of fans, in particular to a step-less speed regulating oscillating fan.
During use of the existing fan, the gear positions are generally mechanically controlled, and the number of the gear positions are 1 to 3 generally, thus step-less speed regulation cannot be realized; when the revolution speed of the fan is controlled, the rotary knob needs to be turned, and noise would be made when the rotary knob is turned; and according to experiences, the rotary knob can only be turned with enough efforts, thus turning the existing rotary knob wastes great efforts.
The utility model aims to provide a step-less speed regulating oscillating fan to solve the problems in the background of the related art.
In order to realize the above purpose, the utility model provides the following technical scheme that the step-less speed regulating oscillating fan comprises a fan body and a base, wherein the fan body is installed on the base; a first motor is fixedly installed on the fan body, and blades are fixedly installed on an output shaft of the first motor;
a battery is installed inside the base, a PCB main board is installed inside the base, an encoder is installed on the base and is used to control the revolution speed of the fan, a rotary knob is fixedly installed on a rotary part of the encoder, and the rotary knob is located on the outer side of the base.
Preferably, a second motor is installed inside the base, and an output shaft of the second motor is fixedly connected with the fan body.
Preferably, an installing port is formed in the upper end of the base, a bearing is installed inside the installing port, and an installing post is fixedly installed at the bottom of the fan body, installed on an inner ring of the bearing, and fixedly connected with an output end of the second motor.
Preferably, a pressing switch is installed on a rotary center of the rotary knob and is used to control the second motor to drive the fan body to oscillate.
Preferably, a bottom cover is installed at the bottom of the base through bolts.
Preferably, a base wire cover is installed at the installing port.
Compared with the prior art, the step-less speed regulating oscillating fan has the beneficial effects that:
according to the step-less speed regulating oscillating fan, the encoder can be used to realize step-less speed regulation of the fan; and speed control of the fan can be realized by gently turning the rotary knob and using the encoder to control the output revolution speed of the first motor and the second motor, limitation of gear positions and mechanical rotary knob are avoided, and more efforts can be saved compared with mechanical rotary knobs.
In the diagrams: 1. fan body; 2. first motor; 3. base; 31. base wire cover; 4. PCB main board; 5. battery; 6. bottom cover; 7. rotary knob; 8. encoder; 9. second motor.
With reference to the brief drawings of the embodiments of the utility model, the technical schemes of the embodiments of the utility model are described clearly and completely. Apparently, the described embodiments are only a part of the embodiments of the utility model rather than all of the embodiments. All other embodiments based on the embodiments of the utility model and obtained by those of ordinary skill in this technical field without creative design belong to the protection scope of the utility model.
As shown in
A battery 5 is installed inside the base 3 and provide power for the first motor 2 and a second motor 9; a PCB main board 4 is installed inside the base 3, and the PCB main board serves as a control system of the whole fan and is used to control the operation of the fan; an MCU module is provided, as shown in
The second motor 9 is installed inside the base 3, the output shaft of the second motor 9 is fixedly connected with the fan body 1; the second motor 9 is used to control the oscillation of the fan body, thus the existing mechanical rotating method is avoided; and due to the complicated structure and the large size of the mechanical rotating method, the size of the existing fan is comparatively large, while a mechanical rotating structure can be avoided by using an individual motor to control the rotation of the step-less speed regulating oscillating fan, the size of the fan can be reduced, and an individual motor is widely used, especially on the existing small-sized and portable fans.
As shown in
PIN8 is a fan output control pin, which is used to control Q1 and step-up module U3-PIN4 to turn on or turn off the fan.
PIN9 is an upgrading pin.
PIN10 is an oscillating limiting pin, and when the fan oscillates to the limiting switch, it will oscillate in an opposite direction.
PIN11 and 12 are oscillating module control pins, which output signals to an oscillating module U2-PIN1 and 2 to control the oscillating direction of the second motor.
PIN13 is a charging input power detecting pin, which detects the supply voltage of a charging module U4-PIN8.
PIN14 is a charging completion detecting pin, which detects the charging completion condition of a charging module U4-PIN7.
PIN15, 16, 17 and 18 are fan gear position speed regulating pins, which regulate a U3-PIN3 through MCU signals to realize the motor revolution speed regulation at different gear positions.
PIN19 is a charging indication output LED indicator,
PIN20 is an oscillating indication output LED indicator,
PIN22 is a switch pin, the fan can be turned on by pressing and holding the switch pin in a power-off state, the fan can be turned off by pressing and holding the switch pin in a power-on state, and the oscillating mode can be turned on or turned off by pressing the switch pin in a power-on state.
PIN23 and 24 are encoder control pins, the fan can be switched to the lowest gear position by continuously rotating the encoder control pins in a power-off state, and the fan can be turned off by continuously rotating the encoder control pins at the lowest gear position in a power-on state. The gear positions of the fan can be regulated at will, and the speed will not be regulated at the largest gear position.
PIN25-32 are fan gear position expansion ports, and as shown in
As shown in
Furthermore, in another embodiment, an installing port is formed in the upper end of the base, a bearing is installed inside the installing port, and an installing post is fixedly installed at the bottom of the fan body 1, installed on an inner ring of the bearing, and fixedly connected with an output end of the second motor 9. The bearing enables the fan body 1 to rotate more easily.
A pressing switch is installed on a rotary center of the rotary knob 7 and is used to control the second motor 9 to drive the fan body 1 to oscillate.
A bottom cover 6 is installed at the bottom of the base 3 through bolts, and the bottom cover can be opened to facilitate placing and installing of parts in the base 3.
A base wire cover 31 is installed at the installing port and can facilitate the arrangement of wires in the base and circuits in the fan body 1.
Although the embodiments of the utility model have been shown and described, for those of ordinary skill in this field, without departing from the principles and spirits of the utility model, various changes, modifications, substitutions and variants of the embodiments can be made; and the scope of the utility model is defined by the attached claims and their equivalents.