JP2002286240A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner, in which miscellaneous germs and mold adhered on respective devices in the inside are positively reduced or sterilized, and their propagation is suppressed by spreading ozone from an ozone generator provided in an indoor unit. SOLUTION: The indoor unit 3 has a front opening 24, a suction port of an upside inlet 25, and an outlet 26, and is provided with a fan 10, and a heat exchanger 8. An ozone generator 52 is provided in the indoor unit 3. A communication path 38 is provided in the indoor unit 3, thus the outlet 26, the front opening 24, and the suction port of the upside inlet 25 can communicate with each other without passing through the heat exchanger 8. A damper 36 is provided to open/close the communication port 35 of the communication path 38.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner which prevents the growth of various bacteria and fungi in an indoor unit.

[0002]

2. Description of the Related Art As is well known, an air conditioner including an outdoor unit and an indoor unit exchanges heat between an indoor heat exchanger provided inside the indoor unit and indoor air. An indoor fan is provided to promote the air, the indoor air is sucked into the indoor unit by the indoor fan, the sucked indoor air is sent to the indoor heat exchanger to exchange heat, and the air after the heat exchange is blown back into the room. I have.

[0003] Therefore, the indoor unit is sucked into the indoor unit together with the indoor air, and dirt and dust easily adhere to an indoor fan and an indoor heat exchanger provided inside the indoor unit and inside the indoor unit. There is a problem that germs and fungi contained in the dust and dust will propagate. In particular, after the cooling operation is stopped, the condensed water condensed in the indoor heat exchanger evaporates in the indoor unit and the humidity inside the indoor unit increases,
There is a problem that germs and fungi increase in number.

[0004] When these germs and mold proliferate, there is a possibility that an odor is generated during operation of the air conditioner, and spores of these germs and mold are blown out into the room.
Not hygienic. In addition, when the fungus attached to the indoor heat exchanger or the indoor fan propagates, there is a risk that the resistance of the ventilation path may be reduced, and the air volume of the indoor fan may be reduced, leading to a decrease in the performance of the air conditioner.

[0005] In such a situation, there is known an air conditioner in which an ozone generator is provided in an indoor unit to increase the ozone concentration in the indoor unit, thereby preventing the propagation of various bacteria and fungi.

Therefore, when an ozone generator is provided in an indoor unit of a general air conditioner to generate ozone, the generated ozone is filled in the indoor unit only by stopping near the ozone generator. Problem was not found in the whole. Bacteria and fungi in the indoor unit adhere to and propagate on equipment such as indoor heat exchangers, drain pans, and indoor fans, so if they remain near the ozone generator, only the equipment near the ozone generator can be used. It was not possible to prevent the growth of various bacteria and fungi, and it was insufficient to sterilize and sterilize the entire interior of the indoor unit to prevent the growth of various bacteria and fungi.

[0007]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to transfer ozone from an ozone generator provided in an indoor unit to the interior of the indoor unit. It is an object of the present invention to provide an air conditioner which can be spread all over, and which can surely sterilize and sterilize germs and molds attached to respective internal device parts to reduce the germ and mold propagation.

[0008]

An air conditioner according to the present invention comprises:
An air conditioner having an air outlet, an air inlet, and an indoor unit that houses an indoor fan and an indoor heat exchanger therein, wherein the ozone generator provided in the indoor unit, the air outlet and the air inlet And a communication passage that communicates the air without passing through the indoor heat exchanger, and an opening and closing mechanism that opens and closes the communication passage. A control device for performing a clean operation of closing the air outlet louver and opening the opening / closing mechanism and operating the ozone generator and the indoor fan while the refrigeration cycle of the air conditioner is stopped. The ozone generator is further provided on one side of the air conditioner, and the communication passage is provided with the ozone generator. The indoor unit further includes a left and right louver for changing the left and right wind direction at the air outlet, and a left and right louver drive device for driving the left and right louvers. At the time of opening, the direction of the left and right louvers is directed to the communication passage side so that the ventilation from the ozone generator side is directed to the communication passage side by the left and right louver drive device, and the indoor unit further comprises: Further, the apparatus has a suction port opening / closing mechanism for opening / closing the suction port, wherein the control device operates the suction port opening / closing mechanism during a clean operation to close the suction port. The control device performs a drying operation of the indoor heat exchanger before the clean operation, and the indoor unit further generates negative ions. A negative ion generator, wherein the control device operates the negative ion generator during a clean operation, and the ozone generator also serves as a discharge electrode of an electric dust collector. Further, the power supply of the electrostatic precipitator can output a voltage in two stages, supplies a high voltage output to the discharge electrode when ozone is generated, and is lower than the high voltage output during the dust collection operation. It is characterized by supplying a low voltage output to the discharge electrode, and further, after the cooling operation,
It is characterized by providing an automatic mode for performing a dry operation and then performing a clean operation, and further,
The air conditioner further includes a remote control device, by the remote control device, after the cooling operation is completed, a drying operation is performed, and then an automatic mode for sequentially performing a clean operation,
After the cooling operation is completed, a drying mode in which only the drying operation is performed, and a non-clean mode in which neither the drying operation nor the clean operation is performed after the cooling operation is performed, further comprising: The indoor unit is characterized in that the air generated by the indoor fan is arranged so as to flow in the order of the ozone generator, the indoor heat exchanger, the indoor fan, and the communication passage. It is characterized by having a fan drive control device driven at low speed rotation, and further,
The air conditioner has an indoor heat exchanger divided into two and a decompression device provided between the indoor heat exchangers, and a drying operation controls the decompression device to control one of the indoor heat exchangers. Is an evaporator and the other is a condenser, and the indoor fan is driven at a low speed.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Before describing one embodiment of the present invention, considerations leading to the present invention will be described. That is, the propagation of various bacteria and fungi is greatly affected by the temperature and humidity conditions, and it is known that they reproduce best especially in a high-temperature and high-humidity state. On the other hand, in the air conditioner, after the cooling operation is completed, drain water attached to the indoor heat exchanger inside the indoor unit evaporates, and the humidity inside the indoor unit may reach nearly 100%. Further, since the temperature is high when the cooling operation is performed, it is considered that various germs and mold grow best after the cooling operation is stopped.

Therefore, it is very effective to perform a drying operation for drying the inside of the indoor unit after the cooling operation is completed, in order to suppress the propagation of various bacteria and fungi. For this reason, if the drying operation inside the indoor unit is performed immediately after the end of the cooling operation, and sterilization and sterilization with ozone are performed, propagation of various bacteria and fungi can be significantly suppressed.

Further, when the ozone generator is installed in the indoor unit, the ozone generated simply by closing the indoor unit stops in the vicinity of the ozone generator and does not spread throughout the indoor unit. It is effective to move the air inside. At this time, if ozone leaks from the indoor unit into the air-conditioned room, it is not preferable because of the problem of odor and the like. Therefore, if air is circulated in the indoor unit,
This is effective in suppressing the growth of various bacteria and fungi and preventing leakage of ozone into the room.

Further, regarding the ozone generator,
When a high voltage is applied to the discharge electrode of the electrostatic precipitator to cause normal dust collection, ozone is generated due to the discharge at the discharge electrode.The electric precipitator functions as an ozone generator by also using the discharge electrode. Can be done. Also,
When a high voltage is applied to the discharge electrode of the electric precipitator so that the potential difference between the discharge electrode and the precipitator becomes larger than that at the time of precipitating, more ozone is generated. For this reason, by providing an electric dust collector in the indoor unit, the electric dust collector is subjected to a normal dust collection operation, and the electric power is applied to the discharge electrodes while the indoor fan is stopped or at a low speed to restrict the movement of the surrounding air. By applying a higher voltage from a high-voltage power supply whose voltage can be changed, an ozone generator that generates a large amount of ozone can be provided.

The present invention has been made based on the above considerations, and an embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is an AB of the indoor unit in FIG.
FIG. 2 is a cross-sectional view in the direction of the arrow, FIG. 2 is a cross-sectional view of the indoor unit in the direction of the arrow A-C in FIG. 3, FIG. 3 is a front view of the indoor unit, FIG. FIG. 5 is a view showing a remote controller, FIG. 5 (a) is a plan view, FIG. 5 (b) is a view showing switching contents by a menu button, FIG. 6 is a flowchart of basic control, FIG.
8 is a flowchart at the time of a drying operation process, FIG. 8 is a flowchart at the time of a clean operation process, and FIG. 9 is a diagram showing a list of operation states of respective units in each operation mode.

In FIG. 4, the air conditioner 1 is composed of an outdoor unit 2 installed outdoors O and an indoor unit 3 installed inside a room R for air conditioning. The compressor 4, the four-way valve 5, the outdoor heat exchanger 6, the outdoor expansion valve 7 which is an electric expansion valve whose opening can be controlled finely, and the indoor heat exchanger 8 provided in the indoor unit 3 form a refrigeration cycle. The room R in which the indoor unit 3 is installed can be cooled and heated by switching the flow direction of the refrigerant by the four-way valve 5. The outdoor unit 2 has a variable speed outdoor fan 9 for promoting heat exchange of the outdoor heat exchanger 6, and the indoor unit 3 has a variable speed cross flow fan for promoting heat exchange of the indoor heat exchanger 8. A fan 10 is provided.

An inverter 11 is connected to the compressor 4 so as to make the operating frequency variable, and is connected to an AC power supply 12 via a main switch 13. And
During cooling and heating operations, the inverter 1
1 is controlled according to the indoor temperature load (the difference between the room temperature of the room R and the set temperature), and the opening degree of the outdoor expansion valve 7 which is an electric expansion valve is controlled according to the refrigeration cycle state. I have. Although not shown, necessary power supply from the AC power supply 12 can be performed to each unit of the outdoor unit 2 and the indoor unit 3.

The indoor heat exchanger 8 is divided into a rear heat exchange section 8a and a front heat exchange section 8b as shown in FIG. 1, and the rear heat exchange section 8a and the front heat exchange section 8b are connected to each other. It is connected via an indoor throttle valve 14, which is a throttled two-way valve, so that the flow of refrigerant between the two parts can be controlled.
The throttled two-way valve of the indoor throttle valve 14 used here is a valve whose opening degree can be operated by electric control, and is fully opened in an open state (when OFF: no throttle). In a heating operation or a heating operation, it can be controlled to the fully opened state, and in a closed state (ON: with a throttle), for example, in a drying operation or a dehumidifying operation described later, it can be controlled to a state having an appropriate throttle area. It has become.

For this reason, during the drying operation and the dehumidifying operation,
The indoor expansion valve 14 is closed with a throttle, and the outdoor expansion valve 7 between the outdoor heat exchanger 6 and the front heat exchange section 8b is fully opened, so that the front heat exchange section 8b is a condenser (reheater). And none
The rear heat exchanger 8a can function as an evaporator, and the air sucked into the indoor unit 3 is warmed by the front heat exchanger 8b and cooled by the rear heat exchanger 8a. On the other hand, the rear heat exchanger at low temperature can be dehumidified at 8a. In addition, by setting the opening degree (throttle amount) of the indoor throttle valve 14 during the dehumidifying operation and appropriately controlling the blowing amount of the outdoor fan 9 and the rotation speed of the compressor 4, the air blown from the indoor unit 3 can be reduced. The temperature can be adjusted finely.

The units 2 and 3 are provided with an outdoor control unit 15 and an indoor control unit 16, respectively, for operating the refrigeration cycle in accordance with the basic control flowchart shown in FIG. The two control units 15 and 16 are connected by a connection line 17. The required control signals and data are exchanged via the connection line 17 in both control units 1.
The operation is performed between the control units 15 and 16, and the operation of each unit in the units 2 and 3 connected to the control units 15 and 16 is performed.

The indoor control unit 16 includes the indoor unit 3.
An operation start or operation end command by an infrared signal transmitted from a wireless remote controller (hereinafter, referred to as a remote control) 18 provided outside, a room temperature, an air volume, a wind direction, and other settings related to operation set by a user. A transmitting / receiving unit 19 for receiving contents and the like, and a temperature sensor 20 including a thermistor for detecting the room temperature and humidity of the room R to be air-conditioned,
A humidity sensor 21 made of ceramic is connected. It should be noted that the remote controller 18 is transmitted with the room temperature, the driving status, and the like from the transmission / reception unit 18 and displays the contents.

On the other hand, the indoor unit 3 is installed on a wall Q near the ceiling of a room R for performing air conditioning as shown in FIGS. 1 and 2, and is connected to the outdoor unit 2 through a wall opening P formed in the wall Q. Are connected by a refrigerant pipe 22 provided with a connection line 17. The indoor unit 3 has a front opening 24 that can be opened and closed by a front panel 23, and also has a main body of a horizontally long housing in which an upper intake port 25 that opens upward at an upper part and an outlet 26 that opens downward at a lower part are formed. Inside the case 27, an indoor fan 10 for driving a horizontally long transverse flow blade 28 whose longitudinal direction is the axial direction by an indoor motor 29 is provided. As the indoor motor 29, a DC motor that can switch the speed in a plurality of stages, has high efficiency, and has high stability even at a low speed is used, but an AC motor may be used.

Further, inside the main body case 27 of the indoor unit 3, the front opening 24 and the upper suction port 25 are connected to the air outlet 26.
Toward the main flow path 30 of the air by the indoor fan 10.
Are formed. In the main passage 30, an indoor heat exchanger 8 is provided upstream of the indoor fan 10, and a front heat exchange section 8 is provided.
b is opposed to the front opening 24, and the rear heat exchange part 8 a is arranged so as to be connected to the upper part of the front heat exchange part 8 b so as to oppose the upper rear part of the main body case 27. At this time, the front heat exchange section 8 formed in an arc shape
b is such that the lower edge is located in the front drain pan 32 provided in the partition member 31 constituting the lower front wall portion of the main flow path 30 with the convex side facing forward, and the rear heat exchange Part 8a
Is provided such that the lower edge is located in a rear drain pan 34 provided on a back plate 33 constituting a rear wall portion of the main flow path 30. In addition, a temperature sensor 20 is provided in a main passage 30 between the front opening 24 serving as a suction port of the air in the room R of the indoor unit 3 and the upper suction port 25 and the front heat exchanger 8b.
And a humidity sensor 21 are provided.

The partition member 31 provided to extend in the longitudinal direction of the main body case 27 is connected to the upstream side and the downstream side of the indoor heat exchanger 8, that is, the front opening 24 and the suction port portion of the upper suction port 25. The outlet 26 is separated from the outlet. The partition member 31 has a communication opening 35 formed on one side, for example, on the left side when viewed from the front opening 24 side of the indoor unit 3, having a length approximately half that of the communication opening 35. Is mounted so that the damper 36 can be opened and closed by a driving mechanism having a damper motor 37. Thereby, the indoor unit 3 that does not pass through the indoor fan 10 and the indoor heat exchanger 8 from the outlet of the outlet 26 to the inlet of the upper inlet 25 and the upper inlet 25 by opening the damper 36.
An internal communication passage 38 is formed.

The front panel 23 which opens and closes the front opening 24 is moved forward and backward by a panel motor 39, for example, by a panel driving mechanism 41 having a rack and pinion gear member 40, to perform opening and closing operations. ing. During the cooling, heating operation, dehumidifying operation, and drying operation, the front panel 23 is advanced, and in this advanced state, the front opening 24 is opened to form a suction port,
Indoor air is drawn into the indoor unit 3. In addition, the front panel 23 is retracted during a clean operation or a stop which will be described later. In this retracted state, the front opening 24 is closed to prevent dirt and dust from entering the indoor unit 3.

The upper suction port 25 has an upper suction louver 42.
The upper suction port 25 is rotatable by an upper louver motor 43. By rotating the upper suction louver 42, the upper suction port 25 can be opened and closed. Then, the upper suction louver 42 opens and rotates at the time of cooling, heating operation or dehumidifying operation,
The indoor air is sucked into the indoor unit 3 from the upper suction port 25, and when the drying operation, the clean operation or the stop is performed, the indoor air is closed and the upper suction port 25 is closed, so that dust and dirt enter the indoor unit 3. Is to be prevented.

On the other hand, a rear outlet louver 44a and a front outlet louver 44b, which are also formed in the outlet 26 and which are elongated in the left-right direction and whose left and right ends are pivotally supported, are driven by a rear louver motor 45a and a front louver motor 45b. The air outlet 26 can be opened and closed by rotating the rear blowout louver 44a and the front blowout louver 44b, respectively. Each of the motors 45a and 45b can be operated individually, and each of the blowout louvers 4
By independently rotating and opening and closing the air conditioners 4a and 44b in accordance with the operation mode of the air conditioner 1, the blowing direction of the conditioned air into the room R can be changed in the vertical direction. And
By closing and rotating both of the outlet louvers 44a and 44b, the outlet 26 is closed.

The closing position X at which the outlet 26 is closed
The two outlet louvers 44a and 44b, which have been in the positions a and Xb, are adjusted to the operation mode of the air conditioner 1, and for example, the rear outlet louvers 4
4a, the opening angle can be changed to the diagonally downward position Ya and the diagonally downward position Za, and the front blowout louver 44b can be changed to the horizontal slightly upward position Yb and the diagonally downward position Zb, and further to an intermediate position between them. . By changing the opening angle of both blowout louvers 44a and 44b depending on the operation mode, the blowout direction of the conditioned air from the indoor unit 3 into the room R can be set to a desired direction.

Further, the two outlet louvers 4 are provided at the outlet 26.
In the vicinity of the upstream side of 4a, 44b, a left and right louver 46 is provided so that the upper edge thereof is pivotally supported by the support member 47, and is rotated by a left and right louver motor 48 in the left and right direction. Thus, the blowing direction of the conditioned air into the room R can be changed.

The indoor unit 3 has a front opening 24.
An electric precipitator 49 having a width approximately half the width of the front heat exchange unit 8b is attached to the front heat exchange unit 8b of the indoor heat exchanger 8 at a position on the upper right side of the front surface when viewed from the side. The electric precipitator 49 has a discharge electrode 50a inside.
And a relatively high negative first high voltage _VH1 and a lower negative second high voltage _VH1 .
Between the discharge electrode 50a and the dust collection electrode 50b from the first high-voltage power supply 51 that generates the high voltage _VH2 of the first and second high voltages _VH1 and _VH2. I have.

[0029] The electrostatic precipitator 49, when operating as an ozone generator 52 is discharged by applying a first high voltage V _H1 to the discharge electrode 50a, to generate ozone. When the dust collecting operation is performed, the second high voltage _VH2 is applied between the discharge electrode 50a and the dust collecting electrode 50b. That is, the potential difference between the discharge electrode 50a and the dust collection electrode 50b is larger when ozone is generated than when it is collected. The voltage applied to the discharge electrode 50a may be the same when functioning as an electric dust collector and when functioning as an ozone generator.

Further, the indoor unit 3 has a main passage 3
Front opening 2 of partition member 31 constituting lower front wall portion 0
A negative ion generator 53 is attached to a wall surface facing the main flow path 30 on the right side as viewed from the fourth side.
The negative ion generator 53 includes a metal needle 54 having both ends sharp, and a second high-voltage power supply 55 for applying a predetermined negative high voltage _VH to the needle 54.
Is installed such that one needle point is directed from the air outlet 26 into the room R, and the other needle point is directed toward the indoor fan 10 inside the indoor unit 3.

When a predetermined negative high voltage _VH is applied to the needle 54 from the second high voltage power supply 55, the tip of the needle 54 emits negative ions in the direction of directing negative ions. . For this reason, during normal cooling and heating operations,
During the dehumidifying operation, negative ions are emitted toward the room R from the tip of the needle 54 on the outlet 26 side together with the conditioned air sent out by the indoor fan 10. At the time of the clean operation, negative ions are emitted toward the interior of the indoor unit 3 from the tip of the needle 54 on the indoor fan 10 side, so that fungi and various germs inside the indoor unit 3 are sterilized and sterilized.

On the other hand, the outdoor control unit 15 and the indoor control unit 16 provided in the outdoor unit 2 and the indoor unit 3 include:
Microcomputers (CP.
U) are provided, and C.I. P. The operation control described below is executed based on the contents preprogrammed in U or the contents set prior to the operation.

[0033] That is, the basic control operation performed by the outdoor control unit 15 and the indoor control unit 16, along a diagram illustrating an operation state of each part of the flow chart and 9 of Figure 6, first, in a first step S _1, Main body 1 of remote controller 18 in FIG.
The lid 18b which covers a part of 8a is opened, and an operation switching button 56 for selecting cooling, heating, dehumidification or automatic operation, a dehumidification button 57, a temperature button 58 for setting room temperature, and the like are displayed on the display unit 18c such as a liquid crystal display. The operation is performed while viewing the contents thus selected, and a desired operation mode is selected in the same manner as in a known air conditioner.

Further, by operating the menu button 59, FIG.
As shown in (b), the selection and setting of an operation mode to be described later, which is performed after the cooling operation and the dehumidifying operation that are cyclically switched every time the button is operated, are performed. The operation mode set here is an automatic clean mode in which the drying operation and the clean operation are combined, a drying mode in which only the drying operation is performed, and three modes without the selection mode. A desired selection is made while looking at the contents that have been set. When this operation mode switching is performed,
The selected operation mode is continuously displayed on the display unit 18c for a predetermined time, for example, 10 seconds, thereby facilitating confirmation by the user.

Then, the operation button 60 for starting and stopping the operation of the air conditioner 1 is operated, the main switch 13 is closed, the power is turned on, and the operation is started. When operating the negative ion generator 53 during normal cooling and heating operations, the air cleaning button 61 is operated as needed.

[0036] Subsequently, in the second step S _2, the operation mode is set to determine what the third cooling operation control in step S _3, if the cooling mode, and the fourth step S if the heating mode ₄ of the heating operation control, a dehumidifying operation control of the fifth step S ₅ if dehumidification mode, similarly to each omitted known air conditioner, as the operating state showing the respective portions in FIG. 9 deeds, in the sixth step S whether the operation has been completed in ₆ judgment is performed until done confirmation of the operation end. Then, the process proceeds to a seventh step S ₇ When the operation end is confirmed in the sixth step S _6.

[0037] Then at the seventh step S _7, immediately before the operation mode of whether the determination is made was a mode cooling or dehumidifying operation, if it is judged that not the cooling and dehumidifying operation, the eighth step proceeds to S _8, performs the operation end process is controlled in the stopped state shown each part in FIG. Also in the seventh step S _7, when it is determined that a cooling or dehumidifying operation, the process proceeds to a ninth step S _9.

[0038] Then, in a ninth step S _9, the cooling operation which is set in advance at the start of operation, the operation mode setting after the dehumidifying operation, an automatic clean mode, dry mode, the line determination of whether a no selection mode Will be And if an automatic clean mode, the drying operation processing in the tenth step S _10, and further executes the cleaning operation processing in the eleventh step S _11, the process proceeds to an eighth step S ₈ after completion,
Operation end processing is performed. Further, when a drying mode, executes the drying operation process in the twelfth step S _12, the process proceeds to an eighth step S ₈ also after completed, the operation end process. Further, when it is no more selection mode, it proceeds to an eighth step S _8, performs the operation end process.

Since the basic control as described above is performed, the air conditioner 1 can perform normal cooling operation, heating operation,
In addition to performing the dehumidifying operation, a drying operation process and a clean operation process as described below can be performed after the cooling operation or the dehumidifying operation by selecting and setting an operation mode in advance. In addition, since such an operation mode can be selected and set without selection, there is anxiety that the operation of the dry operation process and the clean operation process is continuously performed even after the operation is stopped. Depending on the case, it can be selected that these processes are not performed.

First, the control in the operation mode of the drying operation process performed after the cooling operation or the dehumidifying operation is performed according to the flowchart of FIG. 7 and the operation state of each part of FIG. First, in the first step T _1, set to an operating state in the drying operation showing the various parts in Fig. That is, the compressor 4 is fixed at a low speed to reduce the refrigerating capacity, the outdoor fan 9 is fixed at a low speed or a switching operation between low speed and stop, and the indoor fan 10 is fixed at an extremely low speed lower than that during the dehumidifying operation. The indoor throttle valve 14 is in a closed state with a throttle, the outdoor expansion valve 7 is in an open state, and the four-way valve 5 is in a position for cooling.

The upper suction louver 42 of the indoor unit 3 is closed and rotated, the front panel 23 is opened, the front blowout louver 44b is in the horizontal slightly upward position Yb, and the rear blowout louver 44a.
To the closed position Xa. Further, the damper 36 is closed,
The indoor air sucked into the indoor unit 3 through the front opening 24 in which the front panel 23 is in the open state flows through the main passage 30 and passes through the indoor heat exchanger 8 and the indoor fan 1. The air is blown slightly upward from the air outlet 26, flows near the indoor unit 3, and is immediately sucked into the indoor unit 3 again. Note that the electrostatic precipitator 49 may be operated as an ozone generator 52 to apply a first high voltage V _H1 to the discharge electrode 50a in the ON state, or in the OFF state. Further, the negative ion generator 53 may be in an ON state or an OFF state.

Next in the second step _{T 2,} the humidity sensor 21
To measure the humidity Ha of the room air flowing into the main passage 30 upstream of the front heat exchange section 8b. Then, in the subsequent third step _{T 3,} when the humidity Ha is more than 70% and sets the timer (not shown) in the fourth step _{T 4} to 10 minutes.
Also, when the humidity Ha is 40% or more lower than 70% sets the timer to 8 minutes in the fifth step _{T 5.} Furthermore, when the humidity Ha is lower than 40% sets the timer for 5 minutes in a sixth step T _6.

[0043] Thereafter, in a seventh step T _7, to start the drying operation with a timer is started, the time which is set in correspondence to the humidity Ha, continue to operate. And in the eighth step T ₈ performs a predetermined time elapsed is determined whether to terminate the drying operation proceeds to a ninth step T ₉ when a predetermined time has elapsed, based on a preset content,
Cleaning operation processing of the 11 step _{S 11} in the basic control flowchart of FIG. 6 or the eighth step _{S 8,}
The processing shifts to the control contents of the operation end processing of.

The drying operation is a kind of dehumidification operation, and is performed by cooling or dehumidification operation.
A large amount of drain water generated inside is discharged outside through a drain hose (not shown), but a part of the drain water remains in the front drain pan 32 and the rear drain pan 34 even after the cooling or dehumidifying operation is completed, or the indoor heat is discharged. After the cooling and dehumidifying operation is completed, the temperature rises in the indoor unit 3 due to the intruded indoor air, and the drain water starts to evaporate at once, and the humidity inside the indoor unit 3 becomes 100 as it is. %, So that it is carried out in order to eliminate this, and to prevent a breeding environment of high temperature and humidity which is excellent for molds and various germs.

The above-mentioned drying operation is executed so that the high-temperature and high-humidity state inside the indoor unit 3 is quickly eliminated and the high-temperature and high-humidity air does not reach the user. That is, as shown in FIG. 9, unlike the normal dehumidifying operation, the rotation speed of the compressor 4 is fixed at a low speed to lower the refrigerating capacity, the upper suction louver 42 is closed, and the rear heat exchange in which the indoor air is used as an evaporator. The indoor fan 10 is set to an extremely low speed, which is lower than that during the dehumidifying operation, so that the air flow through the indoor fan 10 is reduced as much as possible. Further, the rear blowout louver 44a is closed, only the front blowout louver 44b is opened, and the blowout air is sent to the living area in the room R without turning the front blowout louver 44b horizontally and slightly upward. Return, so-called short circuit operation.

Further, the outdoor fan 9 is maintained at a low speed fixed state or in a switching state between a low speed and a stop, and the temperature of the air flowing through the indoor unit 3 is raised by raising the temperature of the front heat exchange section 8b, and the air blown into the room R is increased. While increasing the temperature, the evaporation of the drain water inside the indoor unit 3 is accelerated, and the temperatures of the indoor fan 10, the outlet 26, and the various louvers 44a, 44b, 46 near the outlet 26 are increased to prevent dew condensation. ing. As a result, the water in the indoor unit evaporates rapidly, and the evaporated water in the indoor unit 3 is condensed by the short circuit in the rear heat exchange unit 8a (evaporator).
They are collected as drain water.

The time of the drying operation is determined based on the humidity H in the room R at the end of the cooling and dehumidifying operations at the start of the operation.
a (the humidity detected by the humidity sensor) is changed in direct proportion. When the cooling and dehumidifying operations are finished in a high humidity state, for example, 10 minutes in a high state, 8 minutes in an intermediate state, and 8 minutes in a low state 5 minutes is set. However, each of these times may be changed depending on the capacity of the air conditioner 1 or the like. Further, since the drying operation time is changed in proportion to the humidity Ha, a long-time drying operation is performed when the amount of residual water in the indoor unit 3 is large, and a short-time drying operation is performed when the remaining water amount is small. An appropriate drying operation is performed according to the situation.

In the drying operation, the electric dust collector 49 and the negative ion generator 53 may be turned on or off from the viewpoint of drying the interior of the indoor unit 3, but it is desirable to turn them on if possible. If it is turned on in this state, the ozone generated from the electrostatic precipitator 49 and the negative ions from the negative ion generator 53 are short-circuited on the blown air and sucked into the indoor unit 3 again. Negative ions pass through each part in the indoor unit 3 and can sterilize and sterilize molds and various germs to a small extent.

As described above, in the above-described drying operation, the indoor heat exchanger 8 is divided into two, and one rear heat exchange section 8a acts on the evaporator and the other front heat exchange section 8b acts on the condenser. Let
By suppressing the wind speed of the indoor fan 10 and preventing as much as possible the new indoor air from being sucked into the interior of the indoor unit 3, the water inside the indoor unit 3 is evaporated, which is removed by the evaporator and drained outside the room. Thus, the humidity inside the indoor unit 3 can be reduced efficiently and in a short time. Furthermore, in this operation, since the air blown into the room R is mixed with the air passed through the evaporator and the air passed through the condenser, the temperature becomes relatively low and the temperature becomes moderate, and a part of the blown air is discharged. Even if the water flows out to the living area side, the user hardly feels any discomfort, and there is little risk of increasing the humidity Ha in the room R.

When the automatic clean mode is set after the cooling operation or the dehumidification operation as the operation mode, the control in the operation mode of the clean operation process performed after the drying operation process is performed by the operation of the flowchart in FIG. This is performed according to the state diagram. First, the first step U
_{In step 1} , each part is set to be in the operation state in the drying operation shown in FIG. That is, the compressor 4 and the outdoor fan 9
Is stopped, the indoor fan 10 is fixed at an extremely low speed lower than that during the dehumidifying operation, the outdoor expansion valve 7 and the indoor throttle valve 14 are opened, and the four-way valve 5 is set to a position for cooling.

The upper suction louver 42 of the indoor unit 3 is closed and rotated, the front panel 23 is also closed, and both the rear blowout louvers 44a and the front blowout louvers 44b are set to the closed positions Xa and Xb. Further, the left and right louvers 46 are rotated so that the front end portion thereof is on the left side when viewed from the front opening 24 side,
The flow by the indoor fan 10 is deflected to the left. In addition, the damper 36 communicates the main flow path 30 near the outlet 26 with the communication path 38 formed on the back surface side of the front panel 23 through the communication opening 35 that is opened to allow the flow.

As a result, in the indoor unit 3, from the main flow path 30 in which the indoor fan 10 is disposed, to the communication opening 35 through the vicinity of the negative ion generator 53, further through the communication path 38, and to the electric precipitator 49. (Ozone generator 5
The main flow path 3 in the upstream part of the indoor heat exchanger 8 in which 2) is arranged
A circulation path leading to the indoor fan 10 through 0 is formed. In the indoor unit 3, the indoor fan 10 flows from the indoor fan 10 through the main passage 30 in the direction of the air outlet 26 to the communication opening 35 as shown by the white dotted arrow in FIG. As shown by the solid arrow, the communication opening 3
5 through the communication passage 38, the electric precipitator 49 (the ozone generator 52), the indoor heat exchanger 8, and the indoor fan 1
A very low-speed circulating flow of air in the indoor unit 3 flowing to zero occurs. The electric precipitator 49 is ON.
In this state, the first high voltage _VH1 is applied to the discharge electrode 50a to operate as the ozone generator 52, and the negative ion generator 53 is also turned on.

Next in the second step _{U 2,} make settings for 10 minutes of the timer (not shown), a timer is started in the third step _{U 3.} Then, in the fourth step U ₄ performs predetermined time elapsed is determined whether to terminate the cleaning operation proceeds to a fifth step U ₅ when a predetermined time has elapsed, controls the respective units in the stopped state shown in FIG. 9 I do.

Note that such a clean operation process is performed in order to reduce mold and various germs attached to each part in the indoor unit 3 by performing a cooling operation, a heating operation, and the like. For this purpose, the refrigeration cycle is stopped, the indoor fan 10 is set to an extremely low speed, and the air outlet 26 and the front opening 2 are opened.
4 and the upper suction port 25 are closed, and the indoor unit 3
The inside is kept closed, the damper 33 is opened, the left and right louvers 46 are deflected to the left, and an extremely low-speed air flow circulating in the indoor unit 3 is formed so as to draw an oblong circle in the diagonal direction. According to this flow, ozone generated by applying the first high voltage V _H1 to the discharge electrode 50a by the electrostatic precipitator 49 to generate ozone as the ozone generator 52, and negative ions generated by turning the negative ion generator 53 on. Is distributed throughout the indoor unit 3.

As a result, mold and germs attached to each part in the indoor unit 3 can be sterilized and sterilized satisfactorily, and the presence of ozone and negative ions at the same time makes it possible to achieve better results than when ozone is present alone. These can be effectively reduced. In this clean operation process, the front opening 24 of the air outlet 26 and the suction port and the upper suction port 25
Is closed, ozone does not leak into the room R, and no ozone odor is generated in the room R. At the same time, to prevent ozone leakage into the room R,
There is an effect that the ozone concentration in the indoor unit 3 can be increased.

In general, the size of an electric dust collector for purifying the same room can be about half the size of a heat exchanger determined by the cooling and heating capacity of an air conditioner. In this case, the size of the indoor heat exchanger may be substantially half that of the indoor heat exchanger. As a result, the concentration of ozone generated when the ozone generator is used increases on one side installed near the electrostatic precipitator and decreases on the other side.
Therefore, in the present embodiment, at the time of the clean operation processing, the ozone generated by forming the communication passage 38 in the indoor unit 3 and forming the circulation path of the air is uniformly distributed throughout the air, and the air is simply discharged. In the case of circulation, the time required to uniformly spread to the other side can be reduced in a short time, and the distribution of ozone concentration in the indoor unit 3 can be made uniform in a short time. ing.

In the above embodiment, the electrostatic precipitator 49 functions as the ozone generator 52 by changing the voltage applied to the discharge electrode 50a. However, the ozone generator 52 is provided independently. Well,
Further, during the drying operation process or the clean operation process, the upper suction louver 42 is provided so that the upper suction port 25 is closed. However, the upper suction louver 42 is not provided and the upper suction port 25 is opened. It may be left as it is, and in this case, although slightly inferior, it is possible to obtain the drying effect in the indoor unit 3, the sterilization of fungi and various bacteria, and the sterilization effect.

[0058]

As is apparent from the above description, according to the present invention, the operation state is switched so that the ozone from the ozone generator provided in the indoor unit is relatively short throughout the indoor unit. It can be spread over time, and it can surely sterilize and sterilize molds and germs attached to each part in the indoor unit, reduce its propagation, and give off odor due to the growth of molds and germs. It is possible to prevent the generation of the air-conditioning and to prevent the air-conditioning performance from being lowered due to a decrease in the air volume, and to achieve an effect that the conditioned air can be blown out in a hygienic manner.

[Brief description of the drawings]

FIG. 1 shows an indoor unit according to one embodiment of the present invention.
FIG. 4 is a cross-sectional view taken along line AB in FIG.

FIG. 2 shows an indoor unit according to one embodiment of the present invention.
FIG. 4 is a cross-sectional view taken along line A-C in FIG.

FIG. 3 is a front view of the indoor unit according to the embodiment of the present invention.

FIG. 4 is a control circuit diagram according to an embodiment of the present invention.

5A and 5B are diagrams showing a remote controller according to an embodiment of the present invention, FIG. 5A is a plan view, and FIG. 5B is a diagram showing switching contents by a menu button.

FIG. 6 is a flowchart of basic control according to an embodiment of the present invention.

FIG. 7 is a flowchart at the time of a drying operation process according to an embodiment of the present invention.

FIG. 8 is a flowchart at the time of a clean operation process according to an embodiment of the present invention.

FIG. 9 is a view showing a list of operation states of respective units in each operation mode according to the embodiment of the present invention.

[Explanation of symbols]

 3 indoor unit 8 indoor heat exchanger 8a rear heat exchange unit 8b front heat exchange unit 10 indoor fan 14 indoor throttle valve 16 indoor control unit 18 remote controller 23 front panel 24 front opening 25 ... Upper suction port 26 ... Blow-out port 35 ... Communication opening 36 ... Damper 37 ... Damper motor 38 ... Communication path 39 ... Panel motor 41 ... Panel drive mechanism 42 ... Upper suction louver 44a ... Rear blowing louver 44b ... Front blowing louver 45a ... Motor for rear louver 45b ... Motor for front louver 46 ... Left and right louver 49 ... Electric precipitator 50a ... Discharge electrode 52 ... Ozone generator 53 ... Negative ion generator

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) F24F 11/02 102 F24F 11/02 102H 4D054 104A 104 11/04 G 11/04 A61L 9/015 // A61L 9/015 F24F 1/00 371Z (72) Inventor Yoshinobu Fujita 336 Tatehara Carrier, Fuji City, Shizuoka Prefecture Inside (72) Inventor Katsuhiro Shimizu 336 Tatehara Carrier in Fuji City, Shizuoka Prefecture Toshiba Carrier Corporation (72) Invention Person Nobuyuki Takeya 336 Tatehara, Tatehara, Fuji City, Shizuoka Prefecture (72) Inventor Mitsuru Ishikawa 336 Tatehara, Fuji City, Shizuoka Prefecture Inside, Toshiba Carrier Corporation (72) Inventor Megumi Kumasaki 336 Tatehara, Fuji City, Shizuoka Prefecture Toshiba Carrier Co., Ltd. (72) Inventor Koji Wada 336 Tatehara, Fuji City, Shizuoka Prefecture Toshiba Carrier Rear F-term (reference) 3L050 BA10 3L051 BC01 BC02 BC10 3L060 AA05 CC17 DD07 DD08 EE01 3L061 BB01 BE02 BF08 4C080 AA07 BB05 HH02 MM08 QQ11 4D054 AA16 BA01 CA20 EA01 EA08 EA11 EA24 EA28

Claims (13)

[Claims] 1. An air conditioner having an air outlet, an air inlet, and an indoor unit that houses an indoor fan and an indoor heat exchanger therein, wherein the ozone generator provided in the indoor unit and the air outlet A communication passage that communicates the portion and the suction port portion without passing through the indoor heat exchanger;
An air conditioner comprising an opening and closing mechanism for opening and closing the communication passage. 2. The ozone generator further comprises an air outlet opening / closing louver for opening / closing the air outlet, closing the air outlet opening / closing louver and opening the opening / closing mechanism while the refrigeration cycle of the air conditioner is stopped. The air conditioner according to claim 1, further comprising a control device for performing a clean operation for operating the indoor fan. 3. The ozone generator is provided on one side of the air conditioner, the communication passage is provided on a side opposite to the ozone generator, and the indoor unit is provided with a blower. A left and right louver for changing left and right wind directions at an outlet, and a left and right louver drive device for driving the left and right louvers are provided. When the communication passage is open, the ventilation from the ozone generator side is performed by the left and right louver drive device. The air conditioner according to claim 2, wherein the left and right louvers are directed toward the communication passage so as to face the side. 4. The indoor unit further has a suction port opening / closing mechanism for opening / closing the suction port, and the control device operates the suction port opening / closing mechanism during a clean operation to close the suction port. The air conditioner according to any one of claims 1 to 3, wherein: 5. The air conditioner according to claim 1, wherein the control device performs a drying operation of the indoor heat exchanger before the clean operation. 6. The indoor unit further includes a negative ion generator for generating negative ions, and the control device operates the negative ion generator during a clean operation. 5. The air conditioner according to any one of 5. 7. The air conditioner according to claim 1, wherein the ozone generator also serves as a discharge electrode of an electric precipitator. 8. The power supply of the electrostatic precipitator can output a voltage in two stages, supplies a high voltage output to the discharge electrode when ozone is generated, and outputs a low voltage output lower than the high voltage output during the dust collection operation. 8. The battery according to claim 7,
The air conditioner as described. 9. The air conditioner according to claim 5, wherein the control device is provided with an automatic mode for performing a drying operation after the cooling operation is completed, and thereafter performing a clean operation. 10. The air conditioner further includes a remote control device. The remote control device performs an automatic mode in which a drying operation is performed after the cooling operation is completed, and then a clean operation is sequentially performed. The air conditioner according to claim 9, wherein a selection can be made between a drying mode in which only the operation is performed and a non-clean mode in which neither the drying operation nor the clean operation is performed after the cooling operation is completed. 11. The indoor unit according to claim 2, wherein the air from the indoor fan is arranged to flow in the order of the ozone generator, the indoor heat exchanger, the indoor fan, and the communication passage. The air conditioner as described. 12. The air conditioner according to claim 2, further comprising a fan drive control device that drives the indoor fan at a low speed during the clean operation. 13. The air conditioner has an indoor heat exchanger divided into two and a decompression device provided between the indoor heat exchangers, and a drying operation controls the decompression device to control the interior of the room. 10. An indoor fan driven at a low speed, wherein one of the heat exchangers is an evaporator and the other is a condenser.
Or the air conditioner according to any one of 10.