JP2011089746A - Indoor unit for air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indoor unit for an air conditioner including a negative ion generating device, capable of efficiently emitting large amount of negative ions to an indoor side, preventing flame spread damage by suppressing adhesion of dust and improving reliability. <P>SOLUTION: A blowout port 6 and suction ports 4, 5 are provided, and a heat exchanger 8 and an air blower 10 are arranged opposing to each other. The negative ion generating device M includes: a needle electrode 31 arranged along the direction orthogonal to the air blowing direction so that a tip faces an approximately central part of the blowout port 6; an earth screw 32 mounted to a position separated from the needle electrode 31 by a predetermined distance; and a case 30 with a semi-closed structure covering the needle electrode 31 and the earth screw 32. The negative ion generating device M is arranged in the blowout port 6. The case 30 includes: a first hole 40 for emitting negative ions opened in a portion opposing to the tip of the needle electrode 31; a second hole 42 arranged adjacent to the first hole 40 and opened in a portion opposing to the earth screw 32; and a slit 24 opened on a face on the side opposite to the first hole 40 and communicating the outer side and the inner side of the case 30 with each other. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an indoor unit of an air conditioner, and more particularly to an improvement of a negative ion generator that is attached to an outlet and supplies negative ions into a room.

The indoor unit of the air conditioner of [Patent Document 1] filed by the present applicant has previously generated negative ions in the blower air passage of the indoor fan in the unit main body that houses the indoor heat exchanger and the indoor fan. The device is in an exposed state.
The negative ion generator includes a generation electrode in a protective container whose surface is subjected to antistatic treatment, and includes a ground portion at a position separated from the generation electrode. The generating electrode includes an electrode plate to which a high voltage is applied, and a plurality of needle-like electrodes that are integrally formed with the electrode plate and are arranged on the air flow downstream side of the electrode plate.

All of these needle-like electrodes are arranged in parallel with the air blowing direction of the air passage, and are provided so that the tip faces the air blowing downstream side. The protective container is a portion facing the tip of each needle-like electrode, and has a slit that opens along the blowing direction of the blowing path, and a distance at which arc discharge does not occur with respect to the generating electrode on the blast side of the generating electrode. There is a boss part.
A lower hole is provided through the boss, and a fixture having a length shorter than the entire length of the lower hole is attached thereto. And the earth terminal which connected the earth wire is attached to a boss | hub part via an attachment tool.

JP 2001-074266 A

  To reiterate, the needle-like electrodes constituting the negative ion generator of [Patent Document 1] are parallel to the air blowing direction of the air blowing path, the tip is directed to the air blowing downstream side, and arranged in parallel to each other. In the protective container that houses these needle-shaped electrodes, a slit opens along the blowing direction of the blowing path.

In such a configuration, since the tip of the needle-like electrode is exposed in the blowing direction, dust tends to adhere to the electrode and the surface of the protective container when used for a long time. For this reason, maintenance is sometimes required to clean the tip of the needle-like electrode to remove dust, but this is troublesome for the user.
When the amount of dust adhering to the tip of the needle electrode increases, abnormal discharge may occur between the needle electrode and the ground portion as the counter electrode. When driving with the room lights turned off at night, the abnormal discharge appears as pale light, which gives the user anxiety.

  The present invention has been made based on the above circumstances, and the object of the present invention is to efficiently release a large amount of negative ions into the room and to suppress the adhesion of dust, even in the event of abnormal discharge. It is an object of the present invention to provide an indoor unit of an air conditioner equipped with a negative ion generator that can prevent fire damage caused by sparks scattered around and improve reliability.

In order to satisfy the above-mentioned object, the present invention provides a heat exchanger and a blower which are arranged opposite to each other in a unit body provided with a suction port and a blowout port, and sucks indoor air into the unit body from the suction port. It is an indoor unit of an air conditioner that exchanges heat with an exchanger and blows out air from the outlet through a blower.
A negative ion generator that generates negative ions when a high voltage is applied to the blowout port and supplies the negative ions to the room is arranged. The negative ion generator blows air so that the tip is directed to the substantially central portion of the blowout port. A needle-like electrode disposed along a direction orthogonal to the direction, a ground screw attached at a predetermined distance from the needle-like electrode, and a semi-sealed case covering the needle-like electrode and the ground screw And.
The case has a first hole for negative ion emission opened at a portion facing the tip of the needle-like electrode, and a second hole opened at a portion adjacent to the first hole and facing the ground screw. And a slit that opens on a surface opposite to the first hole and communicates the outside and the inside of the case.

  According to the present invention, it is possible to efficiently release a large amount of negative ions into a room, and to suppress the adhesion of dust to prevent fire damage and improve reliability.

The longitudinal cross-sectional view of the air conditioner and indoor unit based on one embodiment in this invention. The longitudinal cross-sectional view which expanded a part of indoor unit based on the embodiment. The external appearance perspective view of the indoor unit based on the embodiment. The front view which expanded the blower outlet part based on the embodiment. The negative ion generator which concerns on the same embodiment, and the perspective view which expanded the peripheral part. The disassembled perspective view of the negative ion generator which concerns on the same embodiment. The side view of the negative ion generator based on the embodiment. The top view in the state which opened the upper surface opening part of the negative ion generator based on the embodiment. The perspective view which removed the front panel of the indoor unit based on the embodiment. The disassembled perspective view of the ion generator which comprises the dust collector based on the embodiment. The internal perspective view of the power supply part which comprises the ion generator based on the embodiment. The schematic electric circuit diagram of the negative ion generator based on the embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a longitudinal sectional view schematically showing an indoor unit of an air conditioner when the refrigeration cycle operation is stopped. (Note that parts not denoted by reference numerals are not shown in the description. Some parts are not shown or described. The same applies hereinafter.)
The unit main body 1 includes a front panel 2 constituting a front casing and a rear main body 3 constituting a rear casing, and is formed in a horizontally long shape in the left-right width direction with respect to the vertical direction. A front suction port 4 is opened at a part of the front side of the unit main body 1, and a movable panel 2 </ b> A supported by an opening / closing drive mechanism is fitted into the front panel 2 facing the front suction port 4.

  When the refrigerating cycle operation is stopped, the movable panel 2 </ b> A is flush with the front panel 2 and closes the front suction port 4 to constitute a part of the appearance of the unit body 1. When the refrigeration cycle operation is started, the panel opening / closing mechanism operates, and the movable panel 2A moves away from the front suction port 4 and protrudes to the front side.

Therefore, a gap communicating with the room is formed around the movable panel 2A, and the front suction port 4 can be opened to the room. An upper surface suction port 5 is opened at the upper part of the unit main body 1, and a frame-like bar partitioning into a plurality of spaces is fitted into the upper surface suction port 5.
An air outlet 6 is opened at the lower front of the unit body 1, and a wind direction guide device F is provided at the air outlet 6. The wind direction guide device F includes a single upper and lower louver 7A that is rotatably supported in the vertical direction with respect to the outlet 6 and a plurality of left and right louvers 7B that are attached to the upper surface of the upper and lower louvers 7A.

  That is, the left and right louvers 7B rotate in the vertical direction integrally with the upper and lower louvers 7A, and two sets of left and right are supported so as to be freely rotatable in the left and right directions simultaneously for each set. The outlet 6 is opened and closed according to the rotational postures of the left and right louvers 7B and the upper and lower louvers 7A, and the direction of blowing heat exchange air is set according to the refrigeration cycle operating conditions.

  In the unit main body 1, a heat exchanger 8 formed in a substantially inverted V shape by the front heat exchanger portion 8A and the rear heat exchanger portion 8B is disposed. The front heat exchanger portion 8A is formed in a curved shape so as to face the entire front suction port 4 and a part of the upper surface suction port 5, and the rear heat exchanger portion 8B is straight and obliquely inclined so as to face the upper surface suction port 5. Opposite part.

  An indoor fan 10 is disposed between the front and rear heat exchanger portions 8A and 8B of the heat exchanger 8. The indoor blower 10 includes a fan motor disposed in a space on one side end of the unit main body 1 and a cross-flow fan connected to a rotation shaft of the fan motor. The length of the cross flow fan in the axial direction is set to be the same as the length of the heat exchanger 8 in the width direction and correctly opposes each other.

  The lower end portion of the front side heat exchanger portion 8A is placed on the front drain pan 12a, and the lower end portion of the rear side heat exchanger portion 8B is placed on the rear drain pan 12b. The front and rear drain pans 12a and 12b are formed integrally with the rear main body 3 constituting the unit main body 1, respectively, and receive drain water dripped from the heat exchanger portions 8A and 8B.

  The front and rear drain pans 12a and 12b are communicated with each other via a flange provided over both side portions. Since the rear drain pan 12b is at a high position and the front drain pan 12a is at a low position, the drain water received by the rear drain pan 12b is guided to the front drain pan 12a, and all the drain water is collected in the front drain pan 12a.

  A connecting port protrudes from the left or right side end portion of the front drain pan 12a and is connected to a drain hose. The drain hose is bundled together with the refrigerant pipes and cables that communicate the indoor unit and the outdoor unit, protrudes from either the left or right side of the unit body according to the installation conditions of the indoor unit, and extends outdoors. .

  The outer surfaces of the side walls of the front and rear drain pans 12a and 12b are provided close to the indoor blower 10 and constitute a nose for the crossflow fan of the indoor blower 10. A partition wall member 14 connects the side wall portions of the front and rear drain pans 12a and 12b, which are noses, and the side portions of the outlet port 6.

By driving the indoor blower 10, the space surrounded by the partition wall member 14 becomes a blowout ventilation path 15 </ b> A that communicates the nose and the blowout opening 6. On the other hand, a suction ventilation path 15 </ b> B is formed between the front suction port 4 and the upper suction port 5 and the heat exchanger 8.
On the other hand, a frame assembly 16 is interposed between the upper surface inlet 5 of the front panel 2 and the upper end of the heat exchanger 8. An air filter cleaning unit S is attached along the front end of the frame assembly 16.

An upper air filter 17 is movably supported on the upper surface of the frame assembly 16 on the upper side of the air filter cleaning unit S, and a front air filter 18 is mounted on the front surface of the frame assembly 16 on the lower side of the air filter cleaning unit S. It is supported movably.
If the refrigeration cycle operation is continued for a long time, it is captured by the front air filter 18 and the upper air filter 17, and the amount of adhering dust increases, resulting in resistance to air circulation. Therefore, the air filter cleaning unit S is periodically operated to remove dust adhering to the air filters 18 and 17 so as to be discharged outdoors.

  An ion generator 20 constituting a dust collecting device (dust collecting means) Z is provided in the suction ventilation path 15B between the front air filter 18 and the front heat exchanger section 8A. The dust collector Z is composed of the ion generator 20 and the heat exchanger 8 described above, and performs a dust collecting action on dust, viruses, and the like contained in the indoor air sucked into the unit body 1.

  A negative ion generation device (negative ion generation means) M, which will be described later, is provided at a part of the outlet 6. The negative ion generator M generates negative ions when a high voltage is applied, adds negative ions to the heat exchange air blown into the room from the outlet 6 and supplies the heat exchange air into the room. .

FIG. 2 is a diagram specifically showing the attachment position of the negative ion generator M. As shown in FIG.
As described above, the front drain pan 12a is integrally formed with the rear main body 3 constituting the unit main body 1 together with the rear drain pan 12b. The rear main body 3 is integrally provided with a piece 3a that protrudes further forward from the partition member 14 that forms the bottom surface of the front drain pan 12a, and the negative ion generator M is attached to the piece 3a. .

  Actually, the negative ion generator M is attached in a state of protruding from the piece 3a to the upper side and the lower side. The necessary minimum gap a is ensured even at the closest part between the portion projecting to the lower side and the left and right louvers 7B constituting the wind direction guiding device F. The gap a is 3.5 mm and is not interfered with each other, so that the mutual function is guaranteed.

FIG. 3 is an external perspective view of the indoor unit in a state where the air conditioning operation is performed.
At this time, the panel opening / closing mechanism is activated, and the movable panel 2A moves away from the front suction port 4 and projects to the front side. A gap communicating with the room is formed around the movable panel 2A, and the front suction port 4 is opened to the room. At the same time, the upper and lower louvers 7 </ b> A constituting the wind direction guiding device F rotate to open the outlet 6.

  The negative ion generator M appears to be exposed at a position shifted to the right side of the upper side of the outlet 6 and the left and right central part as a boundary. It is smaller than the size of one left and right louver 7B, and is located between two left and right louvers 7B. Actually, different colors are selected for the front panel 2 and the upper and lower louvers 7A and the left and right louvers 7B to clarify this existence.

FIG. 4 is an enlarged view of the negative ion generator M attached to the outlet 6 and its peripheral part.
The rear surface side of the upper and lower louvers 7A constituting the airflow direction guiding device F from the blowout opening 6, the plurality of left and right louvers 7B mounted thereon, and the piece 3a integrally projecting from the front drain pan 12a of the rear main body 3 The tip edge and part of the lower side of the negative ion generator M are visible. Note that the upper side of the negative ion generator M is hidden behind the outlet 6 and cannot be seen in this figure.

  A slit 24 is provided in a part (right side) of the negative ion generator M exposed to the blowout port 6 so that the inside of the negative ion generator M and the blowout port 6 side which is the outside communicate with each other. Is done.

FIG. 5 is a view showing a structure for attaching the negative ion generator M to the rear main body 3, in which the periphery of the outlet 6 and the wind direction guide device F are removed.
A notch for engagement is provided at a predetermined portion of the piece 3a provided integrally with the rear main body 3, and a negative ion generator M is fitted therein. The negative ion generator M is formed of a box having a rectangular shape in which the left-right direction is longer than the front-rear direction in plan view and a rectangular shape in which the left-right direction is longer than the vertical direction in front view.

  Latching pieces 25 are integrally projected on the left and right side portions of the negative ion generator M so as to be sandwiched from the upper surface and the lower surface of the rear main body piece portion 3a. Therefore, the negative ion generator M is detachably attached to the rear main body piece 3a.

  A lead wire 26 protrudes from the right side surface portion of the negative ion generator M and is wired along the upper surface of the piece portion 3a. The lead wire 26 is a combination of a high-voltage power supply line and a ground wire, which will be described later, and is connected to an electrical component in an electrical component box disposed on the side of the heat exchanger 8.

FIG. 6 is an exploded view of the negative ion generator M. As shown in FIG.
The negative ion generator M includes a case 30, a needle electrode 31 accommodated in the case 30, a ground screw 32, and a cover plate 33 that closes the upper surface opening of the case 30. The lid plate 33 is made of a heat insulating material, and a sheet 34 made of a flame retardant material is attached to the inner surface of the lid plate 33 so as to cover and seal the upper surface opening of the case 30.

  In other words, the case 30 has a rectangular shape in a plan view and a front view, and only the upper surface portion is opened and a slit 24 is provided. From the upper edge to the substantially middle part in the vertical direction is a top box part 30A in which the front and rear, left and right surfaces are formed in a flat plate, and the front and back surfaces from the substantially middle part to the bottom part are curved in cross section, and are formed in so-called streamline shape The lower box portion 30B.

  As shown in FIG. 5 again, with the negative ion generator M attached to the rear main body piece 3a, the lower box portion 30B of the case 30 protrudes downward from the piece 3a and is blown out from the blowout port 6. Exposure to heat exchange air. The upper box portion 30A is not exposed to the heat exchange air from the position protruding upward from the rear main body piece 3a.

  In particular, the right side surface portion of the case 30 is provided with a notch 27 through which the lead wire 26 is inserted between the upper end edge and the upper retaining piece 25. The slit 24 is provided in the lower box portion 30B in the vicinity of the right side surface portion where the notch portion 27 is provided.

  A boss portion 28 having a screw hole is provided inside the left side surface portion of the case 30, and the ground screw 32 is screwed into the screw hole of the boss portion 28. An earth terminal 35 for connecting the earth wire 26 b is fitted to the earth screw 32, and the earth terminal 35 and the earth screw 32 are electrically connected by screwing the earth screw 32 into the screw hole of the boss portion 28. Is done.

  An electrode plate 36 having the needle-like electrode 31 is attached to the vicinity of the boss portion 28 into which the ground screw 32 is screwed. A terminal portion 37 to which the high voltage power supply line 26a is connected is inserted into the electrode plate 36. The high-voltage power supply line 26 a and the ground line 26 b are collected as one lead wire 26 shown in FIG. 5 and extend from the cutout portion 27 of the case 30.

Subsequently, the negative ion generator M will be described.
FIG. 7 is a left side view of the negative ion generator M, and FIG. 8 is a plan view of the inside of the negative ion generator M with the cover plate 33 removed.

  As shown in FIG. 7, a rectangular first hole 40 that is short in the left-right width direction and long in the up-down direction is provided on the left side surface portion of the case 30 constituting the negative ion generator M. As described above, the negative ion generator M is attached to the right side of the outlet 6 from the center in the left-right width direction, so that the first hole 40 is located at the substantially center of the outlet 6. Turn to.

  When viewed from the left side surface portion of the case 30, it can be seen that the tip of the needle electrode 31 is opposed to the lower side of the first hole 40 that is long in the vertical direction. As shown in FIG. 8, the needle-like electrode 31 is placed on the electrode plate 36, and the axial direction of the needle-like electrode 31 is supported along the left-right width direction of the case 30.

  Therefore, the tip of the needle electrode 31 is directed to the substantially central portion of the outlet 6 through the first hole 40, and the axial direction of the needle electrode 31 is the direction of the heat exchange air blown from the outlet 6. Are arranged along the orthogonal direction. The slit 24 is provided on the side opposite to the surface where the first hole 40 is provided.

  The electrode plate 36 that supports the needle electrode 31 is attached and fixed to the inner bottom portion of the lower box portion 30 </ b> B on the lower side of the case 30 via an attachment screw 39. Therefore, the tip of the needle electrode 31 and the ground screw 32 screwed into the screw hole of the boss portion 28 are arranged at a predetermined distance.

  As shown in FIG. 7 again, a second hole 42 made of a round hole is provided on the side of the first hole 40 in the case 30. The second hole portion 42 is opened at a portion facing the ground screw 32, and the creepage distance is horizontally increased from the second hole portion 42 to the first hole portion 40 on the outer surface portion of the case 30. A notch groove 43 for setting is provided.

  With such a negative ion generator M attached to the rear main body piece 3a, the substantially upper half of the first hole 40 is closed by the plate thickness of the rear main body piece 3a. The substantially lower half of the part 40 is below the piece part 3 a and opens to the outlet 6. Similarly, the second hole portion 42 and the notch groove 43 open to the outlet 6.

  On the back side of the negative ion generator M, there is provided a holding piece 25a for contacting the rear main body piece portion 3a from the lower surface to hold the mounting position of the negative ion generator M at a predetermined position.

FIG. 9 is a perspective view of the indoor unit with the front panel 2 and the top air filter 17 and the front air filter 18 removed.
The ion generator 20 and the heat exchanger 8 constituting the dust collector Z can be seen. That is, the ion generator 20 is attached to the frame assembly 16 that movably supports the upper air filter 17 and the front air filter 18. The attachment of the ion generator 20 to the frame assembly 16 is reliable, and the position does not change even if vibration is applied during the transportation of the product.

The ion generator 20 includes a main body 20A and a power supply 20B connected to one side of the main body 20A.
The main body portion 20A is opposed to the front surface of the front heat exchanger portion 8A constituting the heat exchanger 8 and along the substantially middle portion in the vertical direction. One end in the longitudinal direction of the main body portion 20A faces one end of the front heat exchanger portion 8A, and the other end in the longitudinal direction of the main body portion 20A faces a portion near the other side portion of the front heat exchanger portion 8A.

  That is, the main body portion 20A of the ion generator 20 is provided substantially over the width direction of the front heat exchanger portion 8A. The power supply unit 20B connected to the main body unit 20A is disposed on the front surface of one side end portion of the front heat exchanger unit 8A.

FIG. 10 is an exploded perspective view showing the ion generator 20.
The main body portion 20 </ b> A includes an ion generating electrode 45 and a counter electrode which is a ground electrode, and is configured by attaching the ion generating electrode 45 and the counter electrode to the electrode cover 46. In the figure, the ion generating electrode 45 is removed from the electrode cover 46.

  The counter electrode is attached to the electrode cover 46 and is further pressed against the electrode cover 46 by a presser cover. The ion generating electrode 45 has a plurality of needle electrodes b protruding integrally at a predetermined interval along the longitudinal direction. As the counter electrode, for example, a wire-like one is used. The counter electrode has the same overall length as the ion generation electrode 45 and is attached and supported on the electrode cover 46 only at both side ends.

  The presser cover regulates deformation such as loosening of the counter electrode while the counter electrode is attached to the electrode cover 46. In particular, since a high voltage is applied to the ion generating electrode 45, the electrode cover 46 and the presser cover are made of an ABS resin that is a flame-retardant resin.

  As shown in FIG. 1 again, the ion generator 20 is disposed in the indoor air suction passage 15 </ b> B formed as the indoor blower 10 is driven. Here, the heat exchanger 8 has conductivity. Specifically, for the fins of the front heat exchanger portion 8A and the rear heat exchanger portion 8B constituting the heat exchanger 8, a conductive aluminum material is selected so that the same potential as that of the counter electrode is applied. Connected to earth potential.

  Furthermore, antifouling treatment is performed on the fins of the heat exchanger 8. By performing this treatment, when the condensed water is generated on the surface of the heat exchanger 8 and flows down during the cooling operation, the dust adhering to the fin surface is lifted, and the dust is washed out together with the condensed water and left on the fin surface. There is no.

FIG. 11 is a diagram showing an internal structure of a power supply unit 20B that constitutes the ion generator 20 together with the main body unit 20A.
The power supply unit 20 </ b> B has a connection port part 48 </ b> A projecting from one side part of the box body 48 having a curved front part. A protrusion e into which the coil spring 50 is fitted is formed inside the connection port portion 48A, and the power supply unit 20B and the main body unit 20A can be detachably connected. And the high voltage power supply 52 is accommodated in the lower part in the box 48, and the PC board 53 by which electronic parts, such as resistance, were mounted in the upper part is attached.

  One end portion of a lead wire 54 is connected to one side portion of the PC board 53, and a terminal portion is connected to the other end portion of the lead wire 54 via an auxiliary spring 55. Further, a high voltage power source line 57 and a ground line 58 are connected to the PC board 53. The high-voltage power supply line 57 and the ground line 58 are combined into one, extended to the electric component box, and connected to the control electric component. From this, the ion generator 20 is electrically controlled together with other components.

FIG. 12 is a schematic electric circuit diagram of the negative ion generator M described above.
The needle electrode 31 and the ground screw 32 are arranged at a predetermined interval, the needle electrode 31 is connected to the high voltage power source 52 through a resistor, and the ground screw 32 is connected to the ground portion of the high voltage power source 52. Is done.

  The high-voltage power source 52 is the high-voltage power source 52 itself constituting the power source unit 20B of the ion generator 20 described above. In other words, the high-voltage power source 52 of the ion generator 20 is used as the high-voltage power source 52 of the negative ion generator M. Sharing.

  Although not particularly illustrated, the ion generator 20 is electrically connected directly from the high voltage power source 52 to the ion generating electrode 45 via a lead wire. For example, a resistor 60 of 500 MΩ or 1 GΩ is interposed between the electrode 31 and the electrode 31.

Next, the operation of the indoor unit of the air conditioner configured as described above will be described.
When the operation button on the remote controller (remote control panel) is pressed, the indoor blower 10 is driven and the negative ion generator M and the ion generator 20 constituting the dust collector Z are energized. Further, the compressor is driven in the outdoor unit communicating with the indoor unit through the refrigerant pipe, and the refrigeration cycle operation is started.

  The room air is sucked into the unit body 1 from the front suction port 4 and the upper surface suction port 5, is guided along the suction ventilation path 15 </ b> B, and passes through the front air filter 18 and the upper surface air filter 17. At this time, dust contained in the room air is captured by the front air filter 18 and the upper air filter 17.

The room air from which dust has been removed by the front air filter 18 and the top air filter 17 is sterilized and deodorized by the action of the dust collector Z.
Specifically, a negative high potential is applied to the ion generating electrode 45 including the needle electrode b from the high voltage power source 52, and negative ions are generated. Therefore, all dust and viruses passing through the suction ventilation path 15B or captured by the air filters 17 and 18 are efficiently negatively charged.

  On the other hand, since the same ground potential as that of the counter electrode constituting the ion generator 20 is applied to the heat exchanger 8, all the negatively charged dust and viruses are captured and collected in the heat exchanger 8. Dust. Since the dust collecting action is performed not only by the air filters 17 and 18 but also by the heat exchanger 8, an extremely high dust collecting effect can be obtained.

  Since the ion generating electrode 45 provided with the needle electrode b is disposed close to the heat exchanger 8, the discharge current is increased and the dust collection efficiency is improved. Since the ion generator 20 is disposed between the front air filter 18 and the heat exchanger 8, it is possible to prevent large dust such as cotton dust from adhering to the ion generation electrode 45 and the counter electrode.

  Dust adhering to the heat exchanger 8 is naturally removed by an antifouling process on the heat exchanger 8. Dust flows down to the front drain pan 12a or the rear drain pan 12b together with the dew condensation water, and is discharged to the outside through the drain hose. Therefore, it does not take any trouble to remove dust adhering to the heat exchanger 8.

  The cleaned indoor air flows through the heat exchanger 8, and heat exchange action is performed with the refrigerant led to the heat exchange air. The heat exchange air is guided along the blowout air passage 15A and blown into the room from the blowout port 6. At this time, negative ions are released by the action of the negative ion generator M and supplied to the room together with the heat exchange air.

  That is, by supplying a high voltage from the high voltage power supply 52 of the ion generator 20 to the electrode plate 36 constituting the negative ion generator M, negative ions are released from the tip of the needle electrode 31.

  In the negative ion generator M, in order to radiate a larger amount of negative ions, it is necessary to take a large potential difference between the tip of the needle electrode 31 and the periphery of the tip. Here, a ground screw 32 is provided in the vicinity of the tip of the needle electrode 31 and grounded via the ground wire 26b to ensure a potential difference from the tip of the needle electrode 31.

  Further, the distance between the tip of the needle electrode 31 and the ground screw 32 should be as far as possible from the viewpoint of preventing abnormal discharge. However, on the other hand, in order to keep the negative ion generation amount above a certain level, it is necessary to dispose the tip of the needle electrode 31 and the ground screw 32 as close as possible.

Under such circumstances, the distance between the tip of the needle electrode 31 and the ground screw 32 is set optimally (2.64 mm), and the negative ion generation amount is kept at a certain level or more while maintaining a distance at which abnormal discharge hardly occurs. Configured.
The needle electrode 31 is arranged such that this axial direction is perpendicular to the direction of the heat exchange air blown from the blowout port 6, and negative ions are opened facing the tip of the needle electrode 31. The first hole 40 is supplied toward the center of the outlet 6. Compared to the case where the needle electrodes are arranged along the blowing direction as in the conventional case, a larger amount of negative ions is efficiently put on the heat exchange air blown from the blowout port 6 and led into the room.

  The needle-like electrode 31 itself is accommodated in the case 30 and the first hole 40 facing the tip of the needle-like electrode 31 opens in a direction perpendicular to the blowing direction of the outlet 6. Therefore, dust does not easily adhere to the tip of the needle electrode 31 even during long-term use, and almost no maintenance work is required by the user.

  The opening area of the first hole 40 in the case 30 was set to the minimum necessary for negative ion emission. As a result, even if an abnormal discharge or the like occurs, it is possible to prevent sparks from being scattered around and prevent the spread of fire.

  By arranging a structure such as the negative ion generator M at the outlet 6, there are adverse effects such as deterioration in the amount of blown air of the heat exchange air, increase in blowing sound, and condensation when cooling in a high humidity state. Although concerned, since the cross-sectional shape of the lower box part 30B of the case 30 protruding to the outlet 6 is a so-called streamline shape, smooth air blowing can be promoted.

  The case 30 is provided with a slit 24 and has a semi-hermetic structure. In this type of air conditioner, cooling operation is often performed in a high humidity state. At this time, if the case has a sealed structure, the outer surface side is cooled, but the inside is in a state close to the outside air temperature, and condensation occurs inside the case, which may lead to a leakage accident.

  On the other hand, when the case 30 has a semi-sealed structure including the slit 24 as described above, a part of the cool air blown from the blowout port 6 is introduced into the case 30 through the slit 24, and the temperature is lowered. The temperature difference between the inside and the outside of the case 30 is eliminated, and the occurrence of condensation inside the case 30 can be prevented, so that no leakage accident occurs.

  The upper surface portion of the case 30 was opened and sealed with a cover plate 33 covered with a sheet 34 made of a flame-retardant material. By sealing the upper surface opening of the case 30 with a cover plate 33 made of a flame retardant material, even if an abnormal discharge occurs, it is possible to prevent sparks from being scattered inside the unit body 1 and reliably prevent fire damage.

The case 30 was provided with a first hole 40 facing the tip of the needle electrode 31 and a second hole 42 facing the ground screw 32. Therefore, the negative ion emission efficiency from the needle electrode 31 is further improved.
A cutout groove 43 was provided on the outer surface of the case 30 across the first hole 40 and the second hole 42. Due to the presence of the cutout groove 43, the creepage distance from the tip of the needle electrode 31 facing the first hole 40 to the ground screw 32 facing the second hole 42 can be shortened.

  The creeping distance is a distance for preventing radio wave leakage stipulated by law, and the ground screw 32 is passed from the tip of the needle electrode 31 through the first hole 40, the outer surface of the case 30, and the second hole 42. Say the distance to reach. Here, the creepage distance is set to 35.35 mm, and the radio wave leakage prevention effect is good.

  Note that the side wall portion of the case 30, the ground screw 32, and the boss portion 28 do not exist within a range of at least 2.5 mm from the tip of the needle electrode 31, and are a space portion. The distance between the tip of the needle electrode 31 and the ground screw 32 is the discharge distance, but here it is designed to be 8.49 mm. In addition to the creepage distance setting described above, the suppression of abnormal discharge is effective.

  In addition to the negative ion generator M provided at the outlet 6, a dust collector Z was provided at the front inlet 4. The dust collector Z includes an ion generator 20 that discharges negative ions and efficiently charges dust and viruses negatively, and a heat exchanger 8 to which a ground potential is applied.

  Here, negative ions are released from the negative ion generator M into the heat exchange air, and when the indoor air is sucked in, the ion generator 20 negatively charges the dust and viruses and adsorbs them to the heat exchanger 8. , Discharge to the outside with condensed water. Therefore, the removal speed with respect to dust and viruses increases, and no secondary contamination occurs.

  The ion generator 20 constituting the dust collector Z is provided with a high voltage power source 52, and negative ions are emitted from the ion generation electrode 45. The high voltage power source 52, as shown in FIG. It is also used as a high-voltage power source 52 constituting M. Therefore, simplification of the component configuration can be obtained.

  In the negative ion generator M, a resistor 60 having a predetermined capacity is interposed between the high voltage power source 52 and the needle electrode 31. By providing this resistor 60, it is possible to regulate so that an unnecessary current does not flow from the high-voltage power supply 52 to the needle electrode 31, and it is possible to more reliably prevent the occurrence of abnormal discharge.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above-described embodiments.

  DESCRIPTION OF SYMBOLS 4 ... Front suction port, 5 ... Upper surface suction port, 6 ... Outlet port, 1 ... Unit main body, 8 ... Heat exchanger, 10 ... Blower, M ... Negative ion generator (negative ion generation means), 31 ... Needle-like electrode 32 ... Earth screw, 30 ... Case, 40 ... First hole, 42 ... Second hole, 24 ... Slit, 33 ... Cover plate, 43 ... Notch groove, Z ... Dust collector (dust collecting means) ), 20 ... ion generator, 52 ... high voltage power supply, 60 ... resistance.

Claims (5)

In the unit body provided with a suction port and a blowout port, a heat exchanger and a blower are arranged opposite to each other, and indoor air is sucked into the unit body from the suction port to exchange heat with the heat exchanger. In the indoor unit of an air conditioner that blows out from the outlet through the blower into the room,
A negative ion generating means for generating negative ions by applying a high voltage to the outlet and supplying negative ions into the room is disposed.
The negative ion generating means is
A needle-like electrode disposed along a direction orthogonal to the blowing direction so that the tip is directed substantially to the center of the outlet, and a needle-like electrode attached at a predetermined distance from the needle-like electrode. A ground screw for securing a potential difference from the tip, and a semi-sealed case covering these needle electrodes and the ground screw,
The above case
A first hole for negative ion emission that is opened at a portion facing the tip of the needle electrode, and a second hole that is adjacent to the first hole and opened at a portion facing the ground screw A slit that is open on the surface opposite to the first hole and communicates the outside and the inside of the case;
An indoor unit of an air conditioner characterized by comprising:   The indoor unit of an air conditioner according to claim 1, wherein the case has an upper surface portion opened, and the case upper surface opening portion is covered and sealed with a cover plate made of a flame retardant material.   A notch groove is provided on the outer surface of the case, and the first hole and the second hole communicate with each other to shorten a creepage distance from the needle electrode to the ground screw. The indoor unit of an air conditioner according to claim 1, wherein Dust collecting means is attached to the vicinity of the suction port,
This dust collection means
An ion generator that is attached to the indoor air suction side of the heat exchanger and negatively charges dust or viruses contained in the indoor air that passes through the suction port when a negative high potential is applied;
The heat exchanger that secures a potential difference with the ion generator by applying a ground potential, and captures and collects negatively charged dust or viruses by the ion generator, and
The indoor unit of an air conditioner according to claim 1, wherein   The high-voltage power source of the negative ion generator is supplied from the high-voltage power source of the ion generator that constitutes the dust collecting means. The indoor unit of the air conditioner according to claim 4, wherein a resistor for cutting a current more than necessary is interposed.

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