KR20190009969A - Reactor assembly and Window type air conditioner including the same - Google Patents

Abstract

According to an embodiment of the present invention, an integrated air conditioner capable of reducing power consumption comprises a reactor assembly which includes: a reactor bracket having a reactor mounting unit and a base coupling unit coupled to an upper surface of a base of the air conditioner; a reactor supported on the reactor mounting unit; and a reactor cover coupled to the reactor mounting unit and having an inner space receiving the reactor, wherein the base coupling unit further includes a bracket extending unit upwardly extended towards the reactor mounting unit from the base coupling unit, thereby enabling the reactor from being separated from the base.

Description

REACTOR ASSEMBLY AND REACTOR ASSEMBLY INCLUDING THE SAME -

The present invention relates to a reactor assembly and an integrated air conditioner including the same.

The air conditioner refers to a device that cools or heats the room using a refrigeration cycle. The refrigeration cycle includes a compressor, a condenser, an expansion device, and an evaporator, wherein the compressor, the condenser, the expansion device, and the evaporator are sequentially connected by piping. The refrigerant circulates through the pipe, the compressor, the condenser, the expansion device, and the evaporator.

Generally, the air conditioner can be divided into a separate type air conditioner and an integral type air conditioner.

The separate type air conditioner includes an indoor unit disposed in a room and discharging conditioned air in an indoor space, and an outdoor unit connected to the indoor unit through a pipe and disposed outdoors. The outdoor unit and the indoor unit may each include a heat exchanger. Specifically, the indoor unit includes an indoor heat exchanger, and the outdoor unit includes a compressor and an outdoor heat exchanger. When the air conditioner performs cooling operation, the outdoor heat exchanger functions as a condenser and the indoor heat exchanger can function as an evaporator. When the air conditioner performs the heating operation, the indoor heat exchanger functions as a condenser and the outdoor heat exchanger can function as an evaporator.

In the integrated type air conditioner, a condenser and an evaporator are installed together inside the case, and the condenser is disposed on the outdoor side to exchange heat with the outside air, and the evaporator can be disposed on the indoor side to exchange heat with indoor air. The indoor air may be cooled by the evaporator and then discharged into the indoor space.

Regarding such an integrated type air conditioner, the applicant of the present invention has conventionally applied (hereinafter, referred to as the prior art). The information of the preceding documents is as follows.

1. Public number (public date): 10-2005-0104737 (April 29, 2004)

2. Name of invention: air conditioner

According to the prior art, the following problems may exist.

First, a control box having a control part for controlling the operation of the air conditioner is disposed on the indoor side, and the heat generated in the control box flows into the room, thereby lowering the cooling efficiency of the indoor space.

Secondly, there is a problem that the compressor provided in the air conditioner is constituted by the constant-speed compressor, so that the noise is large and the power consumption is increased.

Third, there is a problem that the condensed water scattered by the operation of the blowing fan of the air conditioner penetrates into the electronic parts.

Fourth, there is a problem that the condensed water existing in the base of the air conditioner is infiltrated into the parts disposed on the base.

SUMMARY OF THE INVENTION It is a first object of the present invention to provide an integrated type air conditioner having a compressor and a control part capable of performing inverter control to reduce noise generated in the air conditioner and reduce power consumption.

A second object of the present invention is to provide an integrated type air conditioner in which the control part is appropriately disposed on an air flow path inside a case of an air conditioner to facilitate heat dissipation of the control part and improve space usability .

In particular, it is an object of the present invention to provide an integrated type air conditioner in which the control box and the reactor assembly are disposed on the outdoor side air flow path to facilitate cooling, and the heat generated in the control box and the reactor assembly does not act on the indoor side .

A third object of the present invention is to provide an integrated type air conditioner in which the reactor assembly is stably supported on the base and is not affected by condensed water existing in the base.

A fourth object of the present invention is to provide an integrated type air conditioner in which the structure of the reactor assembly is simplified and the assembling process can be simplified.

In order to achieve the above object, according to a first aspect of the present invention, there is provided an air conditioner comprising: a reactor bracket having a base engaging portion and a reactor seating portion coupled to an upper surface of a base of an air conditioner; And a reactor cover coupled to the reactor seating portion and having an interior space for receiving the reactor, wherein the base engagement portion includes a bracket extension extending upwardly from the base engagement portion toward the reactor seating portion, Additional portions are provided to provide a reactor assembly that allows the reactor to be spaced from the base.

In the second invention, the reactor seat portion extends in the horizontal direction, and the bracket extension portion extends in the vertical direction. That is, the reactor bracket may have a bent shape. In addition, the base coupling portion and the bracket extension portion are respectively disposed on both sides of the reactor seat portion.

In the third invention, the reactor includes a reactor plate for supporting the lower side of the reactor, and the reactor seating portion includes a reactor coupling portion to which the reactor plate is coupled. Particularly, the reactor coupling portion includes an insertion guide portion forming a space into which a part of the reactor plate is inserted.

The insertion guide portion may be formed by cutting a part of an upper surface of the reactor seat portion and extending upward. The reactor coupling portion may further include a reactor fastening hole in which the reactor plate is fastened by a fastening member.

In a fourth aspect of the present invention, the reactor seat portion includes a plate on which the reactor is mounted, and a cover support portion extending outward from the plate and supporting the reactor cover. At this time, the cover supporting portion includes a cover fastening hole to which the reactor cover is fastened by the fastening member.

A fifth invention is characterized in that the base includes a base plate on which the reactor assembly is seated, and a base extension portion extending upward from a rim of the base plate.

Particularly, the base includes a drain portion for allowing the upper portion of the base extension portion to be depressed downward to drain the condensed water present in the base to the outside. At this time, the height between the bottom surface of the base and the reactor seating part is higher than the height between the bottom surface of the base and the stepped surface of the drainage part.

According to the first aspect of the invention, since the reactor is disposed at a position spaced upward from the upper surface of the base, it is possible to prevent the condensed water stored in the base from acting on the reactor and causing erroneous operation of the reactor. Further, the phenomenon that the condensed water dropped from above the reactor assembly is prevented from penetrating into the inside of the reactor is prevented.

According to the second aspect of the present invention, the reactor bracket can be stably fixed to the upper surface of the base.

According to the third aspect of the present invention, the reactor can be stably supported on the reactor bracket. Further, the configuration of the reactor assembly can be simplified, and the assembling process can be simplified.

According to the fourth aspect of the present invention, the reactor cover for protecting the reactor can be stably supported on the reactor bracket.

According to the fifth aspect of the present invention, the condensed water stored in the base can be easily drained to the outside. That is, even if condensed water is present in the base, the condensed water is prevented from penetrating into the inside of the reactor.

1 is a view showing an air conditioner installed on a wall according to an embodiment of the present invention.
FIG. 2 is a perspective view showing an external configuration of an air conditioner according to an embodiment of the present invention. FIG.
3 is an exploded perspective view showing the configuration of an air conditioner according to an embodiment of the present invention.
4 is a perspective view showing the configuration of the main body of the air conditioner according to the embodiment of the present invention.
5 is a side view showing a configuration of the main body.
6 is an exploded perspective view showing a configuration of the main body part.
7 is a cross-sectional view taken along line VII-VII 'of FIG.
8 is a cross-sectional view taken along line VIII-VIII 'of FIG.
9 is a perspective view showing a configuration of a control box according to an embodiment of the present invention.
10 is an exploded perspective view showing the configuration of the control box.
11 is a perspective view showing a configuration of a reactor assembly according to an embodiment of the present invention.
12 is an exploded perspective view showing the configuration of the reactor assembly of FIG.
13 is a view showing the reactor assembly being seated on the base.
FIG. 14 is a view showing the reactor cover removed from the reactor assembly of FIG. 13; FIG.
Figure 15 is a view showing the reactor cover and the reactor removed in the reactor assembly of Figure 13;
Fig. 16 is a view showing the reactor assembly of Fig. 13 viewed from the direction " A ".
17 and 18 are perspective views showing the outward air flow A and the indoor air flow B according to the embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. It is to be understood, however, that the spirit of the invention is not limited to the embodiments shown and that those skilled in the art, upon reading and understanding the spirit of the invention, may easily suggest other embodiments within the scope of the same concept.

FIG. 1 is a view showing a state in which an air conditioner according to an embodiment of the present invention is installed on a wall, and FIG. 2 is a perspective view showing an external configuration of an air conditioner according to an embodiment of the present invention.

[Air conditioner installed on wall or window]

1, an integrated air conditioner 10 according to an embodiment of the present invention may be installed on a wall 1 or a window 2 of a building. For example, FIG. 1 shows a structure in which a wall 1 and a window 2 are provided, and the air conditioner 10 is installed by making a hole in the wall 1. Of course, unlike the drawings, the air conditioner 10 may be provided with an installation space in an area where the window 2 is located, so that the air conditioner 10 may be installed.

[case]

Referring to FIG. 2, the air conditioner 10 may have a substantially hexahedral shape. In detail, the air conditioner (10) includes a case (100) having a hexahedral shape with a front portion opened and forming an inner space. The case 100 is provided with a case side part 101 having an outdoor air intake part 102 through which outdoor air is sucked and a case 100 provided above the case side part 101 and emitting heat generated in the case 100 A case upper surface portion 103 having a heat dissipation port 104 may be included.

The case side portions 101 may be provided on both sides of the case 100 and the outdoor air intake portions 102 may be provided on the case side portions 101 on both sides.

The outdoor suction unit 102 may include a plurality of first through holes formed through at least a portion of the case side surface portion 101. The heat dissipation hole 104 may include a plurality of second through holes formed through at least a portion of the case upper surface 103.

The case upper surface portion 103 is provided with a mounting bracket 108 which can be installed on the wall surface 1 or the window 2. [ The air conditioner 10 can be supported on the wall surface 1 or the window 2 through the mounting bracket 108.

The front portion of the case side portion 101 may be located in the indoor space, and the rear portion may be located in the wall surface 1 or the outdoor space. The boundary line between the front portion and the rear portion is denoted by "L1" in Fig.

The rear portion of the case 100 may have a rear panel having an outdoor discharge portion 109 (see FIG. 13) through which outdoor air is discharged.

The case 100 further includes a case bottom 105 which constitutes a bottom surface of the case 100. The case bottom part 105 can receive the body part 120. For example, the base 121 of the main body 120 may be seated in the case bottom part 105.

[Front Panel]

The air conditioner 10 further includes a front panel 110 provided in front of the case 100 and having a plurality of indoor suction units 115 and 116 and a discharge unit 117.

The front panel 110 includes a panel front surface 111 forming a front surface of the air conditioner 10 and a panel side surface 112 extending rearward from opposite ends of the front surface 111 of the panel. And a panel bottom portion 113 extending rearward from a lower end of the panel front portion 111.

The plurality of indoor suction portions 115 and 116 include a first suction portion 115 formed on the panel side portion 112. The first suction part 115 may be formed on each of the panel side parts 112 on both sides. The panel side part 112 is provided with a first suction grill 115a and the first suction grill 115a defines the first suction part 115. [

The plurality of indoor suction units 115 and 116 include a second suction unit 116 formed on the panel bottom 113. A second suction grill 116a is provided on the panel bottom 113 and a second suction 116 is defined by the second suction grill 116a.

The discharge part 117 may be provided on the front panel 110. A discharge grill 117a is provided at an upper portion of the panel front portion 111 and the discharge grill 117a defines the discharge portion 117. [

The air sucked from both the left and right sides of the front panel 110 through the first suction part 115 and the air sucked from the lower part of the front panel 110 through the second suction part 116, After passing through the main body 120 provided in the inside of the main body 100, the air can be discharged to the front upper portion of the front panel 110 through the discharge portion 117.

A display unit 118 having a display unit for displaying operation information of the air conditioner 10 and an input unit for inputting an operation command may be disposed on the front panel 110. For example, the display device 118 may be positioned at the side of the discharge portion 117.

4 is a perspective view illustrating the configuration of the main body of the air conditioner according to the embodiment of the present invention. FIG. 5 is a sectional view of the main body of the air conditioner according to the embodiment of the present invention. And FIG. 6 is an exploded perspective view showing a configuration of the main body.

<Body part>

Referring to FIG. 3, the air conditioner 10 according to the embodiment of the present invention further includes a main body 120 provided inside the case 100. The main body 120 may be detachably coupled to the case 100. Therefore, the main body 120 can be separated from the case 100 for replacement or repair of parts.

The main body part includes a base 121, an outdoor main body part installed at the upper part of the base 121 and through which outdoor air flows, and an indoor main body part installed at the upper part of the base 121, . The outdoor-side body portion and the indoor-side body portion may be disposed on both sides with respect to the air guide 150. That is, outdoor air flows to one side and indoor air flows to the other side based on the air guide 150.

[Configuration of Outside Body Portion]

The outdoor main body portion includes a compressor 123, a gas-liquid separator 124, a condenser 130, a condensing fan 133, a shroud 135, and a fan motor 180. The outdoor main body unit is provided with a control box 200 as a component (control component) provided for inverter control of the air conditioner 10, for example, for controlling the compressor of the compressor 123 or the blowing fans 133, And a reactor assembly (300). The control box 200 may be referred to as a "first control component" and the reactor assembly 300 as a "second control component".

[Compressor and gas-liquid separator]

The compressor 123 includes an inverter compressor capable of adjusting the frequency. Therefore, when the cooling load of the air conditioner 10 is low, the frequency of the compressor 123 can be lowered, and when the cooling load is high, the frequency of the compressor 123 can be increased. For example, the compressor 123 may include a rotary compressor.

The compressor (123) is installed on the upper surface of the base (121). A sound insulating member 125 for reducing noise generated in the compressor 123 may be provided on the outer circumferential surface of the compressor 123. For example, the soundproofing member 125 may include a rubber, a sponge or a fiber material.

The gas-liquid separator 124 is provided at one side of the compressor 123 to separate the gaseous refrigerant from the refrigerant sucked into the compressor 123 and to guide the gaseous refrigerant to the compressor 123.

The compressor 123 may be disposed adjacent to the inner side surface of one of the two case side portions 101. The control box 200 and the reactor assembly 300 may be disposed adjacent to the inner side surfaces of the other case side portions 101 of the two case side portions 101.

[Condenser and condensing fan]

The condenser 130 is disposed inside the rear portion of the case 100. A first pipe assembly 131 is connected to one side of the condenser 130. The refrigerant compressed by the compressor 123 may be introduced into the condenser 130 through the first piping assembly 131.

The condenser 130 may be disposed so that air passing through the condensing fan 133 passes through the outdoor air based on the outdoor air flow. That is, the condenser 130 may be disposed at the outlet side of the condensing fan 133.

The condensing fan 133 may include an axial flow fan. The outdoor air sucked into the case 100 through the outdoor suction unit 102 formed on both sides of the case 100 is sucked in the axial direction of the condensing fan 133 and is discharged to the outside through the condensing fan 133 As shown in Fig. The outdoor air can be discharged to the outdoor space through the outdoor discharge portion 109 formed in the rear portion of the case 100.

[Shuraud]

The shroud 135 is coupled to the condensing fan 133 to guide the flow of air passing through the condensing fan 133. The shroud 135 is provided with a shroud opening 135a for guiding air to the suction side of the condensing fan 133. That is, outdoor air sucked into the case 100 through the outdoor suction unit 102 can be sucked into the condensing fan 133 through the shroud opening 135a. For example, the shroud opening 135a may have a circular shape and the condensing fan 133 may be configured to be inserted.

[Components for inverter control: control box]

The control box 200 may be disposed between the shroud 135 and the air guide 150. In detail, in the space between the shroud 135 and the air guide 150, an outdoor air passage 195 through which outdoor air flows is formed.

The control box 200 may be disposed above the outdoor air passage 195. According to this arrangement, the outdoor air sucked through the outdoor suction unit 102 passes through the control box 200 during the flow, and the control box 200, which generates high heat in this process, have. The detailed configuration of the control box 200 will be described later.

[fixed bracket]

The outdoor unit body further includes a fixing bracket 190 coupled to the control box 200. The fixing bracket 190 is disposed on the air guide 150 from the shroud 135 so that the control box 200 can be positioned between the shroud 135 and the air guide 150. [ As shown in FIG.

The control box 200 may be coupled to the upper portion of the shroud 135 and the upper portion of the air guide 150 by the fixing bracket 190. The shroud 135 is formed with a shroud fastening portion 135b and the air guide 150 is formed with an air guide fastening portion 150b.

Both side portions of the fixing bracket 190 are coupled to a box bracket 250 (see FIG. 9) provided on both sides of the control box 200, and the shroud fastening portion 135b and the air- And can be fastened to the portion 150b. That is, the fixing bracket 190 can be fastened to the control box 200, the shroud 135, and the air guide 150 at a time through the fastening member. According to this configuration, the control box 200 can be stably supported on the shroud 135 and the air guide 150.

[Components for inverter control: reactor assembly]

The reactor assembly 300 may be understood as an electronic device that stores electromagnetic energy and exhibits a reactivity that is highly inductive to a sudden change in current. The reactor assembly 300 may be installed on the base 121 and may be located on the lower side of the control box 200. The reactor assembly 300 is a device that generates high heat and requires cooling.

In detail, the reactor assembly 300 and the control box 200 may be disposed in the outdoor air passage 195. In other words, the control box 200 and the reactor assembly 300 may be arranged in the outdoor air passage 195 in the vertical direction. According to this configuration, the air in the upper part of the outdoor air flowing through the outdoor side air passage 195 can be radiated while passing through the control box 200, and the lower air passes through the reactor assembly 300 It is possible to radiate heat.

The control box 200 and the reactor assembly 300 are disposed in the outdoor air passage 195 and the outdoor air passage 195 is connected to the indoor air passage 195 by the air guide 150. [ The heat generated in the control box 200 or the reactor assembly 300 can be prevented from being transferred to the indoor space.

[Fan motor]

The fan motor 180 may be understood as a motor for imparting a rotational force to the blowing fans 133 and 160. That is, the fan motor 180 may be coupled to the condensing fan 133 and the evaporating fan 160 to rotate the condensing fan 133 and the evaporating fan 160 together.

The motor shaft 181 is coupled to the fan motor 180 and the motor shaft 181 may extend to both sides of the fan motor 180 through the fan motor 180. Both sides of the motor shaft 181 may be coupled to the condensing fan 133 and the evaporation fan 160. That is, the two fans 133 and 160 are connected to the motor shaft 181 of the fan motor 180. When the fan motor 180 is driven, the two fans 133 and 160 may rotate together.

For example, the fan motor 180 may include a BLDC motor capable of inverter control.

The fan motor 180 may be positioned substantially at the center of the space between the air guide 150 and the shroud 135 with respect to the vertical direction. That is, the fan motor 180 may be positioned in the space between the control box 200 and the reactor assembly 300 with respect to the vertical direction. With such a configuration, space utilization of the outdoor side body portion is improved, and it is possible to prevent the components constituting the outdoor side body portion from interfering with the air flow in the outdoor side air passage 195.

[Motor Mount]

The outdoor unit body further includes a motor mount 185 for supporting the fan motor 180. The motor mount 185 may be supported by the base 121 and protrude upward from the base 121. The motor mount 185 can reduce noise or vibration generated in the fan motor 180 from being transmitted to the base 121.

The fan motor 180 may be spaced upward from the base 121 by the motor mount 185 so that the condensed water present in the base 121 may penetrate the fan motor 180 .

[Configuration of Indoor Side Body]

The indoor unit includes an evaporator 140, an orifice 165, an evaporation fan 160, a discharge guide 170, a fan motor 180, and a motor mount 185.

[Evaporator and Evaporation Fan]

The evaporator 140 is disposed on the inner surface side of the front panel 110 so that indoor air sucked by the plurality of indoor suction units 115 and 116 can pass through. A second piping assembly 141 for guiding the flow of the refrigerant flowing into the evaporator 140 is connected to the evaporator 140. The second piping assembly 141 may include an expansion device for reducing the pressure of the refrigerant condensed in the condenser 130. In one example, the expansion device may include at least one of an expansion valve and a capillary tube.

The evaporation fan 160 may be disposed so that air passing through the evaporator 140 passes through the indoor air flow. That is, the evaporation fan 160 may be disposed at the outlet of the evaporator 140.

The evaporation fan 160 may include a centrifugal fan. The indoor air sucked into the case 100 through the plurality of indoor suction units 115 and 116 formed on both sides of the front panel 110 passes through the front surface of the evaporator 140 and flows backward And can be sucked in the axial direction of the evaporation fan 160. The indoor air can be discharged in the radial direction of the evaporation fan 160.

[Orifice]

The orifice 165 is coupled to the evaporation fan 160 to guide the flow of air passing through the evaporation fan 160. The orifice 165 includes an orifice opening 165a for guiding air to the suction side of the evaporation fan 160. That is, the room air cooled by the evaporator 160 can be sucked into the evaporation fan 160 through the orifice opening 165a. For example, the orifice opening 165a has a circular shape and may be disposed at a position corresponding to the front end of the evaporation fan 160. [

[Discharge Guide]

The discharge guide 170 guides the air that has passed through the evaporation fan 160 to the front panel 110 side, that is, the front side. For example, the discharge guide 170 may have a hollow panel or pipe shape, and a discharge passage through which the air having passed through the evaporation fan 160 passes may be formed therein.

A discharge portion 171 for discharging air to the discharge portion 117 of the front panel 110 is formed at a front portion of the discharge guide 170. The discharge portion 117 and the discharge portion 171 may be aligned in the front and rear directions.

Inside the discharge guide 170, a discharge guide 173 for guiding the flow direction of the air is provided. The discharge guide 173 has a plate shape and may be arranged to extend in the front and rear direction on the inner surface of the discharge guide 170. According to such a configuration, the air flowing through the discharge guide 170 can be stably flowed forward toward the discharge portion 117.

The discharge guide 170 may be coupled to a front surface of the air guide 150 to extend forward. Therefore, the air that has passed through the evaporation fan 160 can be guided toward the discharge guide 170 through the closed space in which the discharge guide 170 and the air guide 150 are formed.

The discharge guide 170 may be supported on the evaporator 140 and the orifice 165. The rear portion of the discharge guide 170 may be supported on the upper surface of the guide support portion 155 of the air guide 150. The guide support portion 155 can be understood as a portion projecting forward from the guide main body 151 of the air guide 150.

[Air Guide]

The air guide 150 functions as a partition plate for partitioning the outdoor main body portion and the indoor main body portion and separates the indoor air passage 191 and the outdoor air passage 195 from each other.

The front portion of the air guide 150 guides indoor air having passed through the evaporation fan 160 to the discharge guide 170. The rear portion of the air guide 150 guides the outdoor air sucked through the outdoor suction unit 102 to be sucked into the condensing fan 133.

The air guide portion 150 includes a guide body 151 for separating the indoor air passage 191 and the outdoor air passage 195 from each other. The guide body 151 may have an upper end which is supported by the base 121 and extends upward so as to engage or contact with the case upper surface portion 103 of the case 100.

The guide body 151 may be formed with an axial through-hole 151a (see FIG. 13) through which the motor shaft 181 passes. The shaft penetrating portion 151a may be formed at a substantially central portion of the guide body 151. [

The air guide part 150 further includes a guide support part 155 projecting forward from the guide main body 151. The discharge guide 170 may be supported on the upper surface of the guide support portion 155.

FIG. 7 is a cross-sectional view taken along the line VII-VII 'of FIG. 2, and FIG. 8 is a cross-sectional view taken along the line VIII-VIII' of FIG.

7 and 8, inside the case 100 according to the embodiment of the present invention, an indoor air passage 191 through which indoor air flows and an outdoor air passage 195 through which outdoor air flows . The indoor air passage 191 and the outdoor air passage 195 may be partitioned by the air guide 150 in the forward and backward directions.

Here, the term "front" means the direction in which the panel 110 is positioned from the air guide 150 in the previous year, and the term "rear" means the direction in which outdoor air is discharged from the air guide 150 (The direction in which the outdoor discharge portion is located).

[Indoor air flow]

The indoor air passage 191 is provided with an evaporator 140 for cooling the air, an evaporation fan 160 for generating a cooled air flow, and air passing through the evaporation fan 160, And a discharge guide 170 for guiding the discharge part 117 to the discharge part 117.

Specifically, the indoor air passage is provided with a first indoor-side flow passage through which the air sucked through the plurality of indoor suction portions 115 and 116 flows to the inflow side of the evaporator 140, that is, to the front side of the evaporator 140, The second indoor side flow path sucked in the axial direction of the evaporation fan 160 from the outflow side of the evaporator 140 and the air discharged in the radial direction of the evaporation fan 160 flow into the discharge guide 170 And a third indoor side flow path that flows to the discharge portion 117 of the front panel 110. [

[Outside air flow path]

The outdoor air passage 195 is provided with a condensing fan 133 for generating outdoor air sucking through the outdoor suction unit 102 and a fan for supplying driving force to the condensing fan 133 and the evaporation fan 160. [ A control box 200 and a reactor assembly (not shown) as a control part for controlling the operation of the motor 180 and the condenser 130 and the air conditioner 10 for condensing outdoor air passing through the fan motor 180 300).

The compressor 123 and the gas-liquid separator 124 may be further disposed in the outdoor air passage 195.

The outdoor air sucked through the one outdoor air intake part 102 of the outdoor air intake part 102 on both sides is cooled while passing through the control box 200 and the reactor assembly 300 A first outdoor outdoor side flow path which is sucked in the axial direction of the condensing fan 133 and a second outdoor outdoor flow path which discharges in the axial direction of the condensing fan 133 and passes through the condenser 130. [

The control box 200 and the reactor assembly 300 are disposed on the inner side of the case side surface portion 101 and allow the outdoor air having a relatively low temperature to pass through the outdoor air intake portion 102, The cooling effect of the control box 200 and the reactor assembly 300 can be improved. That is, the control box 200 and the reactor assembly 300 may be disposed on the upstream side of the condenser 133, based on the flow of outdoor air.

The control box 200 may be disposed above the outdoor air passage 195 and the reactor assembly 300 may be disposed below the outdoor air passage 195. Since the control box 200 and the reactor assembly 300 are spaced from each other and the cooling channels for cooling the control box 200 and the reactor assembly 300 do not affect each other, The cooling effect of the outdoor air flow can be further improved and the resistance of the outdoor air flow can be relatively reduced.

Other embodiments are suggested. Although the control box 200 is disposed above the outdoor air passage 195 and the reactor assembly 300 is disposed below the outdoor air passage 195 in the present embodiment, The control box 200 may be disposed below the outdoor air passage 195 and the reactor assembly 300 may be disposed above the outdoor air passage 195.

The heat radiating plate 235 of the control box 200 is positioned closer to the case side surface 101 than the elements 233 of the control box 200. Therefore, Can be performed more easily.

The outdoor air sucked through the other outdoor air intake part 102 of the outdoor air intake part 102 on both sides is disposed adjacent to the other outdoor air intake part 102 and installed in the outdoor air air flow path 195 And can pass through the compressor 123. In this process, the cooling effect of the compressor 123 can be obtained.

FIG. 9 is a perspective view showing a configuration of a control box according to an embodiment of the present invention, and FIG. 10 is an exploded perspective view showing the configuration of the control box.

<Control box>

9 and 10, a control box 200 according to an embodiment of the present invention includes a box case 210, a PCB support 220 coupled to the box case 210, 220 and a box cover 240 covering the upper side of the PCB assembly 230. The PCB assembly 230 includes a PCB cover 230,

[PCB Assembly]

The PCB assembly 230 includes a substantially rectangular PCB substrate 231 and elements 233 provided on the PCB substrate 231. The device 233 may be disposed on the bottom surface of the PCB substrate 231. The element 233 may include an exothermic component for inverter control of the air conditioner 10. For example, the heat generating component may further include a microcomputer, an inverter, a converter, an EEPROM, a rectifying diode, a capacitor, or the like.

The PCB assembly 230 further includes a heat dissipating plate 235 for dissipating heat generated from the PCB assembly 230 or the device 233. For example, the heat sink 235 may be provided on the bottom surface of the PCB 231. That is, the device 233 and the heat sink 235 may protrude downward from the PCB substrate 231.

The heat dissipation plate 235 includes a plurality of pins spaced apart from each other in the left-right direction. The plurality of fins may each have a rectangular, thin plate shape.

The outdoor air sucked through the outdoor suction unit 102 may flow through the PCB assembly 230 to cool the heat sink 235 while passing through the heat sink 235 first.

[PCB Support]

The control box 200 further includes a PCB support 220 provided below the PCB 231 to support the PCB 231. The PCB supporting part 220 includes a PCB coupling part 229 to which the PCB board 231 is screwed. The PCB coupling part 229 may be disposed on the PCB support part 220.

The PCB support part 220 includes a side part 221 and a support part 223 extending in the vertical direction. The side part 221 includes at least one wire guide 228 for guiding the position of a wire connected to the PCB assembly 230. The wire guide 228 includes a rib projecting from the side portion 221, and the rib may collect or hold the wire so that the wire does not move.

The support partition 223 is positioned between the element 233 and the heat sink 235 so that the outdoor air sucked through the outdoor suction unit 102 does not directly act on the element 233 As a blocking plate. Therefore, when the outdoor air having a high flow rate directly acts on the element 233, it is possible to prevent the malfunction of the PCB assembly 230 from being caused.

A first receiving portion 224 in which the device 233 is located is formed in a space between the side portion 221 and the support partition 223. A second accommodating part 225 may be formed between the support part 223 and the case side part 101 so that the heat sink 235 is positioned. With this configuration, space utilization for installation of the element 233 and the heat sink 235 can be improved.

[Box case]

The control box 200 further includes a box case 210 for providing a space for installing the device 233. The box case 210 may have the shape of a hexahedron whose upper surface is opened.

The box case 210 may be formed with a case heat dissipation hole 212 for discharging heat generated from the PCB assembly 230 to the outside. For example, the case heat dissipation hole 212 may include a through hole through which at least a part of the first surface of the box case 210 is inserted or cut.

The box case 210 includes an electric wire penetration part 214 through which electric wires connected to the PCB assembly 230 can be drawn out of the box case 210. For example, the wire penetration part 214 may be formed by recessing the upper part of the box case 210 downward. The box cover 240 may be coupled to the wire penetration part 214. The electric wire can be passed through the opening formed by the electric wire penetration part 214 and the box cover 240.

The box case 210 may be provided with a clamp 216. The clamp 216 may be configured to fix an electric wire drawn to the outside of the box case 210 through the electric wire penetration part 214. With the structure of the clamp 216, the electric wires can be easily arranged and the electric wire can be prevented from contacting the surface of the control box 200 which forms a relatively high temperature.

[Box bracket]

A box bracket 250 may be coupled to the control box 200. The box bracket 250 is provided on both sides of the control box 200, and the fixing bracket 190 is coupled to the box bracket 250. The box bracket 250 is formed with a coupling hole 252 to be coupled to the fixing bracket 190. For example, a predetermined screw may be inserted into the fastening hole 252 and fastened to the fixing bracket 190.

The predetermined screw is fastened to the shroud fastening portion 135b or the air guide fastening portion 150b so that the fastening bracket 190, the shroud 135, and the air guide 150 Can be fixed.

FIG. 11 is a perspective view showing the construction of the reactor assembly according to the embodiment of the present invention, and FIG. 12 is an exploded perspective view showing the construction of the reactor assembly of FIG.

<Reactor assembly>

Referring to FIGS. 11 and 12, an air conditioner 10 according to an embodiment of the present invention includes a reactor assembly 300. The reactor assembly 300 may be installed on the base 121 and may be located below the outdoor air passage 195, that is, below the control box 200.

The reactor assembly 300 includes a reactor bracket 330 supported on the base 121, a reactor 310 supported on the reactor bracket 330, and a reactor 310 coupled to the reactor bracket 330, And a reactor cover 320 as a "protecting member "

[Reactor Bracket]

The reactor assembly 300 includes a reactor bracket 330 disposed on one side of the base 121 and supporting the reactor 310. The reactor bracket 330 may be seated on the upper surface of the base 121. For example, the reactor bracket 330 may be formed of a metal material and welded to the base 121. Alternatively, the reactor bracket 330 may be formed of a plastic resin material and coupled to the base 121 by fastening members.

[Detailed configuration of reactor bracket: base coupling part and bracket extension part]

The reactor bracket 330 includes a base coupling portion 331 coupled to the base 121. The base coupling portion 331 may be fixed to the base 121 to support the reactor 310 and the reactor bracket 330. The base engaging portion 331 is formed with a weld portion 331a for welding to the base 121. [ Accordingly, the base coupling portion 331 can be fixed to the upper surface of the base 121 by welding. Of course, the base coupling portion 331 can be coupled to the base 121 by a coupling member, not a welding coupling.

In this embodiment, the base coupling portions 331 may be formed as a pair. That is, the pair of base coupling portions 331 may be disposed on both sides of the reactor bracket 330. Therefore, the base coupling part 331 can stably support the reactor bracket 330. [

The reactor bracket 330 further includes a bracket extension part 335 extending upward from the base coupling part 331. In this embodiment, the bracket extension portion 335 extends upward from the pair of base engaging portions 331 and is connected to both side portions of a reactor seating portion 333 to be described later. With such a configuration, the bracket extension portion 335 can separate the reactor seating portion 333 from the base 121 upward.

[Detailed configuration of reactor bracket: reactor seat part]

The reactor bracket 330 further includes a reactor seat 333 on which the reactor 310 is mounted.

In detail, the reactor seating portion 333 is provided with a plate 333a on which a reactor plate 312 to be described later is seated, and a cover support portion 333b extending outward from the plate 333a to support a reactor cover 320 (333b). For example, the reactor seating portion 333, the base coupling portion 331, and the bracket extending portion 335 may be integrally formed. That is, the reactor bracket 330 may be formed by bending a single body several times.

The plate 333a may extend in the lateral direction from the upper end of the bracket extension 335. For example, the plate 333a may have a substantially rectangular shape. Both sides of the plate 333a can be supported by the pair of bracket extension parts 335. [ Due to the structure of the reactor bracket 330, the reactor 310 can be disposed at a position spaced upward from the upper surface of the base 121, so that the condensed water stored in the base 121 flows into the reactor 310 to prevent the erroneous operation of the reactor 310 from occurring.

[Detailed configuration of reactor bracket: insertion guide]

The reactor bracket 330 further includes an insertion guide portion 332 into which a portion of the reactor 310 is inserted. The insertion guide portion 332 can be understood as a component for coupling the reactor 310 to the reactor bracket 330. For example, the insertion guide portion 332 may have a shape in which a part of the reactor seating portion 333 protrudes upward.

In detail, the insertion guide portion 332 is formed such that a part of the upper surface of the plate 333a is cut and protruded upward. The insertion guide portion 332 may have a shape with one side opened so as to insert a reactor plate 312 to be described later. That is, one side of the insertion guide portion 332 may be opened to form an insertion space 332a into which the reactor plate 312 is inserted.

In addition, the insertion guide portions 332 may be formed of a plurality of insertion guide portions 332. At this time, the plurality of insertion guide portions 332 may be spaced apart from each other at positions corresponding to the respective vertexes of the plate 333a.

[Detailed configuration of reactor bracket: Reactor fastening ball]

The reactor bracket 330 further includes a reactor fastening hole 336 to which the reactor 310 is fastened.

In detail, the reactor fastening hole 336 is formed by perforating the upper surface of the plate 333a. The reactor fastening hole 336 is disposed at a position corresponding to the fastening hole 312a formed in the reactor plate 312. [ For example, the predetermined screw may be continuously inserted through the fastening hole 312a and the reactor fastening hole 336 and may be fastened to the reactor bracket 330. [

The reactor fastening holes 336 may be a plurality of. The plurality of reactor fastening holes 336 may be spaced apart from each other at positions corresponding to respective vertexes of the plate 333a.

In the present embodiment, the insertion guide portion 332 is formed of two pieces, and the reactor fastening holes 336 may be formed of two pieces. At this time, the two insertion guiding portions 332 are disposed at positions corresponding to the two vertexes of the four vertexes of the plate 333a, and the two reactor fastening holes 336 are formed at four corners of the plate 333a Are arranged at points corresponding to the remaining two vertexes of the vertexes. With such a configuration, the reactor 310 can be stably coupled to the reactor bracket 330. In addition, since the reactor 310 is fastened at two places of the reactor bracket 330 by the fastening members and is inserted into the other two places in an insertion manner, the fastening operation is reduced, There is an effect of simplification.

[Detailed configuration of reactor bracket: Cover tightening ball]

The reactor bracket 330 further includes a cover fastening hole 337 to which the reactor cover 320 is fastened.

Specifically, the cover fastening hole 337 is formed on the upper surface of the cover supporting portion 333b. The cover fastening hole 337 is disposed at a position corresponding to the fastening hole 322a formed in the cover fastening portion 322 to be described later. For example, a predetermined screw may be continuously inserted through the fastening hole 322a and the cover fastening hole 336 and fastened to the reactor bracket 330.

The cover fastening holes 337 may be a plurality of. The plurality of cover fastening holes 337 may be spaced apart from each other at an edge portion of the reactor seating portion 333.

[Detailed configuration of reactor bracket: forming section]

The reactor bracket 330 further includes a forming unit 334 for reinforcing the strength of the reactor bracket 330. The forming portion 334 can be understood as a portion formed by forming a part of the reactor seating portion 333. For example, the forming section 334 may be formed downward from the reactor seating section 333. That is, the forming portion 334 is formed to be depressed downward from the upper surface of the reactor seating portion 333, so that the strength of the reactor bracket 330 can be improved without interfering with the seating of the reactor 310 .

[Reactor]

The reactor assembly 300 further includes a reactor 310 supported on the reactor bracket 330. The reactor 310 can be understood as an electronic device that stores electromagnetic energy and exhibits a reactivity that is highly inductive to a sudden change in current, as described above.

The reactor 310 may have a substantially hexahedral shape. The reactor 310 includes a reactor plate 312 supporting the lower side of the reactor 310. The reactor plate 312 may support the reactor 310 and may serve to install the reactor 310 on the reactor bracket 330. In one example, the reactor plate 312 may have a substantially rectangular plate shape. The reactor plate 312 may be disposed horizontally below the reactor 130.

The reactor plate 312 is formed with a fastening hole 312a to be fastened to the reactor bracket 330. For example, the predetermined screw may be continuously inserted through the fastening hole 312a and the reactor fastening hole 336 and may be fastened to the reactor bracket 330. [

The plurality of fastening holes 312a may be formed. The plurality of fastening holes 312a may be spaced apart from each other at positions corresponding to the respective vertexes of the reactor plate 312.

In addition, the reactor plate 312 includes an insertion portion 312b to be inserted into the insertion guide portion 332. [ The insertion portion 312b is formed to extend outwardly from one surface of the reactor plate 312. [ For example, the inserting portion 312b may extend in a horizontal direction at the rim of the reactor plate 312. For example, the insertion portion 312b may be disposed at a position corresponding to each vertex of the reactor plate 312.

[Reactor Cover]

The reactor assembly 300 further includes a reactor cover 320 coupled to the reactor bracket 330 and receiving the reactor 310 therein. The reactor cover 320 may have a substantially hexahedral shape with an opened lower surface. Inside the reactor cover 320, a space for accommodating the reactor 310 is formed. Further, the reactor cover 320 is disposed so as to surround the reactor plate 312.

The reactor cover 320 includes a cover fastening part 322 having a fastening hole 322a to be coupled to the reactor bracket 330. The cover fastening portion 322 is formed to extend in a horizontal direction from a lower portion of the reactor cover 320. For example, the cover fastening portions 322 may extend outwardly from both sides of the reactor cover 320. [

The reactor cover 320 includes an electric wire penetration part 325 through which electric wires connected to the reactor 310 can be drawn out to the outside of the reactor cover 320. For example, the wire penetration portion 325 may be formed by cutting the upper portion of the reactor cover 320 from the lower portion.

In addition, on the upper surface of the reactor cover 320, a drainage gradient may be formed to easily drain condensed water that is separated from the reactor cover 320. That is, the upper surface of the reactor cover 320 may be formed so as to prevent the condensed water falling on the upper surface of the reactor cover 320 from accumulating and to drain the condensed water in a predetermined direction. With this configuration, the condensed water scattered by the rotation of the condensing fan 133 is prevented from penetrating into the inside of the reactor 310, and the effect of facilitating the drainage without condensing water in the reactor cover 320 have.

[Assembly method of reactor assembly]

In the reactor assembly 300, the reactor 310 and the reactor cover 320 are assembled by being coupled to the reactor bracket 330.

In detail, the reactor 310 is seated on the reactor mounting portion 333 of the reactor bracket 330. At this time, the insertion portion 312b of the reactor plate 312 is inserted into the insertion space 332a formed by the insertion guide portion 332 of the reactor seat portion 333. That is, the two insertion portions 312b of the four insertion portions 312b formed in the reactor plate 312 are inserted into the insertion space 332a formed by the insertion guide portion 332, 310 may be fixed at one side thereof.

A plurality of fastening holes 312a formed in the reactor plate 312 and the reactor fastening holes 336 are continuously penetrated by a predetermined fastening member in a state where one side of the reactor 310 is fixed and the reactor brackets 330 ). With such a configuration, the reactor 310 can be firmly coupled to the reactor bracket 330.

The reactor cover 320 is finally assembled to the reactor bracket 330 in a state where the reactor 310 is assembled to the reactor bracket 330. That is, the fastening holes 322a formed in the reactor cover 320 and the cover fastening holes 337 are continuously penetrated through a predetermined fastening member and fastened to the reactor bracket 330. With such a configuration, the reactor cover 320 can be firmly fixed to the reactor bracket 330. Further, since the reactor assembly 300 is assembled using not only the fastening member by the fastening member, but also the fastening method by the insertion method, the fastening process using the fastening member is reduced and the assembling is facilitated.

13 is a view showing the reactor assembly being seated on the base.

[Reactor assembly installed on base]

Referring to FIG. 13, the reactor assembly 300 according to the embodiment of the present invention is installed in the base 121. That is, the reactor assembly 300 is assembled by the assembly method described above, and the assembled reactor assembly 300 is seated on the upper surface of the base 121.

[Base]

The base 121 includes a base plate for providing a surface on which the reactor assembly 300 is mounted. The base plate is formed so that its upper surface is entirely stepped. In addition, the base plate may receive a plurality of components included in the main body unit 120 as well as the reactor assembly 300. For example, the base plate may have a substantially rectangular shape.

[Detailed configuration of base: protrusion]

The base 121 includes a protrusion 126 protruding upward from the base plate. The protrusion 126 may define a space in which the components included in the main body 120 are installed, or may maintain a space between the components. For example, the protrusion 126 may be partially disposed on the upper surface of the plate, and the upper surface of the protrusion 126 may be formed flat.

In the present embodiment, the protrusion 126 includes a first upper surface 126a and a second upper surface 126b on which the reactor assembly 300 is mounted. The first upper surface 126a and the second upper surface 126b may have the same height and may be spaced apart from each other. That is, one side of the reactor assembly 300 is supported by the first upper surface 126a and the other side is supported by the second upper surface 126b. The reactor 310 may be disposed at a position spaced upward from the upper surface of the base 121 so that the condensed water stored in the base 121 acts on the reactor 310, It is possible to prevent the erroneous operation of the reactor 310 from being caused.

[Detailed configuration of base: base extension part]

The base 121 further includes a base extension 122 extending upward from the base plate.

Specifically, the base extension 122 extends upward from the rim of the base plate to a predetermined height. The base extension 122 may function as a partition to prevent condensate present in the base 121 from draining to the outside. That is, depending on the shape of the base extension part 122, the condensed water present in the base 121 can be accommodated for a certain amount without draining to the outside.

Although not shown, the base 121 may include a drain pump and a drain pipe for discharging the condensed water present in the base 121 to the outside. Therefore, the condensate present in the base 121 can be drained to the outside by the drain pump and the drain pipe.

[Detailed configuration of base: drainage part]

The base 121 further includes a drain 127 for draining the condensed water present in the base 121 to the outside. For example, the drain portion 127 may be formed such that an upper portion of the base extension portion 122 is depressed downward. According to this configuration, the drainage unit 127 can perform a drainage passage function to drain the condensed water to the outside when the condensed water is filled in the base 121 or when the condensed water exists in a certain amount or more.

FIG. 14 is a view showing a state where the reactor cover is removed from the reactor assembly of FIG. 13, FIG. 15 is a view showing the reactor cover and the reactor removed from the reactor assembly of FIG. 13, In the direction of &quot; A &quot;.

[How to Install Reactor Assembly]

Referring to FIGS. 14 and 15, the assembled reactor assembly 300 is disposed on the protrusion 126 of the base 121. The base engaging portion 331 disposed on one side of the reactor bracket 330 is positioned on the first upper surface 126a and the base engaging portion 331 disposed on the other side of the reactor bracket 330, Is positioned on the second upper surface 126b.

When the reactor bracket 330 is positioned on the first upper surface 126a and the second upper surface 126b, the respective welding portions 331a formed on the base coupling portion 331 are welded, (331) are fixed to the first upper surface (126a) and the second upper surface (126b), respectively. Accordingly, the reactor assembly 300 can be firmly fixed to the base 121.

16, the reactor seating portion 333 of the reactor bracket 330 is positioned higher than the height of the drain portion 127 formed in the base extending portion 122. As shown in FIG. That is, the height H1 between the bottom surface of the base 121 and the reactor seat 333 is higher than the height H2 between the bottom surface of the base 121 and the stepped surface of the drainage 127 . According to this configuration, since the reactor 310 is located at a position higher than the stepped surface of the drainage part 127, even if condensed water is present in the base 121, condensed water acts on the reactor 310, It is possible to prevent the erroneous operation of the first and second electrodes 310 and 310 from occurring.

The reactor assembly 330 is disposed on the protrusion 126 of the base 121 but the present invention is not limited thereto and the reactor assembly 330 may be disposed on the bottom surface of the base 121 Of course, be installed.

17 and 18 are perspective views showing the outward air flow A and the indoor air flow B according to the embodiment of the present invention.

17 and 18, when the air conditioner 10 according to the embodiment of the present invention is operated, the outdoor air flow A and the indoor air flow B are generated.

[Outside Air Flow (A)]

The outdoor air flow A is generated by driving the condensing fan 133. When the condensing fan 133 is driven, outdoor air can be sucked toward the inner center of the case 100 through the outdoor suction unit 102 provided in the two case side parts 101.

The outdoor air sucked into the case 100 through the one outdoor intake part 102 passes through the control box 200 and the reactor assembly 300 located adjacent to the case side part 101, 200 and the reactor assembly 300, respectively.

At this time, since the control box 200 and the reactor assembly 300 are located at the upper and lower portions of the outdoor air passage 195, a part of the drawn outdoor air cools the control box 200, May cool the reactor assembly 300. Therefore, since the cooler outdoor air cools the control box 200 and the reactor assembly 300, the cooling efficiency can be improved.

The outdoor air having passed through the control box 200 and the reactor assembly 300 is rearwardly turned and flows to the axial suction side of the condensing fan 133 to form a first outdoor side flow path.

The outdoor air passing through the condensing fan 133 flows through the axial discharge side of the condensing fan 133 and flows through the outdoor discharge unit 109 after passing through the condenser 130, The second outdoor-side flow path is formed.

[Room side air flow (B)]

The indoor air flow (B) is generated by driving the evaporation fan (160). When the evaporation fan 160 is driven, indoor air can be sucked toward the inner center of the case 100 through the plurality of indoor suction units 115 and 116.

The indoor air sucked into the evaporator 140 forms a first indoor-side flow path toward the inflow side of the evaporator 140 and flows from the outlet side of the evaporator 140 to the second indoor side Thereby forming a flow path.

The indoor air that has passed through the evaporation fan 160 is discharged in the radial direction of the evaporation fan 160 and flows into the third indoor side Thereby forming a flow path. The indoor air flowing inside the discharge guide 170 flows forward toward the front panel 110 and can be discharged to the indoor space through the discharge portion 117 of the front panel 110. [

10: air conditioner 100: case
102: outdoor suction unit 110: front panel
115: first suction portion 116: second suction portion
117: discharging portion 120:
130: condenser 133: condensing fan
140: Evaporator 150: Air guide
160: Evaporation fan 170: Discharge guide
180: Fan motor 190: Fixing bracket
200: Control box 300: Reactor assembly

Claims (16)

A reactor assembly installed in a base of an air conditioner,
A reactor bracket having a base engaging portion and a reactor seating portion coupled to an upper surface of the base;
A reactor supported by the reactor seat; And
A reactor cover coupled to the reactor seating portion and having an inner space for receiving the reactor,
The base coupling portion further comprising a bracket extension extending upwardly from the base coupling portion toward the reactor seating portion such that the reactor is spaced from the base. The method according to claim 1,
Wherein the reactor seating portion extends in a horizontal direction and the bracket extending portion extends in a vertical direction. 3. The method of claim 2,
Wherein the reactor bracket has a bent shape. The method of claim 3,
Wherein the base coupling portion and the bracket extension portion are disposed on both sides of the reactor seating portion, respectively. The method according to claim 1,
The reactor includes a reactor plate for supporting the lower side of the reactor,
Wherein the reactor seating portion includes a reactor coupling portion to which the reactor plate is coupled. 6. The method of claim 5,
Wherein the reactor coupling portion includes an insertion guide portion forming a space into which a portion of the reactor plate is inserted. The method according to claim 6,
Wherein the insertion guide comprises a top portion of the reactor seating portion cut away and extending upwardly. 6. The method of claim 5,
Wherein the reactor coupling portion further includes a reactor fastener that is fastened by the fastening member to the reactor plate. The method according to claim 6,
In the reactor plate,
A plate on which the reactor is seated; And
And an insertion portion extending outwardly from the plate, the insertion portion being inserted into a space formed by the insertion guide portion. The method according to claim 1,
In the reactor seat,
A plate on which the reactor is seated; And
And a cover support portion extending outwardly from the plate and supporting the reactor cover. 11. The method of claim 10,
Wherein the cover support portion includes a cover fastening hole to which the reactor cover is fastened by the fastening member. The method according to claim 1,
Wherein the reactor cover is formed in a polyhedral shape having an open bottom, and surrounds the reactor. The method according to claim 1,
In the base,
A base plate on which the reactor assembly is mounted; And
And a base extension extending upwardly from a rim of the base plate. 14. The method of claim 13,
Wherein the base is provided with a drainage portion for allowing the upper portion of the base extension to be depressed downward to drain the condensed water present in the base to the outside. 15. The method of claim 14,
Wherein the height H1 between the bottom surface of the base and the reactor seat is greater than the height H2 between the bottom surface of the base and the stepped surface of the drain. An integrated type air conditioner comprising the reactor assembly according to any one of claims 1 to 15.

Images