JP2002089868A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner capable of removing floating bacteria in the air by widely spreading the air including plus ions and minus ions all over the inside of a room. SOLUTION: An ion-generating unit 33 built in with an ion generator generating the plus ions and the minus ions simultaneously and a blower is arranged to an indoor unit 1 provided with a heat exchanger 25 and a blower fan 26. A draft air duct B arranged with the ion-generating unit 33 is formed separately from a circulation duct A passing through the heat exchanger 25. The draft air duct B joins the circulation duct A on the down stream side of the heat exchanger 25 and blows out the air including the ions into the inside of the room combining the air including the ions from the ion-generating unit with the air from the circulation duct A.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a separate or integrated air conditioner provided with an ion generator.

[0002]

2. Description of the Related Art Generally, in a room such as an office, a conference room, or a home, due to the presence of a person, carbon dioxide discharged with breathing, and contaminant fine particles such as tobacco smoke and dust increase, and negative ions are generated. Decrease. In particular, when smoking a cigarette, the negative ions are greatly reduced, and tend to be about １ ／ to の of the ion amount in the outdoor air.

For this reason, a negative ion generator alone or an air purifier provided with a negative ion generator is installed to generate negative ions. Commercially available ion generators generate only negative ions, and the generation method is a DC high-voltage type, in which only negative ions are generated, and an AC high-voltage type is used. Nothing co-generates the ions.

[0004] Unlike the outdoor ion distribution, the ion generator generates a large amount of only negative ions. Although this negative ion can be expected to relax humans to some extent, in recent years, with the densification and sealing of the residential environment, it has been effective in actively removing airborne bacteria that are harmful to the human body due to air pollution. There is an unacceptable problem.

[0005] The air conditioner also has a method of adding an air purifying function, sucking room air, and adsorbing or decomposing contaminants with a filter. Furthermore, Japanese Patent Publication No. 7-23777 discloses an air conditioner provided with an ion generator for generating negative ions and positive ions. In this air conditioner, an ion generator is arranged near the air outlet on the downstream side of the heat exchanger, and negative ions and positive ions are blown into the room by the air blower.

[0006]

In the air conditioner provided with the above-mentioned ion generator, when the cooling operation is performed, since the cold air directly hits the ion generator, there is a possibility that the electrodes of the ion generator may be dewed and short-circuited. Yes, there is a safety problem. In addition, when air is blown on the ion generator, the flow is disturbed, resulting in uneven air flow and a reduction in air volume.

[0007] The generated negative ions and positive ions are blown out by driving the blower, and the operation of the negative ions and positive ions depends on the operation state of the air conditioner. For example, at the start of the operation, the air flow becomes strong, and the negative ions and the positive ions diffuse into the room to exhibit the effect. As time elapses and the air volume becomes weaker, it becomes difficult for negative ions and positive ions to spread throughout the room. By the way, in a situation where time has passed, a person has been living for a long time, and there are many contaminating fine particles.
At this time, although the effect of the ions must be exhibited, the ions are unevenly distributed, and the effect cannot be exhibited. Therefore, even if an ion generator is provided, the characteristics of ions are not fully utilized.

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide a safe air conditioner capable of removing airborne bacteria in the air by making full use of the characteristics of negative ions and positive ions.

[0009]

Means for Solving the Problems According to the present invention, there is provided a heat exchanger, a blower, and an ion generator for simultaneously generating positive and negative ions, and a circulation passage from the heat exchanger to the blower. The second air flow from the ion generator is combined with the first air flow flowing through the air. That is, the ion generator is arranged in parallel with the heat exchanger, so that the influence of the air passing through the heat exchanger is not exerted, the safety is improved, and the ion generating capacity is not reduced. Here, if a dehumidifying / humidifying device that adsorbs and desorbs moisture in the air is also used, sterilization can be performed while conditioning the air, and a refreshing comfortable space can be obtained.

[0010] Specifically, a circulation passage in which a heat exchanger is arranged and a ventilation passage in which an ion generator is arranged are separately provided. For example, when making both suction ports common, the air passage is branched from the circulation passage on the upstream side of the heat exchanger,
Either the air is merged into the circulation passage downstream of the heat exchanger, or both outlets are separated, and the air passage is branched upstream of the heat exchanger. When the two suction ports are separately provided, the air passage may be joined to the circulation passage either downstream or upstream of the heat exchanger, or the outlets may be provided separately.

As described above, if the two passages merge and the outlet is common, the positive ions and the negative ions generated from the ion generator are spread into the room by the air flow from the circulation passage, and the sterilization effect is greatly improved. Can be demonstrated. By using a common suction port for both passages, a ventilation passage can be formed in an empty space, and the space can be effectively used. In addition, if the suction ports of both passages are separated, the position of the suction port can be set arbitrarily according to the installation location of the ion generator, so that no useless space is generated and the size of the air conditioner is reduced. Can be achieved. If the outlets of both passages are separated, air containing ions can be blown out regardless of the operating condition of the air conditioner, and stable generation of ions can be performed. Therefore, any combination may be selected according to the purpose, and the ventilation passage can be formed in various ways with respect to the circulation passage. For example, the ion generator can be operated alone or used in combination with another operation. Or
The function of the air conditioner can be improved by utilizing the sterilizing effect of ions.

By the way, the ion generator may be arranged on the upstream side of the heat exchanger, or the junction of the air passage may be located on the upstream side of the heat exchanger. Also in this case, the airflow from the ion generator is combined with the airflow flowing through the circulation passage, and the generated ions can be spread indoors. In addition, since the generated ions pass through the heat exchanger and the circulation passage, they can be sterilized, and clean air containing no bacteria can be blown out, which is sanitary.

Then, the ion generator and the blower are integrated to form an ion generator unit. By such a unitization, air can be reliably introduced into the ion generator, and air containing ions can be sent out,
A stable bactericidal effect is obtained. In addition, since the ion generator unit can be mounted simply by mounting the ion generator unit, the work becomes very easy. In addition, the shape and specifications of the unit need only be set according to the mounted model, and it is easy to respond to a design change of the model.

[0014] A filter may be provided at the suction port of the ion generator unit. As a result, dust can be prevented from adhering to the ion generator, and performance degradation due to long-term use can be prevented. Further, if a viewing window for visually checking the operation state of the ion generator is provided, the degree of dust accumulation can be confirmed, and maintenance becomes easy.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of an air conditioner provided with an ion generator according to the present invention will be described with reference to the drawings. FIG. 1 shows an indoor unit 1 of a separate type air conditioner.
The indoor unit 1 includes a main body casing 2 in which a heat exchanger, an indoor fan, and the like are installed, a front panel 3 that can be opened and closed to visually check the inside of the main body when checking for dirt on a filter, and the like.
An air outlet 4 for blowing cool and warm air, an air inlet 5 for sucking indoor air, a liquid crystal display device 6 for displaying an operation status, and a dehumidifying / humidifying air outlet 7 for blowing dehumidified air from a dehumidifying device are provided. Further, a remote controller 8 for remotely controlling the switching on and off of the operation is provided.

As shown in FIG. 2, the front panel 3 is supported by the main body casing 2 so as to be openable and closable, and faces the suction port 5 formed in the front panel 3 so as to face the main body casing 2.
A right filter 9 and a left filter 10 for removing dirt and dust in the air sucked in from the suction port 5 are provided in the suction port. Air purification filters 11 and 12 are attached to substantially right centers of the right filter 9 and the left filter 10, respectively. On the right side of the main body casing 2, a dehumidification / humidification suction port for sucking room air for the dehumidification / humidification device is formed, and a dehumidification / humidification filter 13 is provided.

A liquid crystal display 6 as shown in FIG. 3 is arranged in the center of the main casing 2. The liquid crystal display device 6 includes a humidity lamp 1 that is turned on according to indoor humidity.
4. Cleanness lamp 1 whose color changes according to indoor air contamination
5, a display unit 16 for displaying the indoor environment and the driving situation in accordance with a signal of an operation button from a remote controller, and a light receiving unit 17 for receiving a signal from the remote controller.

As shown in FIG. 4, the remote controller 8 includes a remote controller display section 18 for displaying an operation state, a transmission display 19 for lighting when a signal is sent to the indoor unit 1, a start / stop switch 20 for operating the air conditioner, A temperature switch 21 for setting the room temperature, a humidity switch 22 for turning on / off the dehumidifying operation of the dehumidifying device, a ventilation switch 23 for turning on / off the ventilation operation of the dehumidifying device, and turning on / off the operation of the ion generator unit. And a cluster switch 24.

As shown in FIG. 5, inside the indoor unit 1,
An indoor heat exchanger 25 for exchanging heat between a heat refrigerant passing through the inside and the outside air inside the room, and sucking room air and blowing out the air exchanged by the indoor heat exchanger 25 to the outside of the main body Indoor fan 26 is mounted. A vertical louver 27 for changing the direction of air flow to the left and right and a horizontal louver 28 for changing the direction of air flow in the up and down direction are attached to the outlet 4 formed in the lower part of the front surface of the main body casing 2 so as to be swingable. Have been.

A filter guide 29 is formed on the front surface of the main body casing 2, and filters 9 and 10 are inserted and mounted along the filter guide 29 with the front panel 3 opened. The right filter 9 has a shape avoiding the liquid crystal display device 6. Further, below the indoor heat exchanger 25, a drain pan 30 for receiving drain generated when exchanging heat with indoor air is provided. In addition, the suction port 5
Is composed of a front suction port 31 formed so as to surround the liquid crystal display device 6 of the front panel 3 and an upper suction port 32 formed on the upper surface of the main casing 2.

Then, filters 9 and 1 are connected through suction port 5.
0, a circulation passage A is formed to reach the outlet 4 through the heat exchanger 25. By this circulation passage A, the air in the room sucked from the inlet 5 is blown into the room from the outlet 4 and circulated. .

An ion generator unit 33 is arranged near the outlet 4 of the main casing 2. A ventilation passage B is provided separately from the circulation passage A so as to pass through the ion generator unit 33. The ventilation passage B is formed between the heat exchanger 25 and the filters 9 and 10 and communicates with the circulation passage A at a junction 34 formed near the outlet 4 of the circulation passage A. As a result, the air that enters from the inlet 5 and passes through the filters 9 and 10 passes directly through the ion generator unit 33 without passing through the heat exchanger 25, and is located at the junction downstream of the heat exchanger 25. 34
Out of the circulation passage A, merges with the air passing through the circulation passage A, and is discharged into the room. Thus, the reason why the ion generator unit 33 is disposed in the air passage that does not pass through the heat exchanger 25 is that the ion generator of the ion generator unit 33 is constantly cooled during cooling. In addition, there is a possibility that the dew condensation may occur around the ion generator, which causes a decrease in ion generating capability. To prevent this, the ion generator unit 33 is disposed in a passage not passing through the heat exchanger 25. Structure.

As shown in FIG. 6, the air conditioner includes an indoor unit 1, an outdoor unit 40, and a remote controller 8. The indoor unit 1 includes an indoor heat exchanger 25 and an indoor fan 26.
The outdoor unit 40 includes an outdoor heat exchanger 41, a compressor 42, an expansion valve 43, and an outdoor fan 44.

The indoor unit 1 is provided with a dehumidifying / humidifying device 50. The dehumidifying / humidifying device 50 includes a moisture absorbing rotor 51 for absorbing and releasing indoor moisture, a dehumidifying fan 52 for absorbing indoor air, and a moisture absorbing rotor 51. Fan 5 to send regeneration air to
3, a regeneration heater 54 for heating the regeneration air sent to the moisture absorption rotor 51, and a damper 55 for switching the path.

As shown in FIG. 7, the ion generator unit 33 comprises an ion generator 60, a blower 61, a unit outlet 62, a filter 63, and a unit main body 64.

As shown in FIG. 8, the ion generator 60 includes a cylindrical dielectric 65, an inner electrode 66 mounted inside the dielectric 65, and a dielectric 6 opposed to the inner electrode 66.
An outer electrode 67 attached to the outside of the housing 5 and insulating packings 68 and 69 for sealing attached to both ends of the dielectric 65.

The glass tube constituting the dielectric body 65 is made of a glass material of Neoceram having a cylindrical shape and both ends opened, and has an outer diameter of 10 mm. The inner electrode 66 is generally called a high-voltage electrode, and is made of SUS316 or S
US 304 stainless steel wire, plain woven with a 40 mesh wire mesh. The outer electrode 67 is generally called a GND electrode, and is made of SUS316 or SUS304.
Stainless steel wire and plain woven with a 16 mesh wire mesh. Lead wires 70 and 71 connected to a high voltage circuit are welded to predetermined positions on the inner electrode 66 and the outer electrode 67, respectively. The lead wires 70 and 71 are made of Teflon (registered trademark), the core wire of which is a stainless steel wire and the surrounding coating is made of Teflon (registered trademark).

On the inner surfaces of the insulating packings 68 and 69, a groove 72 into which the edge of the dielectric 65 is inserted is formed in an annular shape.
The insulating packings 68 and 69 are fitted to both ends of the dielectric 65. A concave portion 73 is formed inside the groove 72, and a hole 74 for passing the lead wire 70 is formed on the bottom surface of the concave portion 73, and a thin film is formed in the hole 74. Lead wire 70
When passing through, the thin film is subjected to a processing to break it. Further, grooves 75 for attachment to the unit body 64 are formed on the outer surfaces of the insulating packings 69 and 70. The material of the insulating packings 69 and 70 is made of chlorosulfonated polyethylene (trade name: Hypalon) or EP rubber.

The ion generator 6 configured as described above
When assembling, the lead wire 70 is placed inside the dielectric 65.
Is inserted into the cylindrical inner electrode 66. Further, after breaking the thin film in the hole 74 of the concave portion 73 of the insulating packing 69 and passing the lead wire 70, the insulating packing 69 is inserted and fitted to one end of the dielectric 65.

The lead wire 7 is provided outside the dielectric 65.
1 is covered with a cylindrical outer electrode 67 to which an insulating packing 6 is attached.
8 is inserted and fitted to the other end of the dielectric 65. Thereby, the ion generator 60 is completed.

The unit body 64 includes an ion generator 60
The casing 61 of the blower 61 is
a is a structure integrally attached and has a shape of an elongated cylinder or a rectangular parallelepiped, but is not limited to this shape. The blower 61 includes an ion generator 60.
And is communicated with the ion generator 60 through the mounting port 76.

The blower 61 is connected to the unit inlet 7
The air taken in from 7 is sent to the ion generator 60 through the attachment port 76 and the vent port 78, and the generated positive ions and negative ions are blown out from the unit outlet 62. The form of the casing, the fan, and the motor may be appropriately selected according to the storage state of the indoor unit 1 in the air passage B.

The unit suction port 77 has a filter 63
Is attached. The filter 63 may be a combination of a pre-filter for removing dust and dirt and a deodorizing filter for removing indoor odor, or a single filter. The unit inlet 77 and the unit outlet 62 are each formed in a direction orthogonal to the axial direction, and are formed so as to be shifted by 90 degrees.

A visual window 79 for viewing the ion generator 60 from outside is formed in the unit main body 64. The viewing window 79 is configured by attaching a transparent resin material to an opening formed in the case 60a so that the inside can be checked from the outside. Then, a monitoring window may be formed in the main body casing 2 so that the viewing window 79 can be seen from the outside, or a structure in which the ion generator unit 33 can be easily attached / detached.

In the configuration of the ion generator unit 33 described above, the insulating packing 68 of the ion generator 60 is fitted into the mounting hole 80 in the unit body 64, and the support plate 81
When the casing 61a of the blower 61 equipped with the filter 63 is attached to the case 60a with screws or the like, the ion generator unit 33
Is completed. The unit 33 is removably attached to a predetermined position in the air passage B with screws or the like.

Next, the operation of the air conditioner will be described.
First, the operation can be performed by the remote controller 8, and the procedure will be described. Each time the operation switch 34 on the control panel of the remote control 8 is pressed, the operation mode changes from “automatic” to “heating”.
The display changes from "cooling" to "dry" to "automatic", and is displayed on the remote control display unit 18, whereby the operation mode is selected.

The signal transmitted from the remote controller 8 is received by the light receiving unit 17 of the liquid crystal display device 6 of the indoor unit 1.
The indoor unit 1 has a built-in control device. As shown in FIG. 9, the control device includes a control unit 90 including a CPU, a memory, and the like, a switch determination unit 91, an indoor fan drive circuit 92, A generator driving circuit 93 and a dehumidifying / humidifying device driving circuit 94 are provided, and each device is operated according to a signal from the remote controller 8.

When the run / stop switch 20 is pressed, the operation contents, the set temperature, and the room temperature are displayed in order on the liquid crystal display device 6 of the indoor unit 1, and the room temperature is always displayed during the operation. When the operation is stopped, when the operation / stop switch 20 is pressed, the display on the liquid crystal display device 6 disappears, and the operation stops. To change the temperature, for example, to increase the temperature by 1 ° C., press the “と” switch of the temperature switch 21 once to increase the set temperature by 1 ° C. In the heating / cooling operation mode, the remote controller display 18 and the liquid crystal display The set temperature is displayed on the device 6. Also, in the automatic / dry operation mode, the temperature corresponding to the temperature to be raised is displayed on the remote control display section 18,
The set temperature is displayed on the liquid crystal display device 6. At this time, the display of the set temperature of the liquid crystal display device 6 returns to the room temperature display after about 4 seconds. When it is desired to change the air volume, the air volume changes each time the air volume switch 35 is pressed, and “automatic air volume” → “air volume △” → “air volume △△” → “air volume △△△” is displayed on the remote control display unit 18.
→ "Automatic air flow" is displayed, and "Automatic air flow" → "Light air flow" → "Low air flow" → "High air flow" →
"Air volume automatic" is displayed.

The desired operation mode is selected as described above. During the cooling operation, the heat exchange medium condensed from the compressor 42 and in a high temperature state is sent to the outdoor heat exchanger 41 of the outdoor unit 40. In the outdoor heat exchanger 41, the outside air is blown by the outdoor fan 44 to the outdoor heat exchanger 41 to take away heat of the heat exchange medium and cool the heat exchange medium. The heat exchange medium passes through the expansion valve 43 and is evaporated and vaporized by the indoor heat exchanger 25. The indoor air sucked by the indoor fan 26 passes through the indoor heat exchanger 25 and is
The heat is taken away by 5. In this way, the indoor air is cooled and circulated, and cooling is performed.

The heating operation is performed by reversely circulating the heat exchange medium, contrary to the cooling operation. The condensed heat exchange medium is sent to the indoor heat exchanger 25, and the indoor air passing through the indoor heat exchanger 25 is heated to perform indoor heating. The heat exchange medium passes through the expansion valve 43 and is evaporated by the outdoor heat exchanger 41. Further, the heat is exchanged with the outside air blown to the outdoor heat exchanger 41 by the outdoor fan 44 to remove heat from the outside air and return to the compressor 42.

Here, the flow of the air is sucked by the indoor fan 26 from the suction port 31 of the front panel 3 of the indoor unit 1 and the suction port 32 of the main body casing 2, passes through the filters 9 and 10, and It reaches the heat exchanger 25.
Since the indoor air is guided to the entire surface of the indoor heat exchanger 25, the heat exchange rate in the indoor heat exchanger 25 is improved. The air passes through the indoor heat exchanger 25 and is blown out from the outlet 4.

When the operation of the air conditioner is started,
In conjunction with this, an AC high voltage is also applied to the ion generator unit 33 to generate positive ions and negative ions. H ⁺ (H ₂ O) n is generated as a positive ion, and O ^2- (H ₂ O) m is generated most stably as a negative ion.

A part of the air sucked from the suction port 31 and passed through the filters 9 and 10 enters the ventilation passage B,
It is sucked into the ion generator unit 33. The air from which the odor, dust, and dust have been removed after passing through the filter 63 of the unit main body 64, including the positive ions and the negative ions generated from the ion generator 60, is blown out from the unit outlet 62. The air blown out from the ion generator unit 33 joins the heat-exchanged air flowing through the circulation passage A from the junction 34 via the air passage B, and is blown out from the air outlet 4, and the air is exhausted to every corner of the room. Convection circulation.

The use of positive ions or negative ions alone has no particular effect on airborne bacteria. However, when these positive ions and negative ions are produced simultaneously, hydrogen peroxide H, which is an active species, is produced by a chemical reaction.
₂ O ₂ or hydroxyl radical / OH is generated. Since they exhibit extremely powerful activity, they can remove airborne bacteria. Therefore, when the air conditioner equipped with the ion generator unit 33 is operated, three hours after the start, 83% of general viable bacteria and 88% of fungi can be removed.

The ion generator unit 33 for generating ions may be operated independently. Ion generator unit 3 even when the operation of the air conditioner is stopped
To operate only three, the cluster switch 24 of the remote controller 8 is turned on. When the operation is started, an AC high voltage is applied to the ion generator unit 33 and is also applied to the indoor fan 26 of the indoor unit 1.

An air flow is generated in the air passage B by the blower 61, and this air flow includes positive ions and negative ions generated from the ion generator 60. The air blown out from the ion generator unit 33 joins the airflow generated in the circulation passage A by the indoor fan 26 from the junction 34 and is discharged from the outlet 4 into the room. As a result, the air conditioner can be operated independently irrespective of the air conditioning operation, and a bactericidal effect against airborne bacteria in the indoor air can be obtained, thereby improving the usability of the product as an air conditioner. At this time, by driving the indoor fan 26, a strong air flow is generated, and positive ions and negative ions can be widely diffused into the room.

Further, by operating the dehumidifying / humidifying device 50, the air in the room can be dehumidified and humidified, thereby conditioning the air. Therefore, when the dehumidifying / humidifying device 50 is operated, the ion generator unit 33 is also operated simultaneously. When the humidity switch 22 or the ventilation switch 23 of the remote controller 8 is turned on and the operation of the dehumidifying / humidifying device 50 is started, an AC high voltage is applied to the ion generator unit 33 and further applied to the indoor fan 26.

Air containing positive ions and negative ions is blown out from the outlet 4, and conditioned air is blown out from the dehumidifying and humidifying outlet 7. Obtainable.

The indoor unit of the second embodiment is shown in FIGS. Here, a ventilation passage B for the ion generator unit 33 is formed independently of the circulation passage A, and has a structure in which only the outlet 4 is shared. Other configurations are the same as those of the first embodiment.

That is, on the front panel 3 of the indoor unit 1, an ion air inlet 100 for sucking air into the ion generator unit 33 is formed, and an ion air inlet 101 is also formed on the main body casing 2 in opposition thereto. Have been. Then, as shown in FIG. 12, a space 102 is formed below the upstream side of the circulation passage A below the filters 9 and 10 and the indoor heat exchanger 25 in the main body casing 2. This space 102 is connected to the downstream side of the circulation passage A by the junction 34 in the vicinity of the outlet 4. Space 1
02 is provided with an ion generator unit 33,
Blower passage B from 00 through outlet 34 to outlet 4
Is formed.

When the ion generator unit 33 is operated independently, the on / off switch for operating the ion generator unit, which is provided separately from the operation switch of the air conditioner, is turned on, and the operation is started. . The blower 61 of the ion generator unit 33 sucks indoor air from the inlet 100 and passes through the filter 63 to remove odors and dust.
The air from which dust has been removed, including the ions generated by the ion generator 60, is blown into the room from the outlet 4 through the junction 34. If the operation is performed using only the ion generator unit as described above, power consumption for operation is reduced, and noise can be reduced. Note that the indoor fan 26 may be operated in accordance with the operation of the ion generator unit 33.

In the third embodiment, the ventilation passage B in which the ion generator unit 33 is disposed is completely separated from the circulation passage A and is made independent. Other configurations are the same as those of the first embodiment.

That is, as shown in FIG. 13, an inlet 105 and an outlet 106 for the ion generator are formed on both sides of the liquid crystal display device 6 of the main body casing 2 respectively. Then, as shown in FIG. 14, a space 107 completely independent of the circulation passage A is formed below the filters 9 and 10 in the main body casing 2 and the indoor heat exchanger 25, and An air passage B communicating with the outlet 106 is formed.

Also in the above configuration, air containing positive ions and negative ions is blown into the room from the outlet 106 by the operation of the blower 61. At this time, the air that has passed through the indoor heat exchanger 25 is also blown out of the outlet 4 by the operation of the indoor fan 26. As described above, even if the outlets of the ventilation passage B and the circulation passage A are different, as a result, both airs are merged, and the air blown out from the indoor unit 1 contains positive ions and negative ions. Will be. In addition, if only the ion generator unit is operated alone, power consumption for operation is reduced and noise can be reduced.

In the fourth embodiment, as shown in FIG.
The ion generator unit 33 is disposed upstream of the indoor heat exchanger 25. That is, the ion generator unit 33 includes the filters 9 and 10 in the circulation passage A.
And the indoor heat exchanger 25. Thereby, the ventilation passage B becomes the same as the circulation passage A. Other configurations are the same as those of the first embodiment.

The air in the room sucked from the suction ports 31 and 32 is cleaned of dust and the like by the filters 9 and 10 and is sucked into the ion generator unit 33. The sucked air includes the positive ions and the negative ions generated by the ion generator 60, and includes the ion generator unit 3
3 It is blown out. Thereafter, the air flows in the circulation passage A, passes through the indoor heat exchanger 25, and is blown into the room from the air outlet 4.

When the air containing the positive ions and the negative ions passes through the indoor heat exchanger 25 and the circulation passage A,
Sterilization is performed by exhibiting a bactericidal effect on the indoor heat exchanger 25 and the wall surface of the circulation passage A or on the floating bacteria. Therefore, the air discharged from the outlet 4 into the room becomes clean air with less floating bacteria. In addition, there is also a bactericidal effect against bacteria floating in the indoor air, and a higher bactericidal effect can be obtained.

It should be noted that the present invention is not limited to the above-described embodiment, and it goes without saying that many modifications and changes can be made to the above-described embodiment within the scope of the present invention. For example, as shown in FIG.
Is formed separately from the suction port 5 of the circulation passage A, and the air outlet is shared with the air outlet 4 of the circulation passage A.
The ion generator unit 33 is disposed upstream of the indoor heat exchanger 25. That is, the ventilation passage B joins the circulation passage A between the filters 9 and 10 and the indoor heat exchanger 25. Thus, the indoor heat exchanger 25 and the circulation passage A can be sterilized as in the fourth embodiment.

In each of the above embodiments, the ion generator unit is provided in the indoor unit of the air conditioner, but may be provided in an integrated air conditioner.

[0060]

As is apparent from the above description, according to the present invention, the air flow in the air supply passage for the ion generator is joined to the air flow in the circulation passage passing through the heat exchanger, so that it can be added to every corner of the room. Air containing ions and negative ions can be spread, and bacteria floating in the room can be removed. At this time, since the ion generator is not disposed downstream of the airflow passing through the heat exchanger, it does not touch the air passing through the heat exchanger,
It is possible to prevent the detrimental effects of dew on the ion generator and the disturbance of the air flow.

Further, the ion generator is installed in front of the heat exchanger,
That is, by arranging it on the upstream side, bacteria adhering to a heat exchanger, a fan, or the like can be removed, and clean air can be blown out.

By unitizing the ion generator and the blower, it is possible to easily attach the ion generator and the blower, and it is easy to adapt to the type of the device. If a filter is provided in the suction port of this unit, dust can be prevented from adhering to the ion generator, and its performance can be maintained for a long period of time.

Moreover, it is possible to diversify the ventilation passage by unitizing. As a result, the ion generation can be used in combination with the normal operation such as cooling and heating, and the single operation of the ion generator unit alone can be performed, so that the operation can be performed quietly and the sterilizing effect can be obtained.

[Brief description of the drawings]

FIG. 1 is a perspective view of an indoor unit of an air conditioner according to a first embodiment of the present invention.

FIG. 2 is a perspective view of the indoor unit with a front panel opened.

FIG. 3 is a schematic diagram of a liquid crystal display device.

FIG. 4 is a front view of a remote controller.

FIG. 5 is a sectional view of an indoor unit.

FIG. 6 is an overall schematic diagram of an air conditioner.

FIG. 7 is a configuration diagram of an ion generator unit.

FIG. 8 is a configuration diagram of an ion generator.

FIG. 9 is a control block diagram of an indoor unit.

FIG. 10 is a perspective view of an indoor unit according to a second embodiment.

FIG. 11 is a perspective view of the indoor unit with a front panel opened.

FIG. 12 is a sectional view of an indoor unit.

FIG. 13 is a perspective view of the indoor unit of the third embodiment with a front panel opened.

FIG. 14 is a sectional view of an indoor unit.

FIG. 15 is a sectional view of an indoor unit according to a fourth embodiment.

FIG. 16 is a sectional view of an indoor unit according to another embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Indoor unit 2 Main body casing 3 Front panel 4 Outlet 5 Inlet 7 Dehumidification / humidification outlet 9, 10 Filter 25 Indoor heat exchanger 26 Indoor fan 33 Ion generator unit 34 Merging port 60 Ion generator 61 Blower 62 Unit blow Outlet 63 Filter 77 Unit inlet

(72) Inventor Hideo Nojima 22-22, Nagaikecho, Abeno-ku, Osaka-shi, Osaka Inside Sharp Corporation (72) Inventor Mamoru Morikawa 22-22, Nagaikecho, Abeno-ku, Osaka-shi, Osaka Inside Sharp Corporation F term (reference) 3L049 BB02 BB09 BB11 BC01 BD02 3L051 BC02 BC04 3L055 AA01 3L060 AA08 CC19 DD01 EE05 EE45

Claims (13)

[Claims] 1. A heat exchanger, a blower, and an ion generator for simultaneously generating positive ions and negative ions, wherein a first airflow flowing from the heat exchanger through a circulation passage passing through the blower is provided. Second from the ion generator
An air conditioner characterized by merging air flows. 2. The air conditioner according to claim 1, wherein a ventilation passage passing through the ion generator is provided separately from the circulation passage. 3. The air conditioner according to claim 1, wherein a suction port of the circulation passage and a suction port of the ventilation passage are common. 4. The air conditioner according to claim 1, wherein a suction port of the air passage is different from a suction port of the circulation path. 5. The air conditioner according to claim 1, wherein an outlet of the circulation passage and an outlet of the air passage are common. 6. The air conditioner according to claim 1, wherein an outlet of the air passage is different from an outlet of the circulation passage. 7. The air flow passage is communicated with the circulation passage, and a junction between the air passage and the circulation passage is formed downstream of the heat exchanger in the circulation passage.
The air conditioner as described. 8. An ion generator unit in which an ion generator and a second blower for forming a second air flow are integrated in an air blowing passage. The air conditioner according to item 1. 9. The air conditioner according to claim 8, wherein a filter is provided at a suction port of the ion generator unit. 10. The air conditioner according to claim 1, further comprising a visual window for visually recognizing the ion generator. 11. A control device for operating the ion generator and driving the blower so that the generated ions are blown out by the first airflow to perform the ion generator alone operation. Item 11. The air conditioner according to any one of Items 1 to 10. 12. The air conditioner according to claim 1, wherein the ion generator is disposed upstream of the heat exchanger. 13. The air conditioner according to claim 1, further comprising a dehumidifying / humidifying device that adsorbs and desorbs moisture in the air.