KR960010259B1 - Fan - Google Patents

Abstract

No content

Description

fan

1 is a longitudinal sectional view of an electric fan head which is an embodiment of the present invention.

2 is a longitudinal sectional view of the fan head from the other direction.

3 is a cross-sectional view of the fan head.

4 is an exploded perspective view of the main part.

5 is a view showing a state in which the fan head facing the front.

6 is a view showing a state in which the electric fan head is soaked in the left direction.

7 is a view showing a state in which the fan head is soaked in the right direction.

8 is a view showing a state in which the center of vibration of the fan head is moved leftward.

9 is a view showing a state in which the center of vibration of the fan head is moved to the right direction.

10 is a sectional view of the main part.

11 is a sectional view of a receiver of the receiver.

12 is a view showing a switch panel of the base.

13 is a front view of the transmitter.

14 is a top view illustrating the operation of the fan.

Fig. 15 is an external perspective view of the fan.

16 is the same circuit diagram.

17 is an input waveform diagram of the control circuit.

18 is a flowchart of the main routine.

19 is a flowchart of the main routine.

20 is a flowchart of the same wind direction setting routine.

21 is a flow chart of the motor driving routine for the same center movement.

Fig. 22 is a flowchart of the motor drive routine for the right and left hand vibrations.

* Explanation of symbols for main parts of the drawings

3: foundation base, 12: receiving unit,

16: receiver, 24: left and right hand motor (drive source),

32: Sujin center adjustment body, 38: Head position detection sensor,

41: electric fan tofu, 42: electric motor,

43: axis, 45: blowing fan,

50: motor for vibration center movement, 54: sensor for vibration center position,

63 transmitter 89 control circuit.

The present invention relates to an improvement of a fan.

A conventional fan is provided with a remote controller for remote operation, and the position of the transmitter is determined so that the fan center of the fan head is moved by an electric motor, and the fan is directed to the direction of the transmitter. It is known from Japanese Unexamined Patent Application, First Publication No. Hei 110895 (F04D 25/08), and Japanese Unexamined Patent Application Publication No. Hei 1-110894 (F04D 25/08). The fan described in these publications is configured to perform water vibration using an electric motor that moves the vibration center of the fan head in the direction of the transmitter.

In order to move the electric fan head in the direction of the transmitter quickly, a reversible electric motor capable of reversing is used. However, a reversible electric motor is used to rotate the electric motor during a blackout / reverse switching. Because of this rapid stop and reversal, there was a drawback that the fan head did not operate smoothly during water reversal.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described drawbacks, and an object of the present invention is to provide a fan capable of smoothly performing a water repellent operation in which the direction of the fan head can be controlled by the transmitter.

The present invention provides a fan head 41 having an electric motor 42 for rotating and driving the blower fan 45, a base 3 for supporting the fan head 41, and one end of the fan head 41. A cam plate 25 mounted to the supported drive link 29 and the left and right oscillation motor 24 as a drive source to rotatably support the other end of the drive link 29, wherein the fan head 41 A left and right oscillation mechanism which swings in the left and right direction with respect to the foundation stage 3 and the oscillation center movement motor which moves the oscillation center of the fan head 41 in the lateral direction with respect to the foundation stage 3. 50) from the transmitter 63 for remotely controlling the vibration center position detection sensor 54 for detecting the direction to the base 3 of the vibration center and the fan 42 for driving the fan rotation. A receiving device 16 for receiving a signal, an output of the receiving device 16, and the vibration center position detection; And a control circuit 89 for controlling the direction of the oscillation center movement base 50 based on the output of the sensor 54 to control the direction of the oscillation center base 3.

In addition, the present invention is a fan head 41 having an electric motor 42 for driving the blowing fan 45, the neck member 20 for supporting the fan head 41, and the neck member 20 in an angle of relief Base plate 3 rotatably supported by the motor, and the cam plate 25 mounted on the rotary shaft 26 of the left and right hand motors 24 and the left and right hand motors 24 mounted on the neck member 20. ), A drive link 29 whose one end is rotatably supported by the cam plate, and the other end is supported by the fan head 41, and the receiving center of the fan head 41 with respect to the base 3; A vibration center movement motor 50 moving in the left and right directions, a vibration center position detection sensor 54 for detecting a direction of the fan head 41 with respect to the vibration center, the motor 42 for blowing fan rotation driving, and the like. Receiver 16 for receiving a signal from transmitter 63 for remote control of the controller, and the output and head position of the receiver 16; On the basis of the output of the outlet sensor 38 and the output of the vibration center position detection sensor 54, the left and right vibration motors 24 and the vibration center movement motor 50 are controlled to form the base of the fan head 41. It characterized in that it comprises a control circuit 89 for controlling the direction with respect to).

In addition, the control circuit of the present invention may control the electric fan for the left and right water discharge at the time of stopping the fan for rotating the fan fan, so that the fan head is directed toward the front of the vibration center.

In addition, the control circuit of the present invention may control the oscillation center moving motor at the time of stopping the blower fan rotation driving motor so that the oscillation center of the fan head is directed toward the front of the base.

In addition, the vibration center position detection sensor is constituted by a variable resistor, and the vibration center position detection sensor is set by the first gear mounted on the vibration center movement motor and the second gear mounted on the vibration center position detection sensor. While interlocking with the mobile electric motor, one of the first gear and the second gear may be formed in an arc shape.

In addition, the vibration center position detection sensor is constituted by a variable resistor, and the vibration center position detection sensor is set by the first gear mounted on the vibration center movement motor and the second gear mounted on the vibration center position detection sensor. At the same time as interlocking with the mobile electric motor, the first gear and the second gear may be provided with a fitting mark point at a position where the fan head is moved in a predetermined position with respect to the base.

According to the configuration of claim 1 of the present invention, when the control signal is transmitted by operating the transmitter, the control circuit is based on the output of the receiver receiving the control signal and the output of the vibration center position detection sensor. By controlling, the center of vibration of the fan head is quickly moved.

According to the configuration of claim 2, when the control signal is transmitted by operating the transmitter, the control circuit is based on the output of the receiver receiving the control signal, the output of the center position detection sensor, and the output of the head position detection sensor. By controlling the motor for vibration center movement, the vibration center of the fan head is moved quickly. When the fan head is moved beyond the range of the oscillation center movement motor, the control circuit controls the left and right oscillation motors together with the oscillation center movement motor to move the fan head in the desired direction.

In addition, according to the configuration of claim 3, since the fan head faces the front of the vibration center when the operation is stopped, the direction of the vibration center can be easily confirmed by the direction of the fan head at the time of re-operation.

Further, according to the configuration of claim 4, since the vibration center of the fan head faces the front of the foundation at the time of stopping operation, the direction of the vibration center can be easily confirmed by the direction of the foundation at the time of reoperation.

Further, according to the configuration of claim 5, the vibration center position detection sensor is interlocked through the gear by the rotation of the vibration center movement motor, and the direction of the vibration center is based on the change of the output value of the vibration center position detection sensor. Detect quickly. If, for some reason, the oscillation center movement motor rotates beyond the rotation range, the gears of the oscillation center movement motor and the oscillation center position detection sensor are separated so that the variable resistor constituting the oscillation center position detection sensor does not rotate. The damage of the variable resistor is prevented.

In addition, according to the configuration of claim 6, the oscillation center position detection sensor is interlocked through the gear by the rotation of the oscillation center movement motor, and the direction of the oscillation center base stage is quickly changed in accordance with the change of the output value of the oscillation center position detection sensor. To be detected. In addition, since the alignment mark of the first gear mounted on the vibration center movement motor and the alignment mark of the second gear mounted on the vibration center position detection sensor coincide with the vibration center oriented to a predetermined position with respect to the foundation. The misalignment of the gears is easily confirmed.

Next, an embodiment of the present invention will be described in detail with reference to the drawings.

(1) is a stand made of synthetic resin, and supports the support post 2 freely, and the base 1 is formed by the stand 1 and the support post 2.

(4) is a switch panel formed in the stand (1), the power supply switch 5 for energizing / disconnecting the power supply to the electric motor 42 to be described later, the blowing fan to control the rotation speed of the electric motor 42 to be described later By moving the center of gravity adjustment body 32 with respect to the air volume control switch 6 for controlling the airflow amount by the 45, the timer switch 7 for controlling the operation time of the electric motor 42, and the neck member 20 which will be described later. The electric fan head 41 is provided with the electric vibration control switch 8 which performs electric current control as the electric motor 24 for oscillating the electric fan head 41, and performs the electric vibration control. Rotation axis 43 is rotated to drive control the motor 50 for moving the center of gravity which moves the center of vibration of the fan head 41, and the fan head 41 is moved to the left with respect to the base 3. To obtain a wind direction left side movement switch 9 and a water-based centrifugal movement motor 50 to be described later. It has a wind direction, and has the wind direction right side movement switch 10 which moves the fan head 41 to the right side with respect to the base 3.

Reference numeral 11 denotes a recess for supporting the transmitter 63, which will be described later, in an approximately upright state.

12 is a receiving unit which is installed on the stand 1 and disposed forward from the center of the oscillation center axis O of the fan head 41 to be described later, that is, the center of the axis 43, and receives the first, second, and third light receivers. The receiver 16 includes elements 13, 14, and 15, and a lens 17 covering the receiver. The receiver 16 includes a holding member 18 for holding the light receiving elements 13, 14, 15, and the first, second, and third light receiving elements 13, 14, 15. And a shielding case 19 for shielding and inserting and fixing the first, second, and third light receiving elements 13, 14, and 15 between the holding member 18 and the shielding case 19. It is supposed to be.

The first, second and third light receiving elements 13, 14 and 15 are formed of light receiving elements for receiving an infrared signal transmitted from a transmitter 63 to be described later, and the first light receiving element 13 is It is arrange | positioned on the line (front) which connects the support | pillar 2 and the receiver 12. The second light receiving element 14 is disposed on the right side of the first light receiving element 13 and the third light receiving element 15 is disposed on the left side of the first light receiving element 13 when viewed from the front of the base 3. , The angle α formed by the first light receiving element 13 and the second light receiving element 14 and the angle β formed by the first light receiving element 13 and the third light receiving element 15 will be described later. The oscillation range angle a in the right direction with respect to the front side and the oscillation range angle in the left direction are formed larger than b.

That is, in this embodiment, the angle α formed by the first light receiving element 13 and the second light receiving element 14 and the angle β formed by the first light receiving element 13 and the third light receiving element 15 together are 77 °. The range of movement of the fan head 41 is set to 65 ° in the left direction and 65 ° in the right direction with respect to the line (front) connecting the support post 2 and the receiver 12.

20 is a neck member rotatably supported at an angle of inclination to the secondary upper portion 21 of the upper part of the support 2, and rotatably supports the cylindrical portion 33 of the vibration center adjustment body 32, which will be described later. The bearing portion 22 and the boss 23 are formed integrally with each other.

The 24 is a drive source housed in the neck member 20, and is constituted by a left and right reversal electric motor, a synchronous motor which rotates only in one direction after starting, and is fixed to the boss 23 by screws.

The cam plate 25 is a cam plate which is mounted on the output shaft 26 of the left and right oscillation motor 24 and is mounted. The eccentric portion 27 is integrally formed on the lower surface of the cam plate. ) Are integrally formed.

(29) is a drive link for loosely fitting the link portion 30 formed at one end to the eccentric portion 27 of the cam plate 25, and the lower eccentric shaft 34 of the water-resonant center adjuster 32 described later at the other end. The shaft hole 31 which fits loosely is formed in ().

Reference numeral 32 is a water-resonant center adjuster for supporting the shaft 43 of the electric fan head 41, which will be described later. The cylindrical part 33 is loosely fitted to the bearing part 22 of the neck member 20, and the cylinder thereof. A lower eccentric shaft 34 which is installed to protrude downward in an eccentric position of the section 33 and loosely fits the shaft hole 31 of the drive link 29, and an upper position of the lower eccentric shaft 34; It is installed to protrude upward, has an upper eccentric shaft 35 for loosely fitting the shaft hole 60 of the swing link 58 to be described later, and an insertion through hole 36 for inserting a power cord (not shown). have.

Then, when the motor for driving the left and right water repellent motors 24, the cam plate 25 is rotated, the drive link 29 to the bearing portion 22 of the neck member 20 by the rotation of the cam plate 25. The oscillation center adjusting body 32 is rocked.

In addition, since the vibration center movement motor 50 incorporated in the fan head 41 to be described later is connected to the vibration center adjustment body 32 through the swing link 58, the non-driving of the vibration center movement motor 50 is performed. In the state, the electric fan head 41 is integrated with the vibration center central control body 32, and the electric fan head 41 oscillates to the left and right in accordance with the movement in the left and right direction of the water vibration center adjusting body 32.

In this embodiment, the electric fan head 41 is subjected to vibration of about 33 ° to the left and about 33 ° to the right by the drive of the left and right vibration motors 24.

Reference numeral 37 is a cover for covering the upper opening of the neck member 20, and is equipped with a head position detecting sensor 38 for detecting the direction of the fan head 41 to be described later, and the head position detecting sensor 38 is It is comprised by the optical sensor which consists of the light emitting element 39 and the light receiving element 40. As shown in FIG.

The head position detecting sensor 38 is disposed such that the cam plate 25 and the shielding wall 28 pass between the light emitting element 39 and the light receiving element 40 by the rotation of the cam plate 25. The rotational position of the cam plate 25, that is, the direction toward the base 3 of the fan head 41, is detected by the change in the amount of light received by the light receiving element 40 by the shielding wall 28.

That is, the electric fan head 41 is formed on the base by the change in the light receiving amount of the light receiving element 40 when the end portion of the shielding wall 28 passes between the light emitting element 39 and the light receiving element 40. With respect to 3), it is determined which position is at the water limit in the right direction and the left direction.

In addition, the light receiving element 40 is disposed at an inner position of the shielding wall 28 so as to reduce the light receiving element 40 to receive external light as much as possible.

Next, the fan head 41 will be described.

Reference numeral 42 is an electric motor having a spindle 43 inserted into the water oscillation center adjusting body 32 and loosely fitted, and the blower fan 45 is detachably attached to the output station 44.

46 is a front cover covering the front part of the electric motor 42, and the guard 47 surrounding the blower fan 45 is detachably mounted.

48 is an attachment plate attached to the rear part of the said electric motor 42, and forms the bending part 29 in the rear end.

Reference numeral 50 denotes a vibration center moving motor mounted on the upper surface of the attachment plate 48, and is constituted by a reversible synchronous motor for switching forward and reverse by energization switching.

Reference numeral 51 is a cam attached to the output shaft of the vibration center movement motor 50. The gear 52 is formed on the upper portion and the eccentric shaft 53 is integrally formed on the lower surface.

54 is a vibration center position detection sensor mounted on the attachment plate 48, and is composed of a variable resistor for varying the output voltage by rotating the shaft, and the gear of the cam 51 on the shaft. 52 is fitted with a gear 55 engaged with it.

The gear 55 is formed in a semicircular shape, and is configured to prevent the vibration center position detecting sensor 54 from being excessively rotated and damaged when the vibration center movement motor 50 is rotated beyond the rotation range. .

The gear 55 is fitted with the alignment mark 56 formed on the gear 52 of the cam 51 in a state in which the fan head 41 faces the front of the base 3. The display point 57 is formed so as to prevent non-uniformity of the output of the vibration center position detection sensor 54 between products.

Reference numeral 58 is an oscillation link in which the insertion through hole 59 formed at one end is loosely inserted into the eccentric shaft 53 of the cam 51, and the insertion through hole 60 formed at the other end is the center of the oscillation. The upper body 32 is loosely fitted to the upper eccentric shaft 35 of the body 32.

Then, when driving the vibration center movement motor 50, the cam 51 is rotated, the oscillation link 58 is the axis of the motor 42 relative to the oscillation center adjuster 32 by the rotation of the cam 51. By rotating 43, the center of vibration of the fan head 41 is moved.

In addition, since the oscillation center adjusting body 32 is connected to the left and right oscillation motors 24 through the drive link 29, the oscillation center adjusting body 32 is in the stopped state of the oscillation motors 24. Integral with the wood member 20, i.e., the base 3, the oscillation center adjuster 32 does not move, and the axis 43 of the electric fan head 41 moves left and right with respect to the oscillation center adjuster 32. Rotation to move the center of the vibration of the fan head 41.

In this embodiment, the driving center of the electric fan head 41 can be moved about 33 ° in the left direction and 33 ° in the right direction with respect to the front of the base 3 by the driving of the vibration center moving motor 50. have.

Reference numeral 61 denotes a condenser for driving the motor 42, and 62 a rear cover covering the motor 42, the vibration center movement motor 50, the vibration center position detection sensor 54, and the like. The front cover 46 is engaged with the rear end portion, and the rear end portion is screwed to the bent portion 49 of the attachment plate 48.

Next, the transmitter will be described based on FIG.

63 shows transmission means (not shown) for outputting an infrared signal in accordance with the conditions of the switches 64, 75, 66, 67 and 68 described later using a battery (not shown) and the battery as a power source. Branch is a transmitter.

64 is a wind direction adjustment switch formed on the transmitter 63. When the fan base receives an infrared signal suitable for the operation of the wind direction adjustment switch 64, the electric fan head 41 is transmitted in the driving state of the electric motor 42. The electric fan head 41 is directed toward the transmitter 63 while the electric motor 24 is driven in the stopped state of the electric motor 42.

Numeral 65 denotes an air flow rate control switch, which outputs an infrared signal for controlling the airflow amount by controlling the rotation speed of the electric motor 42.

Numeral 66 denotes a vibration control switch, which performs energization control of the left and right vibration motors 24, and outputs an infrared signal for moving the fan head 41 left and right.

Reference numeral 67 denotes a timer switch that outputs an infrared signal for controlling the operation time of the electric motor 42.

Reference numeral 68 designates a power-off switch to output an infrared signal for stopping the electric motor 42.

Next, the circuit will be described in detail with reference to FIG.

Reference numeral 69 is a first receiver having a first light receiving element 13 for receiving an infrared signal from the transmitter 63, an amplifier 70 for amplifying an output of the first light receiving element 13, Amplifying the output of the band pass filter section 71 for removing the trapping signal from the output of the amplifying section 70, the detector 72 detecting the output of the band pass filter section 71, and the output of the detector 72 And an amplifier 73 output to the control circuit 89 described later, and an automatic gain control (AGC) adjustment unit 76 described later.

The output of the detector 72 is output to the waveform adjusting unit 74 together with the output of the detector 80 of the second receiver 77 and the detector 86 of the third receiver 83 described later. The waveform is shaped by the waveform adjusting unit 74 and output to the control circuit 89 described later.

The detector 72 outputs the AGC amplifier 75 together with the output of the detector 80 of the second receiver 77 and the detector 86 of the third receiver 83 described later. AGC amplifier 75 outputs from the first receiver 69 to the control circuit 89, from the second receiver 77 to the control circuit 89 and from the third receiver 83 Among the outputs to the circuit 89, the AGC adjusting units 76, 82 and 88 of the receivers 69, 77 and 83 are controlled so that the maximum output becomes a predetermined value, and a control circuit (to be described later) 89).

77 is a second receiver having a second light receiving element 14 for receiving an infrared signal from the transmitter 63, which is an amplifier 78 for amplifying the output of the second light receiving element 14, A band pass filter 79 for removing a noise signal from the output of the amplifier 78, a detector 80 for detecting the output of the band pass filter 79, and an output of the detector 80 AGC which amplifies and outputs the control circuit 89 to be described later from the amplifier 81 based on the output of the amplification section 81 and the AGC amplifier 75 to amplify and output the control circuit 89 to be described later. It has an adjusting part 82.

83 is a third receiver having a third light receiving element 15 for receiving an infrared signal from the transmitter 63, an amplifying unit 84 for amplifying the output of the third light receiving element 15, Amplifying the band pass filter 85 for removing the noise signal from the amplifier 84, a detector 86 for detecting the output of the band pass filter 85, and an output of the detector 86 And an adjusting section for adjusting the output from the amplifying section 87 to the control circuit 89 to be described later based on the output of the amplifying section 87 and the AGC amplifying section 75 outputted to the control circuit 89 to be described later. 88)

Reference numeral 89 denotes a control circuit of a microcomputer, which is connected to the switch panel 4 of the first, second, and third receivers 69, 77, 83, the waveform adjustment unit 74, and the base 3. Input from a switch circuit 90 having the respective switches 5, 6, 7, 8, 9 and 10 formed, the water center position detection sensor 54 and the head position detection sensor 38, It is outputted to the electric motor drive part 91 mentioned later, the electric motor drive part 92 for right and left oscillation, and the water vibration center movement motor 93 suited for each input.

Reference numeral 91 denotes an electric motor drive unit for controlling the drive of the electric motor 42 based on the output of the control circuit 89, and 92 drives the left and right oscillation motor 24 based on the output of the control circuit 89. The left and right oscillation electric motor drive unit 93 controls the oscillation center movement electric motor unit 50 for driving the oscillation center movement motor 50 based on the output of the control circuit 89, and 94 is the control circuit 89. An indicator controller for lighting and controlling the air volume display light emitting diode 95, the timer time display light emitting diode 96, and the wind direction control display light emitting diode 98 arranged on the stand 2 based on the output; It is a voice generator control unit that controls the voice generator (not shown) disposed on the stand 2 based on the output of the circuit 89.

Next, the operation will be described in detail based on the flowchart shown in FIGS. 18 to 22.

First, the main routine will be described with reference to FIGS. 18 to 19. In step S1, it is determined whether or not the receiver 12 has received the infrared signal from the transmitter 63, If the infrared signal is received, it is determined in step S2 whether the signal is a signal when the wind direction control switch 64 is operated, and if it is a signal of the wind direction control switch 64, the flow advances to the wind direction setting routine described later. do.

If the received signal of the receiver 12 is not an operation signal of the wind direction control switch 64 in step S2, it is discriminated whether or not the electric motor 42 is being driven in step S3.

In addition to the wind direction control switch 64, the transmitter 63 is provided with a wind direction control switch 65, a water vibration control switch 66, a timer switch 67, and a power off switch 68, but the electric motor 42 is not driven. Since it is a misoperation that these switches are operated in the state, if it is a non-driven state of the electric motor 42, it will transfer to step S1.

If the electric motor 42 is driving in step S3, it transfers to step S4 and it determines whether the infrared signal from the transmitter 63 is a signal of the air volume control switch 65.

If the signal from the transmitter 63 is the signal of the air volume control switch 65 in step S4, the flow advances to the air volume setting routine.

If the signal from the transmitter 63 is not the signal of the air volume control switch 65 in step S4, the flow advances to step S5 to determine whether or not the signal of the vibration control switch 66 is obtained, and the vibration control switch ( If it is a signal of 66), the flow advances to step S6 to determine whether or not the left and right vibration motor 24 is being driven.

If the left and right vibration motor 24 is driven in step S6, the left and right vibration motor 24 is stopped in step S7, the left and right vibrations of the fan head 41 are stopped, and the fan head ( 41) can be kept facing the desired direction.

In step S6, if the left and right oscillation motors are stopped, in step S8, the left and right oscillation motors are driven, and the fan head 41 is oscillated in the left and right directions centering on the water oscillation center and blows extensively. can do.

FIG. 5 is a view showing a state in which the fan head 41 faces to the front, and FIG. 6 is a view showing a state in which the fan head 41 is moved to the left direction, and FIG. 7 is a view in which the fan head 41 is facing to the right. It is a figure which shows.

If the signal from the transmitter 63 is not the signal of the vibration control switch 66 in step S5, the flow advances to step S9 to determine whether or not the signal of the timer switch 67 is determined and the timer switch 67 is performed. If the signal is negative), the timer moves to the timer setting routine.

If the signal from the transmitter 63 is not the signal of the timer switch 67 in step S9, the flow advances to step S10 to determine whether or not the signal of the power off switch 68 is detected, and the power off switch 68 ), The process proceeds to step S11, stops the motor 42 and stops the operation, and in step S12 drives the left and right oscillation motor 24 and the oscillation center moving motor 50 to make a fan. The head 41 faces the front of the base 3.

Therefore, the center of vibration of the fan head 41 faces the front of the base 3, and the user can reliably determine the position of the center of vibration when restarting, thereby improving usability.

Moreover, since the electric fan head 41 is located in front of the base 3, repackaging can be performed easily.

Next, the wind direction setting routine will be described based on FIG. 20. In step S13, the outputs of the first, second, and third receivers 69, 77, 83 are detected.

In the case where the output of each of the receivers 69, 77 and 83 cannot be output, for example, the output of the second receiver 77 and the output of the third receiver 83 are both the first receiver ( When the output is larger than the output of 69), i.e., when the signal of the transmitter 63 is input to the wall or the like, the input is invalidated so as not to operate.

In this case, the signal output from the first, second, and third receivers 69, 77, 83, and the waveform shaping unit 74 to the control circuit 89 is output based on the infrared signal from the transmitter 63. It demonstrates based on FIG.

FIG. 17A shows an output waveform from the waveform shaping unit 74, (a) is a discrimination signal for discriminating that it is an infrared signal from the transmitter 63, and (b) is a control content signal. When the routine is executed, the control content signal when the wind direction control switch 65 is operated is output. (c) shows the position from 5 msec after the predetermined time from the start of the input when the control content signal when the wind direction control switch 65 is operated to the control circuit 89 as the position signal. The signals from the first, second and third receivers 69, 77 and 83 are inputted only while the signals are input.

17 (b) shows the output waveform of the first receiver 69, (c) shows the output waveform of the second receiver 77, (d) shows the output waveform of the third receiver 83, and the control circuit ( 89 inputs the output of each receiver 69, 77, 83 to determine the relative light receiving intensity of each receiver 69, 77, 83 with respect to the infrared signal of the transmitter 63.

At this time, the waveforms of the receivers 69, 77, 83 shown in Figs. 17 (b), (c), and (d) are the discrimination signals a of the output of the waveform shaping unit 74 shown in Fig. 17 (a). ) Is adjusted so that the maximum value becomes a predetermined value among the outputs of the receivers 69, 77, 83 by the AGC amplifier 75 and the AGC adjusters 76, 82, 88, respectively. Although largely attenuated, the portion corresponding to the control content signal and the position signal of the output of the waveform shaping section 74 is almost constant, and the control circuit 89 reads the portion corresponding to the position signal by reading each portion ( It is possible to accurately detect the relative light receiving intensities of 69 (77) (83).

In particular, since the control circuit 89 starts the input of the position signal after a predetermined time from the start of the input of the position signal of the output of the waveform shaping section 74, the input level is constant, so that each receiver 69 or 77 is provided. It is possible to more reliably detect the relative light receiving intensity of the (83).

Next, in step S14, the output from the AGC amplifier 75 is detected, and in step S15, the outputs of the first, second, and third receivers 69, 77, 83, The intensity of the infrared signal is detected based on the output from the AGC amplifier 75.

The intensity of the infrared signal varies depending on the distance between the receiver 12 and the transmitter 63, the remaining capacity of the battery of the transmitter 63, the ambient brightness, and the like. The deviation of the direction of the transmitter 63 calculated from the ratio of the three receivers 69, 77, 83 and the direction of the actual transmitter 63 may occur, and the first, second, and third receivers Even when the fan head 41 is directed in the direction of the transmitter 63 calculated from the outputs of the 69, 77, and 83, the transmitter is spaced by the distance between the receiver 12 and the center of the oscillation axis O of the fan head 41. There is a fear that a deviation may occur between the direction of 63 and the direction of the fan head 41.

Thus, a look-up table having an appropriate number of correction data suitable for the intensity of the infrared signal and the distance between the receiver 12 and the oscillation center axis O of the fan head 41 in the storage device of the microcomputer constituting the control circuit 89 ( A look-up table is provided and the correction data is derived from the look-up table in accordance with the intensity of the infrared signal detected in step S15 in step S16, and the first, second and third steps are taken in step S17. The direction of the transmitter is calculated by correcting the direction of the transmitter 63 calculated from the ratio of the outputs of the receivers 69, 77, 83.

From the result of the calculation, correction data is calculated using a correction data calculation formula using a neural network method, and a more accurate direction of the transmitter 63 is calculated.

In step S18, it is determined whether the left and right vibration motor 24 is being driven, that is, whether the left and right vibrations are being performed, and if the left and right vibrations are being performed, the flow shifts to the vibration-driven motor-driven routine described later.

If step S18 does not perform left and right oscillation, the flow advances to step S19, and in step S19, the direction of the transmitter 63 calculated in step S17 drives the vibration-recentral moving motor 50. By determining whether or not the fan head 41 is within a range that can be directed to the transmitter 63, in the embodiment, it is determined whether or not it is within about 33 ° in the left and right directions with respect to the front of the base 3, respectively. If it is in the movement range by the center movement electric motor 50, it is discriminated in step S20 whether the fan head 41 is stopped with respect to the water-reduction center adjustment body 32 in the state facing front.

If the electric fan head 41 is stopped in the state facing the front of the vibration center adjusting body 32 in step S20, it transfers to the electric motor drive routine for vibration center movement.

In addition, when the direction of the transmitter 63 is more than the movement range by the vibration center movement motor 50 in step S18, and the fan head 41 is the front of the vibration center center body 32 in step S19. If it is not toward, the driving mechanism routine for oscillating center movement and the driving mechanism for right and left oscillation are executed in step S21.

Referring to Fig. 21, the electric motor driving routine for the vibration center movement is based on the output of the fan center head 41 relative to the base 3 based on the output of the vibration center position detection sensor 54 in step S22. The position is detected, and in step S23, it is determined whether or not the direction of the transmitter 63 calculated in step S17 coincides with the present direction of the water-receiving center position.

If the direction of the transmitter 63 and the water-receiving center position do not coincide in step S23, the fan head 41 moves to the right from the direction of the transmitter 63 calculated in step S17 in step S24. If it is toward the right side, and if it is to the right side, in step S25, the oscillation center moving motor 50 is driven to move the oscillation center of the fan head 41 to the left.

Steps S22 to S25 are repeated, and the direction of the transmitter 63 calculated in step S17 coincides with the position of the center of vibration of the fan head 41.

FIG. 5 is a view showing a state in which the head of the fan head 41 faces the front, and FIG. 8 is a view showing a head of the fan head 41 in the left direction, and FIG. 9 is a head of the fan head 41. It is a figure which shows the state which centered to the right.

In step S23, when it is determined whether or not the position of the center of vibration of the fan head 41 and the position of the transmitter 63 coincide, the position of the center of vibration of the transmitter 63 calculated in step S17 is determined. In the present embodiment, when there are transmitters 63 within a predetermined angle within the left and right directions with respect to the position, the transmitters 63 and the water-resonance center positions are determined to coincide.

Since the blowing of the blower fan 45 is diffused, it can blow in a relatively wide range centering on the direction of the fan head 41, and if it is in the range of about 2 °, the transmitter without moving the head to head 41 Blowing in the direction of 63 can be performed.

Therefore, it is possible to improve durability by reducing unnecessary driving of the water-borne center moving motor 50.

In step S24, the fan head 41 determines whether the fan head 41 faces to the right than the direction of the transmitter 63 calculated in step S17, and if not toward the right, that is, to the left, the step ( In S26, the vibration center movement electric motor 50 is driven to move the vibration center of the fan head 41 to the right direction. Steps S22, S23, S24, and S26 are repeated, and the direction of the transmitter 63 calculated in step S17 coincides with the position of the center of vibration of the fan head 41.

The wind direction control display light emitting diode 97 provided on the switch panel 4 of the stand 1 is flickered during the movement of the center of the fan and the direction of the fan head with respect to the center of vibration by the electric motor driving routine for the left and right vibrations described below. It is to indicate that the wind direction is being adjusted.

If the direction of the transmitter 63 and the vibration center position of the fan head 41 in step S23 coincide, the motor for vibration center movement 50 is stopped in step S27, and will be described later in step S28. It is discriminated whether or not the left and right hand drive motor routine is finished, that is, whether or not the drive control of the left and right hand drive motors 24 is finished.

In addition, in the above-described wind direction setting routine, the step S18, S19 or S20 is understood to be the electric drive motor for driving in the center of vibration, that is, only the motor 50 for driving in the center of movement is controlled by the fan head 41. When the signal is directed in the direction of the transmitter 63, the drive end signal of the motor 24 for lateral movement is input.

If the drive control of the left and right vibration motor 24 is completed in step S28, it is determined whether or not the motor 42 is driven in step S29, and if the motor 42 is not driven, the step In S30, the electric motor 42 is driven.

Therefore, the electric fan head 41 can be moved to the direction of the transmitter 63 only by controlling the wind direction control switch 64 of the transmitter 63, and a ventilation can be started, and operability can be improved.

In addition, the electric motor 42 is driven after the fan head 41 faces the direction of the transmitter 63 to start blowing, and the motor 42 is located in an unnecessary place until the fan head 41 faces the direction of the transmitter 63. Problems such as blowing air and blowing up documents are not issued.

Next, the electric motor driving routine for right and left vibration is explained based on FIG. 22. In step S31, the left and right vibration motor 24 is driven, and in step S32, the head position detection sensor 38 Whether the end of the shielding wall 28 of the cam plate 25 on the front end side of the rotational direction is detected, that is, whether the end of the shielding wall 28 has penetrated between the light emitting element 39 and the light receiving element 40. When the head position detection sensor 38 detects the end of the shielding wall 28, the transmitter 63 calculated in step S17 in the wind direction setting routine described above in step S33 is determined. The drive timers for the left and right water discharge motors 24 are set based on the direction.

When the head position detection sensor 38 does not detect an end portion of the shielding wall tip end side in the rotational direction at step S32, the head position detection sensor 38 is the shielding wall 28 at step S34. Is detected at the end of the rotation direction front end side, i.e., whether or not the portion of the shielding wall 28 has emerged from between the light emitting element 39 and the light receiving element 40, and the head position detecting sensor 38 When the end of the shielding wall 28 on the end side of the rotational direction is detected, in step S35, the drive timer of the left and right water discharge motor 24 is set based on the direction of the transmitter 63 calculated in step S17. Set it.

In step S36, it is determined whether or not the drive timer of the left and right vibration motor 24 set in step S33 or step S35 is finished. When the timer ends, the flow advances to step S37, and the left and right vibration motor (24) is stopped, and in step S38, it is determined whether or not the drive control of the oscillation center movement motor 50 is finished, that is, whether or not the oscillation center movement electric motor drive routine has ended.

The electric motor starter for the left and right water repellent electric motors is configured such that the direction of the transmitter 63 calculated in step S17 in step S19 of the above-described wind direction setting routine drives the electric motor 50 for vibration center movement. It is executed when it is determined that the distance of 41 to the transmitter 63 is greater than about 33 ° in the left and right directions with respect to the front of the base 3 in the embodiment. The drive timer of the left and right vibration motor 24 set in S34 drives the vibration center movement motor 50 to move the vibration center to the limit of movement in the direction of the transmitter 63, and the movement limit and the transmitter 63. The time to move the angle of the difference with the direction of) is set.

Therefore, when the transmitter 63 is located at a position exceeding the movement range of the vibration center, both the left and right vibration motor 24 and the vibration center movement motor 50 are driven to drive the fan head 41 of the transmitter 63. Can be directed in a direction.

In addition, the drive routine of the left and right hand movement center moving motor is executed even when the fan head 41 is not directed to the water vibration center position in step S20 of the above-described wind direction setting routine, and the step S32 or step S34 is performed. In the drive timer of the left and right water discharge motor 24 set in (), after the left and right water discharge motor 24 detects an end portion of the shield wall 28 of the cam plate 25, the fan head 41 is moved to the water vibration center position. The time until it turns to is set.

Accordingly, both of the left and right oscillation motor 24 and the oscillation center movement motor 50 are driven to direct the fan head 41 to the oscillation center position by the left and right oscillation motor 24, and the oscillation center is the transmitter ( The fan head 41 may be directed to the transmitter 63 toward 63.

Since the left and right oscillation motor 24 and the oscillation center movement motor 50 are driven at the same time, they can be quickly directed in the direction of the transmitter 63.

In addition, the position where the blower control switch 64 of the transmitter 63 is operated moves the center of vibration of the base to the limit to the limit of movement, and also moves the fan head 41 to the limit of movement of the fan to the center of vibration. If the angle is within a predetermined angle from the above position, in the embodiment, if the fan head 41 is moved to the moving limit in the range of 65 ° to 75 ° in the left and right directions with respect to the front surface of the base 3, air blowing can be performed. Therefore, the fan head 41 is moved to a position where the center of vibration is moved to the limit of movement and the position where the detection sensor 41 is moved to the limit of movement of the center of vibration.

If the range exceeds the above range, the sounding device control circuit 97 activates the sounding control device without moving the electric fan head 41, so as to generate an alarm sound to notify the user of misuse.

As described above, according to the configuration of claim 1 of the present invention, it is possible to smoothly perform the vibration of the fan head by the left and right oscillation mechanisms, and at the same time, the vibration center of the fan head can be quickly moved in the desired direction by the vibration center moving motor. It can improve the operability and operability.

According to the configuration of claim 2 of the present invention, it is possible to smoothly perform the vibration of the electric fan head by the left and right water repellent motors, and also to move the electric vibration center of the electric fan head to the desired direction quickly by the electric vibration center moving motor, thereby providing operability. And operability can be improved. In addition, since the electric fan head can be moved by using the left and right water repellent motors even at positions beyond the movable range of the water repellent center-moving motor, the convenience of use can be improved.

According to the structure of Claim 3 of the present invention, in the driving stop state, the direction of the water-receiving center can be confirmed by the direction of the head of the fan, and the effect of adjusting the blowing direction at the time of re-operation and the like can be performed with good operability.

According to the configuration of claim 4 of the present invention, in the driving stop state, the direction of the water-receiving center can be confirmed by the direction of the base stand, and the effect of adjusting the blowing direction at the time of re-operation, etc., can be performed with good operability.

According to the configuration of claim 5 of the present invention, since the direction to the base of the vibration center is detected by a vibration center position detecting sensor made of a variable resistor which is interlocked with the motor for moving the vibration center, the vibration center position By changing the output value of the detection sensor, the direction of the vibration center can be detected quickly. Also, because the vibration center position detection sensor is interlocked with the oscillation center movement motor through the circular arc gear, if it is linked with the oscillation center movement motor for some reason, the oscillation center movement motor rotates beyond the moving range for some reason. Even if it moves, the engagement between the first gear mounted on the vibration center movement motor and the second gear mounted on the vibration center position detection sensor is eliminated, and the rotation of the vibration center position detection sensor is prevented, so that the variable of the vibration center position detection sensor is constructed. Breakage of the resistance can be prevented.

According to the structure of claim 6 of the present invention, since the direction to the base of the vibration center is detected by a vibration center position detection sensor made of a variable resistor in conjunction with a motor for moving the vibration center, the vibration center position is detected. By changing the output value of the sensor, the direction of the vibration center can be detected quickly. In addition, since the alignment marks are formed to coincide with the first gear mounted on the vibration center movement motor and the second gear mounted on the vibration center position detection sensor with the vibration center directed to the predetermined position, the first position at the time of assembly is established. The meshing position between the gear and the second gear is not wrong, and the misdetection in the direction of the center of vibration to the foundation can be prevented, so that it is possible to reliably face the center of vibration in the direction of the user's desire. Serve

Claims (6)

A fan head 41 having an electric motor 42 for rotating and driving the blower fan 45, a base 3 for supporting the fan head 41, and one end of the fan head 41 are supported. A cam plate 25 mounted to the drive link 29 and the left and right oscillation motor 24 as a drive source to rotatably support the other end of the drive link 29, wherein the fan head 41 has a water-repellent center. A left-right oscillation mechanism oscillating in the left-right direction with respect to the base stage 3 as a center, and an electric motor 50 for moving the oscillation center which moves the oscillation center of the fan head 41 in the left-right direction with respect to the base stage 3; And a signal from a transmitter 63 for remotely controlling the vibration center position detection sensor 54 for detecting a direction to the base 3 of the vibration center and the blower fan rotation driving motor 42, and the like. Receiving device 16, the output of the receiving device 16 and the vibration center position detection sensor 54 And a control circuit (89) for controlling the direction of the oscillation center base (3) by controlling the oscillation center moving motor (50) based on the output. A fan head 41 having an electric motor 42 for rotating and driving the blower fan 45, a neck member 20 for supporting the fan head 41, and a rotation angle of the neck member 20 at an angle of relief. The base plate 3 to support, the cam plate 25 attached to the output shaft 26 of the left and right oscillation motor 24 mounted to the said neck member 20, and the right and left oscillation motor 24, and the cam plate One end is rotatably supported by (25), and the other end is supported by the fan head (41), and the receiving center of the fan head (41) is in the horizontal direction with respect to the base table (3). Remote control of the motor 50 for moving forward, the position for detecting the center of vibration of the fan head 41, the sensor 54 for detecting the direction with respect to the center of vibration of the fan head 41, and the motor 42 for driving the blowing fan. Receiving device 16 for receiving a signal from the transmitter 63 to control, the output of the receiving device 16, the head position detection sensor 38 Based on the output and the output of the vibration center position detecting sensor 54, the direction of the fan head 41 to the base 3 is controlled by controlling the left and right vibration motor 24 and the vibration center motor 50. And a control circuit (89). 3. The control circuit (89) according to claim 2, wherein the control circuit (89) controls the electric fan head (41) toward the front of the water vibration center by controlling the left and right water discharge motors (24) when the blowing fan rotation driving motor (42) is stopped. Fan, characterized in that. 2. The control circuit (89) according to claim 1, wherein the control circuit (89) controls the water-revolving center movement motor (50) when the blowing fan rotation driving motor (42) stops, thereby restoring the water-receiving center of the fan head (41). Fan facing the front). 3. The second gear position sensor according to claim 2, wherein the oscillation center position detection sensor (54) is constituted by a variable resistor, and is mounted on the first gear (52) mounted on the oscillation center movement motor and the oscillation center position detection sensor (54). The oscillation center position detection sensor 54 is interlocked with the oscillation center movement motor 50 by engaging the gear 55, and at the same time, one of the first gear 52 and the second gear 55 is arcuated. An electric fan characterized in that formed. The vibration center position detection sensor 54 is configured by a variable resistor, and is mounted on the first gear 52 and the vibration center position detection sensor 54 mounted on the vibration center movement motor 50. The oscillation center position detection sensor 54 is interlocked with the oscillation center movement motor 50 by engaging the second gear 55, and at the same time, the first gear 52 and the second gear 55 are connected to the oscillation center. A fan, characterized in that fitting points (56) and (57) are provided at positions coinciding with the center moved to a predetermined position with respect to the base table (3).