JP2002257408A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner reduced in cost and size, wherein the oscillation range of a wind direction plate is rapidly varied and the occurrence of displacement of the oscillation position of the wind direction plate is prevented. SOLUTION: In the air conditioner 1 formed so that a wind direction of air delivered through an air outlet is varied by a wind direction plate 30 capable of oscillating a wind direction of air, a stopper piece 30h protruding from a support shaft 30g to support the wind direction plate 30 has first and second reference positions A and B consisting of positions making contact with the two ends of a fan-shaped part 4d formed around an shaft hole 4b fitted in the support shaft 30g, and a first oscillation range where the wind direction plate 30 is oscillated from the first reference position A by a given angle θ1 and a second oscillation range where the wind direction plate 30 is oscillated by a given angle θ2 from a second reference position can be switched from each other.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner for adjusting the temperature, humidity and the like in a room, and more particularly to an air conditioner having a wind direction adjusting device for adjusting a wind direction of air sent indoors.

[0002]

2. Description of the Related Art The structure of a conventional air conditioner is shown in FIG. The air conditioner 81 adjusts the temperature, humidity, etc., by taking in the air in the room into the air conditioner, and adjusts the temperature of the room by sending the air from the outlet 82. The outlet 82 is provided with a wind direction adjusting device 84 for changing the wind direction of the air to be sent out. The wind direction adjusting device 84 is a rotatable wind direction plate 85.
And a stepping motor 86 is connected to a support shaft 85 a of the wind direction plate 85. The stepping motor 86 is controlled by the control unit 83 and drives the wind direction plate 85.

Before the swing of the wind direction plate 85 starts, the wind direction plate 8
In order to align the position 5, a wind direction detection sensor 87 is provided at one end of the air outlet 82. When the wind direction plate 85 reaches the reference position E at one end of the outlet 82, the wind direction plate detection sensor 87 detects and positions the wind direction plate 85.

Further, the swing range of the wind direction plate 85 can be changed by operating a swing button (not shown) according to the operating condition of the air conditioner 81. That is, the wind direction plate 85 is moved from the reference position E to the first swing range of the swing angle θ1 and the reference position E.
From the reference position F at an angle θ1 to the swing angle θ2
The second swing range can be swung. Thereby, the user can send out air in a desired direction.

When the first swing range is selected by switching a swing button (not shown), a stepping motor 86 is selected.
Drives the wind direction plate 85 in the direction of the reference position E. When the wind direction detection sensor 87 detects the wind direction plate 85 and the wind direction plate 85 reaches the reference position E, the wind direction plate 85 swings at the swing angle θ1 under the control of the control unit 83.

When the second swing range is selected, the wind direction plate 85 moves in the direction of the reference position E by driving the stepping motor 86. The wind direction plate 8 is detected by the wind direction plate detection sensor 87.
5 is detected, when the wind direction plate 85 reaches the reference position E, the stepping motor 86 is driven by the control of the control unit 83 to rotate the wind direction plate 85 by the angle θ1. Then, the wind direction plate 85 swings at the swing angle θ2 from the reference position F.

As a method for causing the wind direction plate 85 to reach the reference position E, in addition to the above-described method using the wind direction plate detection sensor 87, the maximum angle at which the wind direction plate 85 can move structurally is set to the reference position E. By moving the wind direction plate 85 in the direction (clockwise in the figure), the position of the wind direction plate 85 is changed to the reference position E.
There is a method of positioning.

[0008]

However, according to the above-described conventional air conditioner 81, when the second swing range is selected, the wind direction plate 85 moves to the reference position E, so that the quick swing range is obtained. There was a problem that could not be switched. In addition, the wind direction plate position sensor 8 is used to detect the reference position E.
7 is required. Therefore, there is a problem that the cost of the air conditioner 81 increases, and a space for disposing the wind direction plate position sensor 87 is required, so that the air conditioner 81 becomes large.

Further, when positioning the wind direction plate 85 by rotating it by the maximum rotatable angle, the wind direction plate 85 actually reaches the reference position E due to the play between the motor shaft of the stepping motor 86 and the axis of the wind direction plate 85. Without this, there was also a problem that the swing position of the wind direction plate 85 was shifted.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an air conditioner in which the swing range can be quickly changed, the swing position of the wind direction plate does not shift, and the cost and size can be reduced.

[0011]

According to the present invention, there is provided an air conditioner in which the direction of air sent from an air outlet is changed by a swingable wind direction plate. A first swing range having first and second reference positions that can be reached by moving and a predetermined angle from a position based on the first reference position, and a predetermined angle from a position where the wind direction plate is based on the second reference position It is characterized in that it is possible to switch between a swinging second swing range.

According to this configuration, when the wind direction plate is switched to the first swing range, the wind direction plate rotates to the first reference position. When reaching the first reference position, air whose temperature, humidity, and the like are adjusted by a predetermined angle from the first reference position or by swinging from the first reference position by a predetermined angle is sent out from the outlet. Second
When switched to the swing range, the wind direction plate rotates to the second reference position. When reaching the second reference position, air whose temperature, humidity, etc. are adjusted from the outlet by being swung by a predetermined angle from the second reference position or by a predetermined angle from the second reference position is sent out.

According to the present invention, in the air conditioner having the above-described structure, the stopper piece protruding from the support shaft supporting the wind direction plate may be a stopper formed around a shaft hole fitted to the support shaft. It is characterized in that the contact positions are the first and second reference positions.

According to this configuration, when the wind direction plate is switched to the first swing range, the wind direction plate rotates, and the wind direction plate reaches the first reference position, for example, when the stopper piece contacts one stopper. When switched to the second swing range, the wind direction plate rotates,
When the stopper piece contacts another stopper, the wind direction plate reaches the second reference position.

The positions where the two stopper pieces abut on the single stopper may be defined as the first and second reference positions, respectively. Further, the support shaft may be provided on the wind direction plate side, and the shaft hole may be provided on the side supporting the wind direction plate. The support shaft may be provided on the side supporting the wind direction plate, and the shaft hole may be provided on the wind direction plate. It may be provided on the side.

Further, according to the present invention, in the air conditioner having the above-described structure, the wind direction plate is driven by a stepping motor that is pulse-controlled, and the maximum rotation angle of the wind direction plate and the play angle of the bearing of the stepping motor are added. A pulse corresponding to a larger angle is transmitted to the stepping motor so that the wind direction plate reaches the first reference position or the second reference position.

According to this configuration, the stepping motor receives a predetermined number of pulses and rotates the motor shaft by an angle corresponding to the number of pulses. As a result, the wind direction plate rotates. When a pulse corresponding to an angle larger than the sum of the maximum rotation angle of the wind direction plate and the play angle of the bearing of the stepping motor is transmitted to the stepping motor, the wind direction plate rotates at most the maximum angle to the first reference position or The second reference position is reached. Thereafter, the stepping motor further receives a pulse, but the wind direction plate stays and is positioned at the first reference position or the second reference position. As a result, no deviation occurs in the swing position.

The present invention also provides an air conditioner having the above-described structure, wherein a first and second swing range, and a third swing range in which the wind direction plate swings from a first reference position to a second reference position, A stop state in which the wind direction plate stops at an arbitrary position can be sequentially switched, and the state is switched to the stop state after the third swing range. According to this configuration, when the state is switched to the stop state, the wind direction plate that swings in the third swing range is stopped at an arbitrary position.

Further, according to the present invention, in the air conditioner having the above configuration, a standard stop state in which the wind direction plate stops at the second reference position, a second swing range, a first swing range, and a third swing range. In this case, the reference position for starting the swing of the wind direction plate that swings in the third swing range is set to the first reference position.

According to this configuration, the desired wind direction can be quickly obtained by switching the standard stop state, which is frequently used, or the second swing range before the first swing range. Further, if the switching to the third swing range is performed during the standard stop state where the frequency of use is high or the swing in the second swing range, the pulse signal received after reaching the first reference position is small, and the motor stops at the first reference position. Time is shortened.

Further, the present invention is characterized in that, in the air conditioner having the above configuration, when the operation of the air conditioner is stopped, the air outlet is closed by the wind direction plate regardless of the operation state of the wind direction plate. I have.

[0022]

Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 are a front perspective view and a rear perspective view showing a dehumidifier which is an air conditioner of one embodiment. The dehumidifier 1 is installed and used on a floor or the like in the direction shown in these figures, and the vertical direction in the figure matches the vertical direction in use. In the dehumidifier 1, the front side of the side surface, the front side of the bottom surface, and the front surface are covered by the front frame 2, and the rear side of the side surface, the rear side of the bottom surface, and the back surface are covered by the rear frame 3.

Then, the front frame 2 and the rear frame 3 are assembled so that they are engaged with each other by engagement claws (not shown) formed on the peripheral edges of the side surfaces and the bottom surface to form an opening in a part of the upper surface. I have. An exhaust unit 12 for sending out air is attached to the opening. The exhaust unit 12 is provided with outlets 4 and 18 for blowing dry air upward and rearward, respectively. Although details will be described later, a wind direction adjusting device 17 that shields the blow port 4 and changes the wind direction by driving a wind direction plate (not shown) is attached to the blow port 4.

On the rear side of the rear frame 3, a suction port 15 for taking in room air is formed. A filter 7 is attached to the rear frame 3 on the inner side of the dehumidifier 1 at a position corresponding to the suction port 15. The filter 7 has an antibacterial specification antibacterial by apatite or the like.
Dust and pollen contained in the air flowing into the dehumidifier 1 from
Removes viruses, nitrogen oxides, etc. The filter 7 is detachably inserted through an opening 61 formed on the upper surface of the rear frame 3.

A handle 10 is pivotally supported behind the exhaust unit 12 so that the dehumidifier 1 can be carried.
In the front frame 2, a viewing window 14 through which the inside of the dehumidifier 1 can be visually recognized is provided at one of the upper front, and an operation panel 13 for operating and displaying the dehumidifier 1 is provided at substantially the center of the upper front. ing.

FIGS. 3A and 3B are a top view and a front view showing details of the operation panel 13, respectively. On the upper surface side of the operation panel 13, an emptying button 21, a dehumidifying button 22, and a clothes drying button 23 are provided. When the air-cleaning button 21 is pressed, the air-cleaning operation is performed by blowing air without performing the dehumidifying operation,
The positive ions and the negative ions are simultaneously sent out into the room to remove airborne bacteria in the room.

When the dehumidification button 22 is depressed, a compressor described later is driven to dehumidify the indoor air. When the clothes drying button 23 is pressed, the compressor is driven to dehumidify the air in the room and dry the clothes dried in the room. The ion generator described below is driven in combination with the air cleaning operation, the dehumidification operation, and the clothes drying operation.

On the front side of the operation panel 13, there is provided a display panel 29 for displaying the room temperature and the operating state.
Below the display panel 29, a dehumidification switching button 24, an air volume switching button 25, a swing button 27, and a timer switching button 28 are arranged. When the dehumidification switching button 24 is pressed, the operation mode is switched in the order of “automatic dehumidification”, “cavitation tack”, “continuous dehumidification”, and “condensation prevention”.

When the air volume switching button 25 is pressed, the air volume of the air sent into the room is switched in the order of "medium", "silent", and "strong". When the swing button 27 is pressed,
The first vertical wind direction plate 30 is “upward”, “rearward”, “wide angle”,
Switching is performed in the order of “off”, and the wind direction of the air sent into the room can be switched. Timer switch button 28
Press to switch the timer on and off,
A timer time of up to 9 hours can be set.

FIG. 4 is a schematic side view showing the inside of the dehumidifier 1. A compressor 5 is arranged at a lower portion on the back side of the dehumidifier 1,
A tank 6 for collecting condensed water via a drain pan 19 is provided at a lower portion on the front side. The tank 6 can be taken out by opening a part of the front frame 2 and drain the accumulated condensed water. Above the compressor 5, an evaporator 8, a condenser 9, and a blower 11 are arranged in this order from the filter 7 arranged facing the suction port 15. Blower 11
An ion generator 16 that simultaneously generates positive ions and negative ions by discharge is disposed above the ion generator.

The blower 11 is constituted by a sirocco fan which rotates an impeller 11b provided on the outer periphery of the motor 11a by driving the motor 11a and discharges the air sucked from the suction port 15 on the back side of the dehumidifier 1 in the circumferential direction. I have. Thereby, air is guided toward the ion generator 16 and the outlets 4 and 18.

One end of the evaporator 8 and one end of the condenser 9 are connected via a compressor 5 by a first connecting pipe (not shown), and the other end of the evaporator 8 and the other end of the condenser 9 expand. They are connected by a second connection pipe (not shown) via a valve (not shown). Therefore, the refrigerant in the first and second connection pipes flows by driving the compressor 5, and the refrigeration cycle is operated. That is, the compressor 5
The high-temperature refrigerant compressed by the compressor 9 releases heat in the condenser 9 and condenses. After the refrigerant liquefied by the condensation is decompressed by the expansion valve, the vaporized heat is taken by the evaporator 8 and returned to the compressor 5 when being vaporized.

The indoor air sucked from the suction port 15 by driving the blower 11 exchanges heat with the evaporator 8 on the low temperature side and is cooled. At this time, the water contained in the air is condensed and collected in the tank 6 as condensed water. Since the temperature of the air that has been dried by removing moisture (hereinafter referred to as “dry air”) has decreased, the air exchanges heat with the condenser 9 on the high-temperature side and is heated to the temperature before dehumidification.

Thereafter, as will be described in detail later, the dry air passes through the blower 11 and is partially guided to the ion generator 16. The remaining dry air is discharged from the outlets 4 and 18 (see FIG. 2).
And merges with the dry air containing ions after passing through the ion generator 16 and is sent out indoors. This allows
Indoor dehumidification and sterilization are performed.

FIGS. 5, 6 and 7 are a side sectional view, a rear view and a top view showing the details of the upper part of the dehumidifier 1. Dehumidifier 1
An ion generator 16 is disposed at one upper portion on the front side of the device, facing the viewing window 14. The ion generator 16 is covered by a casing 41. The casing 41 is
The fan 11 is attached to a fan case 44 that covers the blower 11 with screws (not shown). The upper surface and the back surface of the casing 41 open a part of the rear of the casing 41 to open the outlet 41.
The upper cover 43 is formed so as to form a.

The casing 41 is vertically partitioned by a partition plate 41h, and the ion generator 16 is disposed on the upper side. FIG. 8 is a sectional view showing details of the ion generator 16. The ion generator 16 includes the cylindrical dielectric 5.
The inner electrode 51 is arranged along the inner surface of the outer electrode 0, and the outer electrode 52 is arranged along the outer surface. The outer electrode 52 is bound to the dielectric 50 by a band 57.

In this embodiment, a glass tube having an outer shape of 20 mm is used as the dielectric 50. Also, the inner electrode 51
A SUS304 flat plate is rolled and used, and the outer electrode 52 is a SUS304 or SUS316 wire rod plain-woven with 16 mesh and rolled.

Both ends of the dielectric 50 are provided with an insulating packing 53,
The insulating packings 53 and 54 are fitted with the grooves 53a and 54a formed in the groove 54. A power supply unit (not shown) composed of a high voltage circuit is provided for the inner electrode 51 and the outer electrode 52.
Lead wires 55 and 56 connected to
The outer electrode 52 is grounded. The lead wire 55 is inserted into and held by an insertion hole 53c formed substantially in the center of the insulating packing 53.

Grooves 5 are formed on the peripheral surfaces of the insulating packings 53 and 54.
3d and 54d are formed. A rib (not shown) provided on the inner wall of the casing 41 is fitted into the grooves 53d and 54d, and the ion generator 16 is supported.

When a high AC voltage is applied between the inner electrode 51 and the outer electrode 52, if the applied voltage is a positive voltage, positive ions mainly composed of H ⁺ (H ₂ O) _n are generated by plasma discharge, If a negative voltage is mainly O ₂ ^- (H ₂ O) negative ions of _m is generated.

The H ⁺ (H ₂ O) _n and O ₂ ^- When (H ₂ O) _m are discharged from the outlet 4, 18 of the dehumidifier 1 indoors, on the surface of airborne fungi, such microorganisms in air Aggregates and surrounds suspended bacteria such as microorganisms. Then, as shown in formulas (1) to (3), the active species [.OH] (hydroxyl radical) and H ₂ O ₂ (hydrogen peroxide) are generated and suspended on the surface of microorganisms and the like by collision. It is designed to kill bacteria.

[0042] ^{_{H + (H 2 O) n}} + O 2 - (H 2 O) m → · OH + 1 / 2O 2 + (n + m) H 2 O ··· (1) H + (H 2 O) n + H ^{_{+ (H 2 O) n '}} + O 2 - (H 2 O) m + O 2 - (H 2 O) m' → 2 · OH + O 2 + (n + n '+ m + m') H 2 O ··· _{^{(2) H + (H 2}} O) n + H + (H 2 O) n '+ O 2 - (H 2 O) m + O 2 - (H 2 O) m' → H 2 O 2 + O 2 + (n + _{n '+ m + m')} H 2 O ··· (3)

5 to 7, a blue lamp 49 made of a light emitting diode or the like for illuminating the ion generator 16 is attached to the upper cover 43. Further, a transparent plate 46 is attached to a front surface of the casing 41 at a position facing the viewing window 14. As a result, the operating state of the ion generator 16 can be visually recognized from the viewing window 14.

The periphery of the impeller 11 b of the blower 11 is covered with a fan case 44. In the upper part of the fan case 44, an opening 44b for discharging dry air is formed. A protective plate 45 made of a wire mesh or the like for preventing foreign matter from entering is provided in the opening 44b, and a humidity sensor 70 for detecting the humidity of dry air discharged from the opening 44b is provided above the protective plate 45. .

In FIG. 6, the fan case 44 is formed with a bypass portion 44a extending substantially horizontally from one end of the opening portion 44b. A duct 42 that covers a part of the opening 44b is provided on the bypass 44a.
By the bypass part 44a and the duct 42, the blower 11
A bypass passage 48 that guides a part of the dry air sent in the circumferential direction to the inflow port 41b of the casing 41 is formed. A movable air volume adjusting plate 60 is provided at an end of the duct 42. The air volume adjusting plate 60 is a fan 11
The amount of dry air flowing into the bypass passage 48 can be adjusted according to the amount of air flow.

The air flowing into the casing 41 from the inflow port 41b is guided to the ion generator 16 through an opening 41c formed in the partition plate 41h. FIG. 9 shows the duct 42
2 shows a top view as viewed from above. As shown in FIGS. 5, 6, and 9, the air that has passed through the ion generator 16 flows out of the outlet 41a. The duct 42 has a step 42
a is formed, and a partition rib 42b for allowing air to flow smoothly is formed on the upper surface of the step portion 42a.

The air flowing out of the outlet 41a is guided to the exhaust unit 12 having the wind direction adjusting device 17. The remaining air sent in the circumferential direction by the blower 11 is guided to the exhaust unit 12 from the opening 44 b by the peripheral wall of the fan case 44. Then, the combined air is sent out by the wind direction adjusting device 17 in a predetermined direction in the room.

FIG. 10 is an exploded view of the wind direction adjusting device 17. 5 and 10, the wind direction adjusting device 17 includes first and second vertical wind direction plates 30, 31 that change the wind direction according to the direction.
And four horizontal wind direction plates 33. First vertical wind direction board 3
0 is curved along the outer shape of the exhaust unit 12. The first vertical wind panel 30 is pivotally supported on the horizontal axis, and the first vertical wind panel 3
Rotating together with the second vertical wind direction plate 31 attached substantially in parallel to 0, the wind direction in the front-rear direction is changed. The horizontal wind direction plate 33 is pivotally supported by the first and second vertical wind direction plates 30 and 31, and changes the wind direction in the left-right direction when viewed from the front of the dehumidifier 1 by rotation.

A shaft portion 12a is provided on one side wall 4a of the outlet 4 formed in the exhaust unit 12. A stepping motor 34 is provided outside the other side wall 4a. The first vertical wind direction plate 30 has an E-shaped cross section, and the top plate 3
0j, side walls 30e and 30f, and an intermediate wall 30b.

A shaft hole 30c is formed in one side wall 30e of the first vertical wind direction plate 30, and a shaft portion 30 is formed in the other side wall 30f.
g is formed. The shaft hole 30c and the shaft portion 12a are fitted,
Shaft 30g and motor shaft 34a of stepping motor 34
Are connected via a hole 4b formed in the side wall 4a, whereby the first vertical wind direction plate 30 is pivotally supported.

The second vertical wind direction plate 31 has a U-shaped cross section, and has a bottom plate 31d and side walls 31e and 31f.
A hole 31c is formed in the center of the bottom plate 31d, and the side wall 31d is formed.
Holes 31b are formed in e and 31f. Hole 31
b engages with the claw portions 30d provided on the side walls 30e and 30f of the first vertical wind direction plate 30. In addition, a screw (not shown) is inserted into the hole 31c and screwed into a screw hole 30e formed in the intermediate wall 30b of the first vertical wind direction plate 30. This allows the first,
The second vertical wind direction plates 30, 31 are integrated substantially in parallel.

A boss hole 30a having a circular cross section is formed at four places on the top plate 30j of the first vertical wind direction plate 30. Four bosses 31 having circular cross sections are provided on the bottom plate 31 d of the second vertical wind direction plate 31.
a is formed. Bosses 33a and boss holes 33b having a circular cross section are formed on the upper and lower sides of the horizontal wind direction plate 33, respectively. The boss hole 30a and the boss 33a are fitted, and the boss 31a
The horizontal wind direction plate 33 is pivotally supported by fitting the boss hole 33b with the boss hole 33b.

The horizontal wind direction plate 33 includes a second vertical wind direction plate 31.
A notch 33g is provided in which a part of the surface opposing to the notch is cut, and a boss 33d having a circular cross section protrudes from the notch 33g. Each boss 33d of the two horizontal wind direction plates 33 is loosely fitted into a hole (not shown) provided in the connection plate 35. Thus, the two horizontal wind direction plates 33 are connected by the connection plate 35, and are rotated in conjunction with each other.

FIG. 21 is a block diagram showing the configuration of drive control of the wind direction adjusting device 17. The control unit 71 includes an input circuit 74 for receiving an input signal from the swing button 27 (see FIG. 3), a memory 72 for storing control data, and a memory 72.
That calculates a control signal based on the information and the input signal
U73, an output circuit 75 for outputting the control signal transmitted from the CPU 73 to the stepping motor 34 is provided.

The input signal from the swing button 27 is input to the input circuit 74. A pulse signal for controlling the operation of the stepping motor 34 is calculated by the CPU 73 based on the information of the memory 72 and the input signal. Then, the pulse signal is transmitted through the output circuit 75 to the stepping motor 3.
4 and the motor shaft 34 of the stepping motor 34
a is driven by an angle corresponding to the number of pulses.

Thus, the first and second vertical wind direction plates 30, 3
1 rotates around the shaft portions 12a and 30g. As shown in FIG. 12, a hole 4b formed in the side wall 4a of the outlet 4 has a sector 4d formed by cutting out a part of the peripheral edge. Further, a stopper piece 30h is protrudingly provided on the peripheral surface of the shaft portion 30g of the first vertical wind direction plate 30.

By driving the stepping motor 34, the first
When the vertical wind direction plate 30 rotates clockwise in FIG.
The stopper piece 30h abuts on one end face 4e (stopper) of d. Thereby, the first vertical wind direction plate 30 is positioned at the first reference position A. In addition, the first vertical wind direction plate 30 is shown in FIG.
When rotated counterclockwise, the stopper piece 30h contacts the other end face 4f (stopper) of the sector 4d. Thereby, the first vertical wind direction plate 30 is positioned at the second reference position B.

As will be described in detail later, when the dehumidifier 1 is not used, the first vertical wind direction plate 30 is disposed at the first reference position A,
As shown in FIG. 5 described above, the air outlet 4 is closed by the first vertical wind direction plate 30. As a result, intrusion of dust and the like from the outlet 4 is prevented.

When the first vertical wind direction plate 30 is rotated counterclockwise in the drawing by an angle θ0 (= 100 °), the first vertical wind direction plate 30 is rotated.
Is located at the second reference position B, and the air outlet 4 is opened as shown in FIG. At this time, the projecting portion 33 of the horizontal wind direction plate 33
By moving c with fingers, the direction of the horizontal wind direction plate 33 can be changed.

In FIGS. 5 and 11, the front wall 4c of the outlet 4 and the upper wall 43a of the outlet 41a prevent a finger that enters when the outlet 4 is opened from coming into contact with the ion generator 16. Constituting shielding means. Thereby, it is possible to prevent an accident such as an electric shock due to contact between the finger and the ion generator 16, and to arrange the ion generator 16 near the outlet 4 so as to be in contact with a wall surface or the like in a distribution channel after ion generation. Extinction due to the collision of ions can be suppressed.

The operation of the dehumidifier 1 having the above configuration will be described below. When the power of the dehumidifier 1 is turned on, the emptying button 21
It waits until one of the dehumidification button 22 and the clothes drying button 23 (both see FIG. 3) is pressed. When the dehumidification button 22 is pressed, the compressor 5 is driven and the blower 1
1 (see FIG. 4) is driven with the air volume “medium”.

By depressing the air volume switching button 25, the air volume is reduced to a "quiet sound" in which the air volume is smaller than the "middle" air volume and the noise caused by the operation of the blower 11 is reduced, and the "strong" air volume is larger than the air volume "middle" Can switch.

Further, the stepping motor 34 of the wind direction adjusting device 17 is driven, and the wind direction is set to “upward stop”. FIG. 13 shows the operation of the wind direction adjusting device 17 at this time.
First, in step # 11, a pulse corresponding to a rotation angle of 110 ° is sent to the stepping motor 34, and the first wind direction plate 30 is moved from the first reference position A shown by a solid line in FIG. Rotation toward B starts.

In this embodiment, the angle θ0 (maximum rotation angle) between the first reference position A and the second reference position B is formed at 100 °. Since there is play between the motor shaft 34a of the stepping motor and the shaft portion 30g of the first vertical wind direction plate 30, an error occurs in the rotation angle of the first vertical wind direction plate 30 with respect to the pulse signal. For this reason, a pulse signal of 110 °, which is larger than the sum of the maximum rotation angle and the play angle, is transmitted to the stepping motor 34 with a margin. Thus, the first vertical wind direction plate 30 can reliably reach the second reference position B.

In step # 12, when the first vertical wind direction plate 30 reaches the second reference position B, a load is applied to the motor shaft 34a, so that the motor shaft 34a is not rotated by a subsequent pulse signal. Thereby, the first vertical wind direction plate 30 stops at the second reference position B. As a result, an "upward stop" state (standard stop state) is set. Then, dry air and ions are sent out from the upper outlet 4.

The wind direction switching device 17 has a swing button 27
By pressing (see FIG. 3), as described above, the swing direction is sequentially switched to “up”, “rear”, “wide angle”, and “off”. At the beginning of the operation of the dehumidifier 1, the wind direction is “upward stop”, and when the swing button 27 is pressed once, the “upward” swing process of FIG. 14 is performed.

In the “upward” swinging process, a pulse corresponding to the turning angle 110 ° is sent to the stepping motor 34 in step # 21, and the first wind direction plate 30 starts turning toward the second reference position B. I do. The first wind direction plate 30 is already disposed at the second reference position B when the wind direction is “upward stop”. However, when the position of the first wind direction plate 30 is manually changed, or in the above-described processing of FIG.
The first wind direction plate 30 is rotated toward the second reference position B in consideration of the case where the swing button 27 is depressed during the rotation of.

In step # 22, when the first vertical wind direction plate 30 reaches the second reference position B, the motor shaft 34a is not rotated by the subsequent pulse signal, and the first vertical wind direction plate 30 is moved to the second reference position B.
It stops at the reference position B. In step # 23, as shown in FIG. 15, the first wind direction plate 30 rotates in the direction of the first reference position A at the swing angle θ2 (50 ° in the present embodiment). First
When the wind direction plate 30 rotates by the swing angle θ2, step #
24, the swing angle θ2 (50) in the direction of the second reference position B.
Rotate in ゜). Then, steps # 23 and # 24 are repeatedly performed, and the first wind direction plate 30 swings.

When the swing button 27 is depressed once while the swing direction is "up", the "back" swing process of FIG. 16 is performed. It is considered that "rearward" rocking is used less frequently than "upward" rocking, and by switching to "rearward" after "upper" rocking, the Switching can be performed quickly.

In the “rearward” swinging process, a pulse corresponding to a rotation angle of 110 ° is sent to the stepping motor 34 in step # 31, and the first wind direction plate 30 starts rotating toward the first reference position A. I do. In step # 32, as shown in FIG. 17, when the first vertical wind direction plate 30 reaches the first reference position A, the motor shaft 34a is not rotated by the subsequent pulse signal, and the first vertical wind direction plate 30 is moved to the first vertical position. It stops at the reference position A.

In step # 33, the first wind direction plate 30 swings in the direction of the second reference position B by the swing angle θ1 (5 in this embodiment).
0 °). When the first wind direction plate 30 rotates by the swing angle θ1, it rotates at the swing angle θ1 (50 °) in the direction of the first reference position A in step # 34. Then, steps # 33 and # 34 are repeatedly performed, and the first wind direction plate 30 swings.

When the swing button 27 is pressed once while the swing direction is "backward", the "wide-angle" swing process of FIG. 18 is performed. In the “wide-angle” swing process, a pulse corresponding to a rotation angle of 110 ° is sent to the stepping motor 34 in step # 41, and the first wind direction plate 30 starts rotating toward the first reference position A.

Since a pulse of 110 ° is sent to the stepping motor 34, the first wind direction plate 30 can reach the first reference position A regardless of the position.
Here, if the swing direction is “rearward” and the first wind direction plate 30 is swinging, the first wind direction plate 30 can reach the first reference position A by rotating about 50 °. However, in the processing of FIG. 14 described above, when the swing button 27 is continuously pressed twice while the first wind direction plate 30 is rotating, or when the wind direction is continuously turned three times from the “upward stop” state. Is rotated by 110 ° in consideration of the case where is pressed.

In step # 42, as shown in FIG. 12, when the first vertical wind direction plate 30 reaches the first reference position A, the motor shaft 34a is not rotated by the subsequent pulse signal and the first vertical wind direction The plate 30 stops at the first reference position A. Thereby, the first reference position A becomes the reference position for the swing. When the swing direction is “wide angle”, the first vertical wind direction plate 30 is the first,
In order to swing between the second reference positions A and B, either of the first and second reference positions A and B may be set as the swing reference position.

However, it is considered that the frequency of use when the swing direction is "rearward" is considered to be infrequent, and the state of "upward stop" or "upward" swing is often switched to "wide angle". For this reason, when a pulse signal of 110 ° is transmitted, the pulse signal that moves to the first reference position A and survives after reaching the first reference position A is better than the pulse signal that moves to the second reference position B and survives. Less. Accordingly, the time during which the vehicle is stopped at the first reference position A is shorter, and a smoother movement than when swinging at “wide angle” after reaching the second reference position B can be obtained.

In step # 43, a pulse signal of 105 ° is transmitted to the stepping motor 34, and the first wind direction plate 30 rotates in the direction of the second reference position B. First wind direction board 3
When 0 rotates by the swing angle θ3 (100 ° in the present embodiment), it reaches the second reference position B, and subsequent pulse signals are ignored. In step # 44, similarly, a pulse signal for 105 ° is transmitted, and rotates in the direction of the first reference position A by the swing angle θ3 (= 100 °). Then, steps # 43 and # 44 are repeatedly performed, and the first wind direction plate 30 swings.

When the swing button 27 is pressed once in the state where the swing direction is "wide angle", the swing "off" process of FIG. 19 is performed. In the swing "off" process, the stepping motor 34 is stopped in step # 51, and the process ends. As a result, dry air and ions are sent out from the air outlet 4 while the first vertical wind direction plate 30 is stopped at the position where the swing button 27 is pressed.

By switching the swing direction from the "wide angle" state to the "off" state, the first vertical wind direction plate 30 can be easily stopped at any position from the closed position to the fully opened position. It can be made to be.

The operation mode of the dehumidifying operation is initially “automatic dehumidifying”.
When the room temperature is lower than 28 ° C., the compressor 5 is stopped when the humidity becomes 60% or less, and when the room temperature is 28 ° C. or more, the compressor 5 is stopped when the humidity becomes 55% or less. It has become. When the operation mode is switched to “Cavia tack” by pressing the dehumidification button 22, the humidity becomes 49%.
%, The compressor 5 is stopped.

When the operation mode is switched to “continuous dehumidification”, the compressor 5 is operated continuously. When the humidity becomes, for example, 30% or less, the dehumidifying efficiency is reduced.
Is stopped. When the operation mode is switched to "prevention of dew condensation", the air volume is automatically switched to "strong" when the room temperature becomes lower than 15 ° C., thereby preventing dew condensation in the room.

When the refrigerating cycle is operated by driving the compressor 5 and the blower 11 is driven, room air is taken into the dehumidifier 1 from the suction port 15. The indoor air containing moisture is cooled by the evaporator 8 on the low temperature side, and the moisture condenses to dry air. Thereafter, the temperature is raised to the original temperature by the condenser 9 on the high temperature side, and the opening 44 of the fan case 44 is opened.
b.

A part of the dry air passes from the fan case 44 through the bypass passage 48 to the ion generator 16 through the inlet 41b. The dry air passing through the ion generator 16 carries the ions generated by the ion generator 16 and flows out of the casing 41 through the outlet 41a.

The opening 44b of the fan case 44
And positive ions and negative ions are discharged into the room from the outlet 4 or the outlet 18 to remove bacteria floating in the room. Therefore, the indoor air is dehumidified, and the floating bacteria in the room harmful to the human body are removed by hydrogen peroxide and hydroxyl radicals, so that a comfortable living environment can be obtained.

When the air volume of the blower 11 is "quiet", the air volume adjusting plate 60 shown in FIG. 6 is at the position indicated by the solid line. As a result, the ratio of dry air flowing into the bypass passage 48 increases. When the air volume of the blower 11 is “strong”, the air volume adjusting plate 60 is at the position indicated by the broken line. As a result, the ratio of dry air flowing into the bypass passage 48 decreases. When the air volume of the blower 11 is “medium”, the air volume adjusting plate 60 is located between the position of the solid line and the position of the broken line.

Accordingly, the amount of dry air guided to the ion generator 16 is kept substantially constant regardless of the air volume of the blower 11. As a result, it is possible to prevent the disappearance of ions due to collision with a wall surface or the like due to an increase in the air flow, and to supply a stable amount of ions.

Next, when the clothes drying button 21 (see FIG. 3) is depressed, the compressor 5 is driven, and the blower 11 is driven with the air volume “medium”. Further, the stepping motor 34 of the wind direction adjusting device 17 is driven, and the wind direction is “upward stopped”.
Is set to In the clothes drying operation, the dehumidifying operation is continuously performed regardless of the state of room temperature or humidity.

At this time, as in the case of the dehumidifying operation, positive ions and negative ions are simultaneously generated by the ion generator 16 and are sent out indoors by dry air. Thereby, the floating bacteria in the room are removed. Also, when the clothes drying operation is performed with the air volume “strong”, the dehumidifying operation can be performed at the maximum air volume, and the clothes dried indoors can be efficiently dried.

When the emptying button 23 (see FIG. 3) is depressed, the compressor 5 is not driven, and the blower 11 is driven at the "medium" air volume. Further, the stepping motor 34 of the wind direction adjusting device 17 is driven, and the wind direction is set to “upward stop”. Then, ions are generated by the ion generator 16 and sent out into the room, and an air cleaning operation for circulating indoor air to remove floating bacteria is performed.

When the dehumidification operation, the clothing drying operation, and the air cleaning operation are stopped by operating the dehumidification button 22, the clothes drying button 21, and the air cleaning button 23, the operation stop processing shown in FIG. 20 is performed. In the operation stop processing, a pulse corresponding to a rotation angle of 110 ° is sent to the stepping motor 34 in step # 61, and the first vertical wind direction plate 30 starts rotating toward the first reference position A.

In step # 62, when the first vertical wind direction plate 30 reaches the first reference position A, the motor shaft 34a of the stepping motor 34 is not rotated by a subsequent pulse signal. As a result, the first vertical wind direction plate 30 stops at the first reference position A, the outlet 4 is closed, and the operation ends.

According to the present embodiment, the stopper piece 30h projecting from the shaft portion 30g of the first vertical wind direction plate 30 and the shaft portion 30
The first vertical wind direction plate 30 is positioned at the first and second reference positions A and B by abutting on both ends of the sector 4d formed around the hole 4b fitted with g.

Therefore, the first vertical wind direction plate 30 can independently reach the first and second reference positions A and B, respectively.
By setting the positions based on the second reference positions A and B as the start positions of the different swing ranges, the wind direction plate can be quickly moved to the start positions of the plurality of swing ranges, which is desired by the user. It is possible to quickly return to the swing range. In addition, there is no need to provide a detection sensor for detecting the position of the first vertical wind direction plate 30, and the cost and size of the dehumidifier 1 can be reduced. Note that the first and second reference positions A,
A position rotated by a predetermined angle from B may be set as a start position of the swing range.

Further, a pulse corresponding to an angle larger than the sum of the maximum rotation angle at which the first vertical wind direction plate 30 can be structurally rotated and the play angle of the bearing of the stepping motor 34 is transmitted to the stepping motor 34. The first vertical wind direction plate 30 can reliably reach the first reference position A or the second reference position B. Therefore, no deviation occurs in the swing position of the swing operation. In addition, when the operation such as the dehumidifying operation is stopped, the air outlet 4 is closed by the first vertical wind direction plate 30, so that the intrusion of dust from the air outlet 4 can be prevented.

Although the present embodiment describes the dehumidifier for operating the refrigerating cycle, the present invention may be applied to an air purifier for removing dust and airborne bacteria in the room and an air conditioner for adjusting the temperature in the room. Good. Also in this case, the same effect as that of the present embodiment can be obtained by providing the wind direction adjusting device of the present embodiment.

[0095]

According to the present invention, the wind direction plate has first and second reference positions that can be independently reached, and the first swing range swings by a predetermined angle from a position based on the first reference position. ,
Since the wind direction plate can be switched from the position based on the second reference position to the second swing range in which the wind direction plate swings by a predetermined angle, the wind direction plate can be quickly moved to the start positions of the plurality of swing ranges, It is possible to quickly return to the swing range desired by the user.

Further, according to the present invention, the positions at which the stopper pieces protruding from the support shaft supporting the wind direction plate abut against the stoppers formed around the shaft hole fitted to the support shaft are defined by the first and second positions. 2
Since the reference position is set, the first and second reference positions to which the wind direction plates can independently reach can be easily formed. Further, there is no need to provide a detection sensor for detecting the position of the wind direction plate, and the cost and size of the air conditioner can be reduced.

According to the present invention, a pulse corresponding to an angle larger than the sum of the maximum rotation angle at which the wind direction plate can structurally rotate and the play angle of the bearing of the stepping motor is transmitted to the stepping motor. Can reliably reach the first reference position or the second reference position. Therefore, no deviation occurs in the swing position of the swing operation.

According to the present invention, after the third swing range in which the wind direction plate swings from the first reference position to the second reference position,
Since the wind direction plate is switched to a stop state in which the wind direction plate stops at an arbitrary position, the wind direction plate can be easily stopped at an arbitrary position, for example, from a closed position of the air outlet to a fully opened position.

According to the present invention, the standard stop state, the second
Since the switching is performed in the order of the swing range, the first swing range, and the third swing range, it is possible to quickly switch to the standard stop state and the second swing range that are frequently used. In addition, since the reference position for starting the swing of the wind direction plate that swings in the third swing range is the first reference position, the reference position can be set during the standard stop state, which is frequently used, or during the swing in the second swing range. Switching to the third swing range reduces the number of pulse signals remaining after arriving at the reference position and shortens the time of stopping at the reference position as compared with the case where the second reference position is set as the reference position, so that smooth movement is achieved. Can be obtained.

Further, according to the present invention, when the operation is stopped, the air outlet is closed by the air flow irrespective of the operation of the air flow louver, so that the intrusion of dust from the air outlet can be prevented.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a front surface of a dehumidifier according to an embodiment of the present invention.

FIG. 2 is a perspective view showing a back surface of the dehumidifier according to the embodiment of the present invention.

FIG. 3 is a diagram showing an operation panel of the dehumidifier according to the embodiment of the present invention.

FIG. 4 is a side view showing the internal structure of the dehumidifier according to the embodiment of the present invention.

FIG. 5 is a side sectional view showing an upper portion of the dehumidifier according to the embodiment of the present invention.

FIG. 6 is a rear view showing the structure of the upper part of the dehumidifier according to the embodiment of the present invention.

FIG. 7 is a top sectional view showing the structure of the upper part of the dehumidifier according to the embodiment of the present invention.

FIG. 8 is a sectional view showing an ion generator of the dehumidifier according to the embodiment of the present invention.

FIG. 9 is a top view showing the structure of the upper part of the dehumidifier according to the embodiment of the present invention.

FIG. 10 is an exploded view showing a wind direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 11 is a side sectional view showing an upper portion of the dehumidifier according to the embodiment of the present invention.

FIG. 12 is a side sectional view illustrating a state in which a first vertical wind direction plate of the dehumidifier according to the embodiment of the present invention rotates from a first reference position.

FIG. 13 is a flowchart showing an operation of starting the operation of the wind direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 14 is a flowchart illustrating the operation of the “upward” swinging process of the wind direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 15 is a side cross-sectional view illustrating a state where the swing direction of the first vertical wind direction plate of the dehumidifier according to the embodiment of the present invention is “up”.

FIG. 16 is a flowchart illustrating an operation of a “rearward” swinging process of the wind direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 17 is a side sectional view illustrating a state where the swing direction of the first vertical wind direction plate of the dehumidifier according to the embodiment of the present invention is “rearward”.

FIG. 18 is a flowchart illustrating an operation of “wide-angle” swing processing of the airflow direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 19 is a flowchart showing an operation of a swing “off” process of the wind direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 20 is a flowchart showing an operation of stopping the operation of the wind direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 21 is a block diagram illustrating a configuration of a wind direction adjusting device of the dehumidifier according to the embodiment of the present invention.

FIG. 22 is a schematic configuration diagram showing a conventional air conditioner.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Dehumidifier 2 Front frame 3 Rear frame 4 Outlet 5 Compressor 6 Tank 7 Filter 8 Evaporator 9 Condenser 10 Handle 11 Blower 12 Exhaust unit 13 Operation panel 14 Viewing window 15 Suction port 16 Ion generator 17 Wind direction adjusting device 18 Air outlet 19 Drain pan 21 Empty button 22 Dehumidification button 23 Clothes drying button 24 Dehumidification switching button 25 Air volume switching button 27 Swing button 28 Timer switching button 29 Display panel 30 First vertical wind panel 31 Second vertical wind panel 33 Horizontal wind panel 34 Stepping Motor 41 Casing 42 Duct 44 Fan case 45 Protective plate 48 Bypass passage 49 Lamp 50 Dielectric 51 Inner electrode 52 Outer electrode 60 Airflow adjusting plate 61 Opening 70 Humidity sensor 71 Control unit

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Morikawa Mamoru Inventor 22-22, Nagaike-cho, Abeno-ku, Osaka City, Osaka F-term (reference) 3L060 AA05 DD05 DD07 EE05 3L081 AA02 AB03 FA07 FC04 HA01 HB02

Claims (6)

[The claims] 1. An air conditioner in which the wind direction of air sent from an air outlet is changed by a wind direction plate capable of swinging, wherein the wind direction plates have first and second reference positions that can be independently reached. A first swing range in which the wind direction plate swings by a predetermined angle from a position based on the first reference position, and a second swing range in which the wind direction plate swings by a predetermined angle from a position based on the second reference position. An air conditioner characterized by the following. 2. A position where a stopper piece protruding from a support shaft supporting the wind direction plate abuts a stopper formed around a shaft hole fitted to the support shaft, as first and second reference positions. The air conditioner according to claim 1, wherein the air conditioner is located. 3. The stepping motor driven by a pulse-controlled stepping motor drives the airflow direction plate, and a pulse corresponding to an angle larger than the sum of a maximum rotation angle of the airflow direction plate and a play angle of a bearing of the stepping motor is applied to the stepping motor. The air conditioner according to claim 1 or 2, wherein the wind direction plate is transmitted to a motor to reach the first reference position or the second reference position. 4. A first and second swing range, a third swing range in which the wind direction plate swings from a first reference position to a second reference position, and a stopped state in which the wind direction plate stops at an arbitrary position. The air conditioner according to any one of claims 1 to 3, wherein the air conditioner is configured to be able to be sequentially switched, and to be switched to the stop state after the third swing range. 5. A standard stop state in which the wind direction plate stops at a second reference position, a second swing range, a first swing range, and a third swing range. The air conditioner according to claim 4, wherein a reference position at which the swinging wind direction plate starts to swing is a first reference position. 6. The air outlet according to claim 1, wherein, when the operation of the air conditioner is stopped, the air outlet is closed by the wind direction plate regardless of an operation state of the air direction plate. The air conditioner according to item 1.