JPWO2020021943A1 - Ceiling fan - Google Patents

Abstract

The ceiling fan (100) has a shaft fixed to the ceiling, a DC motor (2) fixed to the shaft, blades rotated by the DC motor (2), and a power input for supplying power to the DC motor (2). A unit, a current detecting unit (13) for detecting a current value in the DC motor (2), and a rotation speed adjusting unit (15) for controlling the rotation speed of the DC motor (2) are provided. When the rotation speed is less than the predetermined rotation speed, the rotation speed of the DC motor (2) is controlled by the rotation speed adjustment unit. When the rotation speed is equal to or higher than the predetermined rotation speed, the DC motor (2) is determined by the current value. Rotation is controlled.

Description

The present invention relates to a ceiling fan.

Conventionally, as a device for controlling the rotation of blades attached to a motor, a device that detects the current rotation speed of the blades and adjusts the rotation speed according to the difference from the target rotation speed is known (for example, Patent Document). 1).

Hereinafter, a general ceiling fan will be described.

A general ceiling fan is composed of an abduction type DC motor whose center is pivotally supported by a shaft and blades fixed to the DC motor. A power input unit passes through the shaft, and the power input unit supplies power from a commercial power source to the rotation control unit above the DC motor. The rotation control unit on the upper part of the DC motor rotates the DC motor using the power supply supplied from the power input unit. In addition, power is supplied via a wall switch mounted on the wall near the ceiling fan. The rotation of the DC motor supplies wind vertically downward from the ceiling side.

Further, a method of adjusting the rotation speed of the general ceiling fan 1000 will be described with reference to FIG.

FIG. 5 is a block diagram showing a configuration for controlling the rotation of the ceiling fan 1000.

As shown in FIG. 5, the ceiling fan 1000 includes a DC motor 1002, a receiving unit 1007, and a rotation control unit 1005. The rotation control unit 1005 receives an operation mode signal from the remote control 1006, which is an instruction to rotate at a predetermined rotation speed, via the reception unit 1007, and controls the rotation of the DC motor 1002. The rotation control unit 1005 includes a rotation speed constant control unit 1009 that controls the rotation of the DC motor 1002. The rotation speed constant control unit 1009 includes a rotation speed detection unit 1010 and a rotation speed setting unit 1011. The rotation speed detection unit 1010 detects the current rotation speed of the DC motor 1002 and outputs it to the rotation speed setting unit 1011. The rotation speed setting unit 1011 compares the rotation speed set in the rotation speed setting unit 1011 with the current rotation speed of the DC motor 1002 received from the rotation speed detection unit 1010, and accelerates / decelerates according to the rotation speed difference. The instruction is output to the rotation speed adjusting unit 1015. Then, the rotation speed adjusting unit 1015 adjusts the rotation speed of the DC motor 1002 based on the acceleration / deceleration instruction output from the rotation speed setting unit 1011.

International Publication No. 2016/136219

As described above, in the conventional general ceiling fan, only the rotation speed of the DC motor is controlled. In this case, since the load applied to the DC motor differs depending on the installation environment of the ceiling fan, for example, the distance between the ceiling fan and the ceiling, the electric power applied to the DC motor differs depending on the installation environment. That is, since the load and power consumption applied to the DC motor differ depending on the installation environment, the load and power consumption applied to the DC motor may exceed the specified values, especially when the ceiling fan is operated near the maximum air volume. be.

An object of the present invention is to provide a ceiling fan capable of suppressing an increase in load and power consumption applied to a motor even when the motor is operated near the maximum air volume regardless of the installation environment.

The ceiling fan according to the present invention includes a shaft fixed to the ceiling, a DC motor fixed to the shaft, a plurality of blades rotated by the DC motor, a power input unit for supplying power from a commercial power source to the DC motor, and a power input unit. It includes a current detection unit that detects the current value in the DC motor and a rotation speed adjustment unit that controls the rotation speed of the DC motor. When the rotation speed is less than a predetermined rotation speed, the DC motor is provided by the rotation speed adjustment unit. Rotation is controlled. When the rotation speed is equal to or higher than a predetermined rotation speed, the rotation of the DC motor is controlled by the current value.

According to the present invention, when the rotation speed is less than the rotation speed, the rotation of the DC motor is controlled by the rotation speed adjusting unit, and when the rotation speed is more than a predetermined rotation speed, the rotation of the DC motor is controlled by the current value. As a result, the increase in power consumption is suppressed even when the vehicle is operated near the maximum air volume regardless of the installation environment.

FIG. 1 is a schematic cross-sectional view of the ceiling fan according to the first embodiment of the present invention. FIG. 2 is a block diagram of the control of the ceiling fan according to the first embodiment of the present invention. FIG. 3 is a block diagram of the control of the ceiling fan according to the second embodiment of the present invention. FIG. 4 is a schematic circuit diagram of the ceiling fan according to the second embodiment of the present invention. FIG. 5 is a block diagram of control of a ceiling fan according to the prior art.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiments shown below exemplify a ceiling fan for embodying the technical idea of the present invention, and the present invention does not specify the ceiling fan as the following. In addition, the members shown in the claims are never specified as the members of the embodiment. Unless otherwise specified, the dimensions, materials, shapes, relative arrangements, etc. of the constituent members described in the embodiments are not intended to limit the scope of the present invention to that alone, but merely described. It's just an example. The size and positional relationship of the members shown in each drawing may be exaggerated to clarify the explanation. Further, in the following description, members having the same or the same quality are shown with the same name and reference numeral, and detailed description thereof will be omitted as appropriate.

The ceiling fan 100 according to the embodiment of the present invention includes a shaft 1 fixed to the ceiling, a DC motor 2 fixed to the shaft 1, a plurality of blades 3 rotated by the DC motor 2, and a commercial power supply 18 to DC. It includes a power input unit 4 that supplies power to the motor 2, a current detection unit 13 that detects a current value in the DC motor 2, and a rotation speed adjusting unit 15 that controls the rotation speed of the DC motor 2. As a result, when the rotation speed is less than the predetermined rotation speed, the rotation control unit 5 controls the rotation of the DC motor 2, and when the rotation speed is more than the predetermined rotation speed, the rotation of the DC motor 2 is controlled by the current value. It becomes possible to do. Therefore, regardless of the installation environment, the power consumption can be kept constant even when the vehicle is operated near the maximum air volume.

Further, the ceiling fan 100a according to another embodiment of the present invention is further based on a voltage detection unit 16 that detects a voltage value supplied to the power input unit 4 and a voltage value detected by the voltage detection unit 16. The configuration may include a current correction unit 17 that corrects the current value so that the power value supplied to the DC motor 2 becomes a predetermined power value.

As a result, by controlling the rotation of the DC motor 2 with the target current value corrected by the current correction unit 17, the power consumption can be kept constant regardless of the voltage at the destination.

(Embodiment 1)
FIG. 1 is a schematic configuration diagram of the ceiling fan 100 according to the first embodiment. In the following, as shown in FIG. 1, the upper part of the ceiling fan 100 installed on the ceiling, that is, the ceiling side is simply referred to as "upper part". Similarly, the lower part of the ceiling fan 100 installed on the ceiling, that is, the floor side is simply referred to as "lower part".

As shown in FIG. 1, the ceiling fan 100 in the present embodiment includes a shaft 1 for fixing the ceiling fan 100 to the ceiling. A metal fitting for fixing to the ceiling is provided at the end of the shaft 1 on the ceiling side, and the shaft 1 and the ceiling are fixed by the metal fitting. Further, as shown in FIG. 1, a DC motor 2 is built in the main body (hereinafter, simply referred to as “main body”) of the ceiling fan 100 connected to the shaft 1, and a plurality of blades that rotate by the rotation of the DC motor 2. 3 is provided at the bottom of the main body. Further, as shown in FIG. 1, the power input unit 4 that supplies electric power from the commercial power supply 18 (see FIG. 4) to the DC motor 2 passes through the inside of the ceiling, passes through the inside of the ceiling, and passes through the shaft 1 to the DC motor 2 inside the main body. Is supplying power to. Further, a rotation control unit 5 for controlling the rotation speed of the DC motor 2 is provided inside the main body.

Further, the remote controller 6 as an electronic terminal device for instructing the wind speed transmits a predetermined operation mode signal according to the user operation. The operation mode signal is an instruction to rotate the ceiling fan 100 at a predetermined rotation speed corresponding to the wind speed instructed by the user. As shown in FIG. 1, there is a receiving unit 7 at the bottom of the ceiling fan 100, and the receiving unit 7 receives an operation mode signal transmitted from the remote controller 6.

FIG. 2 is a block diagram showing a configuration for controlling the rotation of the ceiling fan 100. As shown in FIG. 2, the rotation control unit 5 of the ceiling fan 100 includes a rotation control determination unit 8, a rotation speed constant control unit 9, and a current constant control unit 12. The rotation control determination unit 8 determines whether the operation mode signal received from the remote control 6 via the reception unit 7 is an instruction to rotate the DC motor 2 at a low rotation speed or an instruction to rotate the DC motor 2 at a high rotation speed, and responds to the determination result. The constant rotation speed control unit 9 and the constant current control unit 12 are made to perform control. Specifically, when it is determined that the operation mode signal is an instruction to rotate the DC motor 2 at a low rotation speed, the rotation speed constant control unit 9 is made to perform the rotation speed constant control described later. Further, when it is determined that the operation mode signal is an instruction to rotate the DC motor 2 at a high rotation speed, the current constant control unit 12 is made to perform the current constant control described later. Here, whether the operation mode signal is determined to be an instruction to rotate the DC motor 2 at a low rotation speed or an instruction to rotate the DC motor 2 at a high rotation speed is determined by the rotation speed of the DC motor 2 or more. It is judged by whether or not. This predetermined number may be set in advance according to, for example, the power consumption of the ceiling fan 100. In this case, when the power consumption of the ceiling fan 100 when the DC motor 2 is rotated by a certain operation mode signal becomes less than the specified value, the instruction is set to rotate the DC motor 2 at a low rotation speed. Further, when the power consumption exceeds the specified value depending on the installation status of the ceiling fan 100, it is set to give an instruction to rotate the DC motor 2 at a high rotation speed.

Here, the rotation speed constant control unit 9 includes a rotation speed detection unit 10 and a rotation speed setting unit 11. The rotation speed detection unit 10 detects the current rotation speed of the DC motor 2 and outputs it to the rotation speed setting unit 11. The rotation speed setting unit 11 compares the target rotation speed set in the rotation speed setting unit 11 with the current rotation speed of the DC motor 2 received from the rotation speed detection unit 10, and accelerates / decelerates according to the rotation speed difference. Is output to the rotation speed adjusting unit 15.

Further, the constant current control unit 12 includes a current detection unit 13 and a current increase / decrease determination unit 14. The current detection unit 13 detects the current output current value of the DC motor 2 and outputs the converted value of the detected output current value to the current increase / decrease determination unit 14. The current increase / decrease determination unit 14 compares the target current value set in the current increase / decrease determination unit 14 with the output current value received from the current detection unit 13, and rotates according to the difference between the target current value and the output current value. An acceleration / deceleration instruction is output to the number adjusting unit 15.

The rotation speed adjusting unit 15 changes the increase / decrease in the rotation speed of the DC motor 2 based on the instructions from the rotation speed setting unit 11 and the current increase / decrease determination unit 14. For example, when the current rotation speed is larger than the target rotation speed or when the output current value is larger than the target current value, the rotation speed adjusting unit 15 controls the DC motor 2 to reduce the rotation speed. Further, when the current rotation speed is smaller than the target rotation speed or when the output current value is smaller than the target current value, the rotation speed adjusting unit 15 controls the DC motor 2 to increase the rotation speed.

The operation of the ceiling fan 100 of the present embodiment will be described separately for low rotation operation and high rotation operation.

First, the low rotation operation will be described with reference to FIG. The rotation control unit 5 performs constant rotation speed control, which is a control for keeping the rotation speed of the DC motor 2 constant during low rotation operation. The constant rotation speed control is realized by the rotation control determination unit 8, the constant rotation speed control unit 9 (rotation speed detection unit 10 and the rotation speed setting unit 11), and the rotation speed adjustment unit 15 operating in cooperation with each other. NS.

The details of the constant rotation speed control will be described. When the rotation control unit 5 selects low rotation operation, that is, the rotation control determination unit 8 determines that the operation mode signal received from the remote controller 6 via the reception unit 7 is an instruction to rotate the motor at low rotation speed. In this case, the constant rotation speed control unit 9 controls the constant rotation speed. A target rotation speed is set in the rotation speed setting unit 11 according to the operation mode. Here, for example, the rotation speed setting unit 11 stores the target rotation speed according to the operation mode, and the corresponding target rotation speed is set based on the operation mode signal received via the reception unit 7. Further, the rotation speed detection unit 10 detects the current rotation speed of the DC motor 2. The rotation speed setting unit 11 compares the rotation speed detected by the rotation speed detection unit 10 with the target rotation speed set in the rotation speed setting unit 11, and gives an acceleration / deceleration instruction according to the rotation speed difference. Output to 15. That is, if the current rotation speed is smaller than the target rotation speed, the rotation speed setting unit 11 instructs the rotation speed adjustment unit 15 to increase the motor output. On the contrary, if the current rotation speed is larger than the target rotation speed, the rotation speed setting unit 11 instructs the rotation speed adjustment unit 15 to reduce the motor output. Then, the rotation speed detection unit 10 again detects the rotation speed of the DC motor 2 whose rotation speed is adjusted by the rotation speed adjustment unit 15, and the rotation speed adjustment unit 15 is the DC motor based on the instruction from the rotation speed setting unit 11. Control is performed to keep the rotation speed constant by repeating the adjustment of the rotation speed of 2. By performing the above control, constant rotation speed control is realized.

The above-mentioned problem of constant rotation speed control will be described below.

By changing the length of the shaft 1, the ceiling fan 100 can adjust the distance from the floor to the ceiling fan 100 according to the installation environment. For example, by shortening the shaft 1, the distance between the ceiling fan 100 and the ceiling is shortened. By shortening the distance between the ceiling fan 100 and the ceiling, the viscous friction of the air blown by the blades 3 of the ceiling fan 100 increases, and even at the same rotation speed, the load required for rotation increases, and the motor Power consumption also increases. Therefore, since the load applied to the motor differs depending on the installation environment of the ceiling fan 100, the electric power applied to the motor differs depending on the installation environment. As described above, the load applied to the motor and the power consumption increase depending on the installation environment. Therefore, in particular, when the ceiling fan 100 is operated near the maximum air volume, there is a problem that the load and power consumption applied to the DC motor 2 exceed the specified values. The specified value referred to here is, for example, a value that is an upper limit of the load and power consumption that can be applied to the DC motor 2.

In the present invention, in order to solve the above problems, the ceiling fan 100 controls the current to be constant at high speeds where the power consumption may exceed the specified value depending on the installation environment, so that the load and the power consumption are made constant. Control to keep.

Hereinafter, the high rotation operation will be described with reference to FIG.

During high-speed operation, the rotation control unit 5 detects the output current value flowing through the DC motor 2 and performs constant current control, which is a control for keeping the value constant. The constant current control is realized by the rotation control determination unit 8, the constant current control unit 12 (current detection unit 13 and current increase / decrease determination unit 14), and the rotation speed adjustment unit 15 operating in cooperation with each other.

The details of the constant current control will be described.

When the rotation control unit 5 selects high rotation operation, that is, the rotation control determination unit 8 determines that the operation mode signal received from the remote controller 6 via the reception unit 7 is an instruction to rotate the motor at high rotation. In this case, the constant current control unit 12 performs constant current control. Here, the current increase / decrease determination unit 14 is set with a target current value according to the operation mode. For example, the current increase / decrease determination unit 14 stores a target current value according to the operation mode, and the corresponding target current value is set based on the operation mode received via the reception unit 7. The target current value is set so as not to exceed the above-mentioned specified value of power consumption.

The current detection unit 13 detects the current current value of the DC motor 2. Here, an example of a method for realizing the current detection unit 13 will be described below.

As a method of detecting the output current of the DC motor 2, for example, there is a method using a shunt resistor 25 as shown in FIG. Note that FIG. 4 is a schematic circuit diagram of the ceiling fan 100a according to the second embodiment, but the method for detecting the output current of the DC motor 2 is the same for the ceiling fan 100 according to the first embodiment. This will be described with reference to FIG.

When a current flows through the shunt resistor 25 having a low resistance value shown in FIG. 4, a voltage difference proportional to the current is generated across the shunt resistor 25. This voltage value is read and amplified by the operational amplifier 23. The current value of the DC motor 2 is detected by reading the amplified value with the microcomputer 24.

The current increase / decrease determination unit 14 compares the current current value of the DC motor 2 detected by the current detection unit 13 with the target current value set in the current increase / decrease determination unit 14, and gives an acceleration / deceleration instruction according to the difference. Output to the rotation speed adjusting unit 15. That is, if the current current value is smaller than the set target current value, the current increase / decrease determination unit 14 instructs the rotation speed adjusting unit 15 to increase the motor output. On the contrary, if the current current value is larger than the set target current value, the current increase / decrease determination unit 14 instructs the rotation speed adjusting unit 15 to reduce the motor output. Then, the current detection unit 13 again detects the current value of the DC motor 2 whose rotation speed has been adjusted by the rotation speed adjustment unit 15, and the rotation speed adjustment unit 15 causes the DC motor 2 based on the instruction from the current increase / decrease determination unit 14. Control is performed to keep the current value constant by repeating the adjustment of the rotation speed of. The above control is constant current control. Therefore, even if the load applied to the motor and the power consumption differ depending on the installation environment of the ceiling fan 100, the output current of the DC motor 2 is kept constant by the constant current control of the rotation control unit 5, and the DC motor 2 Power consumption can be kept constant.

As described above, in the above constant current control, the load and power consumption of the DC motor 2 are different even if the installation environment of the ceiling fan 100, that is, the distance between the ceiling fan 100 and the ceiling is different, when the power supply voltage is the same. Can be constant.

(Embodiment 2)
In the first embodiment, the ceiling fan 100 can keep the power consumption of the DC motor 2 constant regardless of the installation environment by controlling the current applied to the DC motor 2 on the premise that the power supply voltage is constant. Explained.

However, if the power supply voltage is not constant, that is, if the ceiling fan is used in areas where the power supply voltage is different, the voltage applied to the DC motor 2 will be different. When different power supply voltages are applied to the ceiling fan, it is difficult to keep the load and power consumption of the DC motor 2 constant only by current control. For example, Malaysia has a power supply voltage of 240V and Vietnam has a power supply voltage of 220V. Therefore, with only the constant current control described in the first embodiment, the power consumption of the DC motor 2 is larger when used at the power supply voltage of 240 V in Malaysia than when used at the power supply voltage of 220 V in Vietnam. It ends up. That is, there is a problem that the power consumption of the DC motor 2 cannot be made constant by controlling only the current applied to the DC motor 2 when the voltage is used in different regions.

Therefore, in the second embodiment, by controlling the power supplied to the DC motor 2, the power consumption of the DC motor 2 can be kept constant even when the power supply voltage applied to the power input unit 4 is different. The ceiling fan 100a that can be made will be described. In the following, this control will be referred to as constant power control.

In the constant power control, in addition to the constant current control described in the first embodiment, the power supply voltage is detected and the balance between the power supply voltage and the output current of the DC motor 2 is kept constant, so that the ceiling fan 100a is independent of the power supply voltage. It is a control that keeps the power consumption constant.

First, the configuration of the ceiling fan 100a according to the second embodiment will be described with reference to FIG. 3 focusing on the differences from the ceiling fan 100 according to the first embodiment.

The ceiling fan 100a according to the second embodiment includes a rotation control unit 5a instead of the rotation control unit 5 of the ceiling fan 100 according to the first embodiment.

The rotation control unit 5a has a power constant power control unit 12a instead of the current constant control unit 12 according to the first embodiment. The constant power control unit 12a performs constant power control when the rotation control determination unit 8 determines that the operation mode signal is an instruction to rotate the DC motor 2 at high rotation speed. The constant power control unit 12a includes a current increase / decrease determination unit 14a, a voltage detection unit 16, and a current correction unit 17 in addition to the current detection unit 13 according to the first embodiment.

The voltage detection unit 16 detects the power supply voltage input to the power supply input unit 4 and outputs the converted value of the power supply voltage to the current correction unit 17. Further, the current correction unit 17 receives the conversion value of the power supply voltage output from the voltage detection unit 16 and sends an instruction to the current increase / decrease determination unit 14a to change the target current value according to the conversion value of the received power supply voltage. ..

The current increase / decrease determination unit 14a is different from the current increase / decrease determination unit 14 according to the first embodiment in that the target current value is changed based on the instruction received from the current correction unit 17. The current increase / decrease determination unit 14a compares the target current value (the changed target current value when instructed by the current correction unit 17) with the output current value received from the current detection unit 13, and compares the target current value. The point that an acceleration / deceleration instruction is output to the rotation speed adjusting unit 15 according to the difference between the value and the output current value is the same as that of the current increase / decrease determining unit 14 according to the first embodiment. The rotation speed adjusting unit 15 changes the rotation speed of the DC motor 2 based on the instructions from the rotation speed setting unit 11 and the current increase / decrease determination unit 14a. For example, when the output current value is larger than the target current value, the current increase / decrease determination unit 14a transmits a deceleration instruction to the rotation speed adjusting unit 15. Then, the rotation speed adjusting unit 15 controls the DC motor 2 so as to reduce the rotation speed. When the output current value is smaller than the target current value, the current increase / decrease determination unit 14a transmits an acceleration instruction to the rotation speed adjusting unit 15. Then, the rotation speed adjusting unit 15 controls the DC motor 2 so as to increase the rotation speed.

Next, the circuit configuration of the rotation control unit 5a will be described with reference to FIG.

As shown in FIG. 4, the rotation control unit 5a includes a diode bridge 20, a DC power supply 21, a regulator (REG) 22, an operational amplifier 23, a microcomputer (microcomputer) 24, a shunt resistor 25, and a motor control IC 26. The microcomputer (microcomputer) 24 receives the signal input to each port and outputs an instruction to control the DC motor 2. The motor control integrated circuit (IC) 26 controls the rotation of the DC motor 2. Further, the motor control IC 26 detects the rotation speed of the DC motor 2 and outputs it to the microcomputer 24. The shunt resistor 25 converts the output current of the DC motor 2 into a voltage. The operational amplifier 23 receives the power supply voltage and the motor output current, converts each value to the microcomputer 24, and outputs the value.

The rotation speed detection unit 10, the current detection unit 13, and the voltage detection unit 16 shown in FIG. 3 realize their functions by the motor control IC 26 shown in FIG. Further, the rotation speed setting unit 11, the current increase / decrease determination unit 14a, and the current correction unit 17 shown in FIG. 3 realize their functions by the microcomputer 24 shown in FIG.

Here, an example of a method of detecting the power supply voltage will be described with reference to FIG.

The AC power supply voltage 19 input from the commercial power supply 18 is converted into a DC power supply 21 by the diode bridge 20. The DC power source 21 is used as the power source of the DC motor 2. The voltage of the commercial power supply 18 is detected by reading the DC power supply 21 with the microcomputer 24 through the operational amplifier 23.

As shown in FIG. 3, the current correction unit 17 selects a current correction value so that the power value becomes constant based on the detected power supply voltage value, and the target current set in the current increase / decrease determination unit 14a. Correct the value. The current correction value is, for example, the value of "specified power value / detected power supply voltage value". The current increase / decrease determination unit 14a compares the current current value detected by the current detection unit 13 with the target current value set in the current increase / decrease determination unit 14a (if corrected, the corrected target current value). , An acceleration / deceleration instruction is output to the rotation speed adjusting unit 15 according to the difference. That is, if the current current value is smaller than the set target current value, the current increase / decrease determination unit 14a instructs the rotation speed adjusting unit 15 to increase the motor output. On the contrary, if the current current value is larger than the set target current value, the current increase / decrease determination unit 14a instructs the rotation speed adjusting unit 15 to reduce the motor output. The current detection unit 13 again detects the current value of the DC motor 2 whose rotation speed has been adjusted by the rotation speed adjustment unit 15, and the rotation speed adjustment unit 15 rotates the DC motor 2 based on an instruction from the current increase / decrease determination unit 14a. Control is performed to keep the current value constant by repeating the adjustment of the number. The above control is constant power control.

By this constant power control, the power consumption of the motor can be kept constant even in countries where the voltage of the commercial power source 18 is different.

The ceiling fan according to the present invention is useful as a technique used for controlling a ceiling fan whose blades are easily affected by disturbance.

1 Shaft 2 DC motor 3 blades 4 Power input unit 5, 5a Rotation control unit 6 Remote control 7 Receiver 8 Rotation control judgment unit 9 Rotation speed constant control unit 10 Rotation speed detection unit 11 Rotation speed setting unit 12, 12a Current constant control Part 13 Current detection part 14, 14a Current increase / decrease judgment part 15 Rotation speed adjustment part 16 Voltage detection part 17 Current correction part 18 Commercial power supply 19 AC power supply voltage 20 Diode bridge 21 DC power supply 22 Regulator 23 Optotype 24 Microcomputer 25 Shunt resistance 26 Motor control IC
100, 100a, 1000 Ceiling fan 1002 DC motor 1005 Rotation control unit 1006 Remote control 1007 Receiver 1009 Constant rotation control unit 1010 Rotation detection unit 1011 Rotation setting unit 1015 Rotation adjustment unit

Claims (4)

The shaft fixed to the ceiling and
A DC motor fixed to the shaft and
The blades rotated by the DC motor and
A power input unit that supplies electric power from a commercial power source to the DC motor is provided.
A current detection unit that detects the current value in the DC motor, and
A rotation speed adjusting unit for controlling the rotation speed of the DC motor is provided.
When the rotation speed is less than a predetermined rotation speed, the rotation speed adjustment unit controls the rotation of the DC motor.
A ceiling fan characterized in that the rotation of a DC motor is controlled by a current value when the rotation speed is equal to or higher than a predetermined rotation speed. The ceiling fan further includes a voltage detection unit that detects a voltage value supplied to the power input unit, and a voltage detection unit.
A current correction unit that corrects the current value so that the power value supplied to the DC motor becomes a predetermined power value based on the voltage value detected by the voltage detection unit is provided.
The ceiling fan according to claim 1, wherein the rotation speed of the DC motor is controlled by a current value corrected by the current correction unit. The shaft fixed to the ceiling and
A DC motor fixed to the shaft and
The blades rotated by the DC motor and
A power input unit that supplies electric power from a commercial power source to the DC motor is provided.
A current detection unit that detects the current value in the DC motor, and
A rotation speed adjusting unit that controls the rotation speed of the DC motor,
When changing the rotation speed of the DC motor, whether or not the changed rotation speed becomes a predetermined number or more, which is a specified value which is an upper limit of the power value supplied from the power input unit to the DC motor. A rotation control judgment unit that determines whether or not
When the rotation control determination unit makes a positive determination, the rotation speed adjustment unit is based on the current value detected by the current detection unit and the target current value corresponding to the changed rotation speed. The ceiling fan is provided with a current increase / decrease determination unit for controlling the rotation speed of the DC motor. The ceiling fan further includes a voltage detection unit that detects a voltage value supplied to the power input unit, and a voltage detection unit.
Based on the voltage value detected by the voltage detection unit, the current correction for correcting the target current value in the current increase / decrease determination unit so that the power value supplied to the DC motor does not exceed the specified value. With a department,
The current increase / decrease determination unit instructs the rotation speed adjusting unit to increase / decrease the rotation speed of the DC motor based on the difference between the current value detected by the current detection unit and the corrected target current value. The ceiling fan according to claim 3.

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