KR102102759B1 - Ionizer and Air conditioner having the same - Google Patents

Abstract

The ion generator of the present invention includes a housing disposed at an air intake of an air conditioner; A PCB installed in the housing; A wire having one end connected to the PCB; A carbon fiber electrode formed on the other end of the wire; Including the cover that is coupled to the housing to protect the PCB and the wire and the carbon fiber electrode, the service of the ion generator is easy, and there is an advantage that the inside of the air conditioner can be compact.

Description

Ionizer and Air conditioner having the same}

The present invention relates to an ion generator and an air conditioner having the same, and more particularly, to an ion generator disposed at an air intake and an air conditioner having the same.

In general, an air conditioner is a device for cooling or heating a room using a refrigeration cycle including a compressor, an outdoor heat exchanger, an expansion valve, and an indoor heat exchanger. That is, it may be composed of a cooler that cools the room and a heater that heats the room. In addition, it may be configured as an air conditioner combined with air conditioning to cool or heat the room.

The air conditioner is equipped with a dust collecting device that collects and removes foreign substances such as dust floating in the air. Such a dust collecting device may be implemented in various forms, and recently, an electric dust collecting device that charges and collects foreign substances is used.

An object of the present invention is to provide an ion generator and an air conditioner having the ion generator that can easily service the ion generator and can be compact inside the air conditioner.

The ion generator according to the present invention for solving the above problems is a housing disposed in the air intake of the air conditioner; A fish ratio installed in the housing; A wire having one end connected to the PCB; A carbon fiber electrode formed on the other end of the wire; It includes a cover coupled to the housing to protect the PCB and the wire and carbon fiber electrode.

The air conditioner having an ion generator according to the present invention includes a body having an air intake port formed at the top and an air outlet port formed at the bottom; A high voltage generator installed inside the main body; An ion generator connected to the high voltage generator and a connecting wire; A pre-filter through which air sucked into the air intake passes; And after being charged by the ion generator includes an electrostatic filter that collects foreign matter that has passed through the pre-filter, the ion generator is a housing disposed in the air intake; A fish ratio installed in the housing; A wire having one end connected to the PCB; A carbon fiber electrode formed on the other end of the wire; It includes a cover coupled to the housing to protect the PCB and the wire and carbon fiber electrode.

The cover may be exposed outside the air conditioner.

The carbon fiber electrode may include a plurality of carbon fibers disposed toward the air intake.

The housing may be formed with a lower cover portion surrounding the lower portion of the carbon fiber electrode protruding.

A through hole may be formed in the lower cover portion.

In the cover, an upper cover portion surrounding the upper circumference of the carbon fiber electrode may be protruded.

The housing may be installed on the top plate of the body.

A plurality of carbon fiber electrodes may be disposed to face different directions.

The air intake port may be opened in the vertical direction, and the carbon fiber electrode may be horizontally disposed.

The carbon fiber electrode may include a first carbon fiber electrode disposed longitudinally toward the rear left side of the housing, and a second carbon fiber electrode disposed longitudinally toward the rear right side of the housing.

The present invention has the advantage of easily checking the presence or absence of the ion generator and the position of the ion generator outside the air conditioner.

In addition, it is possible to minimize the number of ion generators installed in the air conditioner, there is a high safety advantage.

In addition, there is an advantage in that the amount of ions generated in the air conditioner and the dust collecting ability are high.

1 is a perspective view of an embodiment of an air conditioner according to the present invention,
Figure 2 is a cross-sectional view of one embodiment of the air conditioner according to the present invention,
Figure 3 is a front view showing the front of the main body of an embodiment of the air conditioner according to the present invention,
4 is a plan view of one embodiment of an air conditioner according to the present invention;
5 is a plan view showing the inside of the ion generator of an embodiment of the air conditioner according to the present invention,
6 is a cross-sectional view taken along line AA in FIG. 4.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an embodiment of an air conditioner according to the present invention, FIG. 2 is a cross-sectional view of an embodiment of an air conditioner according to the present invention, and FIG. 3 is a front view of the main body of an embodiment of an air conditioner according to the present invention. .

The air conditioner is provided by the main body 2, the high voltage generator 20 installed inside the main body 2, the ion generator 40 connected by the high voltage generator 20 and the connecting wire 22, and the ion generator 40. And an electrostatic filter 60 in which charged foreign matter is collected.

The main body 2 is formed with at least one air intake and at least one air outlet. The main body 2 may be formed with an air intake port 4 at the top and an air outlet port 6 at the bottom. The main body 2 may include a heat exchanger 7 for heat-exchanging air sucked through the air intake 4. The main body 2 may include a blower 8 that sucks air through the air intake 4 and passes through the heat exchanger 7 and then discharges it through the air outlet 6. The air inlet 4, the air outlet 6, the heat exchanger 7 and the blower 8 are air inlet 4 in the air flow direction, the heat exchanger 7, the blower 8, and the air outlet ( 6) Can be placed in order. The main body 2 may be formed with an air intake port 4 on the upper portion, and an air intake port 9 may be further formed on the front surface. The air intake port 4 formed on the upper portion of the main body 2 may be formed to be opened in the vertical direction to the upper plate portion 10 of the main body 2, and the air intake port 9 formed on the front surface of the main body 2 may be a main body ( It can be formed to open in the front-rear direction on the front plate portion 11 of 2). Hereinafter, the air intake port 4 formed in the upper plate portion 10 of the main body 2 may be an upper surface air intake port 4 formed in the upper surface of the main body 2, and air formed in the front plate portion 11 of the main body 2 The intake port 9 may be a front air intake port 9 formed on the front surface of the main body 2. A suction grill 12 positioned in the upper surface air intake 4 may be formed in the upper plate portion 10 of the main body 2. The suction grill 12 may be disposed to traverse the upper surface air intake 4. The main body 2 may be provided with a pre-filter 13 through which air sucked into the air inlets 4 and 9 passes. The pre-filter 13 may be installed such that a part is located behind the front air intake 9 and another part is located below the top air intake 4. The pre-filter 13 may be installed to be located inside the body 2. Foreign matter having a large size in the air that has passed through the air intake ports 4 and 9 may be filtered by the pre-filter 13.

The main body 2 may include a rear case 14 and a front panel 15 installed in front of the rear case 14. The main body 2 may be formed with an air passage 16 through which air drawn into the air intakes 4 and 9 is guided. In the main body 2, an electric field chamber 18 in which a control box 17 for controlling an air conditioner is installed may be formed. The air passage 16 and the battlefield 18 may be formed independently of the rear case 14. The rear case 14 may constitute a rear plate portion, a left plate portion, and a right plate portion of the main body 2. The front panel 15 may constitute the front plate portion 11 of the main body 2. At least one of the rear case 14 and the front panel 15 may constitute the top plate 10 of the main body 2. Hereinafter, for convenience, the front panel 15 constitutes the top plate portion 10 and the front plate portion 11 of the main body 2, respectively, and the top air intake 4 and front air intake 9 are front panels 13 It can be formed to be opened in different directions. A discharger 19 for discharging air passing through the interior of the body 2 into the room may be disposed under the body 2, and the air discharge port 6 may be formed in the discharger 19.

The high voltage generator 20 may be installed to be located in the battlefield 18 of the body 2. The high voltage generator 20 may be installed so as not to be exposed to the outside of the battlefield 18, and may be protected by the rear case 14 and the front case 15.

The ion generator 40 can ionize air by the high voltage generated by the high voltage generator 20. The ion generator 40 may ionize molecules in the air to generate ions. The ion generator 40 discharges from a carbon fiber electrode, which will be described later, to ionize molecules in the air, and the generated ions can charge foreign substances in the air. The ion generator 40 may be disposed on at least one of the top air intake 4 and the front air intake 9. The ion generator 40 may be installed at a position where a part is exposed outside the air conditioner. Hereinafter, the detailed configuration of the ion generator 40 will be described later.

After being charged by the ion generator 40, foreign matter that has passed through the pre-filter 13 may be collected in the electrostatic filter 60. The electrostatic filter 60 may be located between the pre-filter 13 and the heat exchanger 7 in the air flow direction. Among foreign matters charged by ions, foreign matters that have passed through the pre-filter 13 may be collected in the electrostatic filter 60. The electrostatic filter 60 may include a filter body 61 and a filter case 62 on which the filter body 61 is installed. The filter body 61 is an electrostatic filter body to which static electricity is applied during its manufacture, and charged foreign matter may be attached to the filter body 61 by static electricity of the filter body 61. The filter body 61 may be formed in a shape in which a thin film is bent in a zigzag manner.

 The air conditioner may further include a front panel 80 disposed in front of the body 2 and covering the front surface of the body 2. The front panel 80 may be formed larger than the front air intake 9, and the front panel 80 may be disposed to move forward or backward in the front-rear direction. When the air conditioner is operated, the front panel 80 may form an air intake passage with the front surface of the main body 2, and the air in the room passes through the air intake passage formed between the front panel 80 and the main body. After that, it may be sucked through the front air intake 9.

4 is a plan view of one embodiment of an air conditioner according to the present invention, FIG. 5 is a plan view of the inside of an ion generator of an embodiment of an air conditioner according to the present invention, and FIG. 6 is a cross-sectional view taken along line AA shown in FIG. 4. .

The ion generator 40 may be installed on the top of the body 2. The ion generator 40 may be installed to be located at the top air intake 4 and the front air intake 9. The ion generator 40 may be installed to partially expose the air conditioner. The ion generator 40 may be installed on the top plate 10 of the body 2 so that its top surface is exposed to the outside. The ion generator 40 may be installed on the front portion of the front portion and the rear portion of the top plate 10 of the body 2. The ion generator 40 may be installed to face the top air intake 4 in the top air intake 4. The air conditioner may have an ion generator installation area in which the suction grill 12 is not formed in a part of the upper air intake port 4, and the ion generator 40 may have an ion generator installation area in which the suction grill 12 is not formed. Can be installed on. The ion generator installation area may be 1 to 5% of the total area of the upper air intake 4. The ion generator 40 can be serviced without separating a part of the body 2, and the user can easily check the presence or absence of the ion generator 40 and the position of the ion generator 40 outside the air conditioner. . The ion generator 40 may be provided with a function display unit 90 for expressing the clean function of the air conditioner in a portion exposed to the outside of the air conditioner. The function display unit 90 may express a character or a symbol that the air conditioner can perform a clean function such as removing smoke or removing cigarette odor. The function display unit 90 may be formed on a surface exposed to the outside of the outer surface of the ion generator 40 by printing or coating. Of course, the function display unit 90 may be integrally formed with an intaglio or embossed shape on the outer surface of the ion generator 40. The ion generator 40 is preferably disposed at the top air intake 4.

The ion generator 40 includes a housing 100 disposed at an air intake 4; A PCB 110 installed in the housing 100; A wire 120 having one end connected to the PCB 110; A carbon fiber electrode 130 formed on the other end of the wire 120; It includes a cover 140 coupled to the housing 100 to protect the PCB 110 and the wire 120 and the carbon fiber electrode 130. The housing 100 and the cover 140 may constitute a case of the ion generator 40, and the PCB 110, the wire 120, and the carbon fiber electrode 130 may be connected to the housing 100 and the cover 140. Can be protected by The housing 100 may function as a lower case of the ion generator 40. The cover 140 may function as an upper case of the ion generator 40. An electrode cover portion protecting the carbon fiber electrode 130 may be formed in each of the housing 100 and the cover 140. The electrode cover part may be formed to protrude toward the air intake 4.

The housing 100 may be installed on the top plate 10 of the body 2. The housing 100 may block a part of the front portion of the air intake 4. The housing 100 may be installed to be positioned at the center of the front portion of the air intake 4. The housing 100 may include a housing body portion 102. The PCB 110 may be installed in the housing body portion 102. The wire 120 may be fixed to the housing body portion 102. A rib 103 surrounding at least a portion of the PCB 110 may be formed in the housing body portion 102. The ion generator 40 may further include an insulating portion protecting the PCB 110, and the insulating portion may be made of an insulating material such as silicone rubber. A connecting wire fixing groove 104 in which the connecting wire 22 is fixed may be formed in the rib 103. A rib fixing groove 105 to which the wire 100 is fixed may be formed on the rib 103. The housing 100 may have a lower cover portion 106 surrounding the lower circumference of the carbon fiber electrode 130 protrudingly. The lower cover portion 106 may be formed to protrude from the housing body portion 102. A portion of the housing body portion 102 may face the air intake port 4, and the lower cover portion 106 may be formed to protrude on a surface facing the air intake port 4 of the housing body portion 102. . The lower cover portion 106 may be formed in a semi-cylindrical shape with an open top surface. A through hole 107 may be formed in the lower cover portion 106. Some of the ions generated by the carbon fiber electrode 130 may escape through the through hole 107 to the lower portion of the lower cover 106, and the efficiency of the ion generator 40 may be improved. The through hole 107 may be formed to face a portion of the carbon fiber electrode 130.

The PCB 110 is a circuit that applies a high voltage to the wire 120 so that the carbon fiber electrode 130 can discharge. A connecting wire 22 may be connected to the PCB 110. The same number of wires 120 as the number of carbon fiber electrodes 130 may be connected to the PCB 110. The ratio of the ratio of the fish ratio 110 to the wire 120 and the carbon fiber electrode 130 may be 1: N: N when the number of the carbon fiber electrodes 130 is N. The PCB 110 includes a circuit board and various electronic devices installed on the circuit board. The PCB 110 may generate a high voltage AC current, a positive or negative DC current, a pulse DC current, etc., and supply the wire 120 to the wire 120. The PCB 110 may be a constant voltage circuit that generates a negative electrode DC current, and it is possible to output at an output voltage of -7 kVp ± 8%, an output frequency of 100 Hz ± 10%, and 15 to 25% Duty.

The wire 120 includes a conductor that transmits the high voltage applied from the PCB 110 to the carbon fiber electrode 130 and a plastic material covering the outside of the conductor. The wire 120 electrically connects the PCB 110 and the carbon fiber electrode 130. The wire 120 may be arranged in plural according to the number of carbon fiber electrodes 130. Two to four wires 120 may be spaced left and right in the housing 100.

The carbon fiber electrode 130 may discharge and ionize molecules in the air, and anions such as OH- and O- or cations such as H + may be generated. The carbon fiber electrode 130 may include a plurality of carbon fibers 301, 302, and 303 disposed toward the air intake 4, and generate ions by corona discharge. The carbon fiber electrode 130 is preferably a plurality of ultrafine carbon fibers having a diameter in a micrometer unit tied to the wire 120 with a brush bundle. The carbon fiber electrode 130 may be a brush bundle of about 1000 carbon fibers having a diameter of 7 μm. The plurality of carbon fibers 301, 302, and 303 have a small amount of ozone (O ₃ ) generated and generate high-concentration ions to charge fine particles. The carbon fiber electrode 130 of the brush bundle, which is a bundle of a plurality of carbon fibers 301, 302, 303, may discharge only one of the plurality of carbon fibers. Depending on the embodiment, the carbon fiber electrode 130 may be formed in a needle shape or a mesh shape having a pattern. A plurality of carbon fiber electrodes 130 may be disposed in one ion generator 40. It is preferable that the plurality of carbon fiber electrodes 130 are spaced apart to minimize mutual interference. The plurality of carbon fiber electrodes 130 is preferably disposed at equal intervals on a virtual plane perpendicular to the flow direction of air, and is preferably disposed to be symmetrical in the left and right directions at the air intake 4. The carbon fiber electrode 130 may be disposed horizontally toward the air intake 4. The ions generated in the carbon fiber electrode 130 charge foreign substances. The anion provides electrons to the foreign material to charge the foreign material as the negative electrode, and the positive ions take electrons from the foreign material to charge the foreign material to the positive electrode.

 A plurality of carbon fiber electrodes 130 may be disposed such that a plurality of 103A and 103B are directed in different directions. The carbon fiber electrode 130 includes a first carbon fiber electrode 130A disposed longitudinally toward the rear left side in the housing 100, and a second carbon fiber electrode disposed longitudinally toward the rear right side from the housing 100. It may include (130B). Each of the first carbon fiber electrode 130A and the second carbon fiber electrode 130B may include a plurality of carbon fibers 301, 302, and 303. The wire 120 may be disposed as many as the number of carbon fiber electrodes 130, and the first wire 120A between the one side of the PCB 110 and the first carbon fiber electrode 130A and the other side of the PCB 110. And a second wire 120B between the second carbon fiber electrode 130B.

 The cover 140 may be exposed outside the air conditioner, and the function display unit 90 may be formed on the outer surface of the cover 140. The function display unit 90 may be formed on the upper surface of the cover 140. The cover 140 may have an upper cover portion 146 surrounding the upper circumference of the carbon fiber electrode 130 protrudingly. The upper cover portion 146 may prevent the conductor from contacting the carbon fiber electrode 130 when the user inserts the conductor, and may prevent foreign substances in the air from directly colliding with the carbon fiber electrode 130. The upper cover portion 146 may be formed in a shape protruding from the cover 140. A part of the cover 140 may face the air intake port 4, and the upper cover part 146 may be formed to protrude on a surface facing the air intake port 4 of the cover 140. The upper cover portion 146 may be formed in a semi-cylindrical shape with a lower surface open. The upper cover portion 146 and the lower cover portion 104 may be disposed in a hollow cylindrical shape when the housing 100 and the cover 140 are coupled, and between the upper cover portion 146 and the lower cover portion 106. A hollow space in which the carbon fiber electrode 130 is located may be formed therein.

Hereinafter, the operation of the present invention configured as described above will be described.

First, when the air conditioner is operated, the ion generator 40 may be turned on, and the carbon fiber electrode 130 may be discharged from the ion generator 40 by a high voltage applied from the high voltage generator 20. When the carbon fiber electrode 130 is discharged, air around the carbon fiber electrode 130 may be ionized with molecules such as anions such as OH- and O- or cations such as H +. Foreign matter in the air may be charged by anions or cations generated in the ion generator 40, and may flow into the pre-filter 13 in a charged state. The foreign matter having a large size in the air flowing through the pre-filter 13 may be filtered by the pre-filter 13, and the foreign matter having a small size in the air flowing through the pre-filter 13 may not be filtered by the pre-filter 13. It is possible to pass through the pre-filter 13. Small foreign matter that has passed through the pre-filter 13 may flow into the electrostatic filter 60 in a charged state, and may be attached to the electrostatic filter 60 when passing through the electrostatic filter 60. Fine particles, such as cigarette smoke, may pass through the pre-filter 13 without being filtered by the pre-filter 13, and the electrostatic filter 60 is charged while being charged by the ion generator 40 installed in the air intake 4 Because it passes through, it can be easily attached to the electrostatic filter 60, and the air that has passed through the electrostatic filter 60 can flow in a state in which fine particles such as cigarette smoke are removed. The air that has passed through the electrostatic filter 60 may then be heated or cooled in contact with the heat exchanger 7 and may be discharged through the blower 8 to the air outlet 6. The air conditioner can increase the cleanliness of the room more than when the ion generator 40 is off, and in particular, can effectively remove cigarette smoke and the like.

On the other hand, during the service of the ion generator 40, the operator does not disassemble the body 2, it is possible to separate the ion generator 40 to the upper side of the air intake (4), the ions separated from the body (2) It is possible to service the generator 40. On the other hand, the operator can detach the cover 140 from the housing 100 in a state in which the housing 100 is fixed to the upper part of the body 2, and the PCB is placed in the state in which the housing 100 is positioned in the body 2. It is also possible to service 110 or wire 120 or carbon fiber electrode 130.

2: main body 4: air intake
6: Air outlet 20: High voltage generator
40: ion generator 60: electrostatic filter
100: housing 106: gore cover
107: through 110: PB
120: wire 130: carbon fiber electrode
301,302,303: carbon fiber 140: cover
146: lower cover

Claims (15)

A housing;
A fish ratio installed in the housing;
A wire having one end connected to the PCB;
A carbon fiber electrode formed on the other end of the wire;
Includes a cover coupled to the housing to protect the PCB, wire and carbon fiber electrodes;
The cover further includes an upper cover portion surrounding the upper portion of the carbon fiber electrode,
The housing further includes a lower cover portion surrounding the lower portion of the carbon fiber electrode,
One side is opened between the upper cover portion and the lower cover portion,
The carbon fiber electrode is an ion generator that is hidden inside the upper cover portion and the lower cover portion. According to claim 1,
An ion generator in which the upper cover portion, the lower cover portion, and the carbon fiber electrode are arranged side by side. According to claim 1,
The ion generator comprising a plurality of carbon fibers disposed at the air intake of the air conditioner, the housing and the cover, and the carbon fiber electrode facing the air intake. The method of claim 3,
The lower cover portion is formed to protrude to one side from the housing, the upper cover portion is formed to protrude to one side from the cover,
An ion generator in which the upper cover portion, the lower cover portion, the carbon fiber electrode, and the air intake are arranged side by side. The method of claim 4,
An ion generator formed on the lower cover portion, further comprising a through hole opening toward the air intake, and the carbon fiber electrode exposed through the through through the through. A body having an air intake port formed at an upper portion and an air outlet port formed at a lower portion;
A high voltage generator installed inside the main body;
An ion generator connected to the high voltage generator and a connecting wire;
A pre-filter through which air sucked into the air intake passes;
And an electrostatic filter in which foreign substances that have passed through the pre-filter after being charged by the ion generator are collected,
The ion generator,
A housing disposed at the air intake;
A fish ratio installed in the housing;
A wire having one end connected to the PCB;
A carbon fiber electrode formed on the other end of the wire;
It is coupled to the housing to cover the PCB and the wire and the carbon fiber electrode; includes,
The cover further includes an upper cover portion surrounding the upper portion of the carbon fiber electrode,
The housing further includes a lower cover portion surrounding the lower portion of the carbon fiber electrode,
One side is opened between the upper cover portion and the lower cover portion,
The carbon fiber electrode is an air conditioner concealed inside the upper cover portion and the lower cover portion. The method of claim 6,
The cover is an air conditioner exposed to the outside of the air conditioner. The method of claim 6,
An air conditioner comprising a plurality of carbon fibers in which the carbon fiber electrode and the air intake are arranged side by side. The method of claim 6,
The lower cover portion protrudes from the housing to one side,
The upper cover portion is formed to protrude to one side from the cover,
An air conditioner in which the upper cover portion, the lower cover portion, the carbon fiber electrode, and the air intake are arranged side by side. The method of claim 9,
It is formed in the lower cover portion, and further includes a through hole opened toward the air intake,
An air conditioner in which the carbon fiber electrode is exposed to the air intake through the through hole. delete The method of claim 6,
The main body further includes an upper plate portion on which the air suction port is formed, the air suction port is opened toward the upper side, and the housing is an air conditioner installed on the upper plate portion. The method of claim 6,
The carbon fiber electrode includes a first carbon fiber electrode and a second carbon fiber electrode,
The first carbon fiber electrode and the second carbon fiber electrode is an air conditioner disposed in different directions. The method of claim 6,
The air intake is opened in the vertical direction,
The carbon fiber electrode is an air conditioner having an ion generator disposed horizontally. The method of claim 13,
The first carbon fiber electrode is disposed in the longitudinal direction toward the rear left from the housing,
The second carbon fiber electrode is an air conditioner disposed in the longitudinal direction toward the rear right in the housing.

Images