JPH0470539B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a wind direction control device for an air conditioner, and particularly to control of operation and stop of movable vanes.

[Conventional technology]

FIG. 6 is a structural diagram of an opening/closing vane showing a conventional air conditioner wind direction control device shown in Japanese Patent Application No. 56-173458. In the figure, 61 is a tooth profile A61a.
The opening/closing vane 62 is fixed to the pinion. 63 is a rack having a tooth shape B63a and a handle 63b on a part thereof;
It is housed in the safety chamber 64. The rack 63 and pinion 61 have a tooth profile A61a and a tooth profile 63a, respectively.
are attached so that they interlock with each other, and are fixed with a presser fitting 65 so that they can be freely driven. Figure 7 shows
It is a cross-sectional view of a ceiling-mounted air conditioner in which this opening/closing vane mechanism is adopted, in which 11 is a blower, 12 is a heat exchanger, 13 is a drain pan, 14 is a first air outlet, 15
is a second part outlet, and 16 is a suction grill. 62
6 is a vane that opens and closes the second outlet, and 66 is a swing louver. These are housed in an air conditioner main body 19, and the main body 19 is installed tightly on a ceiling surface 20 and a wall surface 21.

Next, the operation will be explained. The opening/closing vane 62 is opened/closed by manually sliding the handle 63b of the rack 63 in the horizontal direction to rotate the pinion 61. As for the operation of the air conditioner that employs this opening/closing vane 62, the air sucked in from the intake grille 16 is sent to the heat exchanger 12 by the blower 11, where it is cooled or heated by heat exchange and then opened/closed. According to the angle determined by the stop position of the vane 62, the first
The air is blown out from the air outlet 14 and the second air outlet 15.

[Problem that the invention seeks to solve]

In conventional air conditioner wind direction control devices, the mechanism for adjusting the wind direction is manually switched.
When the main unit is located near the ceiling, it is necessary to operate it while standing on a stepladder, which poses a problem of poor operability.

This invention was made to solve the above-mentioned problems, and aims to provide a wind direction control device for an air conditioner that can remotely and freely adjust the movable vanes that control the wind direction of the air conditioner. purpose.

[Means for solving problems]

The wind direction control device for an air conditioner according to the present invention includes:
A movable vane of an air conditioner that is driven by an electric motor to control the wind direction, a movable vane position setting means that can set the position of the movable vane by remote control, and a setting position code set by the movable vane position setting means. a positioning control means for positioning the movable vane according to a signal and a rotation signal of the electric motor; and a vane drive electric motor control means for operating the electric motor and driving the movable vane under the control of the positioning control means. Equipped with
The positioning control means includes a current position confirmation means for confirming the current position code of the movable vane, and a current position code signal of the movable vane confirmed by the current position confirmation means and set by the movable vane position setting means. and a timer that presets a time between each of the plurality of position codes of the movable vane.
The timer controls the vane drive motor control means based on the result of the determination means to advance the position code of the movable vane at preset intervals, and the advanced position code of the movable vane and the and control means for controlling the movable vane until the set position code of the movable vane set by the movable vane position setting means matches.

[Effect]

In the wind direction control device for an air conditioner according to the present invention, the stop position of the movable vane is set by remote control, and the position code of the movable vane is sent every preset time to a timer of the positioning control means that can position the movable vane. By advancing the movable vane and operating the movable vane until the advanced position code matches the set setting position code, the position of the movable vane is brought to the set position.

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a control block diagram showing the present invention. In the figure, 1 is a vane drive electric motor, and a drive shaft 1a of the electric motor 1 has a cam 2 and a disk 3.
is installed. Further, a drive shaft 3a is attached to the disc 3, and the drive shaft A3a is connected to the drive shaft B5b of the movable vane 5 via a connecting plate 4. The connecting plate 4 is provided with a hole 4a. , the movable vane 5 moves up and down with the shaft 5a fixed relative to the rotational movement of the disc 3. Further, as means for controlling the movable vane operating mechanism, a position detection switch 6 is provided which is turned on/off by the rotational movement of the cam 2, and means for detecting the reference position of the movable vane 5 based on the on/off signal. 7. On the other hand, there are means 8 for setting the position of the movable vane 5 at a remote location, both of these means 7, 8
A movable vane positioning control means 9 for positioning the movable vane 5 based on an input signal, and a vane drive motor control means 10 for actually operating and stopping the movable vane drive motor 1 are provided. FIG. 2 is a sectional view of an air conditioner equipped with this wind direction control device, and the same parts as in FIG. 7 are given the same reference numerals.

In this figure, the movable vane 5 can rotate about a shaft 5a until it comes into contact with the upper and lower guide surfaces 17 and 18 of the air conditioner.

FIG. 3 is an electric circuit diagram showing an embodiment of the present invention, and 22 is a microcomputer that controls the positioning of the movable vane 5, and is composed of a memory 23, an input circuit 24, a CPU 25, and an output circuit 26. . Further, 27 is a remote device, in which a movable vane position setting switch 28 and a pull-up resistor 29 are connected in series, and an intermediate position between 28 and 29 is connected to the input circuit 24 of the microcomputer 22, which is used to set the movable vane position. The signal from the on/off of the switch 28 is transmitted to the microcomputer 22.
It is now input to . The reference position detection switch 6 is also connected in series with the resistor 30, and the intermediate position thereof is connected to the input circuit 24 of the microcomputer 22.
The on/off signal of the microcomputer 22
It is now input to . On the other hand, 31 is
This is a relay that is operated by an electric signal output from the output circuit 26 of the microcomputer 22, and 31a is an a contact point of the relay 31, which activates and stops the movable vane drive motor 1 by turning it on and off. . 32 is a power source for the movable vane driving electric motor 1.

Next, the operation will be explained. FIG. 4 is a control flowchart showing one embodiment of the present invention. First, at the start, in step 33, the remote device 2
7, check the input value code x _j of the movable vane position setting switch 28. Next, in step 34, it is checked whether the movable vane reference point detection flag is set, and if it is not set, in the next step 35, a timer T counting flag is set to check whether the timer T is counting. If it is not set, in the next step 36, it is checked whether the timer T count complete flag is set, which checks whether the timer T count is completed, and if it is not set. For example, in the next step 37, it is checked whether the code x _j-1 indicating the current position of the movable vane 5 and the code x _j indicating the stop position of the movable vane to be newly set match. If so, the vane drive motor 1 is stopped in step 38. Meanwhile, in step 37 above, code x _j-1 and code
If x _j does not match, that is, if the stopping position of the movable vane 5 is changed, first step 39, 40,
41, code x _j-1 indicating the current position of movable vane 1
Check if is 0, 1, 2, or 3, and if it is 0, step
42, set the count time of timer T to t ₀ , and
If , step 43 sets t ₁ ; if 2, step 44 sets t ₂ ; if 3, that is, when steps 39, 40, and 41 are all negative, step
45. Set the reference point detection flag, and enter the vane drive motor operation step shown in step 46. On the other hand, if the process goes through steps 42, 43, and 44, the process goes through step 47 in which the timer T starts counting time and step 48 in which the timer T counts flag is set, and then the vane drive motor operation step 46 is entered. . In the above state, step 35
When it is confirmed that the timer T-counting flag is set in step 49, 50, while checking the position of movable vane 1, step 51,
Completion of counting by the timer T is confirmed in steps 52 and 53, and upon completion, the timer T completion flag is set in step 54, the timer counting flag is reset in step 55, and the process returns to step 36. If the timer T count completion flag is set in step 36, step 56 advances the code indicating the current position of the movable vane 1 by 1 (x _j-1 +1→
xj _-1 ) is used as a code indicating the current position of the movable vane 1, the timer T count completion flag is reset in step 57, and the process returns to step 37. If it is confirmed in step 34 that the reference point detection flag is set, that is, if the code indicating the current position of the movable vane is changed from 3 to 0, then in step 58 the reference point detection flag is set. It is checked whether there is an input by switch 6, and if there is an input, a code indicating the current position is entered in step 59.
Set x _j-1 to 0 (0→x _j-1 ) and step 60
to reset the reference point detection flag and proceed to the step.
Return to 37.

FIG. 5 is a diagram showing the relationship between the stop position of the movable vane and the code indicating the position. In the figure, reference position 0 is code 0, position 1 is code 1, position 2 is
Assuming that code 2 is code 2 and position 3 is code 3, the time required to change the position of the movable vane is t ₀ ,
t ₁ and t ₂ are defined.

〔Effect of the invention〕

As described above, according to the present invention, the wind direction of the air conditioner can be adjusted remotely, and since the appropriate positioning control means for the movable vane is provided, the shape of the air outlet of the air conditioner can be adjusted. In addition, since the stop position and drive time of the movable vanes can be set, precise and smooth operation is possible, and an air conditioner with good operability can be provided.

[Brief explanation of drawings]

Fig. 1 is a control block diagram showing an embodiment of the present invention, Fig. 2 is a sectional view of an air conditioner equipped with the wind direction control device of the invention, and Fig. 3 is an electrical control block diagram showing an embodiment of the invention. Circuit diagram, Fig. 4 is a flowchart showing the position control of the movable vane, Fig. 5 is an explanatory diagram showing the relationship between the stop position of the movable vane and the control code, and Fig. 6 shows a conventional wind direction control device. 7 is a sectional view of a conventional air conditioner equipped with the wind direction control device shown in FIG. 6. In the figure, 1 is a movable vane drive electric motor, 2
is a cam, 3 is a disc, 4 is a connecting plate, 5 is a movable vane, 6 is a reference position detection switch, 11 is a blower,
12 is a heat exchanger, 13 is a drain pan, 14 is a first
Air outlet, 15 is a second air outlet, 16 is a blowing grill, 17 is a lower guide surface, 18 is an upper guide surface, 19 is a main body, 20 is a ceiling surface, 21 is a wall surface, 22 is a microcomputer, 27 is a remote device , 28 is a movable vane position setting switch, 29 and 30 are pull-up resistors, 31 is a relay, 32 is a power source, 61 is a pinion, 62 is an opening/closing vane, 63 is a rack, 64 is a safety part, and 65 is a presser metal fitting. Note that the same reference numerals in the figures indicate the same or corresponding parts.

Claims (1)

[Claims] 1. A movable vane of an air conditioner that is driven by an electric motor to control the wind direction, a movable vane position setting means that can set the position of the movable vane by remote control, and a setting position set by the movable vane position setting means. a positioning control means for positioning the movable vane according to a code signal and a rotation signal of the electric motor; and a vane drive electric motor control means for operating the electric motor and driving the movable vane under the control of the positioning control means. and determining means for comparing and determining a current position code signal for confirming the current position code of the movable vane and a set position code signal set by the movable vane position setting means in the positioning control means; , a timer for presetting a time for each of a plurality of position codes of the movable vane; and a timer for controlling the vane drive motor control means based on the result of the discriminating means at each preset time by the timer to control the vane drive motor control means for the movable vane. control means for advancing a vane position code until the advanced position code for the movable vane matches a set position code for the movable vane set by the movable vane position setting means; A wind direction control device for an air conditioner characterized by: