KR102166436B1 - Indoor unit for air condition - Google Patents

Abstract

The present invention relates to an indoor unit of an air conditioner, wherein the indoor unit includes a casing including a front portion, a side portion, and a rear portion coupled to a wall surface; A frame to which the front, side and rear portions are combined; A filter assembly disposed on the upper portion of the casing and filtering and sucking air; A discharge part disposed under the casing and discharging the air sucked from the filter assembly; And an ion generating device disposed at the center of the upper side of the filter assembly and diffusing ions in both directions of the filter assembly, wherein dust in the air is charged by the ions diffused by the ion generating device to the filter assembly. It is characterized by being collected.

Description

Indoor unit of air conditioner {INDOOR UNIT FOR AIR CONDITION}

The present invention relates to an ion generating device and an indoor unit of an air conditioner including the same.

An air conditioner is a device for maintaining the air in a predetermined space in the most suitable state according to the use and purpose. In general, the air conditioner includes a compressor, a condenser, an expansion device, and an evaporator, and a refrigeration cycle for compressing, condensing, expanding, and evaporating a refrigerant is driven to cool or heat the predetermined space. .

The predetermined space may be proposed in various ways depending on the location where the air conditioner is used. For example, when the air conditioner is disposed in a home or office, the predetermined space may be an indoor space of a house or building.

When the air conditioner performs a cooling operation, an outdoor heat exchanger provided in the outdoor unit functions as a condenser, and an indoor heat exchanger provided in the indoor unit functions as an evaporator. On the other hand, when the air conditioner performs a heating operation, the indoor heat exchanger functions as a condenser and the outdoor heat exchanger functions as an evaporator.

The air conditioner can be classified into an upright type, a wall-mounted type, or a ceiling type, depending on the installation location. The upright air conditioner is a type of air conditioner installed to be erected in an indoor space, and the wall-mounted air conditioner is understood as a type of air conditioner installed to be attached to a wall surface. In addition, the ceiling type air conditioner is understood as a type air conditioner installed on the ceiling.

In addition, in the case of the recently released wall-mounted air conditioner, a suction grill or a filter assembly is being released to be disposed on the upper side. This has an effect that when the wall-mounted air conditioner is installed on the inner wall of the indoor space, the user does not see the suction grill or the filter assembly, and the clean appearance of the air conditioner is seen from the outside.

However, when the suction grill or the filter assembly is installed on the upper side, there is a problem that dust of the air flowing into the suction grill or filter assembly is not effectively filtered.

In particular, there has been a problem that foreign matter in the upper air is not collected by the suction grill or the filter assembly, but is dispersed downward.

The present invention is proposed to solve the above problems.

In particular, an object of the present invention is to provide an indoor unit of an air conditioner in which an ion generator is disposed above the filter assembly in order to effectively collect dust in the filter assembly.

Another object of the present invention is to provide an indoor unit of an air conditioner in which the structure of the ion generating device is designed in order to maximize the ion concentration diffused from the ion generating device.

In addition, by specifying the arrangement position of the ion generating device, the purpose of providing an indoor unit of an air conditioner capable of efficiently collecting air from the entire filter assembly by spreading ions evenly throughout the filter assembly do.

The indoor unit of the air conditioner according to an embodiment of the present invention includes a casing including a front portion, a side portion, and a rear portion coupled to a wall surface; A filter assembly disposed on the casing and filtering air; A discharge part disposed under the casing and discharging air that has passed through the filter assembly; A frame disposed inside the casing and to which the front, side and rear portions are combined; And an ion generating device coupled to the frame and disposed above the filter assembly, applying a high voltage to discharge air to ionize molecules in the air to generate ions, wherein the ion generating device generates ions in the air. It is characterized in that the dust is charged and collected in the filter assembly.

In addition, the ion generating device may include an ion generator for ionizing molecules in the air by applying a voltage to both sides in order to form a clean appearance and effectively generate ions; And a case covering the ion generating unit, and ion diffusion ports for diffusing ions may be formed on both sides of the case.

In addition, in order to increase the amount of charged dust diffused into the filter assembly, the diameter of the ion diffusion port is 10 mm or more.

In addition, in order to increase the air ionization rate above the filter assembly, a distance between the ion divergence port and the filter assembly is 20 mm or more.

In addition, the ion generating unit may include a circuit for generating a high voltage; A circuit case surrounding the circuit; And electrodes disposed on both sides of the circuit case and discharging high voltage generated in the circuit to ionize molecules in the air.

In addition, the electrode is disposed in the ion divergence port, and a voltage applied from the electrode through the ion divergence port is discharged so that molecules in the air may be ionized.

In addition, the ion generator may include an electric wire electrically connecting the circuit and the electrode; A wire cover surrounding the wire; And an electrode cover surrounding the electrode, and the electrode cover may be disposed in the ion diffusion port.

In addition, the case, a first case forming an upper surface appearance; A second case coupled to a lower portion of the first case and having an ion generating unit receiving space disposed below the ion generating unit; And a third case coupled to a lower portion of the second case and connected to the frame.

In addition, the second case may include a curved portion forming an upper surface and having a constant curvature upward; And two extension portions extending downward from both sides of the curved portion, and the ion generating portion accommodating space may be formed between the curved portion and the two extension portions.

In addition, the ion generating device is characterized in that the ion diffusion ports are disposed on the two extensions respectively to radiate ions to both sides.

In addition, in order to extend the cable of the ion generating unit to the indoor unit without being exposed to the outside, a first cable opening is formed at the rear side of the lower surface of the second case, and a second cable opening is formed at the third case, and The first cable opening and the second cable opening are characterized in that they communicate.

In addition, the ion generating device is disposed on one side of the case, and further includes a light emitting unit that emits light to the outside when the ion generating unit is driven, so that a user can check the driving of the ion generating device from the outside.

An indoor unit of an air conditioner according to another embodiment of the present invention includes a casing having a rear portion attached to a wall surface; A filter assembly disposed above the casing to filter air; A discharge part for discharging the air filtered from the filler assembly; A frame disposed inside the casing to connect the rear portion and the discharge portion; A case connected to the frame and disposed above the filter assembly; An ion generating unit disposed inside the case and discharging a voltage to generate ions to charge foreign substances in the air; And an ion divergence port disposed on one side of the case and through which ions generated from the ion generating unit are emitted.

In addition, two ion diffusion spheres are formed on each side of the case, and the size of the ion diffusion sphere may be 10 mm or more.

In addition, the filter assembly is characterized in that it collects foreign matter charged by the ion generator.

An indoor unit of an air conditioner according to another embodiment of the present invention includes: a casing including a front portion, a side portion, and a rear portion coupled to a wall; A suction unit disposed on one side of the casing and inhaling air from the outside; A discharge part disposed on the other side of the casing and discharging the air sucked by the suction part; A filter assembly disposed in the suction unit and filtering foreign substances in the air; It is disposed above the suction unit and includes an ion generator for generating ions by ionizing molecules in the air by discharging the air by applying a high voltage, and the dust in the air is charged by the ions generated by the ion generating device, and the filter By collecting the dust in the assembly, it is possible to collect dust from the air sucked into the suction unit.

In addition, the filter assembly may be disposed between the suction unit and the ion generating device.

The indoor unit of the air conditioner according to the embodiment of the present invention having the above configuration has the following effects.

First, by arranging the ion generator above the filter assembly, it is possible to effectively collect dust in the filter assembly by ionizing molecules in the air sucked by the filter assembly and charging the dust in the air.

Second, by designing the diameter of the ion divergence port formed in the ion generating device to have a predetermined size, by increasing the concentration of ions diffused into the ion generating device, it is possible to increase the dust charging rate of the air around the filter assembly, and accordingly, the filter assembly It has the effect of increasing the dust collection rate of

Third, by designing the interval between the ion generator and the filter assembly to maintain a set interval, there is an effect of increasing the ionization efficiency of molecules in the air above the filter assembly.

Fourth, there is an effect of providing an ion generating device having a clean appearance from the outside by forming the outer appearance of the ion generating device as a case and installing the ion generating unit inside.

Fifth, as the cable connected to the ion generator extends from the inside of the case to the inside of the indoor unit, the cable is not visible from the outside and has a neat effect.

1 is a perspective view of an indoor unit of an air conditioner according to an embodiment of the present invention.
2 is a front view of the indoor unit of the air conditioner according to the embodiment of the present invention.
3 is an exploded perspective view of an indoor unit of an air conditioner according to an embodiment of the present invention.
4 is a perspective view of an ion generating device in the configuration of an indoor unit.
5 is an exploded view of an ion generating device in the configuration of an indoor unit.
6 is a bottom view of an ion generator in the configuration of the ion generator.
7 is a bottom view of a first case in the configuration of the ion generating device.
8 is a rear perspective view of the lower surface of a second case in the configuration of the ion generating device.
9 is a front perspective view of a lower surface of a second case and a light emitting portion of the configuration of the ion generating device.
10 is a side view of the lower surface of a second case in the configuration of the ion generating device.
11 is a view showing a configuration in which the ion generator is coupled to the lower surface of the second case.
12 is a bottom perspective view of a third case.
13 is a graph showing the result of measuring the ion concentration according to the diameter of the ion diffusion port of the ion generating device mounted in the indoor unit of the air conditioner according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention will be able to easily propose other embodiments within the scope of the same idea.

1 is a perspective view of an indoor unit of an air conditioner according to an embodiment of the present invention, FIG. 2 is a front view, and FIG. 3 is an exploded perspective view.

1 to 3, an indoor unit 10 is included in an air conditioner according to an embodiment of the present invention. As an example, the indoor unit 10 may include a wall-mounted indoor unit installed on a wall surface of an indoor space.

The indoor unit 10 includes a casing 100 forming an exterior. The casing 100 includes a front portion 101 forming the front appearance of the indoor unit, and side portions 103 provided on both sides of the front portion 101 and extending rearward from the front portion 101 toward the wall surface. Included.

In addition, the casing 100 further includes a rear portion 105 disposed on the rear side of the side portion 103. The rear portion 105 is disposed between the side portions 103 and may be coupled to a wall surface of an indoor space.

The front portion 101, both side portions 103, and the rear portion 105 form an inner space, and a plurality of components provided in the indoor unit 10 may be accommodated in the inner space. The plurality of components may include a heat exchanger (not shown) and a fan (not shown).

The indoor unit 10 further includes a filter assembly 120 disposed on the casing 100. The filter assembly 120 may form an upper surface of the casing 100. In addition, the filter assembly 120 is formed with a plurality of filter inlet (122a) for sucking the air in the indoor space into the interior of the indoor unit (10). The air sucked through the filter inlet 122a may be cooled or heated while passing through the heat exchanger.

That is, the filter assembly 120 may be formed on the upper surface of the casing 100 and disposed in a suction part through which air is sucked to filter air. The suction part may be an opening formed by an upper surface of the front part 101, both side parts 103 and the rear part 105 of the casing 100.

The filter assembly 120 may include a filter member 122 and a filter case 124.

The filter member 122 may have a configuration in which a plurality of filter intake ports 122a are formed, in this case, the filter member 122 is composed of a plurality of frames for forming a plurality of filter intake ports 122a. Can be. In addition, a net may be disposed in the filter inlet 122a to filter the inhaled air.

In addition, when an ion generating device to be described later is coupled to the filter member 122, a filter groove 122b may be formed in a part of the rear end so as not to interfere with the ion generating device 200. This is a configuration for effectively attaching and detaching the filter member 122 in a state in which the ion generating device 200 is coupled, and the filter groove 122b has an area larger than the upper surface area of the ion generating device 200. Can have.

The filter case 124 is disposed under the filter member 122 and has a configuration in which the filter member 122 is coupled. In detail, the filter case 124 may have a plurality of filter case openings 124a corresponding to the plurality of filter suction ports 122a formed in the filter member 122. In addition, a filter case groove 124b may be formed in the filter case 124 in a shape corresponding to the filter groove 122b of the filter member 122.

For example, a plurality of coupling ribs may be disposed on the rim of the filter case 124, and the rim of the filter member 122 may be coupled by being fitted to the plurality of coupling ribs. This is an example, and the filter member 122 and the filter case 124 may be integrally formed.

The indoor unit 10 further includes a discharge panel 140 disposed under the casing 100 and having a discharge port 142 through which air sucked into the indoor unit 10 is discharged. A discharge vane 145 may be installed in the discharge port 142 to be movably provided to adjust a discharge direction or air volume of air discharged from the discharge port 142. For example, the discharge vane 145 may be provided to be rotatable forward and backward around hinge axes provided at both ends of the discharge vane 145.

When the fan is driven, air in the indoor space is sucked into the indoor unit 10 through the filter assembly 120 and heat exchanged in the heat exchanger. In addition, the heat-exchanged air may be discharged through the discharge port 142.

In the present embodiment, it has been described that the filter assembly for sucking air into the indoor unit is positioned above the indoor unit, and the outlet 142 for discharging the air is positioned below the indoor unit 10. However, on the contrary, the filter assembly 120 may be located under the indoor unit and the discharge part 140 may be located above the indoor unit. As another example, an additional filter assembly 120 or a discharge part 140 may be formed on the front part 101 of the casing 100.

In summary, the indoor unit 10 according to the present invention may be configured to generate air flows such as upper suction and lower discharge, lower suction and upper discharge, front suction and lower discharge, upper suction and front discharge.

A sensor device 160 capable of detecting the amount of dust contained in the air in the indoor space may be provided on the side surface 103 of the casing 100. Since the sensor device 160 is installed on the side surface 103, the amount of dust can be detected by inhaling only a small amount of air through the sensor device 160 without being affected by the intake and discharge air flow through the indoor unit 10. have.

In addition, the indoor unit 10 may further include a frame portion 170 to which the side portion 103 is connected and the front portion 101 is coupled.

In detail, the frame part 170 includes a first frame 171 extending a lower front surface of the side part 103, a second frame part 173 extending a rear end of the upper surface of the side part 103, and the first frame. A third frame 175 may be disposed between the 171 and the second frame part 173 to connect the upper front surface of the side part 103.

The front portion 101 may be coupled to the front surface of the side portion 103 by the first frame 171 and the third frame 175. In detail, a plurality of fitting ribs may be formed on the rear surface of the front part 101, and a plurality of protruding ribs 171a protruding forward from the first frame part 171 and the third frame part 175 , 175a) may be formed, and the front portion 101 may be coupled to the front end of the side portion 103 by coupling the plurality of protruding ribs 171a and 175a to the plurality of fitting ribs.

In addition, between the second frame 173 and the third frame 175, a plurality of reinforcing frames 177 supporting the filter assembly 120 and an ion generating device 200 to be described later may be combined. A combination frame 179 may be disposed.

The reinforcement frame 177 is disposed to extend between the second frame 173 and the third frame 175, so that the filter assembly 120 may be supported on the upper side. The reinforcing frame 177 may form a plurality of empty spaces between the plurality of frames as a plurality of frames are combined with each other, and thus may serve as a skeleton supporting the filter assembly 120. have.

In addition, the coupling frame 179 is disposed to extend the second frame 173 and the reinforcing frame 177, so that the ion generating device 200 may be coupled.

The coupling frame 179 is disposed between the second frame 173 and the reinforcing frame 177 in a C shape, so that the ion generating device 200 may be coupled. In detail, the ion generating device 200 may be rotatably coupled to the coupling frame 179.

In more detail, the coupling frame 179 includes two first coupling frames 179a extending the second frame 173 and the reinforcing frame 177, and a front end of the two first coupling frames 179a. It may include a second coupling frame (179b) connecting the.

In addition, a rotation protrusion 179c may be formed on the first coupling frame 179a so that the rotation part 274 of the ion generating device 200 to be described later may be coupled. That is, a rotation protrusion 179c protruding in the direction of the first coupling frame 179a facing each other may be formed on each of the two first coupling frames 179a.

The ion generating device 200 is disposed above the indoor unit 10 and is a means capable of diffusing ions to both sides. In detail, the ion generating device 200 is coupled to the frame 170 and is a means capable of diffusing ions to both sides.

The ion generating device 200 ionizes molecules in the air by generating a high voltage to both sides, thereby charging dust by the ionized molecules, and the charged dust can be effectively collected in the filter assembly 120. .

Hereinafter, the configuration of the ion generating device 200 will be described in detail.

4 is a perspective view of an ion generating device in the configuration of the indoor unit, and FIG. 5 is an exploded view. 6 is a bottom view of the ion generator in the configuration of the ion generator, FIG. 7 is a bottom view of the first case in the configuration of the ion generator, and FIG. 8 is a rear perspective view of the bottom of the second case in the configuration of the ion generator. .

9 is a front perspective view of the lower surface of the second case and the light emitting part of the configuration of the ion generating device 200, FIG. 10 is a side view of the lower surface of the second case of the configuration of the ion generating device, and FIG. 11 is It is a view showing a configuration in which the generator is coupled, and FIG. 12 is a bottom perspective view of a third case.

4 to 12, the ion generating device 200 may include cases 210, 230 and 250 and an ion generating unit 250 installed inside the cases 210, 230 and 250.

The ion generating unit 250 is a means for generating ions in the lateral direction, and the case 210, 230, 250 is coupled to the ion generating unit 250, and guides the ions generated from the ion generating unit 250 to the side. It is a means.

The ion generator 250 generates a high voltage and discharges it at the electrode 253 to ionize molecules in the air. The ions generated in the ion generating unit 250 may be diffused laterally through the cases 210, 230, and 250 to charge foreign substances in the air, and thus charged foreign substances may be collected in the filter assembly 120.

The ion generator 250 is disposed outside the circuit 251 for generating a high voltage, a circuit case 252 surrounding the circuit 251, and the circuit case 252, and in the circuit 251 An electrode 253 that ionizes molecules in the air through discharge by the generated high voltage, a wire 255 electrically connecting the electrode 253 and the circuit 251, and a sideways from the circuit case 252 It may include a wire cover 256 protruding to support the wire 255 and an electrode cover 254 extending from the wire cover 256 and covering the electrode 253.

The circuit 251 is a means for generating a high voltage so that the electrode 253 can discharge. The circuit 251 may generate a high voltage AC current, a positive or negative DC current, a pulse DC current, and the like and supply them to the electrode 253. In this embodiment, the circuit is a constant voltage circuit that generates a cathode DC current. It is desirable to output the circuit with an output voltage of -7kVp ± 8%, an output frequency of 100Hz ± 10%, and a duty of 15 to 25%. The circuit includes a circuit board and various electronic devices.

The circuit case 252 is a means for protecting the circuit 251 and enclosing the circuit so that a short circuit does not occur in the circuit 251. For example, the circuit case 252 is preferably formed of a rectangular parallelepiped made of a plastic material.

In addition, the circuit case 252 may be molded with silicon 257 to protect the circuit 251. In detail, the circuit case 252 may have a rectangular parallelepiped box shape with an open top, and in this case, the circuit 251 may be placed in an opening formed on the top of the circuit case 252. The silicon 257 may be molded to surround the circuit in a state in which the circuit 251 is placed in an opening formed in the upper portion of the circuit case 252.

One or more coupling ribs 252a and 252b may be disposed on an upper front side and an upper rear side of the circuit case 252, respectively. In detail, one or more first coupling ribs 252a may be disposed above the front end of the circuit case 252, and one or more second coupling ribs 252b may be disposed above the rear end of the circuit case 252. have. The coupling configuration of the first coupling rib 252a and the second coupling rib 252b will be described later.

In addition, a first fastening portion 258 may be formed on a side surface of the circuit case 252. The first fastening part 258 is formed with a first fastening hole 258a, so that a screw or screw may be coupled thereto. The second case 230 and the third case 270 to be described later may be coupled by the first fastening part 258, and a detailed description thereof will be described later.

The wire 255 may protrude from the circuit case 252 and be connected to the electrode 253. In detail, the wire 255 is formed in a bar shape, and one end is connected to the circuit case 252 and the other end is connected to the electrode 253, thereby preventing leakage of current. The electric wire 255 may include a conducting wire for transmitting the high voltage generated by the circuit 251 to the electrode 253 and a plastic covering material surrounding the outside of the conducting wire. The wire 255 electrically connects the circuit 251 and the electrode 253.

In addition, the wires 255 may be disposed in plural according to the number of the electrodes 253. In this embodiment, two wires 255 are disposed on both sides of the circuit case 252 to be spaced apart from each other, so that a total of four wires may be disposed. The wire 255 may be supported by the wire cover 256.

The electrode 253 is a means for ionizing molecules in the air through discharge. In detail, when the high voltage generated in the circuit 251 is applied to the electrode 253 through the wire 255, the electrode 253 may be discharged and molecules in the air may ionize to generate ions. When a high voltage is applied to the electrode 253, anions such as OH- and O- or cations such as H+ are generated.

The electrode 253 may include carbon fiber. In detail, the electrode 253 may be made of ultra-fine carbon fiber, and ions may be generated by corona discharge. For example, the electrode 253 is preferably in the form of a brush in which hundreds of ultrafine carbon fibers having a diameter in micrometer unit are bound to the wire 255. In this embodiment, the electrode 253 has a brush shape in which about 1000 carbon fibers having a diameter of 7 μm are gathered.

The brush-shaped electrode 253, which is a bundle of carbon fibers, may discharge only one of hundreds of carbon fibers, and in this case, the discharge effect may be increased by the remaining carbon fibers. According to an exemplary embodiment, the electrode 253 may be formed in a needle shape or a network shape having a pattern. The electrodes 253 may be disposed in plural, and in this embodiment, four are disposed.

It is preferable that the plurality of electrodes 253 are properly spaced apart to minimize mutual interference. For example, the plurality of electrodes 253 are preferably disposed to be spaced apart from each other on a virtual plane perpendicular to the flow direction of air, and are preferably disposed to be symmetrical in the vertical direction and/or the left and right directions. The electrode 253 may be disposed not to contact the circuit case 252 by the wire 255.

Ions generated by the electrode 253 may charge foreign substances in the air. In detail, the anion may provide electrons to the foreign material to charge the foreign material to the negative electrode, and the cation may take electrons from the foreign material and charge the foreign material to the positive electrode.

The wire cover 256 may protrude from the circuit case 252 and may be formed of a plastic material that is the same material as the circuit case 252. The wire cover 256 may be formed integrally with the circuit case 252 or may be formed separately and coupled to the circuit case 252. One side of the wire cover 256 may be connected to the circuit case 252 and the other side may be connected to the electrode cover 254. The wire cover 256 may be provided in plural corresponding to the number of the wires 255, and four are provided in this embodiment.

The wire cover 256 is formed in a cylindrical shape to surround the circumference of the rod-shaped wire 255. The wire cover 256 is formed in a substantially semicircular cylindrical shape with a part of the side open so as to surround only a part of the circumference of the wire 255. In detail, it is preferable that the wire cover 256 is opened upward. Accordingly, a portion of the electric wire 255 may be exposed without being covered by the electric wire cover 256 on the upper side.

The wire cover 256 may include a support protrusion 256a protruding forward from a portion of the opened side. In detail, the support protrusion 256a may support the electric wire 255. The support protrusion 256a may be coupled to the circumference of the electric wire 255 so that a part of the electric wire 255 may be fixedly disposed within the electric wire cover 256.

The electrode cover 254 is connected to the wire cover 256 and is formed of a plastic material. The electrode covers 254 may be provided in plural corresponding to the number of the plurality of electrodes 253, and in this embodiment, four are provided. It is preferable that the plurality of electrode covers 254 are properly spaced apart from each other. In detail, the electrode cover 254 is disposed to be spaced apart from the circuit case 252 by the wire cover 256.

The end of the electrode cover 254 is formed to protrude from the end of the electrode 253. Here, the end means the end of the wire 255 or the wire cover 256 in the longitudinal direction. It is preferable that the distance between the end of the electrode cover 254 and the end of the electrode 253 is about 1 mm. It is preferable that the end of the electrode 253 does not protrude from the end of the electrode cover 254 so that the end of the electrode 253 is protected from the outside.

The cases 210, 230, and 250 include a first case 210 forming an upper exterior of the ion generating device 200, a second case 230 coupled to a lower side of the first case 210, and the second case A third case 270 coupled to the lower side of 230 may be included.

The ion generating unit 250 may be disposed between the second case 230 and the third case 270. A detailed description of this will be described later.

Define the direction. Based on the configuration of the entire indoor unit, it can be seen that the first to third cases 270 are arranged in the vertical direction. Therefore, hereinafter, the first case 210 forms the upper surface of the ion generating device 200 based on the cases 210, 230, 250 of the ion generating device 200, and the third case 270 is It will be described as forming the lower surface of the generator 200. In addition, based on the configuration of the entire indoor unit, the rear direction of the indoor unit is defined as rear and the front direction is defined as front.

The first case 210 has a shape having an upper surface forming a constant curvature upward, and the first case body 211 forming the upper exterior of the ion generating device 200 and the first case body 211 The lower surface may include a plurality of coupling ribs 212 disposed on the front and rear sides.

In this case, the plurality of coupling ribs 212 may be disposed to protrude so as to be spaced apart from each other in a front extension direction and a rear extension direction of the first case body 211. The plurality of coupling ribs 212 is a means for coupling to the second case 230.

The second case 230 may include a second case body forming an installation space in which the ion generating unit 250 and the light emitting unit 280 to be described later may be disposed. In detail, the second case body has a first curved portion 231 formed to have a predetermined curvature in a shape corresponding to the first case body 211, and downward from both side ends of the first curved portion 231 It may include two extension portions 232 that are bent and extended.

The ion generating part 250 and the light emitting part 280 may be disposed in an installation space formed by the first curved part 231 and the extension part 232.

The first curved portion 231 may have a plurality of coupling grooves 231a formed on the upper surface thereof. In detail, a plurality of coupling grooves 231a for coupling a plurality of coupling ribs 212 of the first case 210 may be formed at the front and rear ends of the upper surface of the first curved portion 231. When the first case body 211 is coupled to the first curved portion 231, a plurality of coupling grooves 231a formed on the upper surface of the first curved portion 231 may be provided with the first case body 211 ) May be formed at a position corresponding to the plurality of coupling ribs 212 of the first case 210 so that a plurality of coupling ribs formed in) can be coupled.

Further, a plurality of coupling grooves 231b may be formed on the lower surface of the first curved portion 231. In detail, a plurality of coupling grooves 231b for coupling the third case 270 may be formed at front and rear ends of the lower surface of the first curved portion 231. The coupling relationship between the plurality of coupling grooves 231b formed on the lower surface of the first curved portion 231 will be described later.

A light emitting unit receiving space 310 may be disposed in the front side of the installation space formed under the second case body, that is, the installation space formed by the first curved portion 231 and the extension portion 232.

In detail, the light emitting part accommodating space 310 is formed on the lower front side of the second case body, and the light emitting part 280 to be described later may be installed. In more detail, a light emitting port 231c may be formed on the front surface of the second case body, and the light emitting part 280 may be disposed at a position of the light emitting port 231c.

A light emitting part coupling rib 233 to which the light emitting part 280 is coupled may be disposed in the light emitting part accommodating space 310. In detail, the light-emitting part coupling rib 233 may have a C-shaped shape, and light generated from the light-emitting part 280 by the light-emitting part coupling rib 233 may radiate only toward the light-emitting port 231c It can be used, and light can be blocked from emanating in other directions. That is, the light emitting part coupling rib 233 may include a first rib 233a and a second rib 233b extending forward from both side ends of the first rib 233a.

The light emitting part 280 may be disposed on the front surface of the first rib 233a, and the light generated from the light emitting part 280 by the first rib 233a and the second rib 233b is It may radiate only in the direction of the front light emitting port 231c.

The light-emitting unit 280 may include a light-emitting circuit 281 for generating light by applying a voltage, and a diffusion unit 282 for diffusing the light generated from the light-emitting circuit 281.

The light emitting circuit 281 may include an LED, but is not limited thereto. When the ion generating device 200 is driven, the light emitting circuit 281 generates light by applying a voltage, so that the external user can visually confirm that the ion generating device 200 is being driven. . In addition, the light emitting circuit 281 may be fixed to the first curved portion 231 by being fitted on both sides of the fitting grooves 233c respectively formed in the second ribs 233b.

The diffusion unit 282 is formed of a transparent material, so that light generated from the light emitting circuit 281 may emit light evenly through the diffusion unit 282. In detail, the diffusion part 282 is disposed to shield the light emitting port 231c, so that light emitted in the direction of the light emitting port 231c may be radiated to the outside through the diffusion part 282.

In addition, the diffusion part 282 includes a plate-shaped diffusion plate 252a that shields the light emitting hole 231c, and a coupling plate protruding upward from the diffusion plate 252a to be coupled to the second case body. (252b) may be included.

In this case, a diffusion portion 282 coupling groove for fitting the coupling plate 252b of the diffusion portion 282 may be disposed in the light emitting portion receiving space 310 of the lower surface of the second case body. The diffusion plate 252a may be fixed to the second case body by fitting both side ends of the coupling plate 252b of the diffusion portion 282 into the coupling groove of the diffusion portion 282.

A portion of the installation space in which the second case body is formed except for the light emitting unit receiving space 310 may be defined as an ion generating unit receiving space 320 in which the ion generating unit 250 is accommodated.

One or more guide devices 234 and 235 protruding downward from the lower surface of the second case body and extending laterally may be disposed in the ion generating unit receiving space 320.

In detail, the guide devices 234 and 235 include a first guide device 234 disposed at the front side of the ion generating unit receiving space 320 and a second guide device disposed at the rear side of the ion generating unit receiving space 320 ( 235).

The first guide device 234 may be disposed to extend laterally from the front side of the ion generating unit receiving space 320. In detail, the first guide device 234 is a first guide rib (234a) that extends to the side to contact the upper surface of the circuit case 252, and protrudes downward from one end of the first guide rib (234a). The first protruding rib 234b and the second protruding rib 234c are spaced apart from the other end of the first guide rib 234a and protrude downward to have the same height as the first protruding rib 234b. Can include.

In this case, a distance L1 between the first protruding rib 234b and the second protruding rib 234c may be greater than a distance between both side ends of the upper surface of the circuit case 252. Accordingly, by pushing the circuit case 252 in a state in which the first protruding rib 234b and the second protruding rib 234c are inclined and disposed, the first protruding rib 234b and the second protruding rib The circuit case 252 may be disposed between the ribs 234c.

In addition, between the spaced apart spaces of the first guide rib 234a and the second protruding rib 234c, a cable required for circuit configuration, for example, a cable connected from the circuit 251 to the main circuit inside the indoor unit Can pass.

The second guide device 235 may be disposed to extend laterally from the rear side of the ion generating unit receiving space 320. In this case, the second guide device 235 may be spaced from the first guide device 234 rearward at a predetermined interval, and may have a shape symmetrical to each other with the first guide device 234. In this case, it is preferable that the length of the spaced space between the first guide device 234 and the second guide device 235 is shorter than the length from the front end to the rear end of the circuit case 252.

In detail, the second guide device 235 is a second guide rib 235a that extends laterally and contacts the upper surface of the circuit case 252, and protrudes downward from one end of the second guide rib 235a. A fourth protruding rib 235c that is spaced apart from the other end of the third protruding rib 235b and the second guide rib 235a and protruded downward to have the same height as the third protruding rib 235b. Can include.

In this case, a distance between the third protruding rib 235b and the fourth protruding rib 235c may be greater than a distance L2 between both side ends of the upper surface of the circuit case 252. Accordingly, by pushing the circuit case 252 in a state in which the third protruding rib 235b and the fourth protruding rib 235c are inclined and disposed, the third protruding rib 235b and the fourth protruding The circuit case 252 may be disposed between the ribs 235c.

In addition, a cable required for circuit configuration may pass between the spaced apart spaces of the second guide rib 235a and the fourth protruding rib 235c.

One or more coupling openings 236a and 236b may be formed at front and rear sides of the first curved portion 231 of the second case body. In detail, one or more first coupling openings 236a may be formed on the front side of the first curved portion 231, and one or more second coupling openings 236b may be formed on the rear side of the first curved portion 231. have. In this case, the distance between the first coupling opening 236a and the second coupling opening 236b may be the same as the distance from the front end to the rear end of the circuit case 252.

Accordingly, in order for the ion generating unit 250 to be disposed in the ion generating unit accommodating space 320, the circuit case 252 is attached to the first guide device 234 and the second guide device 235. When fitted, the first coupling rib 252a formed in the circuit case 252 is fitted into the first coupling opening 236a, and the second coupling rib 252b is inserted into the second coupling opening 236b. ), the circuit case 252 may be firmly fixed to the second case body.

In addition, one or more first support ribs 237a protruding rearward from the rear surface of the first rib 233a of the receiving rib of the light emitting unit 280 are disposed under the first coupling opening 236a, and the first 2 One or more second support ribs 237b protruding forward of the protruding surface protruding downward of the second case body may be disposed below the coupling opening 236b.

In this case, the distance between the first coupling opening 236a and the first support rib 237a may be the same as the shear height of the circuit case 252, and the second coupling opening 236b and the second 2 The separation distance between the support ribs 237b may be the same as the height of the rear end of the circuit case 252.

Accordingly, when the first coupling rib 252a and the second coupling rib 252b of the circuit case 252 are fitted into the first coupling opening 236a and the second coupling opening 236b, the circuit The lower front end of the case 252 is supported by the first support rib 237a and the lower end of the case 252 is supported by the second support rib 237b, so that the ion generating device 200 is It may be rigidly fixed to the first curved portion 231.

In addition, one side of the first curved portion 231, in detail, in the remaining space except for the ion generating unit receiving space 320 and the light emitting unit receiving space 310, a fastening means such as a screw or screw can be coupled 2 The fastening part 238 may be disposed. A second fastening hole 238a is formed in the second fastening part 238, whereby the circuit case 252, the third case 270, and the second case 230 may be fixed to each other. . The fastening method will be described later.

A plurality of coupling grooves may be formed on a lower surface of the first curved portion 231. In detail, a plurality of coupling grooves for coupling a plurality of coupling ribs of the third case 270 to be described later may be formed at a front end and a rear end of the lower surface of the first curved portion 231. A coupling relationship between the third case 270 and the second case 230 will be described later.

The extension part 232 may be disposed to extend downwardly from both side ends of the first curved part 231.

In addition, one or more ion divergence ports 239 may be formed in the extension part 232. In detail, when the circuit case 252 is coupled to the first curved portion 231, the ion divergence port 239 may be an opening in which the electrode cover 254 can be accommodated. In this case, the ion divergence port 239 may include a circular opening, and the diameter of the ion divergence port 239 may be larger than the diameter of the electrode cover 254.

In this embodiment, four ion diffusion holes 239 are formed in the extension part 232 equal to the number of the electrode covers 254, but the present invention is not limited thereto, and the number of the electrode covers 254 The number of the ion divergence ports 239 may also vary.

The electrode 253 covered by the electrode cover 254 may ionize air through discharge through the ion diffusion port 239.

The third case 270 is disposed at both ends of the body of the third case 270 and the body of the third case 270 forming the lower exterior of the ion generating device 200, the coupling frame 179 ) May include a rotating portion 274 coupled to be rotatable.

By the body of the third case 270, the ion diffusion port 239 and the filter assembly 120 may be spaced apart by a set interval. In this case, the setting interval may be 20 mm or more. As the ion divergence port 239 and the filter assembly 120 are spaced apart by 20 mm or more, the ions emitted from the ion divergence port 239 are effectively diffused to both ends of the filter assembly 120.

The body of the third case 270 is disposed above the third case 270 and has a second curved portion 271 having a predetermined curvature downward, and a lower side from the rear lower end of the second curved portion 271 It may include a spacing portion 272 extending to the second curved portion 271 to separate from the filter assembly 120.

The second curved portion 271 may have a curved shape having a predetermined curvature downward in a direction opposite to the first curved portion 231, and a first cable opening may be formed at a rear end. In detail, a plurality of cables electrically connected to the light emitting unit 280 and the ion generating device 200 may extend into the indoor unit through the first cable opening.

In addition, a plurality of coupling ribs 271a for coupling the plurality of coupling grooves 231b formed on the lower surface of the first curved portion 231 may be disposed on the second curved portion 271. In detail, a plurality of coupling ribs 271a are disposed at the front and rear ends of the upper surface of the second curved portion 271, and formed on the lower surface of the first curved portion 231 of the second case 230. The coupling groove (231b) may be fitted.

In addition, a third fastening portion 276 may be disposed on an upper surface of the second curved portion 271. A third fastening hole 276a may be formed in the third fastening part 276. In this case, when the second case 230, the ion generating part 250, and the third case 270 are combined, the second fastening part 238 formed in the second case 230 The fastening hole 238a, the first fastening hole 258a of the first fastening part 258 formed in the ion generating part 250, and the third fastening hole 276a formed in the third case 270 are sequentially I can communicate. By coupling a screw such as a screw to the connected fastening hole, the second case 230, the ion generating unit 250, and the third case 270 may be firmly fixed.

The spacer 272 may extend downward from the rear end of the lower surface of the second curved portion 271. In detail, the separation portion 272 may have a second cable opening communicating with the first cable opening formed in the second curved portion 271. The first cable opening and the second cable opening communicate with each other, and the communication opening may be defined as a cable opening 273.

The spacing part 272 may include a shielding part 272b that shields the first cable opening so that it is not visible from the outside, and a communication part 272a extending downward from the rear side of the lower surface of the shielding part 272b. .

In addition, the rotation part 274 may be disposed on both sides of the communication part 272a, respectively. In detail, the rotating part 274 is a means capable of rotating the ion generating device 200 by being coupled to the rotating protrusion formed on the coupling frame 179.

The rotating part 274 includes a plate protruding from the side surface of the communication part 272a, at least one rotation groove 274a, 274b disposed on the rear side of the plate and coupled to the rotation protrusion 179c, and the rotation groove It may include limiting protrusions 274c and 274d disposed on the front side of the plate spaced at a predetermined distance from the 274a and 274b to limit the rotation angle of the ion generating device 200.

The plate may be a protruding surface protruding from the side surface of the communication part 272a at a predetermined interval and having a surface parallel to the side surface of the communication part 272a.

The rotation grooves 274a and 274b are means capable of being rotatably fitted to the rotation protrusion 179c formed in the first coupling frame 179a. In detail, the rotation grooves 274a and 274b may be disposed on the rear side of the side surface of the plate.

In addition, the rotation grooves 274a and 274b may include a first rotation groove 274a and a second rotation groove 274b.

The first rotation groove 274a may be formed at a lower rear side of the plate side, and the second rotation groove 274b may be formed at an upper rear side of the plate side. The reason why each of the first rotation grooves 274a and the second rotation grooves 274b is formed is to meet a standard according to the type of indoor unit coupled to the ion generating device, and the number of rotation grooves 274a and 274b It should be noted that can be one or three or more. As the first rotation groove 274a and the second rotation groove 274b are formed, the ion generator 200 can be mounted interchangeably in different indoor units.

The limiting protrusions 274c and 274d may be disposed on the front side of the side surface of the plate. In detail, the limiting protrusions 274c and 274d may include a first limiting protrusion 274c protruding from an upper front side of the side surface of the plate and a second limiting protrusion 274d protruding from a lower front side of the side surface of the plate. In this case, the first limiting protrusion 274c and the second limiting protrusion 274d may be arranged to be spaced apart by a set interval. Accordingly, the rotation angle of the rotating part 274 may be determined according to the set interval between the first limiting protrusion 274c and the second limiting protrusion 274d.

Hereinafter, a structure in which the ion generating capability of the ion generating device 200 disposed in the indoor unit of the air conditioner according to an embodiment of the present invention is improved will be described.

13 is a graph showing the result of measuring ion concentration according to the diameter of the ion diffusion port of the ion generating device mounted in the indoor unit of the air conditioner according to an embodiment of the present invention.

The ion generating ability of the ion generating device 200 may be changed according to the diameter of the ion divergence port 239 formed in the extension part 232 of the second case 230.

In detail, a graph of the result of measuring the ion concentration generated according to the diameter of the ion divergence port 239 formed in the extension part 232 will be described.

13, and N / cm ₃ used in the ion concentration is the number of ions generated in a volume of 1cm _3.

When the diameter of the ion divergence port 239 is 6 mm, it can be seen that the ion concentration generated by ionization of air is 1,500,000 N/cm ³ . In addition, when the cover diameter is 8 mm, it can be seen that the ion concentration generated by ionization of air is 1,900,000 N/cm ³ .

In addition, when the diameter of the ion divergence port 239 is 10 mm, it can be seen that the ion concentration generated by ionization of air is 2,200,000 N/cm ³ . That is, it can be seen that the ion concentration in the case of 10 mm is approximately 30% higher than that of the case in which the diameter of the ion divergence port 239 is 6 mm.

In addition, as a reference, when the ion emitter is operated in the atmosphere without the ion emitter 239, it can be seen that the ion concentration generated at the electrode 253 of the ion emitter is 2,200,000 N/cm ³ .

That is, when the diameter of the ion divergence port 239 is 10 mm, it can be seen that an ion concentration of 2,200,000 n/cm ³ , which is the maximum ion concentration that the ion generating device 200 can generate, is generated. Through this, it was confirmed that when the diameter of the ion divergence port 239 is 10 mm or more, the ion concentration is highest.

Table 1 below shows that when the indoor unit of the air conditioner is operated while the ion generating device 200 is driven, 1 cm ³ of both sides of the filter assembly 120 according to the diameter size of the ion dissipating port 239 It shows the number of ions measured in the section.

Ion diffusion sphere diameter (mm)

6
8
10
Number of ions (n/cm ³ )

900,000
1,400,000
2,000,000

Referring to Table 1, when the diameter of the ion diffusion sphere 239 is 6 mm, the number of ions at both sides of the filter assembly 120 was measured on average of 900,000, and the diameter of the ion diffusion sphere 239 was 8 mm. In this case, it can be seen that 1.4 million ions were measured at both ends of the filter assembly 120.

In addition, when the diameter of the ion divergence port 239 is 10 mm, it can be seen that the number of ions at both sides of the filter assembly 120 is measured on average of 2 million.

Through this, when the diameter of the ion divergence port 239 is 10 mm, it can be confirmed that ionization in the air is evenly performed at both ends of the filter assembly 120.

Claims (20)

A main body including a front portion, a side portion, and a rear portion coupled to a wall surface;
A frame disposed on the main body and formed with a suction unit through which air is sucked from the outside;
A discharge unit disposed on the main body and discharges the air sucked by the suction unit;
An ion generating device disposed outside the suction unit, discharging air to generate ions and charging dust in the air; And
A filter assembly disposed inside the suction unit and collecting dust charged by the ion generating device,
In the frame, a reinforcing frame on which the filter assembly is supported and a coupling frame to which the ion generating device can be coupled are disposed together.
Indoor unit of air conditioner.
The method of claim 1,
The ion generating device,
An ion generator for ionizing molecules in the air by applying a voltage from both sides; And
Including a case covering the ion generating unit,
An indoor unit of an air conditioner having ion diffusion ports for diffusing ions on both sides of the case.
The method of claim 2,
The indoor unit of the air conditioner, characterized in that the diameter of the ion divergence port is 10 mm or more.
The method of claim 2,
The indoor unit of the air conditioner, characterized in that the distance between the ion diffusion port and the filter assembly is 20 mm or more.
The method of claim 2,
The ion generating unit,
A circuit for generating a high voltage;
A circuit case surrounding the circuit; And
An indoor unit of an air conditioner comprising electrodes disposed on both sides of the circuit case and ionizing molecules in air by discharging a high voltage generated in the circuit.
The method of claim 5,
The electrode is an indoor unit of an air conditioner, characterized in that disposed in the ion diffusion port.
The method of claim 5,
The ion generating unit,
An electric wire electrically connecting the circuit and the electrode;
A wire cover surrounding the wire; And
Further comprising an electrode cover surrounding the electrode,
The electrode cover is an indoor unit of an air conditioner disposed in the ion diffusion port.
The method of claim 5,
The case,
A first case forming a top surface;
A second case coupled to a lower portion of the first case and having an ion generating unit receiving space disposed below the ion generating unit; And
The indoor unit of the air conditioner including a third case coupled to the lower portion of the second case and connected to the frame.
The method of claim 8,
The second case,
A curved portion formed to form an upper surface and have a curvature set upward; And
It includes two extensions extending downward from both sides of the curved portion,
The indoor unit of the air conditioner, characterized in that the ion generating unit receiving space is formed between the curved portion and the two extended portions
The method of claim 9,
The ion divergence port is an indoor unit of an air conditioner, characterized in that formed in the two extensions.
The method of claim 8,
A first cable opening formed on the rear side of the lower surface of the second case; And
A second cable opening formed in the third case is further included,
The indoor unit of an air conditioner, characterized in that the first cable opening and the second cable opening communicate with each other.
The method of claim 2,
The ion generating device,
The indoor unit of the air conditioner further comprising a light-emitting unit disposed on one side of the case to emit light to the outside when the ion generating unit is driven.
The method of claim 7,
The electrode cover is provided on at least one side of the circuit case,
The case covers the circuit,
The ion emission port is an indoor unit of an air conditioner having an opening for receiving the electrode cover.
The method of claim 13,
An electric wire cover protruding from the circuit case and supporting the electric wire is further included,
The wire cover is an indoor unit of an air conditioner disposed between a side surface of the circuit case and the electrode cover.
delete The method of claim 5,
The case,
The first case;
A second case coupled to a lower portion of the first case and having an accommodation space in which the circuit case is disposed; And
An indoor unit of an air conditioner including a third case coupled to a lower portion of the second case and covering a lower portion of the circuit case.
The method of claim 16,
The second case includes a curved portion forming an upper surface and two extension portions extending downward from both sides of the curved portion,
The accommodation space is an indoor unit of an air conditioner formed between the curved portion and the two extension portions.
The method of claim 17,
The ion diffusion port is an indoor unit of an air conditioner formed in the extension part. delete delete

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