JP2017009135A - Indoor equipment of air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an indoor equipment of an air conditioner to achieve high-performance air purification function.SOLUTION: Indoor equipment 1 of an air conditioner includes: a negative ion generator 16 having a negative ion electrode 18 negatively charging dust included in air flowing through a ventilation trunk 7; and a heat exchanger 3 disposed on a downstream side of the negative ion generator 16 in the ventilation trunk 7 to apply earth potential as a counter electrode of the negative ion electrode 18. The negative ion electrode 18 includes a plate-like body part and a plurality of electrode needles projecting from the body part, and is arranged so that the tip end parts of the electrode needles are located at a side inner than the end surface of the heat exchanger 3 by 15 mm or more.SELECTED DRAWING: Figure 1

Description

  The present embodiment relates to an indoor unit of an air conditioner.

  As is well known, an indoor unit of an air conditioner has a heat exchanger inside, and performs air conditioning by circulating the sucked air through the heat exchanger and exchanging heat. In recent years, in addition to a pure air-conditioning function, an air cleaning function that actively captures and removes dust, pollen, etc. (hereinafter referred to as dust) contained in the inhaled air has been proposed. (For example, refer to Patent Document 1).

International Publication No. 2009/028634

By the way, since the above-mentioned dusts can cause allergies, further enhancement of the air cleaning function is desired.
Therefore, an indoor unit of an air conditioner that can improve the performance of the air cleaning function is provided.

  The indoor unit of the air conditioner according to the embodiment has a negative ion electrode that is disposed in the ventilation path and has a negative ion electrode to which a negative potential voltage is applied, and charges the dust contained in the air flowing through the ventilation path to a negative potential. A generator, and a heat exchanger disposed downstream of the negative ion generator in the ventilation path and to which a ground potential is applied as a counter electrode of the negative ion electrode, the negative ion electrode being a plate-like body portion And a plurality of electrode needle portions protruding from the main body portion, and the tip end portion of the electrode needle portion is disposed so as to be located 15 mm or more inside the end face of the heat exchanger.

Vertical side view schematically showing the configuration of the indoor unit of the air conditioner of the present embodiment Diagram showing negative ion electrode The figure which shows the relationship between the distance (W) between front ends, and an end surface distance (D) The figure which shows typically the relationship between end surface distance (D) and dust collection performance The figure which shows typically the relationship between front-end | tip part thickness (T) and dust collection performance. The figure which shows typically the difference in the dust collection performance in the different applied voltage, the front-end | tip part thickness (T), and the distance between front-end | tips (W). The figure which shows the negative ion electrode of other shape typically

Hereinafter, an embodiment will be described with reference to the drawings.
As shown in FIG. 1 (A), an indoor unit 1 of an air conditioner (hereinafter simply referred to as an indoor unit 1) has a horizontally long box shape in which the width dimension in the left-right direction is longer than the height dimension in the up-down direction. An indoor unit body 2 is provided. Inside the indoor unit main body 2, as shown in FIG. 1B, a heat exchanger 3, a blower 4 and the like are arranged.

  The upper surface portion of the indoor unit main body 2 is provided with a suction port 5 that is opened over substantially the whole, and the lower surface portion is provided with a blowout port 6 that blows out the sucked air. In the interior of the indoor unit main body 2, an air passage 7 through which air flows is formed between the inlet 5 and the outlet 6.

  A filter support frame 9 that supports the air filter 8 is attached to the suction port 5. The filter support frame 9 has a curved shape that is convex upward in a side view, and is disposed in a form that covers the heat exchanger 3 from above to the front of the heat exchanger 3. The air filter 8 supported by the filter support frame 9 has air permeability. The air filter 8 is detachably attached to the filter support frame 9 and is arranged in a form that covers the heat exchanger 3 along the filter support frame 9 from the top to the front of the heat exchanger 3. . A gap is formed between the air filter 8 and the heat exchanger 3. The filter support frame 9 and the air filter 8 are also formed long in the left-right direction when viewed from the front.

  A decorative panel 10 for opening and closing the front portion is attached to the front portion of the indoor unit body 2. The decorative panel 10 is made of, for example, a synthetic resin, and both left and right end portions thereof are rotatably supported by the side surface portion of the indoor unit body 2.

  Two lower and upper louvers 11 are provided on the lower surface of the indoor unit body 2. The upper and lower louvers 11 have a rear end portion rotatably supported, and guide the wind blown from the outlet 6 in the vertical direction by swinging the front end portion in the vertical direction. In the indoor unit body 2, a plurality of left and right louvers 12 are provided on the back side above the upper and lower louvers 11. These left and right louvers 12 guide the wind blown from the blowout port 6 in the left-right direction by the tip portions being swung in the left-right direction in conjunction with each other.

  The blower 4 is constituted by a cross-flow fan that is long in the left-right direction when viewed from the front. The blower 4 is positioned above the blowout port 6 and is disposed at a substantially central portion of the indoor unit body 2. When the blower 4 is driven, the air outside the indoor unit body 2 is sucked into the ventilation path 7 from the suction port 5 and the air inside the ventilation path 7 is blown out of the indoor unit body 2 from the blowout port 6. .

  In the present embodiment, the heat exchanger 3 is divided into a front heat exchanger 3a and a rear heat exchanger 3b. The front side heat exchanger 3a and the rear side heat exchanger 3b are connected to each other at an upper portion of the blower 4, and are arranged in a mountain shape when viewed from the side. Further, the front heat exchanger 3a is bent so as to protrude forward at the front portion of the blower 4, and is bent when viewed from the side. The front side heat exchanger 3a and the rear side heat exchanger 3b are formed long in the left-right direction when viewed from the front like the blower 4, and are arranged in a form covering the blower 4 from above and from the front.

  In addition, the front surface 13 of the front heat exchanger 3a is formed in a planar shape facing a negative ion electrode 18 described later. In addition, although mentioned later for details, the position where the front side heat exchanger 3a is refracted corresponds to the end surface of the front surface 13 of the front side heat exchanger 3a and the end surface of the heat exchanger 3.

  The front side heat exchanger 3a and the rear side heat exchanger 3b have a structure in which a pipe 15 through which a refrigerant passes penetrates a plurality of plate-like fins 14 arranged to face each other at a predetermined interval in the lateral direction. ing. Each fin 14 is made of a conductive material such as aluminum. That is, the heat exchanger 3 has conductivity. The pipe 15 of the heat exchanger 3 is connected to a known refrigeration cycle provided with a compressor (not shown).

  A negative ion generator 16 is attached to the back side of the filter support frame 9 so as to be positioned in front of the heat exchanger 3. Therefore, the negative ion generator 16 is disposed at a site downstream of the air filter 8 and upstream of the heat exchanger 3 in the ventilation path 7 in the indoor unit body 2. As will be described later, the negative ion generator 16 includes an electrode support frame 17 and a negative ion electrode 18 attached to the back side of the electrode support frame 17 (on the heat exchanger 3 side as viewed from the electrode support frame 17). doing.

  A control board storage unit 19 is provided on the front surface of the indoor unit body 2. A control board on which various electrical components for controlling the operation of the indoor unit 1 are mounted is housed inside the control board housing unit 19. In a state where the decorative panel 10 closes the front surface portion of the indoor unit body 2, the control board storage unit 19 is covered from the front by the decorative panel 10. In addition, a power source for applying a negative potential voltage to the negative ion electrode 18 is stored in the control board storage portion 19.

  The control board storage unit 19 is located in front of the negative ion generator 16 inside the indoor unit body 2. In this case, the distance between the negative ion electrode 18 in the negative ion generator 16 and the back surface of the control board storage unit 19 is between the negative ion electrode 18 and the front surface 13 of the front heat exchanger 3 a in the heat exchanger 3. It is set to be larger than the distance. In addition, the distance between the negative ion electrode 18 and the front surface 13 of the front heat exchanger 3a in the heat exchanger 3 is approximately 20 mm to 30 mm.

  Here, the negative ion generator 16 will be described in detail. The electrode support frame 17 of the negative ion generator 16 is made of a synthetic resin and is long in the left-right direction. The electrode support frame 17 has an electrode support portion 20 extending in the left-right direction at the center in the vertical direction. On the back surface of the electrode support portion 20, a negative ion electrode 18 that is long in the left-right direction when viewed from the front side or the back surface side is attached by an attachment portion 18c. For this reason, the negative ion generator 16 composed of the unit of the electrode support frame 17 and the negative ion electrode 18 is in a state where the longitudinal direction thereof is along the width direction of the indoor unit 1, in other words, the negative ion electrode 18 is connected to the heat exchanger 3. It is attached to the inside of the indoor unit main body 2 in a state facing the front surface 13 of the indoor unit 2.

  The negative ion electrode 18 as a whole is formed in a horizontally long flat plate shape with a metal plate. As shown in FIG. 2A, the negative ion electrode 18 is linear in the left-right direction when viewed from the front side or the back side of the indoor unit body 2. And a plurality of electrode needle portions 18b that are provided at predetermined intervals in the left-right direction and project in opposite directions from each other in the plate width direction (vertical direction in the drawing) from the main body portion 18a. Yes.

  When the negative ion generator 16 is mounted in the indoor unit main body 2, the main body 18 a faces the front surface 13 of the heat exchanger 3 in a state along the width direction, that is, the longitudinal direction of the indoor unit main body 2. It is arranged with. The electrode needle portion 18b has a shape protruding from the main body portion 18a in a triangular shape in the plate width direction.

  In this embodiment, a voltage in the range of −9.0 kV to −10 kV is applied to the negative ion electrode 18 having such a configuration as a negative potential voltage from a power source (not shown). A ground potential is applied to each fin 14 of the heat exchanger 3 having conductivity. At this time, negative ions are generated by the negative ion electrode 18 to which a high voltage of a negative potential is applied and the heat exchanger 3 as a counter electrode connected to the ground potential. The generated negative ions charge dust contained in the air flowing through the ventilation path 7 to a negative potential, and the dust charged to the negative potential is attracted to the heat exchanger 3 having a potential higher than the negative potential, that is, the ground potential. As a result, dust charged to a negative potential is captured by the heat exchanger 3, and the air cleaning function is activated.

  When it is desired to improve the performance of the air cleaning function, simply considering that the negative ion generator 16 and the negative ion electrode 18 are enlarged, it is expected that the air cleaning function can be improved.

  However, if the negative ion generator 16 or the negative ion electrode 18 is enlarged, the required space increases. Therefore, the indoor unit body 2 is enlarged, or the structure is redesigned to change the mounting position. There is a need to. Therefore, the inventors have sought a method for improving the performance of the air purification function without greatly increasing the size of the current configuration without significantly changing the current configuration. As a result, the negative ion electrode 18 and the heat exchanger are obtained. The fact that the dust collection performance changes depending on the positional relationship with 3 was found.

  Specifically, as shown in FIG. 2A, the distance between the tip portions of the electrode needle portions 18b protruding in opposite directions (hereinafter referred to as the tip-to-tip distance) is W (mm), and FIG. As shown in (B), the tip of the electrode needle 18b, that is, the thickness of the discharge surface 18d (hereinafter referred to as the tip thickness) is T (mm). Further, as shown in FIG. 1B, the distance (hereinafter referred to as the end face) between the tip of the electrode needle 18b and the end of the heat exchanger 3 (more strictly, the end face of the front face 13 of the front heat exchanger 3a). D) (referred to as distance).

  This end face distance (D) is determined by the projection position of the tip of the electrode needle portion 18b and the heat exchanger when the negative ion electrode 18 disposed facing the front face 13 of the heat exchanger 3 is projected onto the front face 13. This corresponds to a distance between the three end portions (end surfaces). For reference, an electrode conventionally used (hereinafter referred to as a conventional configuration for convenience) W = 30.0 (mm), T = 0.3 (mm), D = 15.0 (mm) )Met.

  When the negative ion electrode 18 is attached as shown in FIG. 1B, the relationship between the tip end distance (W) and the end face distance (D) is that the end face distance (D) increases as the tip end distance (W) increases. Becomes smaller. More specifically, in the case of the indoor unit body 2 of the present embodiment, as shown in FIG. 3, the relationship is D = 30.0− (W / 2).

  Then, when the dust collection performance was tested using the negative ion electrodes 18 having different distances (W) between the tips, in other words, when the test was performed while changing the end face distance (D), the dust collection performance is shown in FIG. As shown, the position where the end face distance (D) is 22.5 (mm) (the position between the tips (W) = 15.0 mm) is the peak value (maximum performance in the embodiment), and approximately 15.0 ≦ D The result that dust collection performance exceeded a reference value (conventional collection performance) in the range of ≦ 24.5 was obtained. FIG. 4 shows test results when the applied voltage and the tip thickness (T) are the same and the end face distance (D), that is, the tip-to-tip distance (W) is changed.

  That is, in this embodiment, the negative ion electrode 18 is not increased in size, but conversely, the negative ion electrode 18 is reduced in size, thereby improving the dust collection performance. This is considered to be because dust in the ventilation path 7 charged to a negative potential by the negative ion generator 16 is not captured and removed by the heat exchanger 3 because the end face distance (D) is too small. It is done. In other words, when the end face distance (D) is less than 15 (mm), it is considered that the utilization efficiency of negative ions is low.

  Therefore, if the end face distance (D) is set to 15.0 (mm) or more, that is, if the tip end portion of the electrode needle part 18b is disposed so as to be 15 mm or more inside the end face of the heat exchanger 3, It was confirmed that the generated negative ions could be used sufficiently and the dust collection performance, that is, the air cleaning ability could be improved.

  On the other hand, when the end face distance (D) exceeds 24.5 (mm), the dust collection performance is lower than the reference value. This is because the negative ion electrode 18 becomes too small to generate a sufficient amount of negative ions, and the amount of dust that cannot be removed is relatively increased rather than the utilization efficiency of negative ions is reduced. It is thought that.

  In other words, in order to improve the air cleaning capability, it is also necessary to secure a sufficient amount of negative ions, and for that purpose, the negative ion electrode 18 must be sized to some extent, in other words, between the tips. It is considered that the distance (W) needs to be set to some extent.

  At this time, if the end face distance (D) is in the range of 15.0 ≦ D ≦ 24.5, that is, the distance (W) between the tips is in the range of 11.0 ≦ W ≦ 30.0 from the relationship of FIG. If present, it is considered that a sufficient amount of negative ions can be ensured. However, in this embodiment, in order to have a significant difference with respect to the reference value, the distance (W) between the tips is approximately 12.0. ≦ W ≦ 21.0.

  Further, in order to improve the dust collection performance to the maximum, the peak value D = 23.5 (W = 15.0) is the center and the vicinity thereof, for example, the range of W = 15.0 ± 2 mm. (A range of 13.0 ≦ W ≦ 17.0) is desirable. Note that the tip distance (W) may be set such that the target value of the dust collection performance is set to 90% of the peak value, for example, and the dust collection performance of 90% or more of the peak value can be exhibited.

  As a result of further verification, it has been found that there is a difference in dust collection performance depending on the thickness (T) of the tip of the electrode needle portion 18b. Specifically, as shown in FIG. 5, the result that the dust collection performance from the reference value can be improved as the tip portion thickness (T) becomes thinner. FIG. 5 shows test results when the applied voltage and the end face distance (D) are the same and the tip thickness (T) is changed.

  From this test result, it was confirmed that the dust collection performance could be improved if the tip thickness (T) was in the range up to 3.0 (mm). This is considered to be because the applied voltage is more concentrated and a large number of negative ions can be generated by reducing (thinning) the tip thickness (T).

  However, since the negative ion electrode 18 is a component that constitutes the indoor unit 1, it is not damaged during press molding or assembling, and it must be strong enough to withstand actual use. Therefore, as a range in which the dust collection performance can be improved while ensuring the strength, in the present embodiment, the tip end thickness (T) is in a range up to 3.0 (mm) (that is, a range less than 3.0 (mm)). That is, 0.1 ≦ T <3.0. In this case, it is more desirable to set the range in which the dust collection performance is not greatly reduced, that is, the range of 0.1 ≦ T ≦ 2.0.

  Up to this point, the improvement of the dust collection performance by the shape of the negative ion electrode 18 has been described, but in order to generate negative ions, the applied voltage is increased (more strictly, the negative potential is increased in the negative direction). It is possible.

  FIG. 6 shows the change over time in the dust concentration when the applied voltage (hereinafter, the applied voltage is V) is changed. The earlier the time that the dust concentration decreases, the higher the dust collection performance. ing. Each graph corresponds to the following conditions. Examples A to C are test results using the negative ion electrode 18 of the present embodiment.

G1: D = 15.0 (W = 30.0), T = 0.3, V = −6.0 kV (conventional configuration)
G2: D = 15.0 (W = 30.0), T = 0.3, V = −9.5 kV (Example A)
G3: D = 15.0 (W = 30.0), T = 0.2, V = −9.5 kV (Example B)
G4: D = 22.5 (W = 15.0), T = 0.2, V = −9.5 kV (Example C)
From the test results of FIG. 6, the dust collection performance is improved by increasing the applied voltage (G1 → G2), and the dust collection performance is further improved by reducing the tip thickness (T) (G2 → G3). It was confirmed that the dust collection performance was further improved (G3 → G4) by making the end face distance (D) larger than 15 (mm) (however, in the range of 24.5 (mm) or less). . That is, it is clear that the dust collection performance can be improved by setting the applied voltage (V) to a predetermined range including -9.5 kV, for example, from -9.0 kV to -10.0 kV. Became.

According to the indoor unit 1 described above, the following effects can be obtained.
The indoor unit 1 of the air conditioner according to the embodiment includes a negative ion electrode 18 that is disposed in the ventilation path 7 through which air flows and to which a negative potential voltage is applied, and that contains dust contained in the air flowing through the ventilation path 7. A negative ion generator 16 charged to a negative potential and a heat exchanger 3 to which a ground potential is applied as a counter electrode of the negative ion electrode 18 are provided. The negative ion electrode 18 includes a plate-shaped main body portion 18a and a main body thereof. And a plurality of electrode needle portions 18b protruding from the portion 18a, and the tip end portion of the electrode needle portion 18b is disposed so as to be located 15 mm or more inside the end face of the heat exchanger 3. That is, the end face distance (D) described above was set to 15.0 (mm) or more.

Thereby, the negative ions generated by the negative ion generator 16 can be fully utilized, the dust collection performance can be improved, and the air cleaning performance can be enhanced.
In addition, since the negative ion electrode 18 is miniaturized to improve the performance of air purification, it can be installed as it is in the conventional configuration where the negative ion electrode 18 was attached, and the structure needs to be changed. Furthermore, since the negative ion electrode 18 itself is downsized, manufacturing cost and development cost can be reduced.

  Further, the thickness (tip portion thickness (T)) of the discharge surface 18d at the tip portion of the electrode needle portion 18b is in the range of 0.1 mm to less than 0.3 mm. As a result, as shown in FIG. In addition, the dust collection performance can be improved, the air cleaning performance can be improved, and the strength that can withstand actual use is ensured without being damaged during press molding or assembly. be able to.

  The electrode needle portion 18b is formed so as to protrude in the opposite direction from the main body portion 18a, and the distance between the tips of the electrode needle portion 18b protruding in the opposite direction (distance between the tips (D)) is 12 mm to 17 mm. It is in the range. Thereby, the size for generating a sufficient amount of negative ions can be ensured, and the dust collection performance can be prevented from deteriorating.

  Further, the negative potential voltage applied to the negative ion electrode 18 is set in the range of −9.0 kV to −10 kV. Thereby, the generation amount of negative ions is increased, the dust collection performance can be improved, and the air cleaning ability can be enhanced.

  The shape (outer shape) of the negative ion electrode 18 is not limited to that shown in the embodiment. For example, as shown in FIG. 7A, a negative ion electrode 18 having electrode needle portions 18b that protrude in opposite directions from the flat body portion 18a to the right diagonally upward and diagonally downward to the right in the drawing may be employed. Good. Alternatively, as shown in FIG. 7B, a negative ion electrode 18 having electrode needle portions 18b that protrude in opposite directions and in opposite directions from the flat main body portion 18a to the upper left and lower right in the drawing. It may be adopted. Even in such a configuration, by setting the distance (W) between the tips of the electrode needle portion 18b and the thickness (T) of the tip in the above ranges, the dust collection performance is improved and the air cleaning function is improved. High performance can be achieved.

  This embodiment is presented as an example and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  In the drawings, 1 is an indoor unit of an air conditioner, 3 is a heat exchanger, 5 is a suction port, 6 is a blowout port, 7 is an air passage, 16 is a negative ion generator, 18 is a negative ion electrode, and 18a is a main body. , 18b are electrode needle portions, and 18d is a discharge surface.

Claims (4)

An air inlet for inhaling air;
A ventilation path through which air sucked from the air suction port flows;
A negative ion generator that is disposed in the ventilation path, has a negative ion electrode to which a negative potential voltage is applied, and charges dust contained in the air flowing through the ventilation path to a negative potential;
A heat exchanger disposed on the downstream side of the negative ion generator in the ventilation path, to which a ground potential is applied as a counter electrode of the negative ion electrode,
The negative ion electrode has a plate-like main body part and a plurality of electrode needle parts protruding from the main body part,
An indoor unit of an air conditioner, characterized in that the tip portion of the electrode needle portion is disposed so as to be located 15 mm or more inside the end face of the heat exchanger.   The indoor unit of an air conditioner according to claim 1, wherein the thickness of the discharge surface of the electrode needle portion is in the range of 0.1 mm to less than 0.3 mm.   The electrode needle portion is formed so as to protrude in the opposite direction from the main body portion, and the distance between the tip portions of the electrode needle portion protruding in the opposite direction is in a range of 12 mm to 17 mm. The indoor unit of the air conditioner according to claim 1 or 2.   The indoor unit of the air conditioner according to any one of claims 1 to 3, wherein a negative potential voltage applied to the negative ion electrode is set in a range of -9.0 kV to -10 kV.

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